/* OpenBSC interface to quagga VTY */ /* (C) 2009-2010 by Harald Welte * All Rights Reserved * * 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. * * 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. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../bscconfig.h" /* FIXME: this should go to some common file */ static const struct value_string gprs_ns_timer_strs[] = { { 0, "tns-block" }, { 1, "tns-block-retries" }, { 2, "tns-reset" }, { 3, "tns-reset-retries" }, { 4, "tns-test" }, { 5, "tns-alive" }, { 6, "tns-alive-retries" }, { 0, NULL } }; static const struct value_string gprs_bssgp_cfg_strs[] = { { 0, "blocking-timer" }, { 1, "blocking-retries" }, { 2, "unblocking-retries" }, { 3, "reset-timer" }, { 4, "reset-retries" }, { 5, "suspend-timer" }, { 6, "suspend-retries" }, { 7, "resume-timer" }, { 8, "resume-retries" }, { 9, "capability-update-timer" }, { 10, "capability-update-retries" }, { 0, NULL } }; struct cmd_node net_node = { GSMNET_NODE, "%s(network)#", 1, }; struct cmd_node bts_node = { BTS_NODE, "%s(bts)#", 1, }; struct cmd_node trx_node = { TRX_NODE, "%s(trx)#", 1, }; struct cmd_node ts_node = { TS_NODE, "%s(ts)#", 1, }; extern struct gsm_network *bsc_gsmnet; struct gsm_network *gsmnet_from_vty(struct vty *v) { /* In case we read from the config file, the vty->priv cannot * point to a struct telnet_connection, and thus conn->priv * will not point to the gsm_network structure */ #if 0 struct telnet_connection *conn = v->priv; return (struct gsm_network *) conn->priv; #else return bsc_gsmnet; #endif } static int dummy_config_write(struct vty *v) { return CMD_SUCCESS; } static void net_dump_nmstate(struct vty *vty, struct gsm_nm_state *nms) { vty_out(vty,"Oper '%s', Admin %u, Avail '%s'%s", nm_opstate_name(nms->operational), nms->administrative, nm_avail_name(nms->availability), VTY_NEWLINE); } static void dump_pchan_load_vty(struct vty *vty, char *prefix, const struct pchan_load *pl) { int i; for (i = 0; i < ARRAY_SIZE(pl->pchan); i++) { const struct load_counter *lc = &pl->pchan[i]; unsigned int percent; if (lc->total == 0) continue; percent = (lc->used * 100) / lc->total; vty_out(vty, "%s%20s: %3u%% (%u/%u)%s", prefix, gsm_pchan_name(i), percent, lc->used, lc->total, VTY_NEWLINE); } } static void net_dump_vty(struct vty *vty, struct gsm_network *net) { struct pchan_load pl; vty_out(vty, "BSC is on Country Code %u, Network Code %u " "and has %u BTS%s", net->country_code, net->network_code, net->num_bts, VTY_NEWLINE); vty_out(vty, " Long network name: '%s'%s", net->name_long, VTY_NEWLINE); vty_out(vty, " Short network name: '%s'%s", net->name_short, VTY_NEWLINE); vty_out(vty, " Authentication policy: %s%s", gsm_auth_policy_name(net->auth_policy), VTY_NEWLINE); vty_out(vty, " Location updating reject cause: %u%s", net->reject_cause, VTY_NEWLINE); vty_out(vty, " Encryption: A5/%u%s", net->a5_encryption, VTY_NEWLINE); vty_out(vty, " NECI (TCH/H): %u%s", net->neci, VTY_NEWLINE); vty_out(vty, " RRLP Mode: %s%s", rrlp_mode_name(net->rrlp.mode), VTY_NEWLINE); vty_out(vty, " MM Info: %s%s", net->send_mm_info ? "On" : "Off", VTY_NEWLINE); vty_out(vty, " Handover: %s%s", net->handover.active ? "On" : "Off", VTY_NEWLINE); network_chan_load(&pl, net); vty_out(vty, " Current Channel Load:%s", VTY_NEWLINE); dump_pchan_load_vty(vty, " ", &pl); } DEFUN(show_net, show_net_cmd, "show network", SHOW_STR "Display information about a GSM NETWORK\n") { struct gsm_network *net = gsmnet_from_vty(vty); net_dump_vty(vty, net); return CMD_SUCCESS; } static void e1isl_dump_vty(struct vty *vty, struct e1inp_sign_link *e1l) { struct e1inp_line *line; if (!e1l) { vty_out(vty, " None%s", VTY_NEWLINE); return; } line = e1l->ts->line; vty_out(vty, " E1 Line %u, Type %s: Timeslot %u, Mode %s%s", line->num, line->driver->name, e1l->ts->num, e1inp_signtype_name(e1l->type), VTY_NEWLINE); vty_out(vty, " E1 TEI %u, SAPI %u%s", e1l->tei, e1l->sapi, VTY_NEWLINE); } static void bts_dump_vty(struct vty *vty, struct gsm_bts *bts) { struct pchan_load pl; vty_out(vty, "BTS %u is of %s type in band %s, has CI %u LAC %u, " "BSIC %u, TSC %u and %u TRX%s", bts->nr, btstype2str(bts->type), gsm_band_name(bts->band), bts->cell_identity, bts->location_area_code, bts->bsic, bts->tsc, bts->num_trx, VTY_NEWLINE); vty_out(vty, "Description: %s%s", bts->description ? bts->description : "(null)", VTY_NEWLINE); vty_out(vty, "MS Max power: %u dBm%s", bts->ms_max_power, VTY_NEWLINE); vty_out(vty, "Minimum Rx Level for Access: %i dBm%s", rxlev2dbm(bts->si_common.cell_sel_par.rxlev_acc_min), VTY_NEWLINE); vty_out(vty, "Cell Reselection Hysteresis: %u dBm%s", bts->si_common.cell_sel_par.cell_resel_hyst*2, VTY_NEWLINE); vty_out(vty, "RACH TX-Integer: %u%s", bts->si_common.rach_control.tx_integer, VTY_NEWLINE); vty_out(vty, "RACH Max transmissions: %u%s", rach_max_trans_raw2val(bts->si_common.rach_control.max_trans), VTY_NEWLINE); if (bts->si_common.rach_control.cell_bar) vty_out(vty, " CELL IS BARRED%s", VTY_NEWLINE); vty_out(vty, "System Information present: 0x%08x, static: 0x%08x%s", bts->si_valid, bts->si_mode_static, VTY_NEWLINE); if (is_ipaccess_bts(bts)) vty_out(vty, " Unit ID: %u/%u/0, OML Stream ID 0x%02x%s", bts->ip_access.site_id, bts->ip_access.bts_id, bts->oml_tei, VTY_NEWLINE); vty_out(vty, " NM State: "); net_dump_nmstate(vty, &bts->nm_state); vty_out(vty, " Site Mgr NM State: "); net_dump_nmstate(vty, &bts->site_mgr.nm_state); vty_out(vty, " Paging: FIXME pending requests, %u free slots%s", bts->paging.available_slots, VTY_NEWLINE); if (!is_ipaccess_bts(bts)) { vty_out(vty, " E1 Signalling Link:%s", VTY_NEWLINE); e1isl_dump_vty(vty, bts->oml_link); } /* FIXME: oml_link, chan_desc */ memset(&pl, 0, sizeof(pl)); bts_chan_load(&pl, bts); vty_out(vty, " Current Channel Load:%s", VTY_NEWLINE); dump_pchan_load_vty(vty, " ", &pl); } DEFUN(show_bts, show_bts_cmd, "show bts [number]", SHOW_STR "Display information about a BTS\n" "BTS number") { struct gsm_network *net = gsmnet_from_vty(vty); int bts_nr; if (argc != 0) { /* use the BTS number that the user has specified */ bts_nr = atoi(argv[0]); if (bts_nr > net->num_bts) { vty_out(vty, "%% can't find BTS '%s'%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts_dump_vty(vty, gsm_bts_num(net, bts_nr)); return CMD_SUCCESS; } /* print all BTS's */ for (bts_nr = 0; bts_nr < net->num_bts; bts_nr++) bts_dump_vty(vty, gsm_bts_num(net, bts_nr)); return CMD_SUCCESS; } /* utility functions */ static void parse_e1_link(struct gsm_e1_subslot *e1_link, const char *line, const char *ts, const char *ss) { e1_link->e1_nr = atoi(line); e1_link->e1_ts = atoi(ts); if (!strcmp(ss, "full")) e1_link->e1_ts_ss = 255; else e1_link->e1_ts_ss = atoi(ss); } static void config_write_e1_link(struct vty *vty, struct gsm_e1_subslot *e1_link, const char *prefix) { if (!e1_link->e1_ts) return; if (e1_link->e1_ts_ss == 255) vty_out(vty, "%se1 line %u timeslot %u sub-slot full%s", prefix, e1_link->e1_nr, e1_link->e1_ts, VTY_NEWLINE); else vty_out(vty, "%se1 line %u timeslot %u sub-slot %u%s", prefix, e1_link->e1_nr, e1_link->e1_ts, e1_link->e1_ts_ss, VTY_NEWLINE); } static void config_write_ts_single(struct vty *vty, struct gsm_bts_trx_ts *ts) { vty_out(vty, " timeslot %u%s", ts->nr, VTY_NEWLINE); if (ts->pchan != GSM_PCHAN_NONE) vty_out(vty, " phys_chan_config %s%s", gsm_pchan_name(ts->pchan), VTY_NEWLINE); vty_out(vty, " hopping enabled %u%s", ts->hopping.enabled, VTY_NEWLINE); if (ts->hopping.enabled) { unsigned int i; vty_out(vty, " hopping sequence-number %u%s", ts->hopping.hsn, VTY_NEWLINE); vty_out(vty, " hopping maio %u%s", ts->hopping.maio, VTY_NEWLINE); for (i = 0; i < ts->hopping.arfcns.data_len*8; i++) { if (!bitvec_get_bit_pos(&ts->hopping.arfcns, i)) continue; vty_out(vty, " hopping arfcn add %u%s", i, VTY_NEWLINE); } } else config_write_e1_link(vty, &ts->e1_link, " "); } static void config_write_trx_single(struct vty *vty, struct gsm_bts_trx *trx) { int i; vty_out(vty, " trx %u%s", trx->nr, VTY_NEWLINE); if (trx->description) vty_out(vty, " description %s%s", trx->description, VTY_NEWLINE); vty_out(vty, " rf_locked %u%s", trx->nm_state.administrative == NM_STATE_LOCKED ? 1 : 0, VTY_NEWLINE); vty_out(vty, " arfcn %u%s", trx->arfcn, VTY_NEWLINE); vty_out(vty, " nominal power %u%s", trx->nominal_power, VTY_NEWLINE); vty_out(vty, " max_power_red %u%s", trx->max_power_red, VTY_NEWLINE); config_write_e1_link(vty, &trx->rsl_e1_link, " rsl "); vty_out(vty, " rsl e1 tei %u%s", trx->rsl_tei, VTY_NEWLINE); for (i = 0; i < TRX_NR_TS; i++) config_write_ts_single(vty, &trx->ts[i]); } static void config_write_bts_gprs(struct vty *vty, struct gsm_bts *bts) { unsigned int i; vty_out(vty, " gprs mode %s%s", bts_gprs_mode_name(bts->gprs.mode), VTY_NEWLINE); if (bts->gprs.mode == BTS_GPRS_NONE) return; vty_out(vty, " gprs routing area %u%s", bts->gprs.rac, VTY_NEWLINE); vty_out(vty, " gprs cell bvci %u%s", bts->gprs.cell.bvci, VTY_NEWLINE); for (i = 0; i < ARRAY_SIZE(bts->gprs.cell.timer); i++) vty_out(vty, " gprs cell timer %s %u%s", get_value_string(gprs_bssgp_cfg_strs, i), bts->gprs.cell.timer[i], VTY_NEWLINE); vty_out(vty, " gprs nsei %u%s", bts->gprs.nse.nsei, VTY_NEWLINE); for (i = 0; i < ARRAY_SIZE(bts->gprs.nse.timer); i++) vty_out(vty, " gprs ns timer %s %u%s", get_value_string(gprs_ns_timer_strs, i), bts->gprs.nse.timer[i], VTY_NEWLINE); for (i = 0; i < ARRAY_SIZE(bts->gprs.nsvc); i++) { struct gsm_bts_gprs_nsvc *nsvc = &bts->gprs.nsvc[i]; struct in_addr ia; ia.s_addr = htonl(nsvc->remote_ip); vty_out(vty, " gprs nsvc %u nsvci %u%s", i, nsvc->nsvci, VTY_NEWLINE); vty_out(vty, " gprs nsvc %u local udp port %u%s", i, nsvc->local_port, VTY_NEWLINE); vty_out(vty, " gprs nsvc %u remote udp port %u%s", i, nsvc->remote_port, VTY_NEWLINE); vty_out(vty, " gprs nsvc %u remote ip %s%s", i, inet_ntoa(ia), VTY_NEWLINE); } } static void config_write_bts_single(struct vty *vty, struct gsm_bts *bts) { struct gsm_bts_trx *trx; int i; vty_out(vty, " bts %u%s", bts->nr, VTY_NEWLINE); vty_out(vty, " type %s%s", btstype2str(bts->type), VTY_NEWLINE); if (bts->description) vty_out(vty, " description %s%s", bts->description, VTY_NEWLINE); vty_out(vty, " band %s%s", gsm_band_name(bts->band), VTY_NEWLINE); vty_out(vty, " cell_identity %u%s", bts->cell_identity, VTY_NEWLINE); vty_out(vty, " location_area_code %u%s", bts->location_area_code, VTY_NEWLINE); vty_out(vty, " training_sequence_code %u%s", bts->tsc, VTY_NEWLINE); vty_out(vty, " base_station_id_code %u%s", bts->bsic, VTY_NEWLINE); vty_out(vty, " ms max power %u%s", bts->ms_max_power, VTY_NEWLINE); vty_out(vty, " cell reselection hysteresis %u%s", bts->si_common.cell_sel_par.cell_resel_hyst*2, VTY_NEWLINE); vty_out(vty, " rxlev access min %u%s", bts->si_common.cell_sel_par.rxlev_acc_min, VTY_NEWLINE); if (bts->si_common.chan_desc.t3212) vty_out(vty, " periodic location update %u%s", bts->si_common.chan_desc.t3212 * 10, VTY_NEWLINE); vty_out(vty, " channel allocator %s%s", bts->chan_alloc_reverse ? "descending" : "ascending", VTY_NEWLINE); vty_out(vty, " rach tx integer %u%s", bts->si_common.rach_control.tx_integer, VTY_NEWLINE); vty_out(vty, " rach max transmission %u%s", rach_max_trans_raw2val(bts->si_common.rach_control.max_trans), VTY_NEWLINE); if (bts->rach_b_thresh != -1) vty_out(vty, " rach nm busy threshold %u%s", bts->rach_b_thresh, VTY_NEWLINE); if (bts->rach_ldavg_slots != -1) vty_out(vty, " rach nm load average %u%s", bts->rach_ldavg_slots, VTY_NEWLINE); if (bts->si_common.rach_control.cell_bar) vty_out(vty, " cell barred 1%s", VTY_NEWLINE); if ((bts->si_common.rach_control.t2 & 0x4) == 0) vty_out(vty, " rach emergency call allowed 1%s", VTY_NEWLINE); for (i = SYSINFO_TYPE_1; i < _MAX_SYSINFO_TYPE; i++) { if (bts->si_mode_static & (1 << i)) { vty_out(vty, " system-information %s mode static%s", get_value_string(osmo_sitype_strs, i), VTY_NEWLINE); vty_out(vty, " system-information %s static %s%s", get_value_string(osmo_sitype_strs, i), hexdump_nospc(bts->si_buf[i], sizeof(bts->si_buf[i])), VTY_NEWLINE); } } if (is_ipaccess_bts(bts)) { vty_out(vty, " ip.access unit_id %u %u%s", bts->ip_access.site_id, bts->ip_access.bts_id, VTY_NEWLINE); vty_out(vty, " oml ip.access stream_id %u%s", bts->oml_tei, VTY_NEWLINE); } else { config_write_e1_link(vty, &bts->oml_e1_link, " oml "); vty_out(vty, " oml e1 tei %u%s", bts->oml_tei, VTY_NEWLINE); } config_write_bts_gprs(vty, bts); llist_for_each_entry(trx, &bts->trx_list, list) config_write_trx_single(vty, trx); } static int config_write_bts(struct vty *v) { struct gsm_network *gsmnet = gsmnet_from_vty(v); struct gsm_bts *bts; llist_for_each_entry(bts, &gsmnet->bts_list, list) config_write_bts_single(v, bts); return CMD_SUCCESS; } static int config_write_net(struct vty *vty) { struct gsm_network *gsmnet = gsmnet_from_vty(vty); vty_out(vty, "network%s", VTY_NEWLINE); vty_out(vty, " network country code %u%s", gsmnet->country_code, VTY_NEWLINE); vty_out(vty, " mobile network code %u%s", gsmnet->network_code, VTY_NEWLINE); vty_out(vty, " short name %s%s", gsmnet->name_short, VTY_NEWLINE); vty_out(vty, " long name %s%s", gsmnet->name_long, VTY_NEWLINE); vty_out(vty, " auth policy %s%s", gsm_auth_policy_name(gsmnet->auth_policy), VTY_NEWLINE); vty_out(vty, " location updating reject cause %u%s", gsmnet->reject_cause, VTY_NEWLINE); vty_out(vty, " encryption a5 %u%s", gsmnet->a5_encryption, VTY_NEWLINE); vty_out(vty, " neci %u%s", gsmnet->neci, VTY_NEWLINE); vty_out(vty, " rrlp mode %s%s", rrlp_mode_name(gsmnet->rrlp.mode), VTY_NEWLINE); vty_out(vty, " mm info %u%s", gsmnet->send_mm_info, VTY_NEWLINE); vty_out(vty, " handover %u%s", gsmnet->handover.active, VTY_NEWLINE); vty_out(vty, " handover window rxlev averaging %u%s", gsmnet->handover.win_rxlev_avg, VTY_NEWLINE); vty_out(vty, " handover window rxqual averaging %u%s", gsmnet->handover.win_rxqual_avg, VTY_NEWLINE); vty_out(vty, " handover window rxlev neighbor averaging %u%s", gsmnet->handover.win_rxlev_avg_neigh, VTY_NEWLINE); vty_out(vty, " handover power budget interval %u%s", gsmnet->handover.pwr_interval, VTY_NEWLINE); vty_out(vty, " handover power budget hysteresis %u%s", gsmnet->handover.pwr_hysteresis, VTY_NEWLINE); vty_out(vty, " handover maximum distance %u%s", gsmnet->handover.max_distance, VTY_NEWLINE); vty_out(vty, " timer t3101 %u%s", gsmnet->T3101, VTY_NEWLINE); vty_out(vty, " timer t3103 %u%s", gsmnet->T3103, VTY_NEWLINE); vty_out(vty, " timer t3105 %u%s", gsmnet->T3105, VTY_NEWLINE); vty_out(vty, " timer t3107 %u%s", gsmnet->T3107, VTY_NEWLINE); vty_out(vty, " timer t3109 %u%s", gsmnet->T3109, VTY_NEWLINE); vty_out(vty, " timer t3111 %u%s", gsmnet->T3111, VTY_NEWLINE); vty_out(vty, " timer t3113 %u%s", gsmnet->T3113, VTY_NEWLINE); vty_out(vty, " timer t3115 %u%s", gsmnet->T3115, VTY_NEWLINE); vty_out(vty, " timer t3117 %u%s", gsmnet->T3117, VTY_NEWLINE); vty_out(vty, " timer t3119 %u%s", gsmnet->T3119, VTY_NEWLINE); vty_out(vty, " timer t3141 %u%s", gsmnet->T3141, VTY_NEWLINE); return CMD_SUCCESS; } static void trx_dump_vty(struct vty *vty, struct gsm_bts_trx *trx) { vty_out(vty, "TRX %u of BTS %u is on ARFCN %u%s", trx->nr, trx->bts->nr, trx->arfcn, VTY_NEWLINE); vty_out(vty, "Description: %s%s", trx->description ? trx->description : "(null)", VTY_NEWLINE); vty_out(vty, " RF Nominal Power: %d dBm, reduced by %u dB, " "resulting BS power: %d dBm%s", trx->nominal_power, trx->max_power_red, trx->nominal_power - trx->max_power_red, VTY_NEWLINE); vty_out(vty, " NM State: "); net_dump_nmstate(vty, &trx->nm_state); vty_out(vty, " Baseband Transceiver NM State: "); net_dump_nmstate(vty, &trx->bb_transc.nm_state); if (is_ipaccess_bts(trx->bts)) { vty_out(vty, " ip.access stream ID: 0x%02x%s", trx->rsl_tei, VTY_NEWLINE); } else { vty_out(vty, " E1 Signalling Link:%s", VTY_NEWLINE); e1isl_dump_vty(vty, trx->rsl_link); } } DEFUN(show_trx, show_trx_cmd, "show trx [bts_nr] [trx_nr]", SHOW_STR "Display information about a TRX\n" "BTS Number\n" "TRX Number\n") { struct gsm_network *net = gsmnet_from_vty(vty); struct gsm_bts *bts = NULL; struct gsm_bts_trx *trx; int bts_nr, trx_nr; if (argc >= 1) { /* use the BTS number that the user has specified */ bts_nr = atoi(argv[0]); if (bts_nr >= net->num_bts) { vty_out(vty, "%% can't find BTS '%s'%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts = gsm_bts_num(net, bts_nr); } if (argc >= 2) { trx_nr = atoi(argv[1]); if (trx_nr >= bts->num_trx) { vty_out(vty, "%% can't find TRX '%s'%s", argv[1], VTY_NEWLINE); return CMD_WARNING; } trx = gsm_bts_trx_num(bts, trx_nr); trx_dump_vty(vty, trx); return CMD_SUCCESS; } if (bts) { /* print all TRX in this BTS */ for (trx_nr = 0; trx_nr < bts->num_trx; trx_nr++) { trx = gsm_bts_trx_num(bts, trx_nr); trx_dump_vty(vty, trx); } return CMD_SUCCESS; } for (bts_nr = 0; bts_nr < net->num_bts; bts_nr++) { bts = gsm_bts_num(net, bts_nr); for (trx_nr = 0; trx_nr < bts->num_trx; trx_nr++) { trx = gsm_bts_trx_num(bts, trx_nr); trx_dump_vty(vty, trx); } } return CMD_SUCCESS; } static void ts_dump_vty(struct vty *vty, struct gsm_bts_trx_ts *ts) { vty_out(vty, "Timeslot %u of TRX %u in BTS %u, phys cfg %s%s", ts->nr, ts->trx->nr, ts->trx->bts->nr, gsm_pchan_name(ts->pchan), VTY_NEWLINE); vty_out(vty, " NM State: "); net_dump_nmstate(vty, &ts->nm_state); if (!is_ipaccess_bts(ts->trx->bts)) vty_out(vty, " E1 Line %u, Timeslot %u, Subslot %u%s", ts->e1_link.e1_nr, ts->e1_link.e1_ts, ts->e1_link.e1_ts_ss, VTY_NEWLINE); } DEFUN(show_ts, show_ts_cmd, "show timeslot [bts_nr] [trx_nr] [ts_nr]", SHOW_STR "Display information about a TS\n" "BTS Number\n" "TRX Number\n" "Timeslot Number\n") { struct gsm_network *net = gsmnet_from_vty(vty); struct gsm_bts *bts; struct gsm_bts_trx *trx; struct gsm_bts_trx_ts *ts; int bts_nr, trx_nr, ts_nr; if (argc >= 1) { /* use the BTS number that the user has specified */ bts_nr = atoi(argv[0]); if (bts_nr >= net->num_bts) { vty_out(vty, "%% can't find BTS '%s'%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts = gsm_bts_num(net, bts_nr); } if (argc >= 2) { trx_nr = atoi(argv[1]); if (trx_nr >= bts->num_trx) { vty_out(vty, "%% can't find TRX '%s'%s", argv[1], VTY_NEWLINE); return CMD_WARNING; } trx = gsm_bts_trx_num(bts, trx_nr); } if (argc >= 3) { ts_nr = atoi(argv[2]); if (ts_nr >= TRX_NR_TS) { vty_out(vty, "%% can't find TS '%s'%s", argv[2], VTY_NEWLINE); return CMD_WARNING; } ts = &trx->ts[ts_nr]; ts_dump_vty(vty, ts); return CMD_SUCCESS; } for (bts_nr = 0; bts_nr < net->num_bts; bts_nr++) { bts = gsm_bts_num(net, bts_nr); for (trx_nr = 0; trx_nr < bts->num_trx; trx_nr++) { trx = gsm_bts_trx_num(bts, trx_nr); for (ts_nr = 0; ts_nr < TRX_NR_TS; ts_nr++) { ts = &trx->ts[ts_nr]; ts_dump_vty(vty, ts); } } } return CMD_SUCCESS; } static void subscr_dump_vty(struct vty *vty, struct gsm_subscriber *subscr) { vty_out(vty, " ID: %llu, Authorized: %d%s", subscr->id, subscr->authorized, VTY_NEWLINE); if (subscr->name) vty_out(vty, " Name: '%s'%s", subscr->name, VTY_NEWLINE); if (subscr->extension) vty_out(vty, " Extension: %s%s", subscr->extension, VTY_NEWLINE); if (subscr->imsi) vty_out(vty, " IMSI: %s%s", subscr->imsi, VTY_NEWLINE); if (subscr->tmsi != GSM_RESERVED_TMSI) vty_out(vty, " TMSI: %08X%s", subscr->tmsi, VTY_NEWLINE); vty_out(vty, " Use count: %u%s", subscr->use_count, VTY_NEWLINE); } static void meas_rep_dump_uni_vty(struct vty *vty, struct gsm_meas_rep_unidir *mru, const char *prefix, const char *dir) { vty_out(vty, "%s RXL-FULL-%s: %4d dBm, RXL-SUB-%s: %4d dBm ", prefix, dir, rxlev2dbm(mru->full.rx_lev), dir, rxlev2dbm(mru->sub.rx_lev)); vty_out(vty, "RXQ-FULL-%s: %d, RXQ-SUB-%s: %d%s", dir, mru->full.rx_qual, dir, mru->sub.rx_qual, VTY_NEWLINE); } static void meas_rep_dump_vty(struct vty *vty, struct gsm_meas_rep *mr, const char *prefix) { vty_out(vty, "%sMeasurement Report:%s", prefix, VTY_NEWLINE); vty_out(vty, "%s Flags: %s%s%s%s%s", prefix, mr->flags & MEAS_REP_F_UL_DTX ? "DTXu " : "", mr->flags & MEAS_REP_F_DL_DTX ? "DTXd " : "", mr->flags & MEAS_REP_F_FPC ? "FPC " : "", mr->flags & MEAS_REP_F_DL_VALID ? " " : "DLinval ", VTY_NEWLINE); if (mr->flags & MEAS_REP_F_MS_TO) vty_out(vty, "%s MS Timing Offset: %u%s", prefix, mr->ms_timing_offset, VTY_NEWLINE); if (mr->flags & MEAS_REP_F_MS_L1) vty_out(vty, "%s L1 MS Power: %u dBm, Timing Advance: %u%s", prefix, mr->ms_l1.pwr, mr->ms_l1.ta, VTY_NEWLINE); if (mr->flags & MEAS_REP_F_DL_VALID) meas_rep_dump_uni_vty(vty, &mr->dl, prefix, "dl"); meas_rep_dump_uni_vty(vty, &mr->ul, prefix, "ul"); } static void lchan_dump_full_vty(struct vty *vty, struct gsm_lchan *lchan) { int idx; vty_out(vty, "Lchan %u in Timeslot %u of TRX %u in BTS %u, Type %s%s", lchan->nr, lchan->ts->nr, lchan->ts->trx->nr, lchan->ts->trx->bts->nr, gsm_lchant_name(lchan->type), VTY_NEWLINE); vty_out(vty, " Connection: %u, State: %s%s", lchan->conn ? 1: 0, gsm_lchans_name(lchan->state), VTY_NEWLINE); vty_out(vty, " BS Power: %u dBm, MS Power: %u dBm%s", lchan->ts->trx->nominal_power - lchan->ts->trx->max_power_red - lchan->bs_power*2, ms_pwr_dbm(lchan->ts->trx->bts->band, lchan->ms_power), VTY_NEWLINE); if (lchan->conn && lchan->conn->subscr) { vty_out(vty, " Subscriber:%s", VTY_NEWLINE); subscr_dump_vty(vty, lchan->conn->subscr); } else vty_out(vty, " No Subscriber%s", VTY_NEWLINE); if (is_ipaccess_bts(lchan->ts->trx->bts)) { struct in_addr ia; ia.s_addr = htonl(lchan->abis_ip.bound_ip); vty_out(vty, " Bound IP: %s Port %u RTP_TYPE2=%u CONN_ID=%u%s", inet_ntoa(ia), lchan->abis_ip.bound_port, lchan->abis_ip.rtp_payload2, lchan->abis_ip.conn_id, VTY_NEWLINE); } /* we want to report the last measurement report */ idx = calc_initial_idx(ARRAY_SIZE(lchan->meas_rep), lchan->meas_rep_idx, 1); meas_rep_dump_vty(vty, &lchan->meas_rep[idx], " "); } static void lchan_dump_short_vty(struct vty *vty, struct gsm_lchan *lchan) { struct gsm_meas_rep *mr; int idx; /* we want to report the last measurement report */ idx = calc_initial_idx(ARRAY_SIZE(lchan->meas_rep), lchan->meas_rep_idx, 1); mr = &lchan->meas_rep[idx]; vty_out(vty, "Lchan: %u Timeslot: %u TRX: %u BTS: %u Type: %s - L1 MS Power: %u dBm " "RXL-FULL-dl: %4d dBm RXL-FULL-ul: %4d dBm%s", lchan->nr, lchan->ts->nr, lchan->ts->trx->nr, lchan->ts->trx->bts->nr, gsm_lchant_name(lchan->type), mr->ms_l1.pwr, rxlev2dbm(mr->dl.full.rx_lev), rxlev2dbm(mr->ul.full.rx_lev), VTY_NEWLINE); } static int lchan_summary(struct vty *vty, int argc, const char **argv, void (*dump_cb)(struct vty *, struct gsm_lchan *)) { struct gsm_network *net = gsmnet_from_vty(vty); struct gsm_bts *bts; struct gsm_bts_trx *trx; struct gsm_bts_trx_ts *ts; struct gsm_lchan *lchan; int bts_nr, trx_nr, ts_nr, lchan_nr; if (argc >= 1) { /* use the BTS number that the user has specified */ bts_nr = atoi(argv[0]); if (bts_nr >= net->num_bts) { vty_out(vty, "%% can't find BTS %s%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts = gsm_bts_num(net, bts_nr); } if (argc >= 2) { trx_nr = atoi(argv[1]); if (trx_nr >= bts->num_trx) { vty_out(vty, "%% can't find TRX %s%s", argv[1], VTY_NEWLINE); return CMD_WARNING; } trx = gsm_bts_trx_num(bts, trx_nr); } if (argc >= 3) { ts_nr = atoi(argv[2]); if (ts_nr >= TRX_NR_TS) { vty_out(vty, "%% can't find TS %s%s", argv[2], VTY_NEWLINE); return CMD_WARNING; } ts = &trx->ts[ts_nr]; } if (argc >= 4) { lchan_nr = atoi(argv[3]); if (lchan_nr >= TS_MAX_LCHAN) { vty_out(vty, "%% can't find LCHAN %s%s", argv[3], VTY_NEWLINE); return CMD_WARNING; } lchan = &ts->lchan[lchan_nr]; dump_cb(vty, lchan); return CMD_SUCCESS; } for (bts_nr = 0; bts_nr < net->num_bts; bts_nr++) { bts = gsm_bts_num(net, bts_nr); for (trx_nr = 0; trx_nr < bts->num_trx; trx_nr++) { trx = gsm_bts_trx_num(bts, trx_nr); for (ts_nr = 0; ts_nr < TRX_NR_TS; ts_nr++) { ts = &trx->ts[ts_nr]; for (lchan_nr = 0; lchan_nr < TS_MAX_LCHAN; lchan_nr++) { lchan = &ts->lchan[lchan_nr]; if (lchan->type == GSM_LCHAN_NONE) continue; dump_cb(vty, lchan); } } } } return CMD_SUCCESS; } DEFUN(show_lchan, show_lchan_cmd, "show lchan [bts_nr] [trx_nr] [ts_nr] [lchan_nr]", SHOW_STR "Display information about a logical channel\n" "BTS Number\n" "TRX Number\n" "Timeslot Number\n" "Logical Channel Number\n") { return lchan_summary(vty, argc, argv, lchan_dump_full_vty); } DEFUN(show_lchan_summary, show_lchan_summary_cmd, "show lchan summary [bts_nr] [trx_nr] [ts_nr] [lchan_nr]", SHOW_STR "Display information about a logical channel\n" "BTS Number\n" "TRX Number\n" "Timeslot Number\n" "Logical Channel Number\n") { return lchan_summary(vty, argc, argv, lchan_dump_short_vty); } static void e1drv_dump_vty(struct vty *vty, struct e1inp_driver *drv) { vty_out(vty, "E1 Input Driver %s%s", drv->name, VTY_NEWLINE); } DEFUN(show_e1drv, show_e1drv_cmd, "show e1_driver", SHOW_STR "Display information about available E1 drivers\n") { struct e1inp_driver *drv; llist_for_each_entry(drv, &e1inp_driver_list, list) e1drv_dump_vty(vty, drv); return CMD_SUCCESS; } static void e1line_dump_vty(struct vty *vty, struct e1inp_line *line) { vty_out(vty, "E1 Line Number %u, Name %s, Driver %s%s", line->num, line->name ? line->name : "", line->driver->name, VTY_NEWLINE); } DEFUN(show_e1line, show_e1line_cmd, "show e1_line [line_nr]", SHOW_STR "Display information about a E1 line\n" "E1 Line Number\n") { struct e1inp_line *line; if (argc >= 1) { int num = atoi(argv[0]); llist_for_each_entry(line, &e1inp_line_list, list) { if (line->num == num) { e1line_dump_vty(vty, line); return CMD_SUCCESS; } } return CMD_WARNING; } llist_for_each_entry(line, &e1inp_line_list, list) e1line_dump_vty(vty, line); return CMD_SUCCESS; } static void e1ts_dump_vty(struct vty *vty, struct e1inp_ts *ts) { if (ts->type == E1INP_TS_TYPE_NONE) return; vty_out(vty, "E1 Timeslot %2u of Line %u is Type %s%s", ts->num, ts->line->num, e1inp_tstype_name(ts->type), VTY_NEWLINE); } DEFUN(show_e1ts, show_e1ts_cmd, "show e1_timeslot [line_nr] [ts_nr]", SHOW_STR "Display information about a E1 timeslot\n" "E1 Line Number\n" "E1 Timeslot Number\n") { struct e1inp_line *line = NULL; struct e1inp_ts *ts; int ts_nr; if (argc == 0) { llist_for_each_entry(line, &e1inp_line_list, list) { for (ts_nr = 0; ts_nr < NUM_E1_TS; ts_nr++) { ts = &line->ts[ts_nr]; e1ts_dump_vty(vty, ts); } } return CMD_SUCCESS; } if (argc >= 1) { int num = atoi(argv[0]); llist_for_each_entry(line, &e1inp_line_list, list) { if (line->num == num) break; } if (!line || line->num != num) { vty_out(vty, "E1 line %s is invalid%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } } if (argc >= 2) { ts_nr = atoi(argv[1]); if (ts_nr > NUM_E1_TS) { vty_out(vty, "E1 timeslot %s is invalid%s", argv[1], VTY_NEWLINE); return CMD_WARNING; } ts = &line->ts[ts_nr]; e1ts_dump_vty(vty, ts); return CMD_SUCCESS; } else { for (ts_nr = 0; ts_nr < NUM_E1_TS; ts_nr++) { ts = &line->ts[ts_nr]; e1ts_dump_vty(vty, ts); } return CMD_SUCCESS; } return CMD_SUCCESS; } static void paging_dump_vty(struct vty *vty, struct gsm_paging_request *pag) { vty_out(vty, "Paging on BTS %u%s", pag->bts->nr, VTY_NEWLINE); subscr_dump_vty(vty, pag->subscr); } static void bts_paging_dump_vty(struct vty *vty, struct gsm_bts *bts) { struct gsm_paging_request *pag; llist_for_each_entry(pag, &bts->paging.pending_requests, entry) paging_dump_vty(vty, pag); } DEFUN(show_paging, show_paging_cmd, "show paging [bts_nr]", SHOW_STR "Display information about paging reuqests of a BTS\n" "BTS Number\n") { struct gsm_network *net = gsmnet_from_vty(vty); struct gsm_bts *bts; int bts_nr; if (argc >= 1) { /* use the BTS number that the user has specified */ bts_nr = atoi(argv[0]); if (bts_nr >= net->num_bts) { vty_out(vty, "%% can't find BTS %s%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts = gsm_bts_num(net, bts_nr); bts_paging_dump_vty(vty, bts); return CMD_SUCCESS; } for (bts_nr = 0; bts_nr < net->num_bts; bts_nr++) { bts = gsm_bts_num(net, bts_nr); bts_paging_dump_vty(vty, bts); } return CMD_SUCCESS; } #define NETWORK_STR "Configure the GSM network\n" DEFUN(cfg_net, cfg_net_cmd, "network", NETWORK_STR) { vty->index = gsmnet_from_vty(vty); vty->node = GSMNET_NODE; return CMD_SUCCESS; } DEFUN(cfg_net_ncc, cfg_net_ncc_cmd, "network country code <1-999>", "Set the GSM network country code") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->country_code = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_mnc, cfg_net_mnc_cmd, "mobile network code <1-999>", "Set the GSM mobile network code") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->network_code = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_name_short, cfg_net_name_short_cmd, "short name NAME", "Set the short GSM network name") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); if (gsmnet->name_short) talloc_free(gsmnet->name_short); gsmnet->name_short = talloc_strdup(gsmnet, argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_name_long, cfg_net_name_long_cmd, "long name NAME", "Set the long GSM network name") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); if (gsmnet->name_long) talloc_free(gsmnet->name_long); gsmnet->name_long = talloc_strdup(gsmnet, argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_auth_policy, cfg_net_auth_policy_cmd, "auth policy (closed|accept-all|token)", "Authentication (not cryptographic)\n" "Set the GSM network authentication policy\n" "Require the MS to be activated in HLR\n" "Accept all MS, whether in HLR or not\n" "Use SMS-token based authentication\n") { enum gsm_auth_policy policy = gsm_auth_policy_parse(argv[0]); struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->auth_policy = policy; return CMD_SUCCESS; } DEFUN(cfg_net_reject_cause, cfg_net_reject_cause_cmd, "location updating reject cause <2-111>", "Set the reject cause of location updating reject\n") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->reject_cause = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_encryption, cfg_net_encryption_cmd, "encryption a5 (0|1|2)", "Encryption options\n" "A5 encryption\n" "A5/0: No encryption\n" "A5/1: Encryption\n" "A5/2: Export-grade Encryption\n") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->a5_encryption= atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_neci, cfg_net_neci_cmd, "neci (0|1)", "New Establish Cause Indication\n" "Don't set the NECI bit\n" "Set the NECI bit\n") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->neci = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_rrlp_mode, cfg_net_rrlp_mode_cmd, "rrlp mode (none|ms-based|ms-preferred|ass-preferred)", "Radio Resource Location Protocol\n" "Set the Radio Resource Location Protocol Mode\n" "Don't send RRLP request\n" "Request MS-based location\n" "Request any location, prefer MS-based\n" "Request any location, prefer MS-assisted\n") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->rrlp.mode = rrlp_mode_parse(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_mm_info, cfg_net_mm_info_cmd, "mm info (0|1)", "Whether to send MM INFO after LOC UPD ACCEPT") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->send_mm_info = atoi(argv[0]); return CMD_SUCCESS; } #define HANDOVER_STR "Handover Options\n" DEFUN(cfg_net_handover, cfg_net_handover_cmd, "handover (0|1)", HANDOVER_STR "Don't perform in-call handover\n" "Perform in-call handover\n") { int enable = atoi(argv[0]); struct gsm_network *gsmnet = gsmnet_from_vty(vty); if (enable && ipacc_rtp_direct) { vty_out(vty, "%% Cannot enable handover unless RTP Proxy mode " "is enabled by using the -P command line option%s", VTY_NEWLINE); return CMD_WARNING; } gsmnet->handover.active = enable; return CMD_SUCCESS; } #define HO_WIN_STR HANDOVER_STR "Measurement Window\n" #define HO_WIN_RXLEV_STR HO_WIN_STR "Received Level Averaging\n" #define HO_WIN_RXQUAL_STR HO_WIN_STR "Received Quality Averaging\n" #define HO_PBUDGET_STR HANDOVER_STR "Power Budget\n" DEFUN(cfg_net_ho_win_rxlev_avg, cfg_net_ho_win_rxlev_avg_cmd, "handover window rxlev averaging <1-10>", HO_WIN_RXLEV_STR "How many RxLev measurements are used for averaging") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.win_rxlev_avg = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_ho_win_rxqual_avg, cfg_net_ho_win_rxqual_avg_cmd, "handover window rxqual averaging <1-10>", HO_WIN_RXQUAL_STR "How many RxQual measurements are used for averaging") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.win_rxqual_avg = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_ho_win_rxlev_neigh_avg, cfg_net_ho_win_rxlev_avg_neigh_cmd, "handover window rxlev neighbor averaging <1-10>", HO_WIN_RXLEV_STR "How many RxQual measurements are used for averaging") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.win_rxlev_avg_neigh = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_ho_pwr_interval, cfg_net_ho_pwr_interval_cmd, "handover power budget interval <1-99>", HO_PBUDGET_STR "How often to check if we have a better cell (SACCH frames)") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.pwr_interval = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_ho_pwr_hysteresis, cfg_net_ho_pwr_hysteresis_cmd, "handover power budget hysteresis <0-999>", HO_PBUDGET_STR "How many dB does a neighbor to be stronger to become a HO candidate") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.pwr_hysteresis = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_net_ho_max_distance, cfg_net_ho_max_distance_cmd, "handover maximum distance <0-9999>", HANDOVER_STR "How big is the maximum timing advance before HO is forced") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); gsmnet->handover.max_distance = atoi(argv[0]); return CMD_SUCCESS; } #define DECLARE_TIMER(number, doc) \ DEFUN(cfg_net_T##number, \ cfg_net_T##number##_cmd, \ "timer t" #number " <0-65535>", \ "Configure GSM Timers\n" \ doc) \ { \ struct gsm_network *gsmnet = gsmnet_from_vty(vty); \ int value = atoi(argv[0]); \ \ if (value < 0 || value > 65535) { \ vty_out(vty, "Timer value %s out of range.%s", \ argv[0], VTY_NEWLINE); \ return CMD_WARNING; \ } \ \ gsmnet->T##number = value; \ return CMD_SUCCESS; \ } DECLARE_TIMER(3101, "Set the timeout value for IMMEDIATE ASSIGNMENT.") DECLARE_TIMER(3103, "Set the timeout value for HANDOVER.") DECLARE_TIMER(3105, "Currently not used.") DECLARE_TIMER(3107, "Currently not used.") DECLARE_TIMER(3109, "Currently not used.") DECLARE_TIMER(3111, "Set the RSL timeout to wait before releasing the RF Channel.") DECLARE_TIMER(3113, "Set the time to try paging a subscriber.") DECLARE_TIMER(3115, "Currently not used.") DECLARE_TIMER(3117, "Currently not used.") DECLARE_TIMER(3119, "Currently not used.") DECLARE_TIMER(3141, "Currently not used.") /* per-BTS configuration */ DEFUN(cfg_bts, cfg_bts_cmd, "bts BTS_NR", "Select a BTS to configure\n" "BTS Number\n") { struct gsm_network *gsmnet = gsmnet_from_vty(vty); int bts_nr = atoi(argv[0]); struct gsm_bts *bts; if (bts_nr > gsmnet->num_bts) { vty_out(vty, "%% The next unused BTS number is %u%s", gsmnet->num_bts, VTY_NEWLINE); return CMD_WARNING; } else if (bts_nr == gsmnet->num_bts) { /* allocate a new one */ bts = gsm_bts_alloc(gsmnet, GSM_BTS_TYPE_UNKNOWN, HARDCODED_TSC, HARDCODED_BSIC); } else bts = gsm_bts_num(gsmnet, bts_nr); if (!bts) { vty_out(vty, "%% Unable to allocate BTS %u%s", gsmnet->num_bts, VTY_NEWLINE); return CMD_WARNING; } vty->index = bts; vty->index_sub = &bts->description; vty->node = BTS_NODE; return CMD_SUCCESS; } DEFUN(cfg_bts_type, cfg_bts_type_cmd, "type TYPE", "Set the BTS type\n") { struct gsm_bts *bts = vty->index; int rc; rc = gsm_set_bts_type(bts, parse_btstype(argv[0])); if (rc < 0) return CMD_WARNING; return CMD_SUCCESS; } DEFUN(cfg_bts_band, cfg_bts_band_cmd, "band BAND", "Set the frequency band of this BTS\n") { struct gsm_bts *bts = vty->index; int band = gsm_band_parse(argv[0]); if (band < 0) { vty_out(vty, "%% BAND %d is not a valid GSM band%s", band, VTY_NEWLINE); return CMD_WARNING; } bts->band = band; return CMD_SUCCESS; } DEFUN(cfg_bts_ci, cfg_bts_ci_cmd, "cell_identity <0-65535>", "Set the Cell identity of this BTS\n") { struct gsm_bts *bts = vty->index; int ci = atoi(argv[0]); if (ci < 0 || ci > 0xffff) { vty_out(vty, "%% CI %d is not in the valid range (0-65535)%s", ci, VTY_NEWLINE); return CMD_WARNING; } bts->cell_identity = ci; return CMD_SUCCESS; } DEFUN(cfg_bts_lac, cfg_bts_lac_cmd, "location_area_code <0-65535>", "Set the Location Area Code (LAC) of this BTS\n") { struct gsm_bts *bts = vty->index; int lac = atoi(argv[0]); if (lac < 0 || lac > 0xffff) { vty_out(vty, "%% LAC %d is not in the valid range (0-65535)%s", lac, VTY_NEWLINE); return CMD_WARNING; } if (lac == GSM_LAC_RESERVED_DETACHED || lac == GSM_LAC_RESERVED_ALL_BTS) { vty_out(vty, "%% LAC %d is reserved by GSM 04.08%s", lac, VTY_NEWLINE); return CMD_WARNING; } bts->location_area_code = lac; return CMD_SUCCESS; } DEFUN(cfg_bts_tsc, cfg_bts_tsc_cmd, "training_sequence_code <0-255>", "Set the Training Sequence Code (TSC) of this BTS\n") { struct gsm_bts *bts = vty->index; int tsc = atoi(argv[0]); if (tsc < 0 || tsc > 0xff) { vty_out(vty, "%% TSC %d is not in the valid range (0-255)%s", tsc, VTY_NEWLINE); return CMD_WARNING; } bts->tsc = tsc; return CMD_SUCCESS; } DEFUN(cfg_bts_bsic, cfg_bts_bsic_cmd, "base_station_id_code <0-63>", "Set the Base Station Identity Code (BSIC) of this BTS\n") { struct gsm_bts *bts = vty->index; int bsic = atoi(argv[0]); if (bsic < 0 || bsic > 0x3f) { vty_out(vty, "%% BSIC %d is not in the valid range (0-255)%s", bsic, VTY_NEWLINE); return CMD_WARNING; } bts->bsic = bsic; return CMD_SUCCESS; } DEFUN(cfg_bts_unit_id, cfg_bts_unit_id_cmd, "ip.access unit_id <0-65534> <0-255>", "Set the ip.access BTS Unit ID of this BTS\n") { struct gsm_bts *bts = vty->index; int site_id = atoi(argv[0]); int bts_id = atoi(argv[1]); if (!is_ipaccess_bts(bts)) { vty_out(vty, "%% BTS is not of ip.access type%s", VTY_NEWLINE); return CMD_WARNING; } bts->ip_access.site_id = site_id; bts->ip_access.bts_id = bts_id; return CMD_SUCCESS; } #define OML_STR "Organization & Maintenance Link\n" #define IPA_STR "ip.access Specific Options\n" DEFUN(cfg_bts_stream_id, cfg_bts_stream_id_cmd, "oml ip.access stream_id <0-255>", OML_STR IPA_STR "Set the ip.access Stream ID of the OML link of this BTS\n") { struct gsm_bts *bts = vty->index; int stream_id = atoi(argv[0]); if (!is_ipaccess_bts(bts)) { vty_out(vty, "%% BTS is not of ip.access type%s", VTY_NEWLINE); return CMD_WARNING; } bts->oml_tei = stream_id; return CMD_SUCCESS; } #define OML_E1_STR OML_STR "E1 Line\n" DEFUN(cfg_bts_oml_e1, cfg_bts_oml_e1_cmd, "oml e1 line E1_LINE timeslot <1-31> sub-slot (0|1|2|3|full)", OML_E1_STR "E1 interface to be used for OML\n") { struct gsm_bts *bts = vty->index; parse_e1_link(&bts->oml_e1_link, argv[0], argv[1], argv[2]); return CMD_SUCCESS; } DEFUN(cfg_bts_oml_e1_tei, cfg_bts_oml_e1_tei_cmd, "oml e1 tei <0-63>", OML_E1_STR "Set the TEI to be used for OML") { struct gsm_bts *bts = vty->index; bts->oml_tei = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_challoc, cfg_bts_challoc_cmd, "channel allocator (ascending|descending)", "Channnel Allocator\n" "Channel Allocator\n" "Allocate Timeslots and Transceivers in ascending order\n" "Allocate Timeslots and Transceivers in descending order\n") { struct gsm_bts *bts = vty->index; if (!strcmp(argv[0], "ascending")) bts->chan_alloc_reverse = 0; else bts->chan_alloc_reverse = 1; return CMD_SUCCESS; } #define RACH_STR "Random Access Control Channel\n" DEFUN(cfg_bts_rach_tx_integer, cfg_bts_rach_tx_integer_cmd, "rach tx integer <0-15>", RACH_STR "Set the raw tx integer value in RACH Control parameters IE") { struct gsm_bts *bts = vty->index; bts->si_common.rach_control.tx_integer = atoi(argv[0]) & 0xf; return CMD_SUCCESS; } DEFUN(cfg_bts_rach_max_trans, cfg_bts_rach_max_trans_cmd, "rach max transmission (1|2|4|7)", RACH_STR "Set the maximum number of RACH burst transmissions") { struct gsm_bts *bts = vty->index; bts->si_common.rach_control.max_trans = rach_max_trans_val2raw(atoi(argv[0])); return CMD_SUCCESS; } #define NM_STR "Network Management\n" DEFUN(cfg_bts_rach_nm_b_thresh, cfg_bts_rach_nm_b_thresh_cmd, "rach nm busy threshold <0-255>", RACH_STR NM_STR "Set the NM Busy Threshold in dB") { struct gsm_bts *bts = vty->index; bts->rach_b_thresh = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_rach_nm_ldavg, cfg_bts_rach_nm_ldavg_cmd, "rach nm load average <0-65535>", RACH_STR NM_STR "Set the NM Loadaverage Slots value") { struct gsm_bts *bts = vty->index; bts->rach_ldavg_slots = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_cell_barred, cfg_bts_cell_barred_cmd, "cell barred (0|1)", "Should this cell be barred from access?") { struct gsm_bts *bts = vty->index; bts->si_common.rach_control.cell_bar = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_rach_ec_allowed, cfg_bts_rach_ec_allowed_cmd, "rach emergency call allowed (0|1)", "Should this cell allow emergency calls?") { struct gsm_bts *bts = vty->index; if (atoi(argv[0]) == 0) bts->si_common.rach_control.t2 |= 0x4; else bts->si_common.rach_control.t2 &= ~0x4; return CMD_SUCCESS; } DEFUN(cfg_bts_ms_max_power, cfg_bts_ms_max_power_cmd, "ms max power <0-40>", "Maximum transmit power of the MS") { struct gsm_bts *bts = vty->index; bts->ms_max_power = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_cell_resel_hyst, cfg_bts_cell_resel_hyst_cmd, "cell reselection hysteresis <0-14>", "Cell Re-Selection Hysteresis in dB") { struct gsm_bts *bts = vty->index; bts->si_common.cell_sel_par.cell_resel_hyst = atoi(argv[0])/2; return CMD_SUCCESS; } DEFUN(cfg_bts_rxlev_acc_min, cfg_bts_rxlev_acc_min_cmd, "rxlev access min <0-63>", "Minimum RxLev needed for cell access (better than -110dBm)") { struct gsm_bts *bts = vty->index; bts->si_common.cell_sel_par.rxlev_acc_min = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_per_loc_upd, cfg_bts_per_loc_upd_cmd, "periodic location update <0-1530>", "Periodic Location Updating Interval in Minutes") { struct gsm_bts *bts = vty->index; bts->si_common.chan_desc.t3212 = atoi(argv[0]) / 10; return CMD_SUCCESS; } #define GPRS_TEXT "GPRS Packet Network\n" DEFUN(cfg_bts_prs_bvci, cfg_bts_gprs_bvci_cmd, "gprs cell bvci <2-65535>", GPRS_TEXT "GPRS Cell Settings\n" "GPRS BSSGP VC Identifier") { struct gsm_bts *bts = vty->index; if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.cell.bvci = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_nsei, cfg_bts_gprs_nsei_cmd, "gprs nsei <0-65535>", GPRS_TEXT "GPRS NS Entity Identifier") { struct gsm_bts *bts = vty->index; if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.nse.nsei = atoi(argv[0]); return CMD_SUCCESS; } #define NSVC_TEXT "Network Service Virtual Connection (NS-VC)\n" \ "NSVC Logical Number\n" DEFUN(cfg_bts_gprs_nsvci, cfg_bts_gprs_nsvci_cmd, "gprs nsvc <0-1> nsvci <0-65535>", GPRS_TEXT NSVC_TEXT "NS Virtual Connection Identifier\n" "GPRS NS VC Identifier") { struct gsm_bts *bts = vty->index; int idx = atoi(argv[0]); if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.nsvc[idx].nsvci = atoi(argv[1]); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_nsvc_lport, cfg_bts_gprs_nsvc_lport_cmd, "gprs nsvc <0-1> local udp port <0-65535>", GPRS_TEXT NSVC_TEXT "GPRS NS Local UDP Port") { struct gsm_bts *bts = vty->index; int idx = atoi(argv[0]); if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.nsvc[idx].local_port = atoi(argv[1]); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_nsvc_rport, cfg_bts_gprs_nsvc_rport_cmd, "gprs nsvc <0-1> remote udp port <0-65535>", GPRS_TEXT NSVC_TEXT "GPRS NS Remote UDP Port") { struct gsm_bts *bts = vty->index; int idx = atoi(argv[0]); if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.nsvc[idx].remote_port = atoi(argv[1]); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_nsvc_rip, cfg_bts_gprs_nsvc_rip_cmd, "gprs nsvc <0-1> remote ip A.B.C.D", GPRS_TEXT NSVC_TEXT "GPRS NS Remote IP Address") { struct gsm_bts *bts = vty->index; int idx = atoi(argv[0]); struct in_addr ia; if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } inet_aton(argv[1], &ia); bts->gprs.nsvc[idx].remote_ip = ntohl(ia.s_addr); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_ns_timer, cfg_bts_gprs_ns_timer_cmd, "gprs ns timer " NS_TIMERS " <0-255>", GPRS_TEXT "Network Service\n" "Network Service Timer\n" NS_TIMERS_HELP "Timer Value\n") { struct gsm_bts *bts = vty->index; int idx = get_string_value(gprs_ns_timer_strs, argv[0]); int val = atoi(argv[1]); if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } if (idx < 0 || idx >= ARRAY_SIZE(bts->gprs.nse.timer)) return CMD_WARNING; bts->gprs.nse.timer[idx] = val; return CMD_SUCCESS; } #define BSSGP_TIMERS "(blocking-timer|blocking-retries|unblocking-retries|reset-timer|reset-retries|suspend-timer|suspend-retries|resume-timer|resume-retries|capability-update-timer|capability-update-retries)" #define BSSGP_TIMERS_HELP \ "Tbvc-block timeout\n" \ "Tbvc-block retries\n" \ "Tbvc-unblock retries\n" \ "Tbvcc-reset timeout\n" \ "Tbvc-reset retries\n" \ "Tbvc-suspend timeout\n" \ "Tbvc-suspend retries\n" \ "Tbvc-resume timeout\n" \ "Tbvc-resume retries\n" \ "Tbvc-capa-update timeout\n" \ "Tbvc-capa-update retries\n" DEFUN(cfg_bts_gprs_cell_timer, cfg_bts_gprs_cell_timer_cmd, "gprs cell timer " BSSGP_TIMERS " <0-255>", GPRS_TEXT "Cell / BSSGP\n" "Cell/BSSGP Timer\n" BSSGP_TIMERS_HELP "Timer Value\n") { struct gsm_bts *bts = vty->index; int idx = get_string_value(gprs_bssgp_cfg_strs, argv[0]); int val = atoi(argv[1]); if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } if (idx < 0 || idx >= ARRAY_SIZE(bts->gprs.cell.timer)) return CMD_WARNING; bts->gprs.cell.timer[idx] = val; return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_rac, cfg_bts_gprs_rac_cmd, "gprs routing area <0-255>", GPRS_TEXT "GPRS Routing Area Code") { struct gsm_bts *bts = vty->index; if (bts->gprs.mode == BTS_GPRS_NONE) { vty_out(vty, "%% GPRS not enabled on this BTS%s", VTY_NEWLINE); return CMD_WARNING; } bts->gprs.rac = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_bts_gprs_mode, cfg_bts_gprs_mode_cmd, "gprs mode (none|gprs|egprs)", GPRS_TEXT "GPRS Mode for this BTS\n" "GPRS Disabled on this BTS\n" "GPRS Enabled on this BTS\n" "EGPRS (EDGE) Enabled on this BTS\n") { struct gsm_bts *bts = vty->index; enum bts_gprs_mode mode = bts_gprs_mode_parse(argv[0]); if (mode != BTS_GPRS_NONE && !gsm_bts_has_feature(bts, BTS_FEAT_GPRS)) { vty_out(vty, "This BTS type does not support %s%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } if (mode == BTS_GPRS_EGPRS && !gsm_bts_has_feature(bts, BTS_FEAT_EGPRS)) { vty_out(vty, "This BTS type does not support %s%s", argv[0], VTY_NEWLINE); return CMD_WARNING; } bts->gprs.mode = mode; return CMD_SUCCESS; } #define SI_TEXT "System Information Messages\n" #define SI_TYPE_TEXT "(1|2|3|4|5|6|7|8|9|10|13|16|17|18|19|20|2bis|2ter|2quater|5bis|5ter)" #define SI_TYPE_HELP "System Information Type 1\n" \ "System Information Type 2\n" \ "System Information Type 3\n" \ "System Information Type 4\n" \ "System Information Type 5\n" \ "System Information Type 6\n" \ "System Information Type 7\n" \ "System Information Type 8\n" \ "System Information Type 9\n" \ "System Information Type 10\n" \ "System Information Type 13\n" \ "System Information Type 16\n" \ "System Information Type 17\n" \ "System Information Type 18\n" \ "System Information Type 19\n" \ "System Information Type 20\n" \ "System Information Type 2bis\n" \ "System Information Type 2ter\n" \ "System Information Type 2quater\n" \ "System Information Type 5bis\n" \ "System Information Type 5ter\n" DEFUN(cfg_bts_si_mode, cfg_bts_si_mode_cmd, "system-information " SI_TYPE_TEXT " mode (static|computed)", SI_TEXT SI_TYPE_HELP "System Information Mode\n" "Static user-specified\n" "Dynamic, BSC-computed\n") { struct gsm_bts *bts = vty->index; int type; type = get_string_value(osmo_sitype_strs, argv[0]); if (type < 0) { vty_out(vty, "Error SI Type%s", VTY_NEWLINE); return CMD_WARNING; } if (!strcmp(argv[1], "static")) bts->si_mode_static |= (1 << type); else bts->si_mode_static &= ~(1 << type); return CMD_SUCCESS; } DEFUN(cfg_bts_si_static, cfg_bts_si_static_cmd, "system-information " SI_TYPE_TEXT " static HEXSTRING", SI_TEXT SI_TYPE_HELP "Static System Information filling\n" "Static user-specified SI content in HEX notation\n") { struct gsm_bts *bts = vty->index; int rc, type; type = get_string_value(osmo_sitype_strs, argv[0]); if (type < 0) { vty_out(vty, "Error SI Type%s", VTY_NEWLINE); return CMD_WARNING; } if (!(bts->si_mode_static & (1 << type))) { vty_out(vty, "SI Type %s is not configured in static mode%s", get_value_string(osmo_sitype_strs, type), VTY_NEWLINE); return CMD_WARNING; } /* Fill buffer with padding pattern */ memset(bts->si_buf[type], 0x2b, sizeof(bts->si_buf[type])); /* Parse the user-specified SI in hex format, [partially] overwriting padding */ rc = hexparse(argv[1], bts->si_buf[type], sizeof(bts->si_buf[0])); if (rc < 0 || rc > sizeof(bts->si_buf[0])) { vty_out(vty, "Error parsing HEXSTRING%s", VTY_NEWLINE); return CMD_WARNING; } /* Mark this SI as present */ bts->si_valid |= (1 << type); return CMD_SUCCESS; } #define TRX_TEXT "Radio Transceiver\n" /* per TRX configuration */ DEFUN(cfg_trx, cfg_trx_cmd, "trx TRX_NR", TRX_TEXT "Select a TRX to configure") { int trx_nr = atoi(argv[0]); struct gsm_bts *bts = vty->index; struct gsm_bts_trx *trx; if (trx_nr > bts->num_trx) { vty_out(vty, "%% The next unused TRX number in this BTS is %u%s", bts->num_trx, VTY_NEWLINE); return CMD_WARNING; } else if (trx_nr == bts->num_trx) { /* we need to allocate a new one */ trx = gsm_bts_trx_alloc(bts); } else trx = gsm_bts_trx_num(bts, trx_nr); if (!trx) return CMD_WARNING; vty->index = trx; vty->index_sub = &trx->description; vty->node = TRX_NODE; return CMD_SUCCESS; } DEFUN(cfg_trx_arfcn, cfg_trx_arfcn_cmd, "arfcn <0-1024>", "Set the ARFCN for this TRX\n") { int arfcn = atoi(argv[0]); struct gsm_bts_trx *trx = vty->index; /* FIXME: check if this ARFCN is supported by this TRX */ trx->arfcn = arfcn; /* FIXME: patch ARFCN into SYSTEM INFORMATION */ /* FIXME: use OML layer to update the ARFCN */ /* FIXME: use RSL layer to update SYSTEM INFORMATION */ return CMD_SUCCESS; } DEFUN(cfg_trx_nominal_power, cfg_trx_nominal_power_cmd, "nominal power <0-100>", "Nominal TRX RF Power in dB\n") { struct gsm_bts_trx *trx = vty->index; trx->nominal_power = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_trx_max_power_red, cfg_trx_max_power_red_cmd, "max_power_red <0-100>", "Reduction of maximum BS RF Power in dB\n") { int maxpwr_r = atoi(argv[0]); struct gsm_bts_trx *trx = vty->index; int upper_limit = 24; /* default 12.21 max power red. */ /* FIXME: check if our BTS type supports more than 12 */ if (maxpwr_r < 0 || maxpwr_r > upper_limit) { vty_out(vty, "%% Power %d dB is not in the valid range%s", maxpwr_r, VTY_NEWLINE); return CMD_WARNING; } if (maxpwr_r & 1) { vty_out(vty, "%% Power %d dB is not an even value%s", maxpwr_r, VTY_NEWLINE); return CMD_WARNING; } trx->max_power_red = maxpwr_r; /* FIXME: make sure we update this using OML */ return CMD_SUCCESS; } DEFUN(cfg_trx_rsl_e1, cfg_trx_rsl_e1_cmd, "rsl e1 line E1_LINE timeslot <1-31> sub-slot (0|1|2|3|full)", "E1 interface to be used for RSL\n") { struct gsm_bts_trx *trx = vty->index; parse_e1_link(&trx->rsl_e1_link, argv[0], argv[1], argv[2]); return CMD_SUCCESS; } DEFUN(cfg_trx_rsl_e1_tei, cfg_trx_rsl_e1_tei_cmd, "rsl e1 tei <0-63>", "Set the TEI to be used for RSL") { struct gsm_bts_trx *trx = vty->index; trx->rsl_tei = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_trx_rf_locked, cfg_trx_rf_locked_cmd, "rf_locked (0|1)", "Turn off RF of the TRX.\n") { int locked = atoi(argv[0]); struct gsm_bts_trx *trx = vty->index; gsm_trx_lock_rf(trx, locked); return CMD_SUCCESS; } /* per TS configuration */ DEFUN(cfg_ts, cfg_ts_cmd, "timeslot <0-7>", "Select a Timeslot to configure") { int ts_nr = atoi(argv[0]); struct gsm_bts_trx *trx = vty->index; struct gsm_bts_trx_ts *ts; if (ts_nr >= TRX_NR_TS) { vty_out(vty, "%% A GSM TRX only has %u Timeslots per TRX%s", TRX_NR_TS, VTY_NEWLINE); return CMD_WARNING; } ts = &trx->ts[ts_nr]; vty->index = ts; vty->node = TS_NODE; return CMD_SUCCESS; } DEFUN(cfg_ts_pchan, cfg_ts_pchan_cmd, "phys_chan_config PCHAN", "Physical Channel configuration (TCH/SDCCH/...)") { struct gsm_bts_trx_ts *ts = vty->index; int pchanc; pchanc = gsm_pchan_parse(argv[0]); if (pchanc < 0) return CMD_WARNING; ts->pchan = pchanc; return CMD_SUCCESS; } #define HOPPING_STR "Configure frequency hopping\n" DEFUN(cfg_ts_hopping, cfg_ts_hopping_cmd, "hopping enabled (0|1)", HOPPING_STR "Enable or disable frequency hopping\n" "Disable frequency hopping\n" "Enable frequency hopping\n") { struct gsm_bts_trx_ts *ts = vty->index; int enabled = atoi(argv[0]); if (enabled && !gsm_bts_has_feature(ts->trx->bts, BTS_FEAT_HOPPING)) { vty_out(vty, "BTS model does not support hopping%s", VTY_NEWLINE); return CMD_WARNING; } ts->hopping.enabled = enabled; return CMD_SUCCESS; } DEFUN(cfg_ts_hsn, cfg_ts_hsn_cmd, "hopping sequence-number <0-63>", HOPPING_STR "Which hopping sequence to use for this channel") { struct gsm_bts_trx_ts *ts = vty->index; ts->hopping.hsn = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_ts_maio, cfg_ts_maio_cmd, "hopping maio <0-63>", HOPPING_STR "Which hopping MAIO to use for this channel") { struct gsm_bts_trx_ts *ts = vty->index; ts->hopping.maio = atoi(argv[0]); return CMD_SUCCESS; } DEFUN(cfg_ts_arfcn_add, cfg_ts_arfcn_add_cmd, "hopping arfcn add <0-1023>", HOPPING_STR "Configure hopping ARFCN list\n" "Add an entry to the hopping ARFCN list\n" "ARFCN\n") { struct gsm_bts_trx_ts *ts = vty->index; int arfcn = atoi(argv[0]); bitvec_set_bit_pos(&ts->hopping.arfcns, arfcn, 1); return CMD_SUCCESS; } DEFUN(cfg_ts_arfcn_del, cfg_ts_arfcn_del_cmd, "hopping arfcn del <0-1023>", HOPPING_STR "Configure hopping ARFCN list\n" "Delete an entry to the hopping ARFCN list\n" "ARFCN\n") { struct gsm_bts_trx_ts *ts = vty->index; int arfcn = atoi(argv[0]); bitvec_set_bit_pos(&ts->hopping.arfcns, arfcn, 0); return CMD_SUCCESS; } DEFUN(cfg_ts_e1_subslot, cfg_ts_e1_subslot_cmd, "e1 line E1_LINE timeslot <1-31> sub-slot (0|1|2|3|full)", "E1 sub-slot connected to this on-air timeslot") { struct gsm_bts_trx_ts *ts = vty->index; parse_e1_link(&ts->e1_link, argv[0], argv[1], argv[2]); return CMD_SUCCESS; } void openbsc_vty_print_statistics(struct vty *vty, struct gsm_network *net) { vty_out(vty, "Channel Requests : %lu total, %lu no channel%s", counter_get(net->stats.chreq.total), counter_get(net->stats.chreq.no_channel), VTY_NEWLINE); vty_out(vty, "Channel Failures : %lu rf_failures, %lu rll failures%s", counter_get(net->stats.chan.rf_fail), counter_get(net->stats.chan.rll_err), VTY_NEWLINE); vty_out(vty, "Paging : %lu attempted, %lu complete, %lu expired%s", counter_get(net->stats.paging.attempted), counter_get(net->stats.paging.completed), counter_get(net->stats.paging.expired), VTY_NEWLINE); vty_out(vty, "BTS failures : %lu OML, %lu RSL%s", counter_get(net->stats.bts.oml_fail), counter_get(net->stats.bts.rsl_fail), VTY_NEWLINE); } DEFUN(logging_fltr_imsi, logging_fltr_imsi_cmd, "logging filter imsi IMSI", LOGGING_STR FILTER_STR "Filter log messages by IMSI\n" "IMSI to be used as filter\n") { struct telnet_connection *conn; conn = (struct telnet_connection *) vty->priv; if (!conn->dbg) { vty_out(vty, "Logging was not enabled.%s", VTY_NEWLINE); return CMD_WARNING; } log_set_imsi_filter(conn->dbg, argv[0]); return CMD_SUCCESS; } extern int bsc_vty_init_extra(void); extern const char *openbsc_copyright; int bsc_vty_init(void) { install_element_ve(&show_net_cmd); install_element_ve(&show_bts_cmd); install_element_ve(&show_trx_cmd); install_element_ve(&show_ts_cmd); install_element_ve(&show_lchan_cmd); install_element_ve(&show_lchan_summary_cmd); install_element_ve(&logging_fltr_imsi_cmd); install_element_ve(&show_e1drv_cmd); install_element_ve(&show_e1line_cmd); install_element_ve(&show_e1ts_cmd); install_element_ve(&show_paging_cmd); logging_vty_add_cmds(); install_element(CONFIG_NODE, &cfg_net_cmd); install_node(&net_node, config_write_net); install_default(GSMNET_NODE); install_element(GSMNET_NODE, &ournode_exit_cmd); install_element(GSMNET_NODE, &ournode_end_cmd); install_element(GSMNET_NODE, &cfg_net_ncc_cmd); install_element(GSMNET_NODE, &cfg_net_mnc_cmd); install_element(GSMNET_NODE, &cfg_net_name_short_cmd); install_element(GSMNET_NODE, &cfg_net_name_long_cmd); install_element(GSMNET_NODE, &cfg_net_auth_policy_cmd); install_element(GSMNET_NODE, &cfg_net_reject_cause_cmd); install_element(GSMNET_NODE, &cfg_net_encryption_cmd); install_element(GSMNET_NODE, &cfg_net_neci_cmd); install_element(GSMNET_NODE, &cfg_net_rrlp_mode_cmd); install_element(GSMNET_NODE, &cfg_net_mm_info_cmd); install_element(GSMNET_NODE, &cfg_net_handover_cmd); install_element(GSMNET_NODE, &cfg_net_ho_win_rxlev_avg_cmd); install_element(GSMNET_NODE, &cfg_net_ho_win_rxqual_avg_cmd); install_element(GSMNET_NODE, &cfg_net_ho_win_rxlev_avg_neigh_cmd); install_element(GSMNET_NODE, &cfg_net_ho_pwr_interval_cmd); install_element(GSMNET_NODE, &cfg_net_ho_pwr_hysteresis_cmd); install_element(GSMNET_NODE, &cfg_net_ho_max_distance_cmd); install_element(GSMNET_NODE, &cfg_net_T3101_cmd); install_element(GSMNET_NODE, &cfg_net_T3103_cmd); install_element(GSMNET_NODE, &cfg_net_T3105_cmd); install_element(GSMNET_NODE, &cfg_net_T3107_cmd); install_element(GSMNET_NODE, &cfg_net_T3109_cmd); install_element(GSMNET_NODE, &cfg_net_T3111_cmd); install_element(GSMNET_NODE, &cfg_net_T3113_cmd); install_element(GSMNET_NODE, &cfg_net_T3115_cmd); install_element(GSMNET_NODE, &cfg_net_T3117_cmd); install_element(GSMNET_NODE, &cfg_net_T3119_cmd); install_element(GSMNET_NODE, &cfg_net_T3141_cmd); install_element(GSMNET_NODE, &cfg_bts_cmd); install_node(&bts_node, config_write_bts); install_default(BTS_NODE); install_element(BTS_NODE, &ournode_exit_cmd); install_element(BTS_NODE, &ournode_end_cmd); install_element(BTS_NODE, &cfg_bts_type_cmd); install_element(BTS_NODE, &cfg_description_cmd); install_element(BTS_NODE, &cfg_no_description_cmd); install_element(BTS_NODE, &cfg_bts_band_cmd); install_element(BTS_NODE, &cfg_bts_ci_cmd); install_element(BTS_NODE, &cfg_bts_lac_cmd); install_element(BTS_NODE, &cfg_bts_tsc_cmd); install_element(BTS_NODE, &cfg_bts_bsic_cmd); install_element(BTS_NODE, &cfg_bts_unit_id_cmd); install_element(BTS_NODE, &cfg_bts_stream_id_cmd); install_element(BTS_NODE, &cfg_bts_oml_e1_cmd); install_element(BTS_NODE, &cfg_bts_oml_e1_tei_cmd); install_element(BTS_NODE, &cfg_bts_challoc_cmd); install_element(BTS_NODE, &cfg_bts_rach_tx_integer_cmd); install_element(BTS_NODE, &cfg_bts_rach_max_trans_cmd); install_element(BTS_NODE, &cfg_bts_rach_nm_b_thresh_cmd); install_element(BTS_NODE, &cfg_bts_rach_nm_ldavg_cmd); install_element(BTS_NODE, &cfg_bts_cell_barred_cmd); install_element(BTS_NODE, &cfg_bts_rach_ec_allowed_cmd); install_element(BTS_NODE, &cfg_bts_ms_max_power_cmd); install_element(BTS_NODE, &cfg_bts_per_loc_upd_cmd); install_element(BTS_NODE, &cfg_bts_cell_resel_hyst_cmd); install_element(BTS_NODE, &cfg_bts_rxlev_acc_min_cmd); install_element(BTS_NODE, &cfg_bts_gprs_mode_cmd); install_element(BTS_NODE, &cfg_bts_gprs_ns_timer_cmd); install_element(BTS_NODE, &cfg_bts_gprs_rac_cmd); install_element(BTS_NODE, &cfg_bts_gprs_bvci_cmd); install_element(BTS_NODE, &cfg_bts_gprs_cell_timer_cmd); install_element(BTS_NODE, &cfg_bts_gprs_nsei_cmd); install_element(BTS_NODE, &cfg_bts_gprs_nsvci_cmd); install_element(BTS_NODE, &cfg_bts_gprs_nsvc_lport_cmd); install_element(BTS_NODE, &cfg_bts_gprs_nsvc_rport_cmd); install_element(BTS_NODE, &cfg_bts_gprs_nsvc_rip_cmd); install_element(BTS_NODE, &cfg_bts_si_mode_cmd); install_element(BTS_NODE, &cfg_bts_si_static_cmd); install_element(BTS_NODE, &cfg_trx_cmd); install_node(&trx_node, dummy_config_write); install_default(TRX_NODE); install_element(TRX_NODE, &ournode_exit_cmd); install_element(TRX_NODE, &ournode_end_cmd); install_element(TRX_NODE, &cfg_trx_arfcn_cmd); install_element(TRX_NODE, &cfg_description_cmd); install_element(TRX_NODE, &cfg_no_description_cmd); install_element(TRX_NODE, &cfg_trx_nominal_power_cmd); install_element(TRX_NODE, &cfg_trx_max_power_red_cmd); install_element(TRX_NODE, &cfg_trx_rsl_e1_cmd); install_element(TRX_NODE, &cfg_trx_rsl_e1_tei_cmd); install_element(TRX_NODE, &cfg_trx_rf_locked_cmd); install_element(TRX_NODE, &cfg_ts_cmd); install_node(&ts_node, dummy_config_write); install_default(TS_NODE); install_element(TS_NODE, &ournode_exit_cmd); install_element(TS_NODE, &ournode_end_cmd); install_element(TS_NODE, &cfg_ts_pchan_cmd); install_element(TS_NODE, &cfg_ts_hopping_cmd); install_element(TS_NODE, &cfg_ts_hsn_cmd); install_element(TS_NODE, &cfg_ts_maio_cmd); install_element(TS_NODE, &cfg_ts_arfcn_add_cmd); install_element(TS_NODE, &cfg_ts_arfcn_del_cmd); install_element(TS_NODE, &cfg_ts_e1_subslot_cmd); abis_nm_vty_init(); bsc_vty_init_extra(); return 0; }