/* Nokia XXXsite family specific code */ /* (C) 2011 by Dieter Spaar * * 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 . * */ /* TODO: Attention: There are some static variables used for states during configuration. Those variables have to be moved to a BTS specific context, otherwise there will most certainly be problems if more than one Nokia BTS is used. */ #include #include #include #include #include #include #include #include #include #include /* TODO: put in a separate file ? */ extern int abis_nm_sendmsg(struct gsm_bts *bts, struct msgb *msg); /* was static in system_information.c */ extern int generate_cell_chan_list(uint8_t * chan_list, struct gsm_bts *bts); static void nokia_abis_nm_queue_send_next(struct gsm_bts *bts); static void reset_timer_cb(void *_bts); static int abis_nm_reset(struct gsm_bts *bts, uint16_t ref); static int dump_elements(uint8_t * data, int len) __attribute__((unused)); static void bootstrap_om_bts(struct gsm_bts *bts) { LOGP(DNM, LOGL_NOTICE, "bootstrapping OML for BTS %u\n", bts->nr); if (!bts->nokia.skip_reset) { if (!bts->nokia.did_reset) abis_nm_reset(bts, 1); } else bts->nokia.did_reset = 1; gsm_bts_all_ts_dispatch(bts, TS_EV_OML_READY, NULL); } static void bootstrap_om_trx(struct gsm_bts_trx *trx) { LOGP(DNM, LOGL_NOTICE, "bootstrapping OML for TRX %u/%u\n", trx->bts->nr, trx->nr); gsm_trx_all_ts_dispatch(trx, TS_EV_OML_READY, NULL); } static int shutdown_om(struct gsm_bts *bts) { /* TODO !? */ return 0; } #define SAPI_OML 62 #define SAPI_RSL 0 /* Tell LAPD to start start the SAP (send SABM requests) for all signalling timeslots in this line Attention: this has to be adapted for mISDN */ static void start_sabm_in_line(struct e1inp_line *line, int start, int sapi) { struct e1inp_sign_link *link; int i; for (i = 0; i < ARRAY_SIZE(line->ts); i++) { struct e1inp_ts *ts = &line->ts[i]; if (ts->type != E1INP_TS_TYPE_SIGN) continue; llist_for_each_entry(link, &ts->sign.sign_links, list) { if (sapi != -1 && link->sapi != sapi) continue; #if 0 /* debugging */ printf("sap start/stop (%d): %d tei=%d sapi=%d\n", start, i + 1, link->tei, link->sapi); #endif if (start) { ts->lapd->profile.t200_sec = 1; ts->lapd->profile.t200_usec = 0; lapd_sap_start(ts->lapd, link->tei, link->sapi); } else lapd_sap_stop(ts->lapd, link->tei, link->sapi); } } } /* Callback function to be called every time we receive a signal from INPUT */ static int gbl_sig_cb(unsigned int subsys, unsigned int signal, void *handler_data, void *signal_data) { struct gsm_bts *bts; if (subsys != SS_L_GLOBAL) return 0; switch (signal) { case S_GLOBAL_BTS_CLOSE_OM: bts = signal_data; if (bts->type == GSM_BTS_TYPE_NOKIA_SITE) shutdown_om(signal_data); break; } return 0; } /* Callback function to be called every time we receive a signal from INPUT */ static int inp_sig_cb(unsigned int subsys, unsigned int signal, void *handler_data, void *signal_data) { struct input_signal_data *isd = signal_data; if (subsys != SS_L_INPUT) return 0; switch (signal) { case S_L_INP_LINE_INIT: start_sabm_in_line(isd->line, 1, SAPI_OML); /* start only OML */ break; case S_L_INP_TEI_DN: break; case S_L_INP_TEI_UP: switch (isd->link_type) { case E1INP_SIGN_OML: if (isd->trx->bts->type != GSM_BTS_TYPE_NOKIA_SITE) break; if (isd->tei == isd->trx->bts->oml_tei) bootstrap_om_bts(isd->trx->bts); else bootstrap_om_trx(isd->trx); break; default: break; } break; case S_L_INP_TEI_UNKNOWN: /* We are receiving LAPD frames with one TEI that we do not * seem to know, likely that we (the BSC) stopped working * and lost our local states. However, the BTS is already * configured, we try to take over the RSL links. */ start_sabm_in_line(isd->line, 1, SAPI_RSL); break; } return 0; } static void nm_statechg_evt(unsigned int signal, struct nm_statechg_signal_data *nsd) { if (nsd->bts->type != GSM_BTS_TYPE_NOKIA_SITE) return; } static int nm_sig_cb(unsigned int subsys, unsigned int signal, void *handler_data, void *signal_data) { if (subsys != SS_NM) return 0; switch (signal) { case S_NM_STATECHG_OPER: case S_NM_STATECHG_ADM: nm_statechg_evt(signal, signal_data); break; default: break; } return 0; } /* TODO: put in a separate file ? */ static const struct value_string nokia_msgt_name[] = { { 0x80, "NOKIA_BTS_CONF_DATA" }, { 0x81, "NOKIA_BTS_ACK" }, { 0x82, "NOKIA_BTS_OMU_STARTED" }, { 0x83, "NOKIA_BTS_START_DOWNLOAD_REQ" }, { 0x84, "NOKIA_BTS_MF_REQ" }, { 0x85, "NOKIA_BTS_AF_REQ" }, { 0x86, "NOKIA_BTS_RESET_REQ" }, { 0x87, "NOKIA_reserved" }, { 0x88, "NOKIA_BTS_CONF_REQ" }, { 0x89, "NOKIA_BTS_TEST_REQ" }, { 0x8A, "NOKIA_BTS_TEST_REPORT" }, { 0x8B, "NOKIA_reserved" }, { 0x8C, "NOKIA_reserved" }, { 0x8D, "NOKIA_reserved" }, { 0x8E, "NOKIA_BTS_CONF_COMPL" }, { 0x8F, "NOKIA_reserved" }, { 0x90, "NOKIA_BTS_STM_TEST_REQ" }, { 0x91, "NOKIA_BTS_STM_TEST_REPORT" }, { 0x92, "NOKIA_BTS_TRANSMISSION_COMMAND" }, { 0x93, "NOKIA_BTS_TRANSMISSION_ANSWER" }, { 0x94, "NOKIA_BTS_HW_DB_UPLOAD_REQ" }, { 0x95, "NOKIA_BTS_START_HW_DB_DOWNLOAD_REQ" }, { 0x96, "NOKIA_BTS_HW_DB_SAVE_REQ" }, { 0x97, "NOKIA_BTS_FLASH_ERASURE_REQ" }, { 0x98, "NOKIA_BTS_HW_DB_DOWNLOAD_REQ" }, { 0x99, "NOKIA_BTS_PWR_SUPPLY_CONTROL" }, { 0x9A, "NOKIA_BTS_ATTRIBUTE_REQ" }, { 0x9B, "NOKIA_BTS_ATTRIBUTE_REPORT" }, { 0x9C, "NOKIA_BTS_HW_REQ" }, { 0x9D, "NOKIA_BTS_HW_REPORT" }, { 0x9E, "NOKIA_BTS_RTE_TEST_REQ" }, { 0x9F, "NOKIA_BTS_RTE_TEST_REPORT" }, { 0xA0, "NOKIA_BTS_HW_DB_VERIFICATION_REQ" }, { 0xA1, "NOKIA_BTS_CLOCK_REQ" }, { 0xA2, "NOKIA_AC_CIRCUIT_REQ_NACK" }, { 0xA3, "NOKIA_AC_INTERRUPTED" }, { 0xA4, "NOKIA_BTS_NEW_TRE_INFO" }, { 0xA5, "NOKIA_AC_BSC_CIRCUITS_ALLOCATED" }, { 0xA6, "NOKIA_BTS_TRE_POLL_LIST" }, { 0xA7, "NOKIA_AC_CIRCUIT_REQ" }, { 0xA8, "NOKIA_BTS_BLOCK_CTRL_REQ" }, { 0xA9, "NOKIA_BTS_GSM_TIME_REQ" }, { 0xAA, "NOKIA_BTS_GSM_TIME" }, { 0xAB, "NOKIA_BTS_OUTPUT_CONTROL" }, { 0xAC, "NOKIA_BTS_STATE_CHANGED" }, { 0xAD, "NOKIA_BTS_SW_SAVE_REQ" }, { 0xAE, "NOKIA_BTS_ALARM" }, { 0xAF, "NOKIA_BTS_CHA_ADM_STATE" }, { 0xB0, "NOKIA_AC_POOL_SIZE_REPORT" }, { 0xB1, "NOKIA_AC_POOL_SIZE_INQUIRY" }, { 0xB2, "NOKIA_BTS_COMMISS_TEST_COMPLETED" }, { 0xB3, "NOKIA_BTS_COMMISS_TEST_REQ" }, { 0xB4, "NOKIA_BTS_TRANSP_BTS_TO_BSC" }, { 0xB5, "NOKIA_BTS_TRANSP_BSC_TO_BTS" }, { 0xB6, "NOKIA_BTS_LCS_COMMAND" }, { 0xB7, "NOKIA_BTS_LCS_ANSWER" }, { 0xB8, "NOKIA_BTS_LMU_FN_OFFSET_COMMAND" }, { 0xB9, "NOKIA_BTS_LMU_FN_OFFSET_ANSWER" }, { 0, NULL } }; static const char *get_msg_type_name_string(uint8_t msg_type) { return get_value_string(nokia_msgt_name, msg_type); } static const struct value_string nokia_element_name[] = { { 0x01, "Ny1" }, { 0x02, "T3105_F" }, { 0x03, "Interference band limits" }, { 0x04, "Interference report timer in secs" }, { 0x05, "Channel configuration per TS" }, { 0x06, "BSIC" }, { 0x07, "RACH report timer in secs" }, { 0x08, "Hardware database status" }, { 0x09, "BTS RX level" }, { 0x0A, "ARFN" }, { 0x0B, "STM antenna attenuation" }, { 0x0C, "Cell allocation bitmap" }, { 0x0D, "Radio definition per TS" }, { 0x0E, "Frame number" }, { 0x0F, "Antenna diversity" }, { 0x10, "T3105_D" }, { 0x11, "File format" }, { 0x12, "Last File" }, { 0x13, "BTS type" }, { 0x14, "Erasure mode" }, { 0x15, "Hopping mode" }, { 0x16, "Floating TRX" }, { 0x17, "Power supplies" }, { 0x18, "Reset type" }, { 0x19, "Averaging period" }, { 0x1A, "RBER2" }, { 0x1B, "LAC" }, { 0x1C, "CI" }, { 0x1D, "Failure parameters" }, { 0x1E, "(RF max power reduction)" }, { 0x1F, "Measured RX_SENS" }, { 0x20, "Extended cell radius" }, { 0x21, "reserved" }, { 0x22, "Success-Failure" }, { 0x23, "Ack-Nack" }, { 0x24, "OMU test results" }, { 0x25, "File identity" }, { 0x26, "Generation and version code" }, { 0x27, "SW description" }, { 0x28, "BCCH LEV" }, { 0x29, "Test type" }, { 0x2A, "Subscriber number" }, { 0x2B, "reserved" }, { 0x2C, "HSN" }, { 0x2D, "reserved" }, { 0x2E, "MS RXLEV" }, { 0x2F, "MS TXLEV" }, { 0x30, "RXQUAL" }, { 0x31, "RX SENS" }, { 0x32, "Alarm block" }, { 0x33, "Neighbouring BCCH levels" }, { 0x34, "STM report type" }, { 0x35, "MA" }, { 0x36, "MAIO" }, { 0x37, "H_FLAG" }, { 0x38, "TCH_ARFN" }, { 0x39, "Clock output" }, { 0x3A, "Transmitted power" }, { 0x3B, "Clock sync" }, { 0x3C, "TMS protocol discriminator" }, { 0x3D, "TMS protocol data" }, { 0x3E, "FER" }, { 0x3F, "SWR result" }, { 0x40, "Object identity" }, { 0x41, "STM RX Antenna Test" }, { 0x42, "reserved" }, { 0x43, "reserved" }, { 0x44, "Object current state" }, { 0x45, "reserved" }, { 0x46, "FU channel configuration" }, { 0x47, "reserved" }, { 0x48, "ARFN of a CU" }, { 0x49, "FU radio definition" }, { 0x4A, "reserved" }, { 0x4B, "Severity" }, { 0x4C, "Diversity selection" }, { 0x4D, "RX antenna test" }, { 0x4E, "RX antenna supervision period" }, { 0x4F, "RX antenna state" }, { 0x50, "Sector configuration" }, { 0x51, "Additional info" }, { 0x52, "SWR parameters" }, { 0x53, "HW inquiry mode" }, { 0x54, "reserved" }, { 0x55, "Availability status" }, { 0x56, "reserved" }, { 0x57, "EAC inputs" }, { 0x58, "EAC outputs" }, { 0x59, "reserved" }, { 0x5A, "Position" }, { 0x5B, "HW unit identity" }, { 0x5C, "RF test signal attenuation" }, { 0x5D, "Operational state" }, { 0x5E, "Logical object identity" }, { 0x5F, "reserved" }, { 0x60, "BS_TXPWR_OM" }, { 0x61, "Loop_Duration" }, { 0x62, "LNA_Path_Selection" }, { 0x63, "Serial number" }, { 0x64, "HW version" }, { 0x65, "Obj. identity and obj. state" }, { 0x66, "reserved" }, { 0x67, "EAC input definition" }, { 0x68, "EAC id and text" }, { 0x69, "HW unit status" }, { 0x6A, "SW release version" }, { 0x6B, "FW version" }, { 0x6C, "Bit_Error_Ratio" }, { 0x6D, "RXLEV_with_Attenuation" }, { 0x6E, "RXLEV_without_Attenuation" }, { 0x6F, "reserved" }, { 0x70, "CU_Results" }, { 0x71, "reserved" }, { 0x72, "LNA_Path_Results" }, { 0x73, "RTE Results" }, { 0x74, "Real Time" }, { 0x75, "RX diversity selection" }, { 0x76, "EAC input config" }, { 0x77, "Feature support" }, { 0x78, "File version" }, { 0x79, "Outputs" }, { 0x7A, "FU parameters" }, { 0x7B, "Diagnostic info" }, { 0x7C, "FU BSIC" }, { 0x7D, "TRX Configuration" }, { 0x7E, "Download status" }, { 0x7F, "RX difference limit" }, { 0x80, "TRX HW capability" }, { 0x81, "Common HW config" }, { 0x82, "Autoconfiguration pool size" }, { 0x83, "TRE diagnostic info" }, { 0x84, "TRE object identity" }, { 0x85, "New TRE Info" }, { 0x86, "Acknowledgement period" }, { 0x87, "Synchronization mode" }, { 0x88, "reserved" }, { 0x89, "Block Control Data" }, { 0x8A, "SW load mode" }, { 0x8B, "Recommended recovery action" }, { 0x8C, "BSC BCF id" }, { 0x8D, "Q1 baud rate" }, { 0x8E, "Allocation status" }, { 0x8F, "Functional entity number" }, { 0x90, "Transmission delay" }, { 0x91, "Loop Duration ms" }, { 0x92, "Logical channel" }, { 0x93, "Q1 address" }, { 0x94, "Alarm detail" }, { 0x95, "Cabinet type" }, { 0x96, "HW unit existence" }, { 0x97, "RF power parameters" }, { 0x98, "Message scenario" }, { 0x99, "HW unit max amount" }, { 0x9A, "Master TRX" }, { 0x9B, "Transparent data" }, { 0x9C, "BSC topology info" }, { 0x9D, "Air i/f modulation" }, { 0x9E, "LCS Q1 command data" }, { 0x9F, "Frame number offset" }, { 0xA0, "Abis TSL" }, { 0xA1, "Dynamic pool info" }, { 0xA2, "LCS LLP data" }, { 0xA3, "LCS Q1 answer data" }, { 0xA4, "DFCA FU Radio Definition" }, { 0xA5, "Antenna hopping" }, { 0xA6, "Field record sequence number" }, { 0xA7, "Timeslot offslot" }, { 0xA8, "EPCR capability" }, { 0xA9, "Connectsite optional element" }, { 0xAA, "TSC" }, { 0xAB, "Special TX Power Setting" }, { 0xAC, "Optional sync settings" }, { 0xFA, "Abis If parameters" }, { 0, NULL } }; static const char *get_element_name_string(uint16_t element) { return get_value_string(nokia_element_name, element); } static const struct value_string nokia_bts_types[] = { { 0x0a, "MetroSite GSM 900" }, { 0x0b, "MetroSite GSM 1800" }, { 0x0c, "MetroSite GSM 1900 (PCS)" }, { 0x0d, "MetroSite GSM 900 & 1800" }, { 0x0e, "InSite GSM 900" }, { 0x0f, "InSite GSM 1800" }, { 0x10, "InSite GSM 1900" }, { 0x11, "UltraSite GSM 900" }, { 0x12, "UltraSite GSM 1800" }, { 0x13, "UltraSite GSM/US-TDMA 1900" }, { 0x14, "UltraSite GSM 900 & 1800" }, { 0x16, "UltraSite GSM/US-TDMA 850" }, { 0x18, "MetroSite GSM/US-TDMA 850" }, { 0x19, "UltraSite GSM 800/1900" }, { 0, NULL } }; static const char *get_bts_type_string(uint8_t type) { return get_value_string(nokia_bts_types, type); } static const struct value_string nokia_severity[] = { { 0, "indeterminate" }, { 1, "critical" }, { 2, "major" }, { 3, "minor" }, { 4, "warning" }, { 0, NULL } }; static const char *get_severity_string(uint8_t severity) { return get_value_string(nokia_severity, severity); } /* TODO: put in a separate file ? */ /* some message IDs */ #define NOKIA_MSG_CONF_DATA 128 #define NOKIA_MSG_ACK 129 #define NOKIA_MSG_OMU_STARTED 130 #define NOKIA_MSG_START_DOWNLOAD_REQ 131 #define NOKIA_MSG_MF_REQ 132 #define NOKIA_MSG_RESET_REQ 134 #define NOKIA_MSG_CONF_REQ 136 #define NOKIA_MSG_CONF_COMPLETE 142 #define NOKIA_MSG_BLOCK_CTRL_REQ 168 #define NOKIA_MSG_STATE_CHANGED 172 #define NOKIA_MSG_ALARM 174 /* some element IDs */ #define NOKIA_EI_BTS_TYPE 0x13 #define NOKIA_EI_ACK 0x23 #define NOKIA_EI_ADD_INFO 0x51 #define NOKIA_EI_SEVERITY 0x4B #define NOKIA_EI_ALARM_DETAIL 0x94 #define OM_ALLOC_SIZE 1024 #define OM_HEADROOM_SIZE 128 static uint8_t fu_config_template[] = { 0x7F, 0x7A, 0x39, /* ID = 0x7A (FU parameters) ## constructed ## */ /* length = 57 */ /* [3] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [6] */ 0x00, 0x07, 0x01, 0xFF, 0x41, 0x02, /* ID = 0x01 (Ny1) */ /* length = 2 */ /* [12] */ 0x00, 0x05, 0x42, 0x02, /* ID = 0x02 (T3105_F) */ /* length = 2 */ /* [16] */ 0x00, 0x28, /* FIXME: use net->T3105 */ 0x50, 0x02, /* ID = 0x10 (T3105_D) */ /* length = 2 */ /* [20] */ 0x00, 0x28, /* FIXME: use net->T3105 */ 0x43, 0x05, /* ID = 0x03 (Interference band limits) */ /* length = 5 */ /* [24] */ 0x0F, 0x1B, 0x27, 0x33, 0x3F, 0x44, 0x02, /* ID = 0x04 (Interference report timer in secs) */ /* length = 2 */ /* [31] */ 0x00, 0x10, 0x47, 0x01, /* ID = 0x07 (RACH report timer in secs) */ /* length = 1 */ /* [35] */ 0x1E, 0x4C, 0x10, /* ID = 0x0C (Cell allocation bitmap) ####### */ /* length = 16 */ /* [38] */ 0x8F, 0xB1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x59, 0x01, /* ID = 0x19 (Averaging period) */ /* length = 1 */ /* [56] */ 0x01, 0x5E, 0x01, /* ID = 0x1E ((RF max power reduction)) */ /* length = 1 */ /* [59] */ 0x00, 0x7F, 0x46, 0x11, /* ID = 0x46 (FU channel configuration) ## constructed ## */ /* length = 17 */ /* [63] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [66] */ 0x00, 0x07, 0x01, 0xFF, 0x45, 0x08, /* ID = 0x05 (Channel configuration per TS) */ /* length = 8 */ /* [72] */ 0x01, 0x09, 0x09, 0x09, 0x09, 0x09, 0x09, 0x09, 0x7F, 0x65, 0x0B, /* ID = 0x65 (Obj. identity and obj. state) ## constructed ## */ /* length = 11 */ /* [83] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [86] */ 0x00, 0x04, 0x01, 0xFF, 0x5F, 0x44, 0x01, /* ID = 0x44 (Object current state) */ /* length = 1 */ /* [93] */ 0x03, 0x7F, 0x7C, 0x0A, /* ID = 0x7C (FU BSIC) ## constructed ## */ /* length = 10 */ /* [97] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [100] */ 0x00, 0x07, 0x01, 0xFF, 0x46, 0x01, /* ID = 0x06 (BSIC) */ /* length = 1 */ /* [106] */ 0x00, 0x7F, 0x48, 0x0B, /* ID = 0x48 (ARFN of a CU) ## constructed ## */ /* length = 11 */ /* [110] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [113] */ 0x00, 0x08, 0x01, 0xFF, 0x4A, 0x02, /* ID = 0x0A (ARFN) ####### */ /* length = 2 */ /* [119] */ 0x03, 0x62, 0x7F, 0x49, 0x59, /* ID = 0x49 (FU radio definition) ## constructed ## */ /* length = 89 */ /* [124] */ 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [127] */ 0x00, 0x07, 0x01, 0xFF, 0x4D, 0x50, /* ID = 0x0D (Radio definition per TS) ####### */ /* length = 80 */ /* [133] */ 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* MA */ 0x03, 0x62, /* HSN, MAIO or ARFCN if no hopping */ 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x62, }; /* TODO: put in a separate file ? */ /* build the configuration for each TRX */ static int make_fu_config(struct gsm_bts_trx *trx, uint8_t id, uint8_t * fu_config, int *hopping) { int i; *hopping = 0; memcpy(fu_config, fu_config_template, sizeof(fu_config_template)); /* set ID */ fu_config[6 + 2] = id; fu_config[66 + 2] = id; fu_config[86 + 2] = id; fu_config[100 + 2] = id; fu_config[113 + 2] = id; fu_config[127 + 2] = id; /* set ARFCN */ uint16_t arfcn = trx->arfcn; fu_config[119] = arfcn >> 8; fu_config[119 + 1] = arfcn & 0xFF; for (i = 0; i < ARRAY_SIZE(trx->ts); i++) { struct gsm_bts_trx_ts *ts = &trx->ts[i]; if (ts->hopping.enabled) { /* reverse order */ int j; for (j = 0; j < ts->hopping.ma_len; j++) fu_config[133 + (i * 10) + (7 - j)] = ts->hopping.ma_data[j]; fu_config[133 + 8 + (i * 10)] = ts->hopping.hsn; fu_config[133 + 8 + 1 + (i * 10)] = ts->hopping.maio; *hopping = 1; } else { fu_config[133 + 8 + (i * 10)] = arfcn >> 8; fu_config[133 + 8 + 1 + (i * 10)] = arfcn & 0xFF; } } /* set BSIC */ /* Attention: all TRX except the first one seem to get the TSC from the CHANNEL ACTIVATION command (in CHANNEL IDENTIFICATION, GSM 04.08 CHANNEL DESCRIPTION). There was a bug in rsl_chan_activate_lchan() setting this parameter. */ uint8_t bsic = trx->bts->bsic; fu_config[106] = bsic; /* set CA */ if (generate_cell_chan_list(&fu_config[38], trx->bts) != 0) { fprintf(stderr, "generate_cell_chan_list failed\n"); return 0; } /* set channel configuration */ for (i = 0; i < ARRAY_SIZE(trx->ts); i++) { struct gsm_bts_trx_ts *ts = &trx->ts[i]; uint8_t chan_config; /* 0 = FCCH + SCH + BCCH + CCCH 1 = FCCH + SCH + BCCH + CCCH + SDCCH/4 + SACCH/4 2 = BCCH + CCCH (This combination is not used in any BTS) 3 = FCCH + SCH + BCCH + CCCH + SDCCH/4 with SDCCH2 used as CBCH 4 = SDCCH/8 + SACCH/8 5 = SDCCH/8 with SDCCH2 used as CBCH 6 = TCH/F + FACCH/F + SACCH/F 7 = E-RACH (Talk family) 9 = Dual rate (capability for TCH/F and TCH/H) 10 = reserved for BTS internal use 11 = PBCCH + PCCCH + PDTCH + PACCH + PTCCH (can be used in GPRS release 2). 0xFF = spare TS */ switch (ts->pchan_from_config) { case GSM_PCHAN_NONE: chan_config = 0xFF; break; case GSM_PCHAN_CCCH: chan_config = 0; break; case GSM_PCHAN_CCCH_SDCCH4: chan_config = 1; break; case GSM_PCHAN_TCH_F: chan_config = 6; /* 9 should work too */ break; case GSM_PCHAN_TCH_H: chan_config = 9; break; case GSM_PCHAN_SDCCH8_SACCH8C: chan_config = 4; break; case GSM_PCHAN_PDCH: chan_config = 11; break; default: fprintf(stderr, "unsupported channel config %s for timeslot %d\n", gsm_pchan_name(ts->pchan_from_config), i); return 0; } fu_config[72 + i] = chan_config; } return sizeof(fu_config_template); } /* TODO: put in a separate file ? */ static uint8_t bts_config_1[] = { 0x4E, 0x02, /* ID = 0x0E (Frame number) */ /* length = 2 */ /* [2] */ 0xFF, 0xFF, 0x5F, 0x4E, 0x02, /* ID = 0x4E (RX antenna supervision period) */ /* length = 2 */ /* [7] */ 0xFF, 0xFF, 0x5F, 0x50, 0x02, /* ID = 0x50 (Sector configuration) */ /* length = 2 */ /* [12] */ 0x01, 0x01, }; static uint8_t bts_config_2[] = { 0x55, 0x02, /* ID = 0x15 (Hopping mode) */ /* length = 2 */ /* [2] */ 0x01, 0x00, 0x5F, 0x75, 0x02, /* ID = 0x75 (RX diversity selection) */ /* length = 2 */ /* [7] */ 0x01, 0x01, }; static uint8_t bts_config_3[] = { 0x5F, 0x20, 0x02, /* ID = 0x20 (Extended cell radius) */ /* length = 2 */ /* [3] */ 0x01, 0x00, }; static uint8_t bts_config_4[] = { 0x5F, 0x74, 0x09, /* ID = 0x74 (Real Time) */ /* length = 9 */ /* [3] year-high, year-low, month, day, hour, minute, second, msec-high, msec-low */ 0x07, 0xDB, 0x06, 0x02, 0x0B, 0x20, 0x0C, 0x00, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [15] */ 0x01, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [21] */ 0x02, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [27] */ 0x03, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [33] */ 0x04, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [39] */ 0x05, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [45] */ 0x06, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [51] */ 0x07, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [57] */ 0x08, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [63] */ 0x09, 0x01, 0x00, 0x5F, 0x76, 0x03, /* ID = 0x76 (EAC input config) */ /* length = 3 */ /* [69] */ 0x0A, 0x01, 0x00, }; static uint8_t bts_config_insite[] = { 0x4E, 0x02, /* ID = 0x0E (Frame number) */ /* length = 2 */ /* [2] */ 0xFF, 0xFF, 0x5F, 0x4E, 0x02, /* ID = 0x4E (RX antenna supervision period) */ /* length = 2 */ /* [7] */ 0xFF, 0xFF, 0x5F, 0x50, 0x02, /* ID = 0x50 (Sector configuration) */ /* length = 2 */ /* [12] */ 0x01, 0x01, 0x55, 0x02, /* ID = 0x15 (Hopping mode) */ /* length = 2 */ /* [16] */ 0x01, 0x00, 0x5F, 0x20, 0x02, /* ID = 0x20 (Extended cell radius) */ /* length = 2 */ /* [21] */ 0x01, 0x00, 0x5F, 0x74, 0x09, /* ID = 0x74 (Real Time) */ /* length = 9 */ /* [26] */ 0x07, 0xDB, 0x07, 0x0A, 0x0F, 0x09, 0x0B, 0x00, 0x00, }; void set_real_time(uint8_t * real_time) { time_t t; struct tm *tm; t = time(NULL); tm = localtime(&t); /* year-high, year-low, month, day, hour, minute, second, msec-high, msec-low */ real_time[0] = (1900 + tm->tm_year) >> 8; real_time[1] = (1900 + tm->tm_year) & 0xFF; real_time[2] = tm->tm_mon + 1; real_time[3] = tm->tm_mday; real_time[4] = tm->tm_hour; real_time[5] = tm->tm_min; real_time[6] = tm->tm_sec; real_time[7] = 0; real_time[8] = 0; } /* TODO: put in a separate file ? */ /* build the configuration data */ static int make_bts_config(uint8_t bts_type, int n_trx, uint8_t * fu_config, int need_hopping) { /* is it an InSite BTS ? */ if (bts_type == 0x0E || bts_type == 0x0F || bts_type == 0x10) { /* TODO */ if (n_trx != 1) { fprintf(stderr, "InSite has only one TRX\n"); return 0; } if (need_hopping != 0) { fprintf(stderr, "InSite does not support hopping\n"); return 0; } memcpy(fu_config, bts_config_insite, sizeof(bts_config_insite)); set_real_time(&fu_config[26]); return sizeof(bts_config_insite); } int len = 0; int i; memcpy(fu_config + len, bts_config_1, sizeof(bts_config_1)); /* set sector configuration */ fu_config[len + 12 - 1] = 1 + n_trx; /* len */ for (i = 0; i < n_trx; i++) fu_config[len + 12 + 1 + i] = ((i + 1) & 0xFF); len += (sizeof(bts_config_1) + (n_trx - 1)); memcpy(fu_config + len, bts_config_2, sizeof(bts_config_2)); /* set hopping mode (Baseband and RF hopping work for the MetroSite) */ if (need_hopping) fu_config[len + 2 + 1] = 1; /* 0: no hopping, 1: Baseband hopping, 2: RF hopping */ len += sizeof(bts_config_2); /* set extended cell radius for each TRX */ for (i = 0; i < n_trx; i++) { memcpy(fu_config + len, bts_config_3, sizeof(bts_config_3)); fu_config[len + 3] = ((i + 1) & 0xFF); len += sizeof(bts_config_3); } memcpy(fu_config + len, bts_config_4, sizeof(bts_config_4)); set_real_time(&fu_config[len + 3]); len += sizeof(bts_config_4); return len; } /* TODO: put in a separate file ? */ static struct msgb *nm_msgb_alloc(void) { return msgb_alloc_headroom(OM_ALLOC_SIZE, OM_HEADROOM_SIZE, "OML"); } /* TODO: put in a separate file ? */ struct abis_om_nokia_hdr { uint8_t msg_type; uint8_t spare; uint16_t reference; uint8_t data[0]; } __attribute__ ((packed)); #define ABIS_OM_NOKIA_HDR_SIZE (sizeof(struct abis_om_hdr) + sizeof(struct abis_om_nokia_hdr)) static int abis_nm_send(struct gsm_bts *bts, uint8_t msg_type, uint16_t ref, uint8_t * data, int len_data) { struct abis_om_hdr *oh; struct abis_om_nokia_hdr *noh; struct msgb *msg = nm_msgb_alloc(); oh = (struct abis_om_hdr *)msgb_put(msg, ABIS_OM_NOKIA_HDR_SIZE + len_data); oh->mdisc = ABIS_OM_MDISC_FOM; oh->placement = ABIS_OM_PLACEMENT_ONLY; oh->sequence = 0; oh->length = sizeof(struct abis_om_nokia_hdr) + len_data; noh = (struct abis_om_nokia_hdr *)oh->data; noh->msg_type = msg_type; noh->spare = 0; noh->reference = htons(ref); memcpy(noh->data, data, len_data); DEBUGPC(DNM, "Sending %s\n", get_msg_type_name_string(msg_type)); return abis_nm_sendmsg(bts, msg); } /* TODO: put in a separate file ? */ static uint8_t download_req[] = { 0x5F, 0x25, 0x0B, /* ID = 0x25 (File identity) */ /* length = 11 */ /* [3] */ 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x2A, 0x5F, 0x78, 0x03, /* ID = 0x78 (File version) */ /* length = 3 */ /* [17] */ 0x2A, 0x2A, 0x2A, 0x5F, 0x81, 0x0A, 0x01, /* ID = 0x8A (SW load mode) */ /* length = 1 */ /* [24] */ 0x01, 0x5F, 0x81, 0x06, 0x01, /* ID = 0x86 (Acknowledgement period) */ /* length = 1 */ /* [29] */ 0x01, }; static int abis_nm_download_req(struct gsm_bts *bts, uint16_t ref) { uint8_t *data = download_req; int len_data = sizeof(download_req); return abis_nm_send(bts, NOKIA_MSG_START_DOWNLOAD_REQ, ref, data, len_data); } /* TODO: put in a separate file ? */ static uint8_t ack[] = { 0x5F, 0x23, 0x01, /* ID = 0x23 (Ack-Nack) */ /* length = 1 */ /* [3] */ 0x01, }; static int abis_nm_ack(struct gsm_bts *bts, uint16_t ref) { uint8_t *data = ack; int len_data = sizeof(ack); return abis_nm_send(bts, NOKIA_MSG_ACK, ref, data, len_data); } /* TODO: put in a separate file ? */ static uint8_t reset[] = { 0x5F, 0x40, 0x04, /* ID = 0x40 (Object identity) */ /* length = 4 */ /* [3] */ 0x00, 0x01, 0xFF, 0xFF, }; static int abis_nm_reset(struct gsm_bts *bts, uint16_t ref) { uint8_t *data = reset; int len_data = sizeof(reset); LOGP(DLINP, LOGL_INFO, "Nokia BTS reset timer: %d\n", bts->nokia.bts_reset_timer_cnf); return abis_nm_send(bts, NOKIA_MSG_RESET_REQ, ref, data, len_data); } /* TODO: put in a separate file ? */ static int abis_nm_send_multi_segments(struct gsm_bts *bts, uint8_t msg_type, uint16_t ref, uint8_t * data, int len) { int len_remain, len_to_send, max_send; int seq = 0; int ret; len_remain = len; while (len_remain) { struct abis_om_hdr *oh; struct abis_om_nokia_hdr *noh; struct msgb *msg = nm_msgb_alloc(); if (seq == 0) max_send = 256 - sizeof(struct abis_om_nokia_hdr); else max_send = 256; if (len_remain > max_send) { len_to_send = max_send; if (seq == 0) { /* first segment */ oh = (struct abis_om_hdr *)msgb_put(msg, ABIS_OM_NOKIA_HDR_SIZE + len_to_send); oh->mdisc = ABIS_OM_MDISC_FOM; oh->placement = ABIS_OM_PLACEMENT_FIRST; /* first segment of multi-segment message */ oh->sequence = seq; oh->length = 0; /* 256 bytes */ noh = (struct abis_om_nokia_hdr *)oh->data; noh->msg_type = msg_type; noh->spare = 0; noh->reference = htons(ref); memcpy(noh->data, data, len_to_send); } else { /* segment in between */ oh = (struct abis_om_hdr *)msgb_put(msg, sizeof (struct abis_om_hdr) + len_to_send); oh->mdisc = ABIS_OM_MDISC_FOM; oh->placement = ABIS_OM_PLACEMENT_MIDDLE; /* segment of multi-segment message */ oh->sequence = seq; oh->length = 0; /* 256 bytes */ memcpy(oh->data, data, len_to_send); } } else { len_to_send = len_remain; /* check if message fits in a single segment */ if (seq == 0) return abis_nm_send(bts, msg_type, ref, data, len_to_send); /* last segment */ oh = (struct abis_om_hdr *)msgb_put(msg, sizeof(struct abis_om_hdr) + len_to_send); oh->mdisc = ABIS_OM_MDISC_FOM; oh->placement = ABIS_OM_PLACEMENT_LAST; /* last segment of multi-segment message */ oh->sequence = seq; oh->length = len_to_send; memcpy(oh->data, data, len_to_send); } DEBUGPC(DNM, "Sending multi-segment %d\n", seq); ret = abis_nm_sendmsg(bts, msg); if (ret < 0) return ret; nokia_abis_nm_queue_send_next(bts); /* next segment */ len_remain -= len_to_send; data += len_to_send; seq++; } return 0; } /* TODO: put in a separate file ? */ static int abis_nm_send_config(struct gsm_bts *bts, uint8_t bts_type) { struct gsm_bts_trx *trx; uint8_t config[2048]; /* TODO: might be too small if lots of TRX are used */ int len = 0; int idx = 0; int ret; int hopping = 0; int need_hopping = 0; memset(config, 0, sizeof(config)); llist_for_each_entry(trx, &bts->trx_list, list) { #if 0 /* debugging */ printf("TRX\n"); printf(" arfcn: %d\n", trx->arfcn); printf(" bsic: %d\n", trx->bts->bsic); uint8_t ca[20]; memset(ca, 0xFF, sizeof(ca)); ret = generate_cell_chan_list(ca, trx->bts); printf(" ca (%d): %s\n", ret, osmo_hexdump(ca, sizeof(ca))); int i; for (i = 0; i < ARRAY_SIZE(trx->ts); i++) { struct gsm_bts_trx_ts *ts = &trx->ts[i]; printf(" pchan %d: %d\n", i, ts->pchan); } #endif ret = make_fu_config(trx, idx + 1, config + len, &hopping); need_hopping |= hopping; len += ret; idx++; } ret = make_bts_config(bts_type, idx, config + len, need_hopping); len += ret; #if 0 /* debugging */ dump_elements(config, len); #endif return abis_nm_send_multi_segments(bts, NOKIA_MSG_CONF_DATA, 1, config, len); } #define GET_NEXT_BYTE if(idx >= len) return 0; \ ub = data[idx++]; static int find_element(uint8_t * data, int len, uint16_t id, uint8_t * value, int max_value) { uint8_t ub; int idx = 0; int found = 0; int constructed __attribute__((unused)); uint16_t id_value; for (;;) { GET_NEXT_BYTE; /* encoding bit, construced means that other elements are contained */ constructed = ((ub & 0x20) ? 1 : 0); if ((ub & 0x1F) == 0x1F) { /* fixed pattern, ID follows */ GET_NEXT_BYTE; /* ID */ id_value = ub & 0x7F; if (ub & 0x80) { /* extension bit */ GET_NEXT_BYTE; /* ID low part */ id_value = (id_value << 7) | (ub & 0x7F); } if (id_value == id) found = 1; } else { id_value = (ub & 0x3F); if (id_value == id) found = 1; } GET_NEXT_BYTE; /* length */ if (found) { /* get data */ uint8_t n = ub; uint8_t i; for (i = 0; i < n; i++) { GET_NEXT_BYTE; if (max_value <= 0) return -1; /* buffer too small */ *value = ub; value++; max_value--; } return n; /* length */ } else { /* skip data */ uint8_t n = ub; uint8_t i; for (i = 0; i < n; i++) { GET_NEXT_BYTE; } } } return 0; /* not found */ } static int dump_elements(uint8_t * data, int len) { uint8_t ub; int idx = 0; int constructed; uint16_t id_value; static char indent[100] = ""; /* TODO: move static to BTS context */ for (;;) { GET_NEXT_BYTE; /* encoding bit, construced means that other elements are contained */ constructed = ((ub & 0x20) ? 1 : 0); if ((ub & 0x1F) == 0x1F) { /* fixed pattern, ID follows */ GET_NEXT_BYTE; /* ID */ id_value = ub & 0x7F; if (ub & 0x80) { /* extension bit */ GET_NEXT_BYTE; /* ID low part */ id_value = (id_value << 7) | (ub & 0x7F); } } else { id_value = (ub & 0x3F); } GET_NEXT_BYTE; /* length */ printf("%s--ID = 0x%02X (%s) %s\n", indent, id_value, get_element_name_string(id_value), constructed ? "** constructed **" : ""); printf("%s length = %d\n", indent, ub); printf("%s %s\n", indent, osmo_hexdump(data + idx, ub)); if (constructed) { int indent_len = strlen(indent); strcat(indent, " "); dump_elements(data + idx, ub); indent[indent_len] = 0; } /* skip data */ uint8_t n = ub; uint8_t i; for (i = 0; i < n; i++) { GET_NEXT_BYTE; } } return 0; } /* TODO: put in a separate file ? */ /* taken from abis_nm.c */ static void nokia_abis_nm_queue_send_next(struct gsm_bts *bts) { int wait = 0; struct msgb *msg; /* the queue is empty */ while (!llist_empty(&bts->abis_queue)) { msg = msgb_dequeue(&bts->abis_queue); wait = OBSC_NM_W_ACK_CB(msg); abis_sendmsg(msg); if (wait) break; } bts->abis_nm_pend = wait; } /* TODO: put in a separate file ? */ /* timer for restarting OML after BTS reset */ static void reset_timer_cb(void *_bts) { struct gsm_bts *bts = _bts; struct gsm_e1_subslot *e1_link = &bts->oml_e1_link; struct e1inp_line *line; bts->nokia.wait_reset = 0; /* OML link */ line = e1inp_line_find(e1_link->e1_nr); if (!line) { LOGP(DLINP, LOGL_ERROR, "BTS %u OML link referring to " "non-existing E1 line %u\n", bts->nr, e1_link->e1_nr); return; } start_sabm_in_line(line, 0, -1); /* stop all first */ start_sabm_in_line(line, 1, SAPI_OML); /* start only OML */ } /* TODO: put in a separate file ? */ /* This is how the configuration is done: - start OML link - reset BTS - receive ACK, wait some time and restart OML link - receive OMU STARTED message, send START DOWNLOAD REQ - receive CNF REQ message, send CONF DATA - receive ACK, start RSL link(s) ACK some other messages received from the BTS. Probably its also possible to configure the BTS without a reset, this has not been tested yet. */ static int abis_nm_rcvmsg_fom(struct msgb *mb) { struct e1inp_sign_link *sign_link = (struct e1inp_sign_link *)mb->dst; struct gsm_bts *bts = sign_link->trx->bts; struct abis_om_hdr *oh = msgb_l2(mb); struct abis_om_nokia_hdr *noh = msgb_l3(mb); uint8_t mt = noh->msg_type; int ret = 0; uint16_t ref = ntohs(noh->reference); uint8_t info[256]; uint8_t ack = 0xFF; uint8_t severity = 0xFF; int str_len; int len_data; if (bts->nokia.wait_reset) { LOGP(DNM, LOGL_INFO, "Ignore message while waiting for reset\n"); return ret; } if (oh->length < sizeof(struct abis_om_nokia_hdr)) { LOGP(DNM, LOGL_ERROR, "Message too short\n"); return -EINVAL; } len_data = oh->length - sizeof(struct abis_om_nokia_hdr); LOGP(DNM, LOGL_INFO, "(0x%02X) %s\n", mt, get_msg_type_name_string(mt)); #if 0 /* debugging */ dump_elements(noh->data, len_data); #endif switch (mt) { case NOKIA_MSG_OMU_STARTED: if (find_element(noh->data, len_data, NOKIA_EI_BTS_TYPE, &bts->nokia.bts_type, sizeof(uint8_t)) == sizeof(uint8_t)) LOGP(DNM, LOGL_INFO, "BTS type = %d (%s)\n", bts->nokia.bts_type, get_bts_type_string(bts->nokia.bts_type)); else LOGP(DNM, LOGL_ERROR, "BTS type not found\n"); /* send START_DOWNLOAD_REQ */ abis_nm_download_req(bts, ref); break; case NOKIA_MSG_MF_REQ: break; case NOKIA_MSG_CONF_REQ: /* send ACK */ abis_nm_ack(bts, ref); nokia_abis_nm_queue_send_next(bts); /* send CONF_DATA */ abis_nm_send_config(bts, bts->nokia.bts_type); bts->nokia.configured = 1; break; case NOKIA_MSG_ACK: if (find_element (noh->data, len_data, NOKIA_EI_ACK, &ack, sizeof(uint8_t)) == sizeof(uint8_t)) { LOGP(DNM, LOGL_INFO, "ACK = %d\n", ack); if (ack != 1) { LOGP(DNM, LOGL_ERROR, "No ACK received (%d)\n", ack); /* TODO: properly handle failures (NACK) */ } } else LOGP(DNM, LOGL_ERROR, "ACK not found\n"); /* TODO: the assumption for the following is that no NACK was received */ /* ACK for reset message ? */ if (!bts->nokia.did_reset) { bts->nokia.did_reset = 1; /* TODO: For the InSite processing the received data is blocked in the driver during reset. Otherwise the LAPD module might assert because the InSite sends garbage on the E1 line during reset. This is done by looking at "wait_reset" in the driver (function handle_ts1_read()) and ignoring the received data. It seems to be necessary for the MetroSite too. */ bts->nokia.wait_reset = 1; osmo_timer_setup(&bts->nokia.reset_timer, reset_timer_cb, bts); osmo_timer_schedule(&bts->nokia.reset_timer, bts->nokia.bts_reset_timer_cnf, 0); struct gsm_e1_subslot *e1_link = &bts->oml_e1_link; struct e1inp_line *line; /* OML link */ line = e1inp_line_find(e1_link->e1_nr); if (!line) { LOGP(DLINP, LOGL_ERROR, "BTS %u OML link referring to " "non-existing E1 line %u\n", bts->nr, e1_link->e1_nr); return -ENOMEM; } start_sabm_in_line(line, 0, -1); /* stop all first */ } /* ACK for CONF DATA message ? */ if (bts->nokia.configured != 0) { /* start TRX (RSL link) */ struct gsm_e1_subslot *e1_link = &sign_link->trx->rsl_e1_link; struct e1inp_line *line; bts->nokia.configured = 0; /* RSL Link */ line = e1inp_line_find(e1_link->e1_nr); if (!line) { LOGP(DLINP, LOGL_ERROR, "TRX (%u/%u) RSL link referring " "to non-existing E1 line %u\n", sign_link->trx->bts->nr, sign_link->trx->nr, e1_link->e1_nr); return -ENOMEM; } /* start TRX */ start_sabm_in_line(line, 1, SAPI_RSL); /* start only RSL */ } break; case NOKIA_MSG_STATE_CHANGED: /* send ACK */ abis_nm_ack(bts, ref); break; case NOKIA_MSG_CONF_COMPLETE: /* send ACK */ abis_nm_ack(bts, ref); break; case NOKIA_MSG_BLOCK_CTRL_REQ: /* seems to be send when something goes wrong !? */ /* send ACK (do we have to send an ACK ?) */ abis_nm_ack(bts, ref); break; case NOKIA_MSG_ALARM: find_element(noh->data, len_data, NOKIA_EI_SEVERITY, &severity, sizeof(severity)); /* TODO: there might be alarms with both elements set */ str_len = find_element(noh->data, len_data, NOKIA_EI_ADD_INFO, info, sizeof(info)); if (str_len > 0) { info[str_len] = 0; LOGP(DNM, LOGL_INFO, "ALARM Severity %s (%d) : %s\n", get_severity_string(severity), severity, info); } else { /* nothing found, try details */ str_len = find_element(noh->data, len_data, NOKIA_EI_ALARM_DETAIL, info, sizeof(info)); if (str_len > 0) { uint16_t code; info[str_len] = 0; code = (info[0] << 8) + info[1]; LOGP(DNM, LOGL_INFO, "ALARM Severity %s (%d), code 0x%X : %s\n", get_severity_string(severity), severity, code, info + 2); } } /* send ACK */ abis_nm_ack(bts, ref); break; } nokia_abis_nm_queue_send_next(bts); return ret; } /* TODO: put in a separate file ? */ int abis_nokia_rcvmsg(struct msgb *msg) { struct abis_om_hdr *oh = msgb_l2(msg); int rc = 0; /* Various consistency checks */ if (oh->placement != ABIS_OM_PLACEMENT_ONLY) { LOGP(DNM, LOGL_ERROR, "ABIS OML placement 0x%x not supported\n", oh->placement); if (oh->placement != ABIS_OM_PLACEMENT_FIRST) return -EINVAL; } if (oh->sequence != 0) { LOGP(DNM, LOGL_ERROR, "ABIS OML sequence 0x%x != 0x00\n", oh->sequence); return -EINVAL; } msg->l3h = (unsigned char *)oh + sizeof(*oh); switch (oh->mdisc) { case ABIS_OM_MDISC_FOM: LOGP(DNM, LOGL_INFO, "ABIS_OM_MDISC_FOM\n"); rc = abis_nm_rcvmsg_fom(msg); break; case ABIS_OM_MDISC_MANUF: LOGP(DNM, LOGL_INFO, "ABIS_OM_MDISC_MANUF\n"); break; case ABIS_OM_MDISC_MMI: case ABIS_OM_MDISC_TRAU: LOGP(DNM, LOGL_ERROR, "unimplemented ABIS OML message discriminator 0x%x\n", oh->mdisc); break; default: LOGP(DNM, LOGL_ERROR, "unknown ABIS OML message discriminator 0x%x\n", oh->mdisc); return -EINVAL; } msgb_free(msg); return rc; } static int bts_model_nokia_site_start(struct gsm_network *net); static void bts_model_nokia_site_e1line_bind_ops(struct e1inp_line *line) { e1inp_line_bind_ops(line, &bts_isdn_e1inp_line_ops); } static struct gsm_bts_model model_nokia_site = { .type = GSM_BTS_TYPE_NOKIA_SITE, .name = "nokia_site", .start = bts_model_nokia_site_start, .oml_rcvmsg = &abis_nokia_rcvmsg, .e1line_bind_ops = &bts_model_nokia_site_e1line_bind_ops, }; static struct gsm_network *my_net; static int bts_model_nokia_site_start(struct gsm_network *net) { model_nokia_site.features.data = &model_nokia_site._features_data[0]; model_nokia_site.features.data_len = sizeof(model_nokia_site._features_data); osmo_bts_set_feature(&model_nokia_site.features, BTS_FEAT_HOPPING); osmo_bts_set_feature(&model_nokia_site.features, BTS_FEAT_HSCSD); osmo_bts_set_feature(&model_nokia_site.features, BTS_FEAT_MULTI_TSC); osmo_signal_register_handler(SS_L_INPUT, inp_sig_cb, NULL); osmo_signal_register_handler(SS_L_GLOBAL, gbl_sig_cb, NULL); osmo_signal_register_handler(SS_NM, nm_sig_cb, NULL); my_net = net; return 0; } int bts_model_nokia_site_init(void) { return gsm_bts_model_register(&model_nokia_site); }