#ifndef _GSM_DATA_H #define _GSM_DATA_H #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define GSM_T3122_DEFAULT 10 struct mgcp_client_conf; struct mgcp_client; struct gsm0808_cell_id; struct osmo_mgcpc_ep; /** annotations for msgb ownership */ #define __uses #define OBSC_NM_W_ACK_CB(__msgb) (__msgb)->cb[3] struct bsc_subscr; struct gprs_ra_id; struct handover; #define OBSC_LINKID_CB(__msgb) (__msgb)->cb[3] #define tmsi_from_string(str) strtoul(str, NULL, 10) /* 3-bit long values */ #define EARFCN_PRIO_INVALID 8 #define EARFCN_MEAS_BW_INVALID 8 /* 5-bit long values */ #define EARFCN_QRXLV_INVALID 32 #define EARFCN_THRESH_LOW_INVALID 32 struct msgb; typedef int gsm_cbfn(unsigned int hooknum, unsigned int event, struct msgb *msg, void *data, void *param); /* Maximum number of neighbor cells whose average we track */ #define MAX_NEIGH_MEAS 10 /* Maximum size of the averaging window for neighbor cells */ #define MAX_WIN_NEIGH_AVG 10 /* Maximum number of report history we store */ #define MAX_MEAS_REP 10 /* processed neighbor measurements for one cell */ struct neigh_meas_proc { uint16_t arfcn; uint8_t bsic; uint8_t rxlev[MAX_WIN_NEIGH_AVG]; unsigned int rxlev_cnt; uint8_t last_seen_nr; }; struct gsm_classmark { bool classmark1_set; struct gsm48_classmark1 classmark1; uint8_t classmark2_len; uint8_t classmark2[3]; uint8_t classmark3_len; uint8_t classmark3[14]; /* if cm3 gets extended by spec, it will be truncated */ }; enum subscr_sccp_state { SUBSCR_SCCP_ST_NONE, SUBSCR_SCCP_ST_WAIT_CONN_CONF, SUBSCR_SCCP_ST_CONNECTED }; enum channel_rate { CH_RATE_SDCCH, CH_RATE_HALF, CH_RATE_FULL, }; struct channel_mode_and_rate { enum gsm48_chan_mode chan_mode; enum channel_rate chan_rate; uint16_t s15_s0; }; /* Information retrieved during an Assignment Request from the MSC. This is storage of the Assignment instructions * parsed from the Assignment Request message, to pass on until the gscon and assignment FSMs have decided whether an * Assignment is actually going to be carried out. Should remain unchanged after initial decoding. */ struct assignment_request { bool aoip; uint16_t msc_assigned_cic; char msc_rtp_addr[INET_ADDRSTRLEN]; uint16_t msc_rtp_port; bool use_osmux; uint8_t osmux_cid; /* Rate/codec setting in preference order (need at least 1 !) */ int n_ch_mode_rate; struct channel_mode_and_rate ch_mode_rate[3]; }; /* State of an ongoing Assignment, while the assignment_fsm is still busy. This serves as state separation to keep the * currently used lchan and gscon unmodified until the outcome of an Assignment is known. If the Assignment fails, this * state is simply discarded, and the gscon carries on with the original lchan remaining unchanged. */ struct assignment_fsm_data { struct assignment_request req; bool requires_voice_stream; struct osmo_fsm_inst *fi; struct gsm_lchan *new_lchan; /* Whether this assignment triggered creation of the MGW endpoint: if the assignment * fails, we will release that again as soon as possible. (If false, the endpoint already * existed before or isn't needed at all.)*/ struct osmo_mgcpc_ep_ci *created_ci_for_msc; enum gsm0808_cause failure_cause; enum gsm48_rr_cause rr_cause; bool result_rate_ctr_done; }; enum hodec_id { HODEC_NONE, HODEC1 = 1, HODEC2 = 2, HODEC_USER, HODEC_REMOTE, }; /* For example, to count specific kinds of ongoing handovers, it is useful to be able to OR-combine * scopes. */ enum handover_scope { HO_NO_HANDOVER = 0, HO_INTRA_CELL = 0x1, HO_INTRA_BSC = 0x2, HO_INTER_BSC_OUT = 0x4, HO_INTER_BSC_IN = 0x8, HO_SCOPE_ALL = 0xffff, }; extern const struct value_string handover_scope_names[]; inline static const char *handover_scope_name(enum handover_scope val) { return get_value_string(handover_scope_names, val); } struct handover_out_req { enum hodec_id from_hodec_id; struct gsm_lchan *old_lchan; struct neighbor_ident_key target_nik; enum gsm_chan_t new_lchan_type; /*< leave GSM_LCHAN_NONE to use same as old_lchan */ }; struct handover_in_req { struct gsm0808_channel_type ct; struct gsm0808_speech_codec_list scl; struct gsm0808_encrypt_info ei; struct gsm_classmark classmark; /* chosen_encr_alg reflects the encoded value as in RSL_ENC_ALG_A5(a5_numer): * chosen_encr_alg == 1 means A5/0 i.e. no encryption, chosen_encr_alg == 4 means A5/3. * chosen_encr_alg == 0 means no such IE was present. */ uint8_t chosen_encr_alg; struct gsm0808_cell_id cell_id_serving; char cell_id_serving_name[64]; struct gsm0808_cell_id cell_id_target; char cell_id_target_name[64]; uint16_t msc_assigned_cic; char msc_assigned_rtp_addr[INET_ADDRSTRLEN]; uint16_t msc_assigned_rtp_port; }; struct handover { struct osmo_fsm_inst *fi; enum hodec_id from_hodec_id; enum handover_scope scope; enum gsm_chan_t new_lchan_type; struct neighbor_ident_key target_cell; uint8_t ho_ref; struct gsm_bts *new_bts; struct gsm_lchan *new_lchan; bool async; struct handover_in_req inter_bsc_in; struct osmo_mgcpc_ep_ci *created_ci_for_msc; }; /* active radio connection of a mobile subscriber */ struct gsm_subscriber_connection { /* global linked list of subscriber_connections */ struct llist_head entry; /* FSM instance to control the subscriber connection state (RTP, A) */ struct osmo_fsm_inst *fi; /* libbsc subscriber information (if available) */ struct bsc_subscr *bsub; /* back pointers */ struct gsm_network *network; /* the primary / currently active lchan to the BTS/subscriber. During Assignment and Handover, separate lchans * are kept in the .assignment or .handover sub-structs, respectively, so that this lchan remains unaffected * until Assignment or Handover have actually succeeded. */ struct gsm_lchan *lchan; /* Only valid during an ongoing Assignment; might be overwritten at any time by a failed Assignment attempt. * Once an Assignment was successful, all relevant state must be copied out of this sub-struct. */ struct assignment_fsm_data assignment; /* handover information, if a handover is pending for this conn. Valid only during an ongoing Handover * operation. If a Handover was successful, all relevant state must be copied out of this sub-struct. */ struct handover ho; /* buffer/cache for classmark of the ME of the subscriber */ struct gsm_classmark classmark; /* Queue DTAP messages during handover/assignment (msgb_enqueue()/msgb_dequeue())*/ struct llist_head dtap_queue; unsigned int dtap_queue_len; struct { int failures; struct penalty_timers *penalty_timers; } hodec2; /* "Codec List (MSC Preferred)" as received by the BSSAP Assignment Request. 3GPP 48.008 * 3.2.2.103 says: * The "Codec List (MSC Preferred)" shall not include codecs * that are not supported by the MS. * i.e. by heeding the "Codec list (MSC Preferred)", we inherently heed the MS bearer * capabilities, which the MSC is required to translate into the codec list. */ struct gsm0808_speech_codec_list codec_list; /* flag to prevent multiple simultaneous ciphering commands */ int ciphering_handled; /* state related to welcome USSD */ uint8_t new_subscriber; /* state related to osmo_bsc_filter.c */ struct bsc_filter_state filter_state; /* SCCP connection associatd with this subscriber_connection */ struct { /* for advanced ping/pong */ int send_ping; /* SCCP connection realted */ struct bsc_msc_data *msc; /* Sigtran connection ID */ int conn_id; enum subscr_sccp_state state; } sccp; /* for audio handling */ struct { uint16_t msc_assigned_cic; /* RTP address where the MSC expects us to send the RTP stream coming from the BTS. */ char msc_assigned_rtp_addr[INET_ADDRSTRLEN]; uint16_t msc_assigned_rtp_port; /* The endpoint at the MGW used to join both BTS and MSC side connections, e.g. * "rtpbridge/23@mgw". */ struct osmo_mgcpc_ep *mgw_endpoint; /* The connection identifier of the osmo_mgcpc_ep used to transceive RTP towards the MSC. * (The BTS side CI is handled by struct gsm_lchan and the lchan_fsm.) */ struct osmo_mgcpc_ep_ci *mgw_endpoint_ci_msc; } user_plane; /* LCLS (local call, local switch) related state */ struct { uint8_t global_call_ref[15]; uint8_t global_call_ref_len; /* length of global_call_ref */ enum gsm0808_lcls_config config; /* TS 48.008 3.2.2.116 */ enum gsm0808_lcls_control control; /* TS 48.008 3.2.2.117 */ /* LCLS FSM */ struct osmo_fsm_inst *fi; /* pointer to "other" connection, if Call Leg Relocation was successful */ struct gsm_subscriber_connection *other; } lcls; }; /* 16 is the max. number of SI2quater messages according to 3GPP TS 44.018 Table 10.5.2.33b.1: 4-bit index is used (2#1111 = 10#15) */ #define SI2Q_MAX_NUM 16 /* length in bits (for single SI2quater message) */ #define SI2Q_MAX_LEN 160 #define SI2Q_MIN_LEN 18 struct osmo_bsc_data; struct osmo_bsc_sccp_con; /* Channel Request reason */ enum gsm_chreq_reason_t { GSM_CHREQ_REASON_EMERG, GSM_CHREQ_REASON_PAG, GSM_CHREQ_REASON_CALL, GSM_CHREQ_REASON_LOCATION_UPD, GSM_CHREQ_REASON_OTHER, GSM_CHREQ_REASON_PDCH, }; /* lchans 0..3 are SDCCH in combined channel configuration, use 4 as magic number for BCCH hack - see osmo-bts-../oml.c:opstart_compl() */ #define CCCH_LCHAN 4 #define TRX_NR_TS 8 #define TS_MAX_LCHAN 8 #define HARDCODED_ARFCN 123 #define HARDCODED_BSIC 0x3f /* NCC = 7 / BCC = 7 */ /* for multi-drop config */ #define HARDCODED_BTS0_TS 1 #define HARDCODED_BTS1_TS 6 #define HARDCODED_BTS2_TS 11 #define MAX_VERSION_LENGTH 64 enum gsm_hooks { GSM_HOOK_NM_SWLOAD, GSM_HOOK_RR_PAGING, GSM_HOOK_RR_SECURITY, }; enum bts_gprs_mode { BTS_GPRS_NONE = 0, BTS_GPRS_GPRS = 1, BTS_GPRS_EGPRS = 2, }; struct gsm_lchan; struct osmo_rtp_socket; struct rtp_socket; /* Network Management State */ struct gsm_nm_state { uint8_t operational; uint8_t administrative; uint8_t availability; }; struct gsm_abis_mo { uint8_t obj_class; uint8_t procedure_pending; struct abis_om_obj_inst obj_inst; const char *name; struct gsm_nm_state nm_state; struct tlv_parsed *nm_attr; struct gsm_bts *bts; }; /* Ericsson OM2000 Managed Object */ struct abis_om2k_mo { uint8_t class; uint8_t bts; uint8_t assoc_so; uint8_t inst; } __attribute__ ((packed)); struct om2k_mo { struct abis_om2k_mo addr; struct osmo_fsm_inst *fsm; }; #define A38_XOR_MIN_KEY_LEN 12 #define A38_XOR_MAX_KEY_LEN 16 #define A38_COMP128_KEY_LEN 16 #define RSL_ENC_ALG_A5(x) (x+1) #define MAX_EARFCN_LIST 32 /* is the data link established? who established it? */ #define LCHAN_SAPI_UNUSED 0 #define LCHAN_SAPI_MS 1 #define LCHAN_SAPI_NET 2 /* BTS ONLY */ #define MAX_NUM_UL_MEAS 104 #define LC_UL_M_F_L1_VALID (1 << 0) #define LC_UL_M_F_RES_VALID (1 << 1) struct bts_ul_meas { /* BER in units of 0.01%: 10.000 == 100% ber, 0 == 0% ber */ uint16_t ber10k; /* timing advance offset (in quarter bits) */ int16_t ta_offs_qbits; /* C/I ratio in dB */ float c_i; /* flags */ uint8_t is_sub:1; /* RSSI in dBm * -1 */ uint8_t inv_rssi; }; struct bts_codec_conf { uint8_t hr; uint8_t efr; uint8_t amr; }; struct amr_mode { uint8_t mode; uint8_t threshold; uint8_t hysteresis; }; struct amr_multirate_conf { uint8_t gsm48_ie[2]; struct amr_mode ms_mode[4]; struct amr_mode bts_mode[4]; uint8_t num_modes; }; /* /BTS ONLY */ enum lchan_csd_mode { LCHAN_CSD_M_NT, LCHAN_CSD_M_T_1200_75, LCHAN_CSD_M_T_600, LCHAN_CSD_M_T_1200, LCHAN_CSD_M_T_2400, LCHAN_CSD_M_T_9600, LCHAN_CSD_M_T_14400, LCHAN_CSD_M_T_29000, LCHAN_CSD_M_T_32000, }; /* State of the SAPIs in the lchan */ enum lchan_sapi_state { LCHAN_SAPI_S_NONE, LCHAN_SAPI_S_REQ, LCHAN_SAPI_S_ASSIGNED, LCHAN_SAPI_S_REL, LCHAN_SAPI_S_ERROR, }; #define MAX_A5_KEY_LEN (128/8) struct gsm_encr { uint8_t alg_id; uint8_t key_len; uint8_t key[MAX_A5_KEY_LEN]; }; #define LOGPLCHAN(lchan, ss, level, fmt, args...) \ LOGP(ss, level, "%s (ss=%d,%s) (%s) " fmt, \ lchan ? gsm_ts_and_pchan_name(lchan->ts) : "-", \ lchan ? lchan->nr : 0, \ lchan ? gsm_lchant_name(lchan->type) : "-", \ bsc_subscr_name(lchan && lchan->conn ? lchan->conn->bsub : NULL), \ ## args) /* Iterate lchans that have an FSM allocated based based on explicit pchan kind * (GSM_PCHAN_* constant). * Remark: PDCH related lchans are not handled in BSC but in PCU, so trying to * iterate through GSM_PCHAN_PDCH is considered a void loop. */ #define ts_as_pchan_for_each_lchan(lchan, ts, as_pchan) \ for (lchan = (ts)->lchan; \ ((lchan - (ts)->lchan) < ARRAY_SIZE((ts)->lchan)) \ && lchan->fi \ && lchan->nr < pchan_subslots(as_pchan); \ lchan++) /* Iterate lchans that have an FSM allocated based on current PCHAN * mode set in \ref ts. * usage: * struct gsm_lchan *lchan; * struct gsm_bts_trx_ts *ts = get_some_timeslot(); * ts_for_each_lchan(lchan, ts) { * LOGPLCHAN(DMAIN, LOGL_DEBUG, "hello world\n"); * } */ #define ts_for_each_lchan(lchan, ts) ts_as_pchan_for_each_lchan(lchan, ts, (ts)->pchan_is) /* Iterate over all possible lchans available that have an FSM allocated based * on PCHAN \ref ts (dynamic) configuration. * Iterate all lchan instances set up by this \ref ts type, including those * lchans currently disabled or in process of being enabled (e.g. due to dynamic * timeslot in switchover). Compare ts_for_each_lchan(), which iterates only the * enabled lchans. * For example, it is useful in case dynamic timeslot \ref ts is in process of * switching from configuration PDCH (no lchans) to TCH_F (1 lchan), where * pchan_is is still set to PDCH but \ref ts may contain already an \ref lchan * of type TCH_F which initiated the request to switch the \ts configuration. */ #define ts_for_each_potential_lchan(lchan, ts) ts_as_pchan_for_each_lchan(lchan, ts, (ts)->pchan_on_init) enum lchan_activate_mode { FOR_NONE, FOR_MS_CHANNEL_REQUEST, FOR_ASSIGNMENT, FOR_HANDOVER, FOR_VTY, }; extern const struct value_string lchan_activate_mode_names[]; static inline const char *lchan_activate_mode_name(enum lchan_activate_mode activ_for) { return get_value_string(lchan_activate_mode_names, activ_for); } struct lchan_activate_info { enum lchan_activate_mode activ_for; struct gsm_subscriber_connection *for_conn; /* This always is for a specific lchan, so its lchan->type indicates full or half rate. * When a dyn TS was selected, the lchan->type has been set to the desired rate. */ enum gsm48_chan_mode chan_mode; struct gsm_encr encr; /* AMR config */ uint16_t s15_s0; bool requires_voice_stream; bool wait_before_switching_rtp; /*< true = requires LCHAN_EV_READY_TO_SWITCH_RTP */ uint16_t msc_assigned_cic; /* During intra-BSC handover, we keep the MGW endpoint intact and just re-route to the new lchan. This * activate_info is for the new lchan, the re_use_mgw_endpoint_from_lchan points at the old lchan. */ struct gsm_lchan *re_use_mgw_endpoint_from_lchan; }; struct gsm_lchan { /* The TS that we're part of */ struct gsm_bts_trx_ts *ts; /* The logical subslot number in the TS */ uint8_t nr; char *name; char *last_error; struct osmo_fsm_inst *fi; struct osmo_fsm_inst *fi_rtp; struct osmo_mgcpc_ep_ci *mgw_endpoint_ci_bts; struct { struct lchan_activate_info info; bool activ_ack; /*< true as soon as RSL Chan Activ Ack is received */ bool immediate_assignment_sent; /*! This flag ensures that when an lchan activation has succeeded, and we have already * sent ACKs like Immediate Assignment or BSSMAP Assignment Complete, and if other errors * occur later, e.g. during release, that we don't send a NACK out of context. */ bool concluded; enum gsm0808_cause gsm0808_error_cause; } activate; struct { /* If an event to release the lchan comes in while still waiting for responses, just mark this * flag, so that the lchan will gracefully release at the next sensible junction. */ bool requested; bool do_rr_release; /* There is an RSL error cause of value 0, so we need a separate flag. */ bool in_error; /* RSL error code, RSL_ERR_* */ uint8_t rsl_error_cause; /* If a release event is being handled, ignore other ricocheting release events until that * release handling has concluded. */ bool in_release_handler; /* is this release at the end of a CSFB call? */ bool is_csfb; } release; /* The logical channel type */ enum gsm_chan_t type; /* RSL channel mode */ enum rsl_cmod_spd rsl_cmode; /* If TCH, traffic channel mode */ enum gsm48_chan_mode tch_mode; enum lchan_csd_mode csd_mode; /* Power levels for MS and BTS */ uint8_t bs_power; uint8_t ms_power; /* Encryption information */ struct gsm_encr encr; /* AMR bits */ uint8_t mr_ms_lv[7]; uint8_t mr_bts_lv[7]; /* AMR bits were based on these rate bits: */ uint16_t s15_s0; /* Established data link layer services */ uint8_t sapis[8]; struct { uint32_t bound_ip; /*< where the BTS receives RTP */ uint16_t bound_port; uint32_t connect_ip; /*< where the BTS sends RTP to (MGW) */ uint16_t connect_port; uint16_t conn_id; uint8_t rtp_payload; uint8_t rtp_payload2; uint8_t speech_mode; /* info we need to postpone the AoIP * assignment completed message */ struct { uint8_t rr_cause; bool valid; } ass_compl; } abis_ip; uint8_t rqd_ta; /* table of neighbor cell measurements */ struct neigh_meas_proc neigh_meas[MAX_NEIGH_MEAS]; /* cache of last measurement reports on this lchan */ struct gsm_meas_rep meas_rep[MAX_MEAS_REP]; int meas_rep_idx; int meas_rep_count; uint8_t meas_rep_last_seen_nr; /* GSM Random Access data */ /* TODO: don't allocate this, rather keep an "is_present" flag */ struct gsm48_req_ref *rqd_ref; struct gsm_subscriber_connection *conn; /* Depending on the preferences that where submitted together with * the assignment and the current channel load, the BSC has to select * one of the offered codec/rates. The final selection by the BSC is * stored here and is used when sending the assignment complete or * when performing a handover procedure. */ struct channel_mode_and_rate ch_mode_rate; }; /* One Timeslot in a TRX */ struct gsm_bts_trx_ts { struct gsm_bts_trx *trx; /* number of this timeslot at the TRX */ uint8_t nr; struct osmo_fsm_inst *fi; char *last_errmsg; /* vty phys_chan_config setting, not necessarily in effect in case it was changed in the telnet * vty after OML activation. Gets written on vty 'write file'. */ enum gsm_phys_chan_config pchan_from_config; /* When the timeslot OML is established, pchan_from_config is copied here. This is the pchan * currently in effect; for dynamic ts, this is the dyn kind (GSM_PCHAN_TCH_F_TCH_H_PDCH or * GSM_PCHAN_TCH_F_PDCH) and does not show the pchan type currently active. */ enum gsm_phys_chan_config pchan_on_init; /* This is the *actual* pchan type currently active. For dynamic timeslots, this reflects either * GSM_PCHAN_NONE or one of the standard GSM_PCHAN_TCH_F, GSM_PCHAN_TCH_H, GSM_PCHAN_PDCH. * Callers can use this transparently without being aware of dyn ts. */ enum gsm_phys_chan_config pchan_is; /* After a PDCH ACT NACK, we shall not infinitely loop to try and ACT again. * Also marks a timeslot where PDCH was deactivated by VTY. This is cleared whenever a timeslot * enters IN_USE state, i.e. after each TCH use we try to PDCH ACT once again. */ bool pdch_act_allowed; /* Whether TS_EV_OML_READY was received */ bool is_oml_ready; /* Whether TS_EV_RSL_READY was received */ bool is_rsl_ready; struct gsm_abis_mo mo; struct tlv_parsed nm_attr; uint8_t nm_chan_comb; int tsc; /* -1 == use BTS TSC */ struct { /* Parameters below are configured by VTY */ int enabled; uint8_t maio; uint8_t hsn; struct bitvec arfcns; uint8_t arfcns_data[1024/8]; /* This is the pre-computed MA for channel assignments */ struct bitvec ma; uint8_t ma_len; /* part of ma_data that is used */ uint8_t ma_data[8]; /* 10.5.2.21: max 8 bytes value part */ } hopping; /* To which E1 subslot are we connected */ struct gsm_e1_subslot e1_link; union { struct { struct om2k_mo om2k_mo; } rbs2000; }; struct gsm_lchan lchan[TS_MAX_LCHAN]; }; /* One TRX in a BTS */ struct gsm_bts_trx { /* list header in bts->trx_list */ struct llist_head list; struct gsm_bts *bts; /* number of this TRX in the BTS */ uint8_t nr; /* human readable name / description */ char *description; /* how do we talk RSL with this TRX? */ struct gsm_e1_subslot rsl_e1_link; uint8_t rsl_tei; struct e1inp_sign_link *rsl_link; /* Timeout for initiating the RSL connection. */ struct osmo_timer_list rsl_connect_timeout; /* Some BTS (specifically Ericsson RBS) have a per-TRX OML Link */ struct e1inp_sign_link *oml_link; struct gsm_abis_mo mo; struct tlv_parsed nm_attr; struct { struct gsm_abis_mo mo; } bb_transc; uint16_t arfcn; int nominal_power; /* in dBm */ unsigned int max_power_red; /* in actual dB */ union { struct { struct { struct gsm_abis_mo mo; } bbsig; struct { struct gsm_abis_mo mo; } pa; } bs11; struct { unsigned int test_state; uint8_t test_nr; struct rxlev_stats rxlev_stat; } ipaccess; struct { struct { struct om2k_mo om2k_mo; } trxc; struct { struct om2k_mo om2k_mo; } rx; struct { struct om2k_mo om2k_mo; } tx; } rbs2000; }; struct gsm_bts_trx_ts ts[TRX_NR_TS]; }; #define GSM_BTS_SI2Q(bts, i) (struct gsm48_system_information_type_2quater *)((bts)->si_buf[SYSINFO_TYPE_2quater][i]) #define GSM_BTS_HAS_SI(bts, i) ((bts)->si_valid & (1 << i)) #define GSM_BTS_SI(bts, i) (void *)((bts)->si_buf[i][0]) #define GSM_LCHAN_SI(lchan, i) (void *)((lchan)->si.buf[i][0]) enum gsm_bts_type { GSM_BTS_TYPE_UNKNOWN, GSM_BTS_TYPE_BS11, GSM_BTS_TYPE_NANOBTS, GSM_BTS_TYPE_RBS2000, GSM_BTS_TYPE_NOKIA_SITE, GSM_BTS_TYPE_OSMOBTS, _NUM_GSM_BTS_TYPE }; enum gsm_bts_type_variant { BTS_UNKNOWN, BTS_OSMO_LITECELL15, BTS_OSMO_OCTPHY, BTS_OSMO_SYSMO, BTS_OSMO_TRX, _NUM_BTS_VARIANT }; /* Used by OML layer for BTS Attribute reporting */ enum bts_attribute { BTS_TYPE_VARIANT, BTS_SUB_MODEL, TRX_PHY_VERSION, }; struct vty; struct gsm_bts_model { struct llist_head list; enum gsm_bts_type type; enum gsm_bts_type_variant variant; const char *name; bool started; int (*start)(struct gsm_network *net); int (*oml_rcvmsg)(struct msgb *msg); char * (*oml_status)(const struct gsm_bts *bts); void (*e1line_bind_ops)(struct e1inp_line *line); void (*config_write_bts)(struct vty *vty, struct gsm_bts *bts); void (*config_write_trx)(struct vty *vty, struct gsm_bts_trx *trx); void (*config_write_ts)(struct vty *vty, struct gsm_bts_trx_ts *ts); /* Should SI2bis and SI2ter be disabled by default on this BTS model? */ bool force_combined_si; struct tlv_definition nm_att_tlvdef; /* features of a given BTS model set via gsm_bts_model_register() locally */ struct bitvec features; uint8_t _features_data[MAX_BTS_FEATURES/8]; }; /* * This keeps track of the paging status of one BTS. It * includes a number of pending requests, a back pointer * to the gsm_bts, a timer and some more state. */ struct gsm_bts_paging_state { /* pending requests */ struct llist_head pending_requests; struct gsm_bts *bts; struct osmo_timer_list work_timer; struct osmo_timer_list credit_timer; /* free chans needed */ int free_chans_need; /* load */ uint16_t available_slots; }; struct gsm_envabtse { struct gsm_abis_mo mo; }; struct gsm_bts_gprs_nsvc { struct gsm_bts *bts; /* data read via VTY config file, to configure the BTS * via OML from BSC */ int id; uint16_t nsvci; uint16_t local_port; /* on the BTS */ uint16_t remote_port; /* on the SGSN */ uint32_t remote_ip; /* on the SGSN */ struct gsm_abis_mo mo; }; enum gprs_rlc_par { RLC_T3142, RLC_T3169, RLC_T3191, RLC_T3193, RLC_T3195, RLC_N3101, RLC_N3103, RLC_N3105, CV_COUNTDOWN, T_DL_TBF_EXT, /* ms */ T_UL_TBF_EXT, /* ms */ _NUM_RLC_PAR }; enum gprs_cs { GPRS_CS1, GPRS_CS2, GPRS_CS3, GPRS_CS4, GPRS_MCS1, GPRS_MCS2, GPRS_MCS3, GPRS_MCS4, GPRS_MCS5, GPRS_MCS6, GPRS_MCS7, GPRS_MCS8, GPRS_MCS9, _NUM_GRPS_CS }; struct gprs_rlc_cfg { uint16_t parameter[_NUM_RLC_PAR]; struct { uint16_t repeat_time; /* ms */ uint8_t repeat_count; } paging; uint32_t cs_mask; /* bitmask of gprs_cs */ uint8_t initial_cs; uint8_t initial_mcs; }; enum neigh_list_manual_mode { NL_MODE_AUTOMATIC = 0, NL_MODE_MANUAL = 1, NL_MODE_MANUAL_SI5SEP = 2, /* SI2 and SI5 have separate neighbor lists */ }; enum bts_loc_fix { BTS_LOC_FIX_INVALID = 0, BTS_LOC_FIX_2D = 1, BTS_LOC_FIX_3D = 2, }; extern const struct value_string bts_loc_fix_names[]; struct bts_location { struct llist_head list; time_t tstamp; enum bts_loc_fix valid; double lat; double lon; double height; }; /* Channel load counter */ struct load_counter { unsigned int total; unsigned int used; }; /* Useful to track N-N relations between BTS, for example neighbors. */ struct gsm_bts_ref { struct llist_head entry; struct gsm_bts *bts; }; /* One BTS */ struct gsm_bts { /* list header in net->bts_list */ struct llist_head list; /* Geographical location of the BTS */ struct llist_head loc_list; /* number of ths BTS in network */ uint8_t nr; /* human readable name / description */ char *description; /* Cell Identity */ uint16_t cell_identity; /* location area code of this BTS */ uint16_t location_area_code; /* Base Station Identification Code (BSIC), lower 3 bits is BCC, * which is used as TSC for the CCCH */ uint8_t bsic; /* type of BTS */ enum gsm_bts_type type; enum gsm_bts_type_variant variant; struct gsm_bts_model *model; enum gsm_band band; char version[MAX_VERSION_LENGTH]; char sub_model[MAX_VERSION_LENGTH]; /* features of a given BTS set/reported via OML */ struct bitvec features; uint8_t _features_data[MAX_BTS_FEATURES/8]; /* Connected PCU version (if any) */ char pcu_version[MAX_VERSION_LENGTH]; /* maximum Tx power that the MS is permitted to use in this cell */ int ms_max_power; /* how do we talk OML with this TRX? */ struct gsm_e1_subslot oml_e1_link; uint8_t oml_tei; struct e1inp_sign_link *oml_link; /* Timer to use for deferred drop of OML link, see \ref ipaccess_drop_oml_deferred */ struct osmo_timer_list oml_drop_link_timer; /* when OML link was established */ time_t uptime; /* Abis network management O&M handle */ struct abis_nm_h *nmh; struct gsm_abis_mo mo; /* number of this BTS on given E1 link */ uint8_t bts_nr; /* DTX features of this BTS */ enum gsm48_dtx_mode dtxu; bool dtxd; /* paging state and control */ struct gsm_bts_paging_state paging; /* CCCH is on C0 */ struct gsm_bts_trx *c0; struct { struct gsm_abis_mo mo; } site_mgr; /* bitmask of all SI that are present/valid in si_buf */ uint32_t si_valid; /* 3GPP TS 44.018 Table 10.5.2.33b.1 INDEX and COUNT for SI2quater */ uint8_t si2q_index; /* distinguish individual SI2quater messages */ uint8_t si2q_count; /* si2q_index for the last (highest indexed) individual SI2quater message */ /* buffers where we put the pre-computed SI */ sysinfo_buf_t si_buf[_MAX_SYSINFO_TYPE][SI2Q_MAX_NUM]; /* offsets used while generating SI2quater */ size_t e_offset; size_t u_offset; /* 3GPP TS 08.58 ยง8.5.1 BCCH INFORMATION. Some nanoBTS fail upon * receival of empty SI disabling unsupported SI. see OS#3707. */ bool si_unused_send_empty; /* ip.accesss Unit ID's have Site/BTS/TRX layout */ union { struct { uint16_t site_id; uint16_t bts_id; uint32_t flags; uint32_t rsl_ip; } ip_access; struct { struct { struct gsm_abis_mo mo; } cclk; struct { struct gsm_abis_mo mo; } rack; struct gsm_envabtse envabtse[4]; } bs11; struct { struct { struct om2k_mo om2k_mo; struct gsm_abis_mo mo; struct llist_head conn_groups; } cf; struct { struct om2k_mo om2k_mo; struct gsm_abis_mo mo; struct llist_head conn_groups; } is; struct { struct om2k_mo om2k_mo; struct gsm_abis_mo mo; struct llist_head conn_groups; } con; struct { struct om2k_mo om2k_mo; struct gsm_abis_mo mo; } dp; struct { struct om2k_mo om2k_mo; struct gsm_abis_mo mo; } tf; uint32_t use_superchannel:1; } rbs2000; struct { uint8_t bts_type; unsigned int configured:1, skip_reset:1, no_loc_rel_cnf:1, bts_reset_timer_cnf, did_reset:1, wait_reset:1; struct osmo_timer_list reset_timer; } nokia; }; /* Not entirely sure how ip.access specific this is */ struct { uint8_t supports_egprs_11bit_rach; enum bts_gprs_mode mode; struct { struct gsm_abis_mo mo; uint16_t nsei; uint8_t timer[7]; } nse; struct { struct gsm_abis_mo mo; uint16_t bvci; uint8_t timer[11]; struct gprs_rlc_cfg rlc_cfg; } cell; struct gsm_bts_gprs_nsvc nsvc[2]; uint8_t rac; uint8_t net_ctrl_ord; bool ctrl_ack_type_use_block; } gprs; /* RACH NM values */ int rach_b_thresh; int rach_ldavg_slots; /* transceivers */ int num_trx; struct llist_head trx_list; /* SI related items */ int force_combined_si; bool force_combined_si_set; int bcch_change_mark; /* Abis NM queue */ struct llist_head abis_queue; int abis_nm_pend; struct gsm_network *network; /* should the channel allocator allocate channels from high TRX to TRX0, * rather than starting from TRX0 and go upwards? */ int chan_alloc_reverse; enum neigh_list_manual_mode neigh_list_manual_mode; /* parameters from which we build SYSTEM INFORMATION */ struct { struct gsm48_rach_control rach_control; uint8_t ncc_permitted; struct gsm48_cell_sel_par cell_sel_par; struct gsm48_si_selection_params cell_ro_sel_par; /* rest octet */ struct gsm48_cell_options cell_options; struct gsm48_control_channel_descr chan_desc; struct bitvec neigh_list; struct bitvec cell_alloc; struct bitvec si5_neigh_list; struct osmo_earfcn_si2q si2quater_neigh_list; size_t uarfcn_length; /* index for uarfcn and scramble lists */ struct { /* bitmask large enough for all possible ARFCN's */ uint8_t neigh_list[1024/8]; uint8_t cell_alloc[1024/8]; /* If the user wants a different neighbor list in SI5 than in SI2 */ uint8_t si5_neigh_list[1024/8]; uint8_t meas_bw_list[MAX_EARFCN_LIST]; uint16_t earfcn_list[MAX_EARFCN_LIST]; uint16_t uarfcn_list[MAX_EARFCN_LIST]; uint16_t scramble_list[MAX_EARFCN_LIST]; } data; } si_common; bool early_classmark_allowed; bool early_classmark_allowed_3g; /* for testing only: Have an infinitely long radio link timeout */ bool infinite_radio_link_timeout; /* do we use static (user-defined) system information messages? (bitmask) */ uint32_t si_mode_static; /* access control class ramping */ struct acc_ramp acc_ramp; /* exclude the BTS from the global RF Lock handling */ int excl_from_rf_lock; /* supported codecs beside FR */ struct bts_codec_conf codec; /* BTS dependencies bit field */ uint32_t depends_on[256/(8*4)]; /* full and half rate multirate config */ struct amr_multirate_conf mr_full; struct amr_multirate_conf mr_half; /* PCU socket state */ char *pcu_sock_path; struct pcu_sock_state *pcu_state; struct rate_ctr_group *bts_ctrs; struct osmo_stat_item_group *bts_statg; struct handover_cfg *ho; /* A list of struct gsm_bts_ref, indicating neighbors of this BTS. * When the si_common neigh_list is in automatic mode, it is populated from this list as well as * gsm_network->neighbor_bss_cells. */ struct llist_head local_neighbors; /* BTS-specific overrides for timer values from struct gsm_network. */ uint8_t T3122; /* ASSIGMENT REJECT wait indication */ bool T3113_dynamic; /* Calculate T3113 timeout dynamically based on BTS channel config and load */ /* Periodic channel load measurements are used to maintain T3122. */ struct load_counter chan_load_samples[7]; int chan_load_samples_idx; uint8_t chan_load_avg; /* current channel load average in percent (0 - 100). */ }; /* One rejected BTS */ struct gsm_bts_rejected { /* list header in net->bts_rejected */ struct llist_head list; uint16_t site_id; uint16_t bts_id; char ip[INET6_ADDRSTRLEN]; time_t time; }; struct gsm_network *gsm_network_init(void *ctx); struct gsm_bts *gsm_bts_alloc(struct gsm_network *net, uint8_t bts_num); struct gsm_bts *gsm_bts_num(const struct gsm_network *net, int num); bool gsm_bts_matches_lai(const struct gsm_bts *bts, const struct osmo_location_area_id *lai); bool gsm_bts_matches_cell_id(const struct gsm_bts *bts, const struct gsm0808_cell_id *cell_id); struct gsm_bts *gsm_bts_by_cell_id(const struct gsm_network *net, const struct gsm0808_cell_id *cell_id, int match_idx); int gsm_bts_local_neighbor_add(struct gsm_bts *bts, struct gsm_bts *neighbor); int gsm_bts_local_neighbor_del(struct gsm_bts *bts, const struct gsm_bts *neighbor); struct gsm_bts_trx *gsm_bts_trx_alloc(struct gsm_bts *bts); struct gsm_bts_trx *gsm_bts_trx_num(const struct gsm_bts *bts, int num); enum gsm_bts_type str2btstype(const char *arg); const char *btstype2str(enum gsm_bts_type type); enum bts_attribute str2btsattr(const char *s); const char *btsatttr2str(enum bts_attribute v); enum gsm_bts_type_variant str2btsvariant(const char *arg); const char *btsvariant2str(enum gsm_bts_type_variant v); extern const struct value_string gsm_chreq_descs[]; extern const struct value_string gsm_pchant_names[]; extern const struct value_string gsm_pchant_descs[]; extern const struct value_string gsm_pchan_ids[]; const char *gsm_pchan_name(enum gsm_phys_chan_config c); static inline const char *gsm_pchan_id(enum gsm_phys_chan_config c) { return get_value_string(gsm_pchan_ids, c); } enum gsm_phys_chan_config gsm_pchan_parse(const char *name); const char *gsm_lchant_name(enum gsm_chan_t c); const char *gsm_chreq_name(enum gsm_chreq_reason_t c); char *gsm_bts_name(const struct gsm_bts *bts); char *gsm_trx_name(const struct gsm_bts_trx *trx); char *gsm_ts_name(const struct gsm_bts_trx_ts *ts); char *gsm_ts_and_pchan_name(const struct gsm_bts_trx_ts *ts); char *gsm_lchan_name_compute(const struct gsm_lchan *lchan); static inline char *gsm_lchan_name(const struct gsm_lchan *lchan) { return lchan->name; } void gsm_abis_mo_reset(struct gsm_abis_mo *mo); struct gsm_nm_state * gsm_objclass2nmstate(struct gsm_bts *bts, uint8_t obj_class, const struct abis_om_obj_inst *obj_inst); void * gsm_objclass2obj(struct gsm_bts *bts, uint8_t obj_class, const struct abis_om_obj_inst *obj_inst); /* reset the state of all MO in the BTS */ void gsm_bts_mo_reset(struct gsm_bts *bts); uint8_t gsm_pchan2chan_nr(enum gsm_phys_chan_config pchan, uint8_t ts_nr, uint8_t lchan_nr); uint8_t gsm_lchan2chan_nr(const struct gsm_lchan *lchan); uint8_t gsm_lchan_as_pchan2chan_nr(const struct gsm_lchan *lchan, enum gsm_phys_chan_config as_pchan); void gsm48_lchan2chan_desc(struct gsm48_chan_desc *cd, const struct gsm_lchan *lchan); void gsm48_lchan2chan_desc_as_configured(struct gsm48_chan_desc *cd, const struct gsm_lchan *lchan); /* return the gsm_lchan for the CBCH (if it exists at all) */ struct gsm_lchan *gsm_bts_get_cbch(struct gsm_bts *bts); /* * help with parsing regexps */ int gsm_parse_reg(void *ctx, regex_t *reg, char **str, int argc, const char **argv) __attribute__ ((warn_unused_result)); static inline uint8_t gsm_ts_tsc(const struct gsm_bts_trx_ts *ts) { if (ts->tsc != -1) return ts->tsc; else return ts->trx->bts->bsic & 7; } struct gsm_lchan *rsl_lchan_lookup(struct gsm_bts_trx *trx, uint8_t chan_nr, int *rc); enum gsm_phys_chan_config ts_pchan(struct gsm_bts_trx_ts *ts); uint8_t pchan_subslots(enum gsm_phys_chan_config pchan); bool ts_is_tch(struct gsm_bts_trx_ts *ts); static inline struct gsm_bts *conn_get_bts(struct gsm_subscriber_connection *conn) { OSMO_ASSERT(conn->lchan); return conn->lchan->ts->trx->bts; } enum { BTS_CTR_CHREQ_TOTAL, BTS_CTR_CHREQ_NO_CHANNEL, BTS_CTR_CHAN_RF_FAIL, BTS_CTR_CHAN_RLL_ERR, BTS_CTR_BTS_OML_FAIL, BTS_CTR_BTS_RSL_FAIL, BTS_CTR_CODEC_AMR_F, BTS_CTR_CODEC_AMR_H, BTS_CTR_CODEC_EFR, BTS_CTR_CODEC_V1_FR, BTS_CTR_CODEC_V1_HR, BTS_CTR_PAGING_ATTEMPTED, BTS_CTR_PAGING_ALREADY, BTS_CTR_PAGING_RESPONDED, BTS_CTR_PAGING_EXPIRED, BTS_CTR_CHAN_ACT_TOTAL, BTS_CTR_CHAN_ACT_NACK, BTS_CTR_RSL_UNKNOWN, BTS_CTR_RSL_IPA_NACK, BTS_CTR_MODE_MODIFY_NACK, }; static const struct rate_ctr_desc bts_ctr_description[] = { [BTS_CTR_CHREQ_TOTAL] = {"chreq:total", "Received channel requests."}, [BTS_CTR_CHREQ_NO_CHANNEL] = {"chreq:no_channel", "Sent to MS no channel available."}, [BTS_CTR_CHAN_RF_FAIL] = {"chan:rf_fail", "Received a RF failure indication from BTS."}, [BTS_CTR_CHAN_RLL_ERR] = {"chan:rll_err", "Received a RLL failure with T200 cause from BTS."}, [BTS_CTR_BTS_OML_FAIL] = {"oml_fail", "Received a TEI down on a OML link."}, [BTS_CTR_BTS_RSL_FAIL] = {"rsl_fail", "Received a TEI down on a OML link."}, [BTS_CTR_CODEC_AMR_F] = {"codec:amr_f", "Count the usage of AMR/F codec by channel mode requested."}, [BTS_CTR_CODEC_AMR_H] = {"codec:amr_h", "Count the usage of AMR/H codec by channel mode requested."}, [BTS_CTR_CODEC_EFR] = {"codec:efr", "Count the usage of EFR codec by channel mode requested."}, [BTS_CTR_CODEC_V1_FR] = {"codec:fr", "Count the usage of FR codec by channel mode requested."}, [BTS_CTR_CODEC_V1_HR] = {"codec:hr", "Count the usage of HR codec by channel mode requested."}, [BTS_CTR_PAGING_ATTEMPTED] = {"paging:attempted", "Paging attempts for a subscriber."}, [BTS_CTR_PAGING_ALREADY] = {"paging:already", "Paging attempts ignored as subsciber was already being paged."}, [BTS_CTR_PAGING_RESPONDED] = {"paging:responded", "Paging attempts with successful paging response."}, [BTS_CTR_PAGING_EXPIRED] = {"paging:expired", "Paging Request expired because of timeout T3113."}, [BTS_CTR_CHAN_ACT_TOTAL] = {"chan_act:total", "Total number of Channel Activations."}, [BTS_CTR_CHAN_ACT_NACK] = {"chan_act:nack", "Number of Channel Activations that the BTS NACKed"}, [BTS_CTR_RSL_UNKNOWN] = {"rsl:unknown", "Number of unknown/unsupported RSL messages received from BTS"}, [BTS_CTR_RSL_IPA_NACK] = {"rsl:ipa_nack", "Number of IPA (RTP/dyn-PDCH) related NACKs received from BTS"}, [BTS_CTR_MODE_MODIFY_NACK] = {"chan:mode_modify_nack", "Number of Channel Mode Modify NACKs received from BTS"}, }; static const struct rate_ctr_group_desc bts_ctrg_desc = { "bts", "base transceiver station", OSMO_STATS_CLASS_GLOBAL, ARRAY_SIZE(bts_ctr_description), bts_ctr_description, }; enum { BTS_STAT_CHAN_LOAD_AVERAGE, BTS_STAT_T3122, BTS_STAT_RACH_BUSY, BTS_STAT_RACH_ACCESS, }; enum { BSC_CTR_ASSIGNMENT_ATTEMPTED, BSC_CTR_ASSIGNMENT_COMPLETED, BSC_CTR_ASSIGNMENT_STOPPED, BSC_CTR_ASSIGNMENT_NO_CHANNEL, BSC_CTR_ASSIGNMENT_TIMEOUT, BSC_CTR_ASSIGNMENT_FAILED, BSC_CTR_ASSIGNMENT_ERROR, BSC_CTR_HANDOVER_ATTEMPTED, BSC_CTR_HANDOVER_COMPLETED, BSC_CTR_HANDOVER_STOPPED, BSC_CTR_HANDOVER_NO_CHANNEL, BSC_CTR_HANDOVER_TIMEOUT, BSC_CTR_HANDOVER_FAILED, BSC_CTR_HANDOVER_ERROR, BSC_CTR_INTER_BSC_HO_OUT_ATTEMPTED, BSC_CTR_INTER_BSC_HO_OUT_COMPLETED, BSC_CTR_INTER_BSC_HO_OUT_STOPPED, BSC_CTR_INTER_BSC_HO_OUT_TIMEOUT, BSC_CTR_INTER_BSC_HO_OUT_ERROR, BSC_CTR_INTER_BSC_HO_IN_ATTEMPTED, BSC_CTR_INTER_BSC_HO_IN_COMPLETED, BSC_CTR_INTER_BSC_HO_IN_STOPPED, BSC_CTR_INTER_BSC_HO_IN_NO_CHANNEL, BSC_CTR_INTER_BSC_HO_IN_FAILED, BSC_CTR_INTER_BSC_HO_IN_TIMEOUT, BSC_CTR_INTER_BSC_HO_IN_ERROR, BSC_CTR_PAGING_ATTEMPTED, BSC_CTR_PAGING_DETACHED, BSC_CTR_PAGING_RESPONDED, BSC_CTR_UNKNOWN_UNIT_ID, }; static const struct rate_ctr_desc bsc_ctr_description[] = { [BSC_CTR_ASSIGNMENT_ATTEMPTED] = {"assignment:attempted", "Assignment attempts."}, [BSC_CTR_ASSIGNMENT_COMPLETED] = {"assignment:completed", "Assignment completed."}, [BSC_CTR_ASSIGNMENT_STOPPED] = {"assignment:stopped", "Connection ended during Assignment."}, [BSC_CTR_ASSIGNMENT_NO_CHANNEL] = {"assignment:no_channel", "Failure to allocate lchan for Assignment."}, [BSC_CTR_ASSIGNMENT_TIMEOUT] = {"assignment:timeout", "Assignment timed out."}, [BSC_CTR_ASSIGNMENT_FAILED] = {"assignment:failed", "Received Assignment Failure message."}, [BSC_CTR_ASSIGNMENT_ERROR] = {"assignment:error", "Assigment failed for other reason."}, [BSC_CTR_HANDOVER_ATTEMPTED] = {"handover:attempted", "Intra-BSC handover attempts."}, [BSC_CTR_HANDOVER_COMPLETED] = {"handover:completed", "Intra-BSC handover completed."}, [BSC_CTR_HANDOVER_STOPPED] = {"handover:stopped", "Connection ended during HO."}, [BSC_CTR_HANDOVER_NO_CHANNEL] = {"handover:no_channel", "Failure to allocate lchan for HO."}, [BSC_CTR_HANDOVER_TIMEOUT] = {"handover:timeout", "Handover timed out."}, [BSC_CTR_HANDOVER_FAILED] = {"handover:failed", "Received Handover Fail messages."}, [BSC_CTR_HANDOVER_ERROR] = {"handover:error", "Re-assigment failed for other reason."}, [BSC_CTR_INTER_BSC_HO_OUT_ATTEMPTED] = {"interbsc_ho_out:attempted", "Attempts to handover to remote BSS."}, [BSC_CTR_INTER_BSC_HO_OUT_COMPLETED] = {"interbsc_ho_out:completed", "Handover to remote BSS completed."}, [BSC_CTR_INTER_BSC_HO_OUT_STOPPED] = {"interbsc_ho_out:stopped", "Connection ended during HO."}, [BSC_CTR_INTER_BSC_HO_OUT_TIMEOUT] = {"interbsc_ho_out:timeout", "Handover timed out."}, [BSC_CTR_INTER_BSC_HO_OUT_ERROR] = {"interbsc_ho_out:error", "Handover to remote BSS failed for other reason."}, [BSC_CTR_INTER_BSC_HO_IN_ATTEMPTED] = {"interbsc_ho_in:attempted", "Attempts to handover from remote BSS."}, [BSC_CTR_INTER_BSC_HO_IN_COMPLETED] = {"interbsc_ho_in:completed", "Handover from remote BSS completed."}, [BSC_CTR_INTER_BSC_HO_IN_STOPPED] = {"interbsc_ho_in:stopped", "Connection ended during HO."}, [BSC_CTR_INTER_BSC_HO_IN_NO_CHANNEL] = {"interbsc_ho_in:no_channel", "Failure to allocate lchan for HO."}, [BSC_CTR_INTER_BSC_HO_IN_TIMEOUT] = {"interbsc_ho_in:timeout", "Handover from remote BSS timed out."}, [BSC_CTR_INTER_BSC_HO_IN_FAILED] = {"interbsc_ho_in:failed", "Received Handover Fail message."}, [BSC_CTR_INTER_BSC_HO_IN_ERROR] = {"interbsc_ho_in:error", "Handover from remote BSS failed for other reason."}, [BSC_CTR_PAGING_ATTEMPTED] = {"paging:attempted", "Paging attempts for a subscriber."}, [BSC_CTR_PAGING_DETACHED] = {"paging:detached", "Paging request send failures because no responsible BTS was found."}, [BSC_CTR_PAGING_RESPONDED] = {"paging:responded", "Paging attempts with successful response."}, [BSC_CTR_UNKNOWN_UNIT_ID] = {"abis:unknown_unit_id", "Connection attempts from unknown IPA CCM Unit ID."}, }; static const struct rate_ctr_group_desc bsc_ctrg_desc = { "bsc", "base station controller", OSMO_STATS_CLASS_GLOBAL, ARRAY_SIZE(bsc_ctr_description), bsc_ctr_description, }; struct gsm_tz { int override; /* if 0, use system's time zone instead. */ int hr; /* hour */ int mn; /* minute */ int dst; /* daylight savings */ }; struct gsm_network { /* TODO MSCSPLIT the gsm_network struct is basically a kitchen sink for * global settings and variables, "madly" mixing BSC and MSC stuff. Split * this in e.g. struct osmo_bsc and struct osmo_msc, with the things * these have in common, like country and network code, put in yet * separate structs and placed as members in osmo_bsc and osmo_msc. */ struct osmo_plmn_id plmn; /* bit-mask of permitted encryption algorithms. LSB=A5/0, MSB=A5/7 */ uint8_t a5_encryption_mask; int neci; struct handover_cfg *ho; struct { unsigned int congestion_check_interval_s; struct osmo_timer_list congestion_check_timer; } hodec2; struct rate_ctr_group *bsc_ctrs; unsigned int num_bts; struct llist_head bts_list; struct llist_head bts_rejected; /* shall reference gsm_network_T[] */ struct osmo_tdef *T_defs; enum gsm_chan_t ctype_by_chreq[_NUM_CHREQ_T]; /* Use a TCH for handling requests of type paging any */ int pag_any_tch; /* MSC data in case we are a true BSC */ struct osmo_bsc_data *bsc_data; /* control interface */ struct ctrl_handle *ctrl; /* Allow or disallow TCH/F on dynamic TCH/F_TCH/H_PDCH; OS#1778 */ bool dyn_ts_allow_tch_f; /* all active subscriber connections. */ struct llist_head subscr_conns; /* if override is nonzero, this timezone data is used for all MM * contexts. */ /* TODO: in OsmoNITB, tz-override used to be BTS-specific. To enable * BTS|RNC specific timezone overrides for multi-tz networks in * OsmoMSC, this should be tied to the location area code (LAC). */ struct gsm_tz tz; /* List of all struct bsc_subscr used in libbsc. This llist_head is * allocated so that the llist_head pointer itself can serve as a * talloc context (useful to not have to pass the entire gsm_network * struct to the bsc_subscr_* API, and for bsc_susbscr unit tests to * not require gsm_data.h). In an MSC-without-BSC environment, this * pointer is NULL to indicate absence of a bsc_subscribers list. */ struct llist_head *bsc_subscribers; /* Timer for periodic channel load measurements to maintain each BTS's T3122. */ struct osmo_timer_list t3122_chan_load_timer; struct { struct mgcp_client_conf *conf; struct mgcp_client *client; struct osmo_tdef *tdefs; } mgw; /* Remote BSS Cell Identifier Lists */ struct neighbor_ident_list *neighbor_bss_cells; }; struct gsm_audio_support { uint8_t hr : 1, ver : 7; }; static inline const struct osmo_location_area_id *bts_lai(struct gsm_bts *bts) { static struct osmo_location_area_id lai; lai = (struct osmo_location_area_id){ .plmn = bts->network->plmn, .lac = bts->location_area_code, }; return &lai; } extern void talloc_ctx_init(void *ctx_root); int gsm_set_bts_type(struct gsm_bts *bts, enum gsm_bts_type type); enum gsm_bts_type parse_btstype(const char *arg); const char *btstype2str(enum gsm_bts_type type); struct gsm_bts *gsm_bts_by_lac(struct gsm_network *net, unsigned int lac, struct gsm_bts *start_bts); extern void *tall_bsc_ctx; /* this actaully refers to the IPA transport, not the BTS model */ static inline int is_ipaccess_bts(struct gsm_bts *bts) { switch (bts->type) { case GSM_BTS_TYPE_NANOBTS: case GSM_BTS_TYPE_OSMOBTS: return 1; default: break; } return 0; } static inline int is_sysmobts_v2(struct gsm_bts *bts) { switch (bts->type) { case GSM_BTS_TYPE_OSMOBTS: return 1; default: break; } return 0; } static inline int is_siemens_bts(struct gsm_bts *bts) { switch (bts->type) { case GSM_BTS_TYPE_BS11: return 1; default: break; } return 0; } static inline int is_nokia_bts(struct gsm_bts *bts) { switch (bts->type) { case GSM_BTS_TYPE_NOKIA_SITE: return 1; default: break; } return 0; } static inline int is_e1_bts(struct gsm_bts *bts) { switch (bts->type) { case GSM_BTS_TYPE_BS11: case GSM_BTS_TYPE_RBS2000: case GSM_BTS_TYPE_NOKIA_SITE: return 1; default: break; } return 0; } extern struct gsm_network *bsc_gsmnet; enum bts_gprs_mode bts_gprs_mode_parse(const char *arg, int *valid); const char *bts_gprs_mode_name(enum bts_gprs_mode mode); int bts_gprs_mode_is_compat(struct gsm_bts *bts, enum bts_gprs_mode mode); void gsm48_ra_id_by_bts(struct gsm48_ra_id *buf, struct gsm_bts *bts); void gprs_ra_id_by_bts(struct gprs_ra_id *raid, struct gsm_bts *bts); int gsm_bts_model_register(struct gsm_bts_model *model); struct gsm_subscriber_connection *bsc_subscr_con_allocate(struct gsm_network *network); struct gsm_subscriber_connection *msc_subscr_con_allocate(struct gsm_network *network); void msc_subscr_con_free(struct gsm_subscriber_connection *conn); struct gsm_bts *gsm_bts_alloc_register(struct gsm_network *net, enum gsm_bts_type type, uint8_t bsic); struct gsm_bts *bsc_bts_alloc_register(struct gsm_network *net, enum gsm_bts_type type, uint8_t bsic); void set_ts_e1link(struct gsm_bts_trx_ts *ts, uint8_t e1_nr, uint8_t e1_ts, uint8_t e1_ts_ss); void gsm_trx_lock_rf(struct gsm_bts_trx *trx, bool locked, const char *reason); struct gsm_bts_trx *gsm_bts_trx_by_nr(struct gsm_bts *bts, int nr); int gsm_bts_trx_set_system_infos(struct gsm_bts_trx *trx); int gsm_bts_set_system_infos(struct gsm_bts *bts); /* generic E1 line operations for all ISDN-based BTS. */ extern struct e1inp_line_ops bts_isdn_e1inp_line_ops; extern const struct value_string bts_type_names[_NUM_GSM_BTS_TYPE+1]; extern const struct value_string bts_type_descs[_NUM_GSM_BTS_TYPE+1]; char *get_model_oml_status(const struct gsm_bts *bts); unsigned long long bts_uptime(const struct gsm_bts *bts); /* control interface handling */ int bsc_base_ctrl_cmds_install(void); /* dependency handling */ void bts_depend_mark(struct gsm_bts *bts, int dep); void bts_depend_clear(struct gsm_bts *bts, int dep); int bts_depend_check(struct gsm_bts *bts); int bts_depend_is_depedency(struct gsm_bts *base, struct gsm_bts *other); int gsm_bts_get_radio_link_timeout(const struct gsm_bts *bts); void gsm_bts_set_radio_link_timeout(struct gsm_bts *bts, int value); bool classmark_is_r99(struct gsm_classmark *cm); bool trx_is_usable(const struct gsm_bts_trx *trx); bool ts_is_usable(const struct gsm_bts_trx_ts *ts); int gsm_lchan_type_by_pchan(enum gsm_phys_chan_config pchan); enum gsm_phys_chan_config gsm_pchan_by_lchan_type(enum gsm_chan_t type); void gsm_bts_all_ts_dispatch(struct gsm_bts *bts, uint32_t ts_ev, void *data); void gsm_trx_all_ts_dispatch(struct gsm_bts_trx *trx, uint32_t ts_ev, void *data); int bts_count_free_ts(struct gsm_bts *bts, enum gsm_phys_chan_config pchan); #endif /* _GSM_DATA_H */