/* bts.h * * Copyright (C) 2012 Ivan Klyuchnikov * Copyright (C) 2013 by Holger Hans Peter Freyther * * 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #pragma once #ifdef __cplusplus extern "C" { #include #include #include #include #include #include #include } #include #include "poll_controller.h" #include "sba.h" #include "tbf.h" #include "gprs_ms_storage.h" #include "gprs_coding_scheme.h" #include #endif #include #include #define LLC_CODEL_DISABLE 0 #define LLC_CODEL_USE_DEFAULT (-1) #define MAX_EDGE_MCS 9 #define MAX_GPRS_CS 4 /* see bts->gsmtap_categ_mask */ enum pcu_gsmtap_category { PCU_GSMTAP_C_DL_UNKNOWN = 0, /* unknown or undecodable downlink blocks */ PCU_GSMTAP_C_DL_DUMMY = 1, /* downlink dummy blocks */ PCU_GSMTAP_C_DL_CTRL = 2, /* downlink control blocks */ PCU_GSMTAP_C_DL_DATA_GPRS = 3, /* downlink GPRS data blocks */ PCU_GSMTAP_C_DL_DATA_EGPRS = 4, /* downlink EGPRS data blocks */ PCU_GSMTAP_C_DL_PTCCH = 5, /* downlink PTCCH blocks */ PCU_GSMTAP_C_DL_AGCH = 6, /* downlink AGCH blocks */ PCU_GSMTAP_C_DL_PCH = 7, /* downlink PCH blocks */ PCU_GSMTAP_C_UL_UNKNOWN = 15, /* unknown or undecodable uplink blocks */ PCU_GSMTAP_C_UL_DUMMY = 16, /* uplink dummy blocks */ PCU_GSMTAP_C_UL_CTRL = 17, /* uplink control blocks */ PCU_GSMTAP_C_UL_DATA_GPRS = 18, /* uplink GPRS data blocks */ PCU_GSMTAP_C_UL_DATA_EGPRS = 19, /* uplink EGPRS data blocks */ PCU_GSMTAP_C_UL_RACH = 20, /* uplink RACH bursts */ }; struct BTS; struct GprsMs; struct gprs_rlcmac_trx { void *fl1h; uint16_t arfcn; struct gprs_rlcmac_pdch pdch[8]; /* back pointers */ struct BTS *bts; uint8_t trx_no; #ifdef __cplusplus void reserve_slots(enum gprs_rlcmac_tbf_direction dir, uint8_t slots); void unreserve_slots(enum gprs_rlcmac_tbf_direction dir, uint8_t slots); #endif }; #ifdef __cplusplus extern "C" { #endif void bts_update_tbf_ta(const char *p, uint32_t fn, uint8_t trx_no, uint8_t ts, int8_t ta, bool is_rach); #ifdef __cplusplus } #endif /** * This is the data from C. As soon as our minimal compiler is gcc 4.7 * we can start to compile pcu_vty.c with c++ and remove the split. */ struct gprs_rlcmac_bts { bool active; uint8_t bsic; uint8_t fc_interval; uint16_t fc_bucket_time; uint32_t fc_bvc_bucket_size; uint32_t fc_bvc_leak_rate; uint32_t fc_ms_bucket_size; uint32_t fc_ms_leak_rate; uint8_t cs1; uint8_t cs2; uint8_t cs3; uint8_t cs4; uint8_t initial_cs_dl, initial_cs_ul; uint8_t initial_mcs_dl, initial_mcs_ul; uint8_t max_cs_dl, max_cs_ul; uint8_t max_mcs_dl, max_mcs_ul; uint8_t force_cs; /* 0=use from BTS 1=use from VTY */ uint16_t force_llc_lifetime; /* overrides lifetime from SGSN */ uint32_t llc_discard_csec; uint32_t llc_idle_ack_csec; uint32_t llc_codel_interval_msec; /* 0=disabled, -1=use default interval */ /* Timer defintions */ struct osmo_tdef *T_defs_bts; /* timers controlled by BTS, received through PCUIF */ struct osmo_tdef *T_defs_pcu; /* timers controlled by PCU */ uint8_t n3101; uint8_t n3103; uint8_t n3105; struct gsmtap_inst *gsmtap; uint32_t gsmtap_categ_mask; struct gprs_rlcmac_trx trx[8]; int (*alloc_algorithm)(struct gprs_rlcmac_bts *bts, struct GprsMs *ms, struct gprs_rlcmac_tbf *tbf, bool single, int8_t use_tbf); uint8_t force_two_phase; uint8_t alpha, gamma; uint8_t egprs_enabled; bool dl_tbf_preemptive_retransmission; uint8_t si13[GSM_MACBLOCK_LEN]; bool si13_is_set; /* 0 to support resegmentation in DL, 1 for no reseg */ uint8_t dl_arq_type; uint8_t cs_adj_enabled; /* whether cs_adj_{upper,lower}_limit are used to adjust DL CS */ uint8_t cs_adj_upper_limit; /* downgrade DL CS if error rate above its value */ uint8_t cs_adj_lower_limit; /* upgrade DL CS if error rate below its value */ /* downgrade DL CS when less than specified octets are left in tx queue. Optimization, see paper: "Theoretical Analysis of GPRS Throughput and Delay" */ uint16_t cs_downgrade_threshold; /* Link quality range for each UL (M)CS. Below or above, next/prev (M)CS is selected. */ struct {int16_t low; int16_t high; } cs_lqual_ranges[MAX_GPRS_CS]; struct {int16_t low; int16_t high; } mcs_lqual_ranges[MAX_EDGE_MCS]; uint16_t ws_base; uint16_t ws_pdch; /* increase WS by this value per PDCH */ /* State for dynamic algorithm selection */ int multislot_disabled; /** * Point back to the C++ object. This is used during the transition * period. */ struct BTS *bts; /* Path to be used for the pcu-bts socket */ char *pcu_sock_path; /* Are we talking Gb with IP-SNS (true) or classic Gb? */ bool gb_dialect_sns; /* Packet Application Information (3GPP TS 44.060 11.2.47, usually ETWS primary message). We don't need to store * more than one message, because they get sent so rarely. */ struct msgb *app_info; uint32_t app_info_pending; /* Count of MS with active TBF, to which we did not send app_info yet */ }; #ifdef __cplusplus /** * I represent a GSM BTS. I have one or more TRX, I know the current * GSM time and I have controllers that help with allocating resources * on my TRXs. */ struct BTS { public: enum { CTR_TBF_DL_ALLOCATED, CTR_TBF_DL_FREED, CTR_TBF_DL_ABORTED, CTR_TBF_UL_ALLOCATED, CTR_TBF_UL_FREED, CTR_TBF_UL_ABORTED, CTR_TBF_REUSED, CTR_TBF_ALLOC_ALGO_A, CTR_TBF_ALLOC_ALGO_B, CTR_TBF_FAILED_EGPRS_ONLY, CTR_RLC_SENT, CTR_RLC_RESENT, CTR_RLC_RESTARTED, CTR_RLC_STALLED, CTR_RLC_NACKED, CTR_RLC_FINAL_BLOCK_RESENT, CTR_RLC_ASS_TIMEDOUT, CTR_RLC_ASS_FAILED, CTR_RLC_ACK_TIMEDOUT, CTR_RLC_ACK_FAILED, CTR_RLC_REL_TIMEDOUT, CTR_RLC_LATE_BLOCK, CTR_RLC_SENT_DUMMY, CTR_RLC_SENT_CONTROL, CTR_RLC_DL_BYTES, CTR_RLC_DL_PAYLOAD_BYTES, CTR_RLC_UL_BYTES, CTR_RLC_UL_PAYLOAD_BYTES, CTR_DECODE_ERRORS, CTR_SBA_ALLOCATED, CTR_SBA_FREED, CTR_SBA_TIMEDOUT, CTR_LLC_FRAME_TIMEDOUT, CTR_LLC_FRAME_DROPPED, CTR_LLC_FRAME_SCHED, CTR_LLC_DL_BYTES, CTR_LLC_UL_BYTES, CTR_RACH_REQUESTS, CTR_11BIT_RACH_REQUESTS, CTR_SPB_UL_FIRST_SEGMENT, CTR_SPB_UL_SECOND_SEGMENT, CTR_SPB_DL_FIRST_SEGMENT, CTR_SPB_DL_SECOND_SEGMENT, CTR_IMMEDIATE_ASSIGN_UL_TBF, CTR_IMMEDIATE_ASSIGN_REJ, CTR_IMMEDIATE_ASSIGN_DL_TBF, CTR_CHANNEL_REQUEST_DESCRIPTION, CTR_PKT_UL_ASSIGNMENT, CTR_PKT_ACCESS_REJ, CTR_PKT_DL_ASSIGNMENT, CTR_RLC_RECV_CONTROL, CTR_PUA_POLL_TIMEDOUT, CTR_PUA_POLL_FAILED, CTR_PDA_POLL_TIMEDOUT, CTR_PDA_POLL_FAILED, CTR_PUAN_POLL_TIMEDOUT, CTR_PUAN_POLL_FAILED, CTR_PDAN_POLL_TIMEDOUT, CTR_PDAN_POLL_FAILED, CTR_GPRS_DL_CS1, CTR_GPRS_DL_CS2, CTR_GPRS_DL_CS3, CTR_GPRS_DL_CS4, CTR_EGPRS_DL_MCS1, CTR_EGPRS_DL_MCS2, CTR_EGPRS_DL_MCS3, CTR_EGPRS_DL_MCS4, CTR_EGPRS_DL_MCS5, CTR_EGPRS_DL_MCS6, CTR_EGPRS_DL_MCS7, CTR_EGPRS_DL_MCS8, CTR_EGPRS_DL_MCS9, CTR_GPRS_UL_CS1, CTR_GPRS_UL_CS2, CTR_GPRS_UL_CS3, CTR_GPRS_UL_CS4, CTR_EGPRS_UL_MCS1, CTR_EGPRS_UL_MCS2, CTR_EGPRS_UL_MCS3, CTR_EGPRS_UL_MCS4, CTR_EGPRS_UL_MCS5, CTR_EGPRS_UL_MCS6, CTR_EGPRS_UL_MCS7, CTR_EGPRS_UL_MCS8, CTR_EGPRS_UL_MCS9, }; enum { STAT_MS_PRESENT, }; BTS(); ~BTS(); void cleanup(); static BTS* main_bts(); struct gprs_rlcmac_bts *bts_data(); SBAController *sba(); /** TODO: change the number to unsigned */ void set_current_frame_number(int frame_number); void set_current_block_frame_number(int frame_number, unsigned max_delay); int current_frame_number() const; /** add paging to paging queue(s) */ int add_paging(uint8_t chan_needed, uint8_t *identity_lv); gprs_rlcmac_dl_tbf *dl_tbf_by_poll_fn(uint32_t fn, uint8_t trx, uint8_t ts); gprs_rlcmac_ul_tbf *ul_tbf_by_poll_fn(uint32_t fn, uint8_t trx, uint8_t ts); gprs_rlcmac_dl_tbf *dl_tbf_by_tfi(uint8_t tfi, uint8_t trx, uint8_t ts); gprs_rlcmac_ul_tbf *ul_tbf_by_tfi(uint8_t tfi, uint8_t trx, uint8_t ts); int tfi_find_free(enum gprs_rlcmac_tbf_direction dir, uint8_t *_trx, int8_t use_trx) const; int rcv_imm_ass_cnf(const uint8_t *data, uint32_t fn); uint32_t rfn_to_fn(int32_t rfn); int rcv_rach(uint16_t ra, uint32_t Fn, int16_t qta, bool is_11bit, enum ph_burst_type burst_type); int rcv_ptcch_rach(uint8_t trx_nr, uint8_t ts_nr, uint32_t fn, int16_t qta); void snd_dl_ass(gprs_rlcmac_tbf *tbf, bool poll, const char *imsi); GprsMsStorage &ms_store(); GprsMs *ms_by_tlli(uint32_t tlli, uint32_t old_tlli = 0); GprsMs *ms_by_imsi(const char *imsi); GprsMs *ms_alloc(uint8_t ms_class, uint8_t egprs_ms_class = 0); void send_gsmtap(enum pcu_gsmtap_category categ, bool uplink, uint8_t trx_no, uint8_t ts_no, uint8_t channel, uint32_t fn, const uint8_t *data, unsigned int len); /* * Statistics */ void tbf_dl_created(); void tbf_dl_freed(); void tbf_dl_aborted(); void tbf_ul_created(); void tbf_ul_freed(); void tbf_ul_aborted(); void tbf_reused(); void tbf_alloc_algo_a(); void tbf_alloc_algo_b(); void tbf_failed_egprs_only(); void rlc_sent(); void rlc_resent(); void rlc_restarted(); void rlc_stalled(); void rlc_nacked(); void rlc_final_block_resent(); void rlc_ass_timedout(); void rlc_ass_failed(); void rlc_ack_timedout(); void rlc_ack_failed(); void rlc_rel_timedout(); void rlc_late_block(); void rlc_sent_dummy(); void rlc_sent_control(); void rlc_dl_bytes(int bytes); void rlc_dl_payload_bytes(int bytes); void rlc_ul_bytes(int bytes); void rlc_ul_payload_bytes(int bytes); void decode_error(); void sba_allocated(); void sba_freed(); void sba_timedout(); void llc_timedout_frame(); void llc_dropped_frame(); void llc_frame_sched(); void llc_dl_bytes(int bytes); void llc_ul_bytes(int bytes); void rach_frame(); void rach_frame_11bit(); void spb_uplink_first_segment(); void spb_uplink_second_segment(); void spb_downlink_first_segment(); void spb_downlink_second_segment(); void immediate_assignment_ul_tbf(); void immediate_assignment_reject(); void immediate_assignment_dl_tbf(); void channel_request_description(); void pkt_ul_assignment(); void pkt_access_reject(); void pkt_dl_assignemnt(); void rlc_rcvd_control(); void pua_poll_timedout(); void pua_poll_failed(); void pda_poll_timedout(); void pda_poll_failed(); void pkt_ul_ack_nack_poll_timedout(); void pkt_ul_ack_nack_poll_failed(); void pkt_dl_ack_nack_poll_timedout(); void pkt_dl_ack_nack_poll_failed(); void gprs_dl_cs1(); void gprs_dl_cs2(); void gprs_dl_cs3(); void gprs_dl_cs4(); void egprs_dl_mcs1(); void egprs_dl_mcs2(); void egprs_dl_mcs3(); void egprs_dl_mcs4(); void egprs_dl_mcs5(); void egprs_dl_mcs6(); void egprs_dl_mcs7(); void egprs_dl_mcs8(); void egprs_dl_mcs9(); void gprs_ul_cs1(); void gprs_ul_cs2(); void gprs_ul_cs3(); void gprs_ul_cs4(); void egprs_ul_mcs1(); void egprs_ul_mcs2(); void egprs_ul_mcs3(); void egprs_ul_mcs4(); void egprs_ul_mcs5(); void egprs_ul_mcs6(); void egprs_ul_mcs7(); void egprs_ul_mcs8(); void egprs_ul_mcs9(); void ms_present(int32_t n); int32_t ms_present_get(); /* * Below for C interface for the VTY */ struct rate_ctr_group *rate_counters() const; struct osmo_stat_item_group *stat_items() const; LListHead& ul_tbfs(); LListHead& dl_tbfs(); private: int m_cur_fn; int m_cur_blk_fn; struct gprs_rlcmac_bts m_bts; PollController m_pollController; SBAController m_sba; struct rate_ctr_group *m_ratectrs; struct osmo_stat_item_group *m_statg; GprsMsStorage m_ms_store; /* list of uplink TBFs */ LListHead m_ul_tbfs; /* list of downlink TBFs */ LListHead m_dl_tbfs; /* disable copying to avoid slicing */ BTS(const BTS&); BTS& operator=(const BTS&); }; inline int BTS::current_frame_number() const { return m_cur_fn; } inline SBAController *BTS::sba() { return &m_sba; } inline GprsMsStorage &BTS::ms_store() { return m_ms_store; } inline GprsMs *BTS::ms_by_tlli(uint32_t tlli, uint32_t old_tlli) { return ms_store().get_ms(tlli, old_tlli); } inline GprsMs *BTS::ms_by_imsi(const char *imsi) { return ms_store().get_ms(0, 0, imsi); } inline LListHead& BTS::ul_tbfs() { return m_ul_tbfs; } inline LListHead& BTS::dl_tbfs() { return m_dl_tbfs; } inline struct rate_ctr_group *BTS::rate_counters() const { return m_ratectrs; } inline struct osmo_stat_item_group *BTS::stat_items() const { return m_statg; } #define CREATE_COUNT_ADD_INLINE(func_name, ctr_name) \ inline void BTS::func_name(int inc) {\ rate_ctr_add(&m_ratectrs->ctr[ctr_name], inc); \ } #define CREATE_COUNT_INLINE(func_name, ctr_name) \ inline void BTS::func_name() {\ rate_ctr_inc(&m_ratectrs->ctr[ctr_name]); \ } CREATE_COUNT_INLINE(tbf_dl_created, CTR_TBF_DL_ALLOCATED) CREATE_COUNT_INLINE(tbf_dl_freed, CTR_TBF_DL_FREED) CREATE_COUNT_INLINE(tbf_dl_aborted, CTR_TBF_DL_ABORTED) CREATE_COUNT_INLINE(tbf_ul_created, CTR_TBF_UL_ALLOCATED) CREATE_COUNT_INLINE(tbf_ul_freed, CTR_TBF_UL_FREED) CREATE_COUNT_INLINE(tbf_ul_aborted, CTR_TBF_UL_ABORTED) CREATE_COUNT_INLINE(tbf_reused, CTR_TBF_REUSED) CREATE_COUNT_INLINE(tbf_alloc_algo_a, CTR_TBF_ALLOC_ALGO_A) CREATE_COUNT_INLINE(tbf_alloc_algo_b, CTR_TBF_ALLOC_ALGO_B) CREATE_COUNT_INLINE(tbf_failed_egprs_only, CTR_TBF_FAILED_EGPRS_ONLY) CREATE_COUNT_INLINE(rlc_sent, CTR_RLC_SENT) CREATE_COUNT_INLINE(rlc_resent, CTR_RLC_RESENT) CREATE_COUNT_INLINE(rlc_restarted, CTR_RLC_RESTARTED) CREATE_COUNT_INLINE(rlc_stalled, CTR_RLC_STALLED) CREATE_COUNT_INLINE(rlc_nacked, CTR_RLC_NACKED) CREATE_COUNT_INLINE(rlc_final_block_resent, CTR_RLC_FINAL_BLOCK_RESENT); CREATE_COUNT_INLINE(rlc_ass_timedout, CTR_RLC_ASS_TIMEDOUT); CREATE_COUNT_INLINE(rlc_ass_failed, CTR_RLC_ASS_FAILED); CREATE_COUNT_INLINE(rlc_ack_timedout, CTR_RLC_ACK_TIMEDOUT); CREATE_COUNT_INLINE(rlc_ack_failed, CTR_RLC_ACK_FAILED); CREATE_COUNT_INLINE(rlc_rel_timedout, CTR_RLC_REL_TIMEDOUT); CREATE_COUNT_INLINE(rlc_late_block, CTR_RLC_LATE_BLOCK); CREATE_COUNT_INLINE(rlc_sent_dummy, CTR_RLC_SENT_DUMMY); CREATE_COUNT_INLINE(rlc_sent_control, CTR_RLC_SENT_CONTROL); CREATE_COUNT_ADD_INLINE(rlc_dl_bytes, CTR_RLC_DL_BYTES); CREATE_COUNT_ADD_INLINE(rlc_dl_payload_bytes, CTR_RLC_DL_PAYLOAD_BYTES); CREATE_COUNT_ADD_INLINE(rlc_ul_bytes, CTR_RLC_UL_BYTES); CREATE_COUNT_ADD_INLINE(rlc_ul_payload_bytes, CTR_RLC_UL_PAYLOAD_BYTES); CREATE_COUNT_INLINE(decode_error, CTR_DECODE_ERRORS) CREATE_COUNT_INLINE(sba_allocated, CTR_SBA_ALLOCATED) CREATE_COUNT_INLINE(sba_freed, CTR_SBA_FREED) CREATE_COUNT_INLINE(sba_timedout, CTR_SBA_TIMEDOUT) CREATE_COUNT_INLINE(llc_timedout_frame, CTR_LLC_FRAME_TIMEDOUT); CREATE_COUNT_INLINE(llc_dropped_frame, CTR_LLC_FRAME_DROPPED); CREATE_COUNT_INLINE(llc_frame_sched, CTR_LLC_FRAME_SCHED); CREATE_COUNT_ADD_INLINE(llc_dl_bytes, CTR_LLC_DL_BYTES); CREATE_COUNT_ADD_INLINE(llc_ul_bytes, CTR_LLC_UL_BYTES); CREATE_COUNT_INLINE(rach_frame, CTR_RACH_REQUESTS); CREATE_COUNT_INLINE(rach_frame_11bit, CTR_11BIT_RACH_REQUESTS); CREATE_COUNT_INLINE(spb_uplink_first_segment, CTR_SPB_UL_FIRST_SEGMENT); CREATE_COUNT_INLINE(spb_uplink_second_segment, CTR_SPB_UL_SECOND_SEGMENT); CREATE_COUNT_INLINE(spb_downlink_first_segment, CTR_SPB_DL_FIRST_SEGMENT); CREATE_COUNT_INLINE(spb_downlink_second_segment, CTR_SPB_DL_SECOND_SEGMENT); CREATE_COUNT_INLINE(immediate_assignment_ul_tbf, CTR_IMMEDIATE_ASSIGN_UL_TBF); CREATE_COUNT_INLINE(immediate_assignment_reject, CTR_IMMEDIATE_ASSIGN_REJ); CREATE_COUNT_INLINE(immediate_assignment_dl_tbf, CTR_IMMEDIATE_ASSIGN_DL_TBF); CREATE_COUNT_INLINE(channel_request_description, CTR_CHANNEL_REQUEST_DESCRIPTION); CREATE_COUNT_INLINE(pkt_ul_assignment, CTR_PKT_UL_ASSIGNMENT); CREATE_COUNT_INLINE(pkt_access_reject, CTR_PKT_ACCESS_REJ); CREATE_COUNT_INLINE(pkt_dl_assignemnt, CTR_PKT_DL_ASSIGNMENT); CREATE_COUNT_INLINE(rlc_rcvd_control, CTR_RLC_RECV_CONTROL); CREATE_COUNT_INLINE(pua_poll_timedout, CTR_PUA_POLL_TIMEDOUT); CREATE_COUNT_INLINE(pua_poll_failed, CTR_PUA_POLL_FAILED); CREATE_COUNT_INLINE(pda_poll_timedout, CTR_PDA_POLL_TIMEDOUT); CREATE_COUNT_INLINE(pda_poll_failed, CTR_PDA_POLL_FAILED); CREATE_COUNT_INLINE(pkt_ul_ack_nack_poll_timedout, CTR_PUAN_POLL_TIMEDOUT); CREATE_COUNT_INLINE(pkt_ul_ack_nack_poll_failed, CTR_PUAN_POLL_FAILED); CREATE_COUNT_INLINE(pkt_dl_ack_nack_poll_timedout, CTR_PDAN_POLL_TIMEDOUT); CREATE_COUNT_INLINE(pkt_dl_ack_nack_poll_failed, CTR_PDAN_POLL_FAILED); CREATE_COUNT_INLINE(gprs_dl_cs1, CTR_GPRS_DL_CS1); CREATE_COUNT_INLINE(gprs_dl_cs2, CTR_GPRS_DL_CS2); CREATE_COUNT_INLINE(gprs_dl_cs3, CTR_GPRS_DL_CS3); CREATE_COUNT_INLINE(gprs_dl_cs4, CTR_GPRS_DL_CS4); CREATE_COUNT_INLINE(egprs_dl_mcs1, CTR_EGPRS_DL_MCS1); CREATE_COUNT_INLINE(egprs_dl_mcs2, CTR_EGPRS_DL_MCS2); CREATE_COUNT_INLINE(egprs_dl_mcs3, CTR_EGPRS_DL_MCS3); CREATE_COUNT_INLINE(egprs_dl_mcs4, CTR_EGPRS_DL_MCS4); CREATE_COUNT_INLINE(egprs_dl_mcs5, CTR_EGPRS_DL_MCS5); CREATE_COUNT_INLINE(egprs_dl_mcs6, CTR_EGPRS_DL_MCS6); CREATE_COUNT_INLINE(egprs_dl_mcs7, CTR_EGPRS_DL_MCS7); CREATE_COUNT_INLINE(egprs_dl_mcs8, CTR_EGPRS_DL_MCS8); CREATE_COUNT_INLINE(egprs_dl_mcs9, CTR_EGPRS_DL_MCS9); CREATE_COUNT_INLINE(gprs_ul_cs1, CTR_GPRS_UL_CS1); CREATE_COUNT_INLINE(gprs_ul_cs2, CTR_GPRS_UL_CS2); CREATE_COUNT_INLINE(gprs_ul_cs3, CTR_GPRS_UL_CS3); CREATE_COUNT_INLINE(gprs_ul_cs4, CTR_GPRS_UL_CS4); CREATE_COUNT_INLINE(egprs_ul_mcs1, CTR_EGPRS_UL_MCS1); CREATE_COUNT_INLINE(egprs_ul_mcs2, CTR_EGPRS_UL_MCS2); CREATE_COUNT_INLINE(egprs_ul_mcs3, CTR_EGPRS_UL_MCS3); CREATE_COUNT_INLINE(egprs_ul_mcs4, CTR_EGPRS_UL_MCS4); CREATE_COUNT_INLINE(egprs_ul_mcs5, CTR_EGPRS_UL_MCS5); CREATE_COUNT_INLINE(egprs_ul_mcs6, CTR_EGPRS_UL_MCS6); CREATE_COUNT_INLINE(egprs_ul_mcs7, CTR_EGPRS_UL_MCS7); CREATE_COUNT_INLINE(egprs_ul_mcs8, CTR_EGPRS_UL_MCS8); CREATE_COUNT_INLINE(egprs_ul_mcs9, CTR_EGPRS_UL_MCS9); #undef CREATE_COUNT_INLINE #define CREATE_STAT_INLINE(func_name, func_name_get, stat_name) \ inline void BTS::func_name(int32_t val) {\ osmo_stat_item_set(m_statg->items[stat_name], val); \ } \ inline int32_t BTS::func_name_get() {\ return osmo_stat_item_get_last(m_statg->items[stat_name]); \ } CREATE_STAT_INLINE(ms_present, ms_present_get, STAT_MS_PRESENT); #undef CREATE_STAT_INLINE #endif #ifdef __cplusplus extern "C" { #endif void bts_cleanup(); struct gprs_rlcmac_bts *bts_main_data(); struct rate_ctr_group *bts_main_data_stats(); struct osmo_stat_item_group *bts_main_data_stat_items(); #ifdef __cplusplus } #endif