/** * * \section COPYRIGHT * * Copyright 2013-2015 Software Radio Systems Limited * * \section LICENSE * * This file is part of the srsUE library. * * srsUE 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. * * srsUE 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. * * A copy of the GNU Affero General Public License can be found in * the LICENSE file in the top-level directory of this distribution * and at http://www.gnu.org/licenses/. * */ #ifndef SRSUE_RRC_H #define SRSUE_RRC_H #include "pthread.h" #include "rrc_common.h" #include "srslte/common/buffer_pool.h" #include "srslte/common/log.h" #include "srslte/common/common.h" #include "srslte/interfaces/ue_interfaces.h" #include "srslte/common/security.h" #include "srslte/common/threads.h" #include "srslte/common/block_queue.h" #include #include #include typedef struct { uint32_t ue_category; uint32_t feature_group; uint8_t supported_bands[LIBLTE_RRC_BAND_N_ITEMS]; uint32_t nof_supported_bands; }rrc_args_t; using srslte::byte_buffer_t; namespace srsue { class cell_t { public: bool is_valid() { return phy_cell.earfcn != 0 && srslte_cell_isvalid(&phy_cell.cell); } bool equals(cell_t *x) { return equals(x->phy_cell.earfcn, x->phy_cell.cell.id); } bool equals(uint32_t earfcn, uint32_t pci) { return earfcn == this->phy_cell.earfcn && pci == phy_cell.cell.id; } // NaN means an RSRP value has not yet been obtained. Keep then in the list and clean them if never updated bool greater(cell_t *x) { return rsrp > x->rsrp || isnan(rsrp); } bool plmn_equals(LIBLTE_RRC_PLMN_IDENTITY_STRUCT plmn_id) { if (has_valid_sib1) { for (uint32_t i = 0; i < sib1.N_plmn_ids; i++) { if (plmn_id.mcc == sib1.plmn_id[i].id.mcc && plmn_id.mnc == sib1.plmn_id[i].id.mnc) { return true; } } } return false; } uint32_t nof_plmns() { if (has_valid_sib1) { return sib1.N_plmn_ids; } else { return 0; } } LIBLTE_RRC_PLMN_IDENTITY_STRUCT get_plmn(uint32_t idx) { if (idx < sib1.N_plmn_ids && has_valid_sib1) { return sib1.plmn_id[idx].id; } else { LIBLTE_RRC_PLMN_IDENTITY_STRUCT null; null.mnc = 0; null.mcc = 0; return null; } } uint16_t get_tac() { if (has_valid_sib1) { return sib1.tracking_area_code; } else { return 0; } } cell_t() { phy_interface_rrc::phy_cell_t tmp = {}; cell_t(tmp, 0); } cell_t(phy_interface_rrc::phy_cell_t phy_cell, float rsrp) { gettimeofday(&last_update, NULL); this->has_valid_sib1 = false; this->has_valid_sib2 = false; this->has_valid_sib3 = false; this->has_valid_sib13 = false; this->phy_cell = phy_cell; this->rsrp = rsrp; in_sync = true; bzero(&sib1, sizeof(sib1)); bzero(&sib2, sizeof(sib2)); bzero(&sib3, sizeof(sib3)); bzero(&sib13, sizeof(sib13)); } uint32_t get_earfcn() { return phy_cell.earfcn; } uint32_t get_pci() { return phy_cell.cell.id; } void set_rsrp(float rsrp) { if (!isnan(rsrp)) { this->rsrp = rsrp; } in_sync = true; gettimeofday(&last_update, NULL); } float get_rsrp() { return rsrp; } void set_sib1(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_1_STRUCT *sib1) { memcpy(&this->sib1, sib1, sizeof(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_1_STRUCT)); has_valid_sib1 = true; } void set_sib2(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_2_STRUCT *sib2) { memcpy(&this->sib2, sib2, sizeof(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_2_STRUCT)); has_valid_sib2 = true; } void set_sib3(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_3_STRUCT *sib3) { memcpy(&this->sib3, sib3, sizeof(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_3_STRUCT)); has_valid_sib3 = true; } void set_sib13(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_13_STRUCT *sib13) { memcpy(&this->sib13, sib13, sizeof(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_13_STRUCT)); has_valid_sib13 = true; } uint32_t timeout_secs(struct timeval now) { struct timeval t[3]; memcpy(&t[2], &now, sizeof(struct timeval)); memcpy(&t[1], &last_update, sizeof(struct timeval)); get_time_interval(t); return t[0].tv_sec; } LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_1_STRUCT *sib1ptr() { return &sib1; } LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_2_STRUCT *sib2ptr() { return &sib2; } LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_3_STRUCT *sib3ptr() { return &sib3; } uint32_t get_cell_id() { return sib1.cell_id; } bool has_sib1() { return has_valid_sib1; } bool has_sib2() { return has_valid_sib2; } bool has_sib3() { return has_valid_sib3; } bool has_sib13() { return has_valid_sib13; } bool has_sib(uint32_t index) { switch(index) { case 0: return has_sib1(); case 1: return has_sib2(); case 2: return has_sib3(); case 12: return has_sib13(); } return false; } uint16_t get_mcc() { if (has_valid_sib1) { if (sib1.N_plmn_ids > 0) { return sib1.plmn_id[0].id.mcc; } } return 0; } uint16_t get_mnc() { if (has_valid_sib1) { if (sib1.N_plmn_ids > 0) { return sib1.plmn_id[0].id.mnc; } } return 0; } phy_interface_rrc::phy_cell_t phy_cell; bool in_sync; private: float rsrp; struct timeval last_update; bool has_valid_sib1; bool has_valid_sib2; bool has_valid_sib3; bool has_valid_sib13; LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_1_STRUCT sib1; LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_2_STRUCT sib2; LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_3_STRUCT sib3; LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_13_STRUCT sib13; }; class rrc :public rrc_interface_nas ,public rrc_interface_phy ,public rrc_interface_mac ,public rrc_interface_pdcp ,public rrc_interface_rlc ,public srslte::timer_callback ,public thread { public: rrc(); ~rrc(); void init(phy_interface_rrc *phy_, mac_interface_rrc *mac_, rlc_interface_rrc *rlc_, pdcp_interface_rrc *pdcp_, nas_interface_rrc *nas_, usim_interface_rrc *usim_, srslte::mac_interface_timers *mac_timers_, srslte::log *rrc_log_); void stop(); rrc_state_t get_state(); void set_args(rrc_args_t *args); // Timeout callback interface void timer_expired(uint32_t timeout_id); void liblte_rrc_log(char *str); // NAS interface void write_sdu(uint32_t lcid, byte_buffer_t *sdu); void enable_capabilities(); uint16_t get_mcc(); uint16_t get_mnc(); int plmn_search(found_plmn_t found_plmns[MAX_FOUND_PLMNS]); void plmn_select(LIBLTE_RRC_PLMN_IDENTITY_STRUCT plmn_id); bool connection_request(LIBLTE_RRC_CON_REQ_EST_CAUSE_ENUM cause, srslte::byte_buffer_t *dedicatedInfoNAS); void set_ue_idenity(LIBLTE_RRC_S_TMSI_STRUCT s_tmsi); // PHY interface void in_sync(); void out_of_sync(); void new_phy_meas(float rsrp, float rsrq, uint32_t tti, int earfcn, int pci); // MAC interface void ho_ra_completed(bool ra_successful); void release_pucch_srs(); void run_tti(uint32_t tti); void ra_problem(); // GW interface bool is_connected(); // this is also NAS interface bool have_drb(); // PDCP interface void write_pdu(uint32_t lcid, byte_buffer_t *pdu); void write_pdu_bcch_bch(byte_buffer_t *pdu); void write_pdu_bcch_dlsch(byte_buffer_t *pdu); void write_pdu_pcch(byte_buffer_t *pdu); private: typedef struct { enum { PCCH, STOP } command; byte_buffer_t *pdu; } cmd_msg_t; bool running; srslte::block_queue cmd_q; void run_thread(); void process_pcch(byte_buffer_t *pdu); srslte::byte_buffer_pool *pool; srslte::log *rrc_log; phy_interface_rrc *phy; mac_interface_rrc *mac; rlc_interface_rrc *rlc; pdcp_interface_rrc *pdcp; nas_interface_rrc *nas; usim_interface_rrc *usim; LIBLTE_RRC_UL_DCCH_MSG_STRUCT ul_dcch_msg; LIBLTE_RRC_UL_CCCH_MSG_STRUCT ul_ccch_msg; LIBLTE_RRC_DL_CCCH_MSG_STRUCT dl_ccch_msg; LIBLTE_RRC_DL_DCCH_MSG_STRUCT dl_dcch_msg; byte_buffer_t *dedicatedInfoNAS; byte_buffer_t* byte_align_and_pack(); void send_ul_ccch_msg(); void send_ul_dcch_msg(); srslte::bit_buffer_t bit_buf; pthread_mutex_t mutex; rrc_state_t state; uint8_t transaction_id; LIBLTE_RRC_S_TMSI_STRUCT ueIdentity; bool ueIdentity_configured; bool drb_up; rrc_args_t args; uint32_t cell_clean_cnt; uint16_t ho_src_rnti; cell_t ho_src_cell; phy_interface_rrc::phy_cfg_t previous_phy_cfg; mac_interface_rrc::mac_cfg_t previous_mac_cfg; bool pending_mob_reconf; LIBLTE_RRC_CONNECTION_RECONFIGURATION_STRUCT mob_reconf; uint8_t k_rrc_enc[32]; uint8_t k_rrc_int[32]; uint8_t k_up_enc[32]; uint8_t k_up_int[32]; // Not used: only for relay nodes (3GPP 33.401 Annex A.7) srslte::CIPHERING_ALGORITHM_ID_ENUM cipher_algo; srslte::INTEGRITY_ALGORITHM_ID_ENUM integ_algo; std::map srbs; std::map drbs; // RRC constants and timers srslte::mac_interface_timers *mac_timers; uint32_t n310_cnt, N310; uint32_t n311_cnt, N311; uint32_t t300, t301, t302, t310, t311, t304; // Radio bearers typedef enum{ RB_ID_SRB0 = 0, RB_ID_SRB1, RB_ID_SRB2, RB_ID_DRB1, RB_ID_DRB2, RB_ID_DRB3, RB_ID_DRB4, RB_ID_DRB5, RB_ID_DRB6, RB_ID_DRB7, RB_ID_DRB8, RB_ID_MAX } rb_id_t; static const std::string rb_id_str[]; std::string get_rb_name(uint32_t lcid) { if (lcid < RB_ID_MAX) { return rb_id_str[lcid]; } else { return "INVALID_RB"; } } // List of strongest neighbour cell const static int NEIGHBOUR_TIMEOUT = 5; const static int NOF_NEIGHBOUR_CELLS = 8; std::vector neighbour_cells; cell_t *serving_cell; void set_serving_cell(uint32_t cell_idx); void set_serving_cell(phy_interface_rrc::phy_cell_t phy_cell); int find_neighbour_cell(uint32_t earfcn, uint32_t pci); bool add_neighbour_cell(uint32_t earfcn, uint32_t pci, float rsrp); bool add_neighbour_cell(phy_interface_rrc::phy_cell_t phy_cell, float rsrp); bool add_neighbour_cell(cell_t *cell); void sort_neighbour_cells(); void clean_neighbours(); std::vector::iterator delete_neighbour(std::vector::iterator it); void delete_neighbour(uint32_t cell_idx); bool configure_serving_cell(); bool si_acquire(uint32_t index); uint32_t sib_start_tti(uint32_t tti, uint32_t period, uint32_t offset, uint32_t sf); const static int SIB_SEARCH_TIMEOUT_MS = 1000; const static uint32_t NOF_REQUIRED_SIBS = 3; // SIB1, SIB2 and SIB3 bool initiated; bool ho_start; bool go_idle; // Measurements sub-class class rrc_meas { public: void init(rrc *parent); void reset(); bool parse_meas_config(LIBLTE_RRC_MEAS_CONFIG_STRUCT *meas_config); void new_phy_meas(uint32_t earfcn, uint32_t pci, float rsrp, float rsrq, uint32_t tti); void run_tti(uint32_t tti); bool timer_expired(uint32_t timer_id); void ho_finish(); void delete_report(uint32_t earfcn, uint32_t pci); private: const static int NOF_MEASUREMENTS = 3; typedef enum {RSRP = 0, RSRQ = 1, BOTH = 2} quantity_t; typedef struct { uint32_t pci; float q_offset; } meas_cell_t; typedef struct { uint32_t earfcn; float q_offset; std::map cells; } meas_obj_t; typedef struct { uint32_t interval; uint32_t max_cell; uint32_t amount; quantity_t trigger_quantity; quantity_t report_quantity; LIBLTE_RRC_EVENT_EUTRA_STRUCT event; enum {EVENT, PERIODIC} trigger_type; } report_cfg_t; typedef struct { float ms[NOF_MEASUREMENTS]; bool triggered; bool timer_enter_triggered; bool timer_exit_triggered; uint32_t enter_tti; uint32_t exit_tti; } meas_value_t; typedef struct { uint32_t nof_reports_sent; uint32_t report_id; uint32_t object_id; bool triggered; uint32_t periodic_timer; std::map cell_values; // Value for each PCI in this object } meas_t; std::map objects; std::map reports_cfg; std::map active; rrc *parent; srslte::log *log_h; phy_interface_rrc *phy; srslte::mac_interface_timers *mac_timers; uint32_t filter_k_rsrp, filter_k_rsrq; float filter_a[NOF_MEASUREMENTS]; meas_value_t pcell_measurement; bool s_measure_enabled; float s_measure_value; void stop_reports(meas_t *m); void stop_reports_object(uint32_t object_id); void remove_meas_object(uint32_t object_id); void remove_meas_report(uint32_t report_id); void remove_meas_id(uint32_t measId); void remove_meas_id(std::map::iterator it); void calculate_triggers(uint32_t tti); void update_phy(); void L3_filter(meas_value_t *value, float rsrp[NOF_MEASUREMENTS]); bool find_earfcn_cell(uint32_t earfcn, uint32_t pci, meas_obj_t **object, int *cell_idx); float range_to_value(quantity_t quant, uint8_t range); uint8_t value_to_range(quantity_t quant, float value); bool process_event(LIBLTE_RRC_EVENT_EUTRA_STRUCT *event, uint32_t tti, bool enter_condition, bool exit_condition, meas_t *m, meas_value_t *cell); void generate_report(uint32_t meas_id); }; rrc_meas measurements; // Measurement object from phy typedef struct { float rsrp; float rsrq; uint32_t tti; uint32_t earfcn; uint32_t pci; } phy_meas_t; void process_phy_meas(); void process_new_phy_meas(phy_meas_t meas); std::queue phy_meas_q; // Cell selection/reselection functions/variables typedef struct { float Qrxlevmin; float Qrxlevminoffset; float Qqualmin; float Qqualminoffset; float s_intrasearchP; float q_hyst; float threshservinglow; } cell_resel_cfg_t; cell_resel_cfg_t cell_resel_cfg; float get_srxlev(float Qrxlevmeas); float get_squal(float Qqualmeas); bool cell_selection(); bool cell_selection_criteria(float rsrp, float rsrq = 0); void cell_reselection(float rsrp, float rsrq); phy_interface_rrc::cell_search_ret_t cell_search(); LIBLTE_RRC_PLMN_IDENTITY_STRUCT selected_plmn_id; bool plmn_is_selected; bool security_is_activated; // RLC interface void max_retx_attempted(); // Senders void send_con_request(LIBLTE_RRC_CON_REQ_EST_CAUSE_ENUM cause); void send_con_restablish_request(LIBLTE_RRC_CON_REEST_REQ_CAUSE_ENUM cause); void send_con_restablish_complete(); void send_con_setup_complete(byte_buffer_t *nas_msg); void send_ul_info_transfer(byte_buffer_t *nas_msg); void send_security_mode_complete(); void send_rrc_con_reconfig_complete(); void send_rrc_ue_cap_info(); // Parsers void parse_dl_ccch(byte_buffer_t *pdu); void parse_dl_dcch(uint32_t lcid, byte_buffer_t *pdu); void parse_dl_info_transfer(uint32_t lcid, byte_buffer_t *pdu); // Helpers bool con_reconfig(LIBLTE_RRC_CONNECTION_RECONFIGURATION_STRUCT *reconfig); void con_reconfig_failed(); bool con_reconfig_ho(LIBLTE_RRC_CONNECTION_RECONFIGURATION_STRUCT *reconfig); bool ho_prepare(); void ho_failed(); void rrc_connection_release(); void radio_link_failure(); void leave_connected(); void apply_rr_config_common_dl(LIBLTE_RRC_RR_CONFIG_COMMON_STRUCT *config); void apply_rr_config_common_ul(LIBLTE_RRC_RR_CONFIG_COMMON_STRUCT *config); void handle_sib1(); void handle_sib2(); void handle_sib3(); void handle_sib13(); void apply_sib2_configs(LIBLTE_RRC_SYS_INFO_BLOCK_TYPE_2_STRUCT *sib2); void handle_con_setup(LIBLTE_RRC_CONNECTION_SETUP_STRUCT *setup); void handle_con_reest(LIBLTE_RRC_CONNECTION_REESTABLISHMENT_STRUCT *setup); void handle_rrc_con_reconfig(uint32_t lcid, LIBLTE_RRC_CONNECTION_RECONFIGURATION_STRUCT *reconfig); void add_srb(LIBLTE_RRC_SRB_TO_ADD_MOD_STRUCT *srb_cnfg); void add_drb(LIBLTE_RRC_DRB_TO_ADD_MOD_STRUCT *drb_cnfg); void release_drb(uint8_t lcid); bool apply_rr_config_dedicated(LIBLTE_RRC_RR_CONFIG_DEDICATED_STRUCT *cnfg); void apply_phy_config_dedicated(LIBLTE_RRC_PHYSICAL_CONFIG_DEDICATED_STRUCT *phy_cnfg, bool apply_defaults); void apply_mac_config_dedicated(LIBLTE_RRC_MAC_MAIN_CONFIG_STRUCT *mac_cfg, bool apply_defaults); // Helpers for setting default values void set_phy_default_pucch_srs(); void set_phy_default(); void set_mac_default(); void set_rrc_default(); }; } // namespace srsue #endif // SRSUE_RRC_H