/** * Copyright 2013-2022 Software Radio Systems Limited * * This file is part of srsRAN. * * srsRAN 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. * * srsRAN 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 SRSENB_PHY_UE_DB_H_ #define SRSENB_PHY_UE_DB_H_ #include "phy_interfaces.h" #include "srsran/interfaces/enb_mac_interfaces.h" #include "srsran/interfaces/enb_phy_interfaces.h" #include #include #include namespace srsenb { class phy_ue_db { private: /** * Primary serving cell configuration flow * ---------------------------------------- * Initially UEs are created with a default configuration. When it receives a new configuration for a UE from the * stack, it does not apply the primary serving cell straightforward. The primary cell configuration is stashed and * not applied. However, some parameters are copied to the actual configuration order to allow PHY transmitting the * upper layers messages and receiving the messages before applying the full configuration. * * The stashed primary cell configuration is applied as soon as the stack indicates the completion of the * configuration procedure. * * +---------+ Stack set config +--------------+ Stack Config complete +--------------------+ * | Default |----------------->| Stash config |---------------------->| Full configuration | * +---------+ +--------------+ +--------------------+ * ^ | * | User reconfiguration | * +------------------------------------------+ * * Secondary serving cell configuration flow * ------------------------------------------ * Secondary serving cell configuration uses the cell_state attribute for indicating whether the they have been * configured from the stack set and activated/deactivated. * * Initially the the state is default (none) and it goes to inactive as soon as it is configured from the stack, then * it can transition to active as soon as the stack indicates so. * * Consider that once the secondary serving cell is configured, the state transition between active and deactivated * shall be performed by stack calls activation/deactivation and not re-configuration. * * +---------+ Set SCell Configuration +-------------+ SCell activation +--------+ * | Default | --------------------------->| Deactivated |--------------------->| Active | * +---------+ +-------------+ +--------+ * ^ ^ ^ | | * | | | | | * --+ | | SCell deactivation | | * | +---------------------------------+ | * | Remove SCell configuration | * +-----------------------------------------------------------------------------+ */ typedef enum { cell_state_none = 0, ///< Uninitialized cell_state_primary, ///< PCell cell_state_secondary_inactive, ///< Configured from RRC but not activated cell_state_secondary_active ///< Configured and activated from MAC } cell_state_t; /** * Cell information for the UE database */ struct cell_info_t { cell_state_t state = cell_state_none; ///< Configuration state uint32_t enb_cc_idx = 0; ///< Corresponding eNb cell/carrier index uint8_t last_ri = 0; ///< Last reported rank indicator srsran::circular_array last_tb = {}; ///< Stores last PUSCH Resource allocation bool stash_use_tbs_index_alt = false; srsran::phy_cfg_t phy_cfg; ///< Configuration, it has a default constructor srsran::circular_array is_grant_available; ///< Indicates whether there is an available grant }; /** * UE object stored in the PHY common database */ struct common_ue { bool stashed_multiple_csi_request_enabled = false; srsran::circular_array pdsch_ack = {}; ///< Pending acknowledgements for this Cell std::array cell_info = {}; ///< Cell information, indexed by ue_cell_idx }; /** * UE database indexed by RNTI */ std::map ue_db; /** * Concurrency protection mutex, allowed modifications from const methods. */ mutable std::mutex mutex; /** * Stack interface */ stack_interface_phy_lte* stack = nullptr; /** * PHY arguments pointer, used for loading the common UE parameters when a new configuration is set */ const phy_args_t* phy_args = {}; /** * Cell list */ const phy_cell_cfg_list_t* cell_cfg_list = nullptr; /** * Internal RNTI addition, it is not thread safe protected * * @param rnti identifier of the UE * @return SRSRAN_SUCCESS if the RNTI is not duplicated and is added successfully, SRSRAN_ERROR code if it exists */ inline int _add_rnti(uint16_t rnti); /** * Internal pending ACK clear for a given RNTI and TTI, it is not thread safe protected * * @param tti is the given TTI (requires assertion prior to call) * @param rnti identifier of the UE (requires assertion prior to call) */ inline void _clear_tti_pending_rnti(uint32_t tti, uint16_t rnti); /** * Helper method to set the constant attributes of a given RNTI after the configuration is set, it does not modify * internal states. * * @param rnti identifier of the UE (requires assertion prior to call) * @param phy_cfg points to the PHY configuration for a given cell/carrier */ inline void _set_common_config_rnti(uint16_t rnti, srsran::phy_cfg_t& phy_cfg) const; /** * Gets the SCell index for a given RNTI and a eNb cell/carrier. It returns the SCell index (0 if PCell) if the cc_idx * is found among the configured cells/carriers. Otherwise, it returns SRSRAN_MAX_CARRIERS. * * @param rnti identifier of the UE (requires assertion prior to call) * @param enb_cc_idx the eNb cell/carrier index to look for in the RNTI. * @return the SCell index as described above. */ inline uint32_t _get_ue_cc_idx(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Gets the eNb Cell/Carrier index in which the UCI shall be carried. This corresponds to the serving cell with lowest * index that has an UL grant available. * * If no grant is available in the indicated TTI, it returns the number of the eNb Cells/Carriers. * * @param tti The UL processing TTI * @param rnti Temporal UE ID * @return the eNb Cell/Carrier with lowest serving cell index that has an UL grant */ uint32_t _get_uci_enb_cc_idx(uint32_t tti, uint16_t rnti) const; /** * Checks if a given RNTI exists in the database * @param rnti provides UE identifier * @return SRSRAN_SUCCESS if the indicated RNTI exists, otherwise it returns SRSRAN_ERROR */ inline int _assert_rnti(uint16_t rnti) const; /** * Checks if an RNTI is configured to use an specified eNb cell/carrier as PCell or SCell * @param rnti provides UE identifier * @param enb_cc_idx provides eNb cell/carrier * @return SRSRAN_SUCCESS if the indicated RNTI exists, otherwise it returns SRSRAN_ERROR */ inline int _assert_enb_cc(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Checks if an RNTI uses a given eNb cell/carrier as PCell * @param rnti provides UE identifier * @param enb_cc_idx provides eNb cell/carrier index * @return SRSRAN_SUCCESS if the indicated eNb cell/carrier of the RNTI is a PCell, otherwise it returns SRSRAN_ERROR */ inline int _assert_enb_pcell(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Checks if an RNTI is configured to use an specified UE cell/carrier as PCell or SCell * @param rnti provides UE identifier * @param ue_cc_idx UE cell/carrier index that is asserted * @return SRSRAN_SUCCESS if the indicated cell/carrier index is valid, otherwise it returns SRSRAN_ERROR */ inline int _assert_ue_cc(uint16_t rnti, uint32_t ue_cc_idx) const; /** * Checks if an RNTI is configured to use an specified eNb cell/carrier as PCell or SCell and it is active * @param rnti provides UE identifier * @param enb_cc_idx UE cell/carrier index that is asserted * @return SRSRAN_SUCCESS if the indicated eNb cell/carrier is active, otherwise it returns SRSRAN_ERROR */ inline int _assert_active_enb_cc(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Internal eNb stack assertion * @return SRSRAN_SUCCESS if available, otherwise it returns SRSRAN_ERROR */ inline int _assert_stack() const; /** * Internal eNb Cell list assertion * @return SRSRAN_SUCCESS if available, otherwise it returns SRSRAN_ERROR */ inline int _assert_cell_list_cfg() const; /** * Internal eNb general configuration getter, returns default configuration if the UE does not exist in the given cell * * @param rnti provides UE identifier * @param enb_cc_idx eNb cell index * @param[out] phy_cfg The PHY configuration of the indicated UE for the indicated eNb carrier/call index. * @return SRSRAN_SUCCESS if provided context is correct, SRSRAN_ERROR code otherwise */ inline int _get_rnti_config(uint16_t rnti, uint32_t enb_cc_idx, srsran::phy_cfg_t& phy_cfg) const; /** * Count number of configured secondary serving cells * * @param rnti provides UE identifier * @return The number of configured secondary cells */ inline uint32_t _count_nof_configured_scell(uint16_t rnti); public: /** * Initialises the UE database with the stack and cell list * @param stack_ptr points to the stack (read/write) * @param cell_cfg_list_ points to the cell configuration list (read only) */ void init(stack_interface_phy_lte* stack_ptr, const phy_args_t& phy_args_, const phy_cell_cfg_list_t& cell_cfg_list_); /** * Adds or modifies a user in the UE database setting. This function requires the physical layer configuration coming * from the RRC in order to extract cross carrier information such as channel quality reporting configuration. The * first element of the list must be the PCell and the rest will be SCell in the order * * @param rnti identifier of the user * @param phy_cfg_list List of the eNb physical layer configuration coming for the RRC */ void addmod_rnti(uint16_t rnti, const phy_interface_rrc_lte::phy_rrc_cfg_list_t& phy_cfg_list); /** * Removes a whole UE entry from the UE database * * @param rnti identifier of the UE * @return SRSRAN_SUCCESS if provided RNTI exists, SRSRAN_ERROR code otherwise */ int rem_rnti(uint16_t rnti); /** * Stack callback for indicating the completion of the configuration process and apply the stashed configuration in * the primary cell. * * @param rnti identifier of the user * @return SRSRAN_SUCCESS if provided RNTI exists, SRSRAN_ERROR code otherwise */ int complete_config(uint16_t rnti); /** * Activates or deactivates configured secondary cells for a given RNTI and SCell index (UE SCell index), index 0 is * reserved for primary cell * @param rnti identifier of the UE * @param scell_idx * @param activate * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int activate_deactivate_scell(uint16_t rnti, uint32_t ue_cc_idx, bool activate); /** * Asserts a given eNb cell is PCell of the given RNTI * @param rnti identifier of the UE * @param enb_cc_idx eNb cell/carrier index * @return It returns true if it is the primary cell, otherwise it returns false */ bool is_pcell(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Asserts a given eNb cell is part of the given RNTI * @param rnti identifier of the UE * @param enb_cc_idx eNb cell/carrier index * @return It returns true if the cell is part of the UE, othwerwise it returns false */ bool ue_has_cell(uint16_t rnti, uint32_t enb_cc_idx) const; /** * Get the current down-link physical layer configuration for an RNTI and an eNb cell/carrier * * @param rnti identifier of the UE * @param cc_idx the eNb cell/carrier identifier * @param[out] dl_cfg Current DL PHY configuration * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int get_dl_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dl_cfg_t& dl_cfg) const; /** * Get the current DCI configuration for PDSCH physical layer configuration for an RNTI and an eNb cell/carrier * * @param rnti identifier of the UE * @param cc_idx the eNb cell/carrier identifier * @param[out] dci_cfg Current DL-DCI configuration * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int get_dci_dl_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dci_cfg_t& dci_cfg) const; /** * Get the current PUCCH physical layer configuration for an RNTI and an eNb cell/carrier. * * @param rnti identifier of the UE * @param cc_idx the eNb cell/carrier identifier * @param[out] ul_cfg Current UL PHY configuration * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int get_ul_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_ul_cfg_t& ul_cfg) const; /** * Get the current DCI configuration for PUSCH physical layer configuration for an RNTI and an eNb cell/carrier * * @param rnti identifier of the UE * @param cc_idx the eNb cell/carrier identifier * @param[out] dci_cfg Current UL-DCI configuration * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int get_dci_ul_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dci_cfg_t& dci_cfg) const; /** * Removes all the pending ACKs of all the RNTIs for a given TTI * * @param tti is the given TTI to clear */ void clear_tti_pending_ack(uint32_t tti); /** * Sets the pending ACK for a given TTI in a given Component Carrier and user (RNTI is a member of the DCI) * * @param tti is the given TTI to fill * @param cc_idx the carrier where the DCI is scheduled * @param dci carries the Transport Block and required scheduling information * */ bool set_ack_pending(uint32_t tti, uint32_t enb_cc_idx, const srsran_dci_dl_t& dci); /** * Fills the Uplink Control Information (UCI) configuration and returns true/false idicating if UCI bits are required. * @param tti the current UL reception TTI * @param cc_idx the eNb cell/carrier where the UL receiption is happening * @param rnti is the UE identifier * @param aperiodic_cqi_request indicates if aperiodic CQI was requested * @param uci_cfg brings the UCI configuration * @return 1 if UCI decoding is required, 0 if not, -1 if error */ int fill_uci_cfg(uint32_t tti, uint32_t enb_cc_idx, uint16_t rnti, bool aperiodic_cqi_request, bool is_pusch_available, srsran_uci_cfg_t& uci_cfg); /** * Sends the decoded Uplink Control Information by PUCCH or PUSCH to MAC * @param tti the current TTI * @param rnti is the UE identifier * @param uci_cfg is the UCI configuration * @param uci_value is the UCI received value * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int send_uci_data(uint32_t tti, uint16_t rnti, uint32_t enb_cc_idx, const srsran_uci_cfg_t& uci_cfg, const srsran_uci_value_t& uci_value); static void send_cqi_data(uint32_t tti, uint16_t rnti, uint32_t cqi_cc_idx, const srsran_cqi_cfg_t& cqi_cfg, const srsran_cqi_value_t& cqi_value, const srsran_cqi_report_cfg_t& cqi_report_cfg, const srsran_cell_t& cell, stack_interface_phy_lte* stack); /** * Set the latest UL Transport Block resource allocation for a given RNTI, eNb cell/carrier and UL HARQ process * identifier. * * @param rnti the UE temporal ID * @param enb_cc_idx the cell/carrier origin of the transmission * @param pid HARQ process identifier * @param tb the Resource Allocation for the PUSCH transport block * @return SRSRAN_SUCCESS if provided RNTI exists in the given cell, SRSRAN_ERROR code otherwise */ int set_last_ul_tb(uint16_t rnti, uint32_t enb_cc_idx, uint32_t pid, srsran_ra_tb_t tb); /** * Get the latest UL Transport Block resource allocation for a given RNTI, eNb cell/carrier and UL HARQ process * identifier. It returns the resource allocation if the RNTI and cell/eNb are valid, otherwise it will return an * default Resource allocation (all zeros by default). * * @param rnti the UE temporal ID * @param cc_idx the cell/carrier origin of the transmission * @param pid HARQ process identifier * @param[out] ra_tb the Resource Allocation for the PUSCH transport block * @return SRSRAN_SUCCESS if the provided context is valid */ int get_last_ul_tb(uint16_t rnti, uint32_t enb_cc_idx, uint32_t pid, srsran_ra_tb_t& ra_tb) const; /** * Flags to true the UL grant available for a given TTI, RNTI and eNb cell/carrier index * @param tti the current TTI * @param rnti * @param enb_cc_idx */ int set_ul_grant_available(uint32_t tti, const stack_interface_phy_lte::ul_sched_list_t& ul_sched_list); }; } // namespace srsenb #endif // SRSENB_PHY_UE_DB_H_