/** * * \section COPYRIGHT * * Copyright 2013-2021 Software Radio Systems Limited * * By using this file, you agree to the terms and conditions set * forth in the LICENSE file which can be found at the top level of * the distribution. * */ #ifndef SRSRAN_SCELL_STATE_H #define SRSRAN_SCELL_STATE_H #include #include #include namespace srsue { namespace scell { /** * References * * According to 3GPP 36.321 R10 (MAC procedures) section 5.13 Activation/Deactivation of SCells * An activated cell operation shall include (Summarised): * - SRS transmissions on the SCell; * - CQI/PMI/RI/PTI reporting for the SCell; * - PDCCH monitoring on the SCell; * - PDCCH monitoring for the SCell * * According to 3GPP 36.213 R10 (PHY procedures) section 4.3 Timing for Secondary Cell Activation / Deactivation * When a UE receives an activation command for a secondary cell in subframe n, the corresponding actions shall be * applied at subframe n+8. (Summarised) */ class state { private: static constexpr uint32_t activation_delay_tti = FDD_HARQ_DELAY_DL_MS + FDD_HARQ_DELAY_UL_MS; static constexpr uint32_t activation_margin_tti = FDD_HARQ_DELAY_DL_MS; // SCell EARFCN, PCI, configured and enabled list struct cfg { uint32_t earfcn = 0; uint32_t pci = 0; enum { none = 0, inactive, active } status = none; }; std::array scell_cfg; enum { idle = 0, waiting, transition } activation_state = idle; uint32_t activation_cmd = 0; uint32_t activation_tti = 0; mutable std::mutex mutex; bool _get_cmd_activation(uint32_t cc_idx) const { return ((activation_cmd >> cc_idx) & 0x1) == 0x1; } bool _tti_greater_or_equal_than(uint32_t a, uint32_t b) const { return TTI_SUB(a, b) < 10240 / 2; } public: /** * A SCell Activation/Deactivation command is received. Stores the new command and the TTI. Also, the internal state * goes to waiting. * * If a previous command was received and not applied, it will discard it. * * @param cmd SCell Activation/Deactivation command * @param tti TTI in which the command was received */ void set_activation_deactivation(uint32_t cmd, uint32_t tti) { std::unique_lock lock(mutex); // Store command activation_cmd = cmd; // Command is waiting activation_state = waiting; activation_tti = TTI_ADD(tti, activation_delay_tti); } /** * @brief Deactivates all the active SCells */ void deactivate_all() { std::unique_lock lock(mutex); for (cfg& e : scell_cfg) { if (e.status == cfg::active) { e.status = cfg::inactive; } } } void run_tti(uint32_t tti) { std::unique_lock lock(mutex); switch (activation_state) { case idle: // waiting for receiving a command, do nothing break; case waiting: // Detect that TTI when the CMD needs to be applied, the activation cannot be done instantly because some // workers might be currently ongoing, so only update state if (_tti_greater_or_equal_than(tti, activation_tti)) { activation_state = transition; } break; case transition: // Detect when the TTI has increased enough to make sure there arent workers, set the configuration if (TTI_SUB(tti, activation_tti) >= activation_margin_tti) { // Reload cell states for (uint32_t i = 1; i < SRSRAN_MAX_CARRIERS; i++) { // Get Activation command value bool activate = _get_cmd_activation(i); // Apply activation only if the cell was configured if (scell_cfg[i].status != cfg::none) { scell_cfg[i].status = activate ? cfg::active : cfg::inactive; } } // Go back to initial state activation_state = idle; } break; } } void configure(uint32_t cc_idx, uint32_t earfcn, uint32_t pci) { std::unique_lock lock(mutex); if (cc_idx == 0 or cc_idx >= SRSRAN_MAX_CARRIERS) { ERROR("CC IDX %d out-of-range", cc_idx); return; } scell_cfg[cc_idx].status = cfg::inactive; scell_cfg[cc_idx].earfcn = earfcn; scell_cfg[cc_idx].pci = pci; } bool is_active(uint32_t cc_idx, uint32_t tti) const { if (cc_idx == 0) { return true; } if (cc_idx >= SRSRAN_MAX_CARRIERS) { return false; } std::unique_lock lock(mutex); // Use stashed activation if the activation is transitioning and the current TTI requires new value if (activation_state == transition and scell_cfg[cc_idx].status != cfg::none and _tti_greater_or_equal_than(tti, activation_tti)) { return _get_cmd_activation(cc_idx); } return scell_cfg[cc_idx].status == cfg::active; } bool is_configured(uint32_t cc_idx) const { if (cc_idx == 0) { return true; } if (cc_idx >= SRSRAN_MAX_CARRIERS) { return false; } std::unique_lock lock(mutex); return scell_cfg[cc_idx].status != cfg::none; } void reset(uint32_t cc_idx) { if (cc_idx == 0 or cc_idx >= SRSRAN_MAX_CARRIERS) { return; } std::unique_lock lock(mutex); activation_state = idle; cfg& e = scell_cfg[cc_idx]; e.status = cfg::none; e.earfcn = 0; e.pci = UINT32_MAX; } void reset() { std::unique_lock lock(mutex); activation_state = idle; for (cfg& e : scell_cfg) { e.status = cfg::none; e.earfcn = 0; e.pci = UINT32_MAX; } } uint32_t get_pci(uint32_t cc_idx) { std::unique_lock lock(mutex); if (cc_idx == 0 or cc_idx >= SRSRAN_MAX_CARRIERS) { ERROR("CC IDX %d out-of-range", cc_idx); return 0; } return scell_cfg[cc_idx].pci; } uint32_t get_earfcn(uint32_t cc_idx) { std::unique_lock lock(mutex); if (cc_idx == 0 or cc_idx >= SRSRAN_MAX_CARRIERS) { ERROR("CC IDX %d out-of-range", cc_idx); return 0; } return scell_cfg[cc_idx].earfcn; } }; } // namespace scell } // namespace srsue #endif // SRSRAN_SCELL_STATE_H