You cannot select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.

797 lines
27 KiB
C++

/**
*
* \section COPYRIGHT
*
* Copyright 2013-2020 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.
*
*/
#include "srsenb/hdr/phy/phy_ue_db.h"
using namespace srsenb;
void phy_ue_db::init(stack_interface_phy_lte* stack_ptr,
const phy_args_t& phy_args_,
const phy_cell_cfg_list_t& cell_cfg_list_)
{
stack = stack_ptr;
phy_args = &phy_args_;
cell_cfg_list = &cell_cfg_list_;
}
inline int phy_ue_db::_add_rnti(uint16_t rnti)
{
// Private function not mutexed
// Assert RNTI does NOT exist
if (ue_db.count(rnti)) {
return SRSRAN_ERROR;
}
// Create new UE by accesing it
ue_db[rnti].cell_info[0] = {};
// Get UE
common_ue& ue = ue_db[rnti];
// Load default values to PCell
ue.cell_info[0].phy_cfg.set_defaults();
// Set constant configuration fields
_set_common_config_rnti(rnti, ue.cell_info[0].phy_cfg);
// Configure as PCell
ue.cell_info[0].state = cell_state_primary;
// Iterate all pending ACK
for (uint32_t tti = 0; tti < TTIMOD_SZ; tti++) {
_clear_tti_pending_rnti(tti, rnti);
}
return SRSRAN_SUCCESS;
}
inline void phy_ue_db::_clear_tti_pending_rnti(uint32_t tti, uint16_t rnti)
{
// Private function not mutexed, no need to assert RNTI or TTI
// Get UE
common_ue& ue = ue_db[rnti];
srsran_pdsch_ack_t& pdsch_ack = ue.pdsch_ack[tti];
// Reset ACK information
pdsch_ack = {};
uint32_t nof_active_cc = 0;
for (auto& cell_info : ue.cell_info) {
if (cell_info.state == cell_state_primary or cell_info.state == cell_state_secondary_active) {
nof_active_cc++;
}
}
// Copy essentials. It is assumed the PUCCH parameters are the same for all carriers
pdsch_ack.transmission_mode = ue.cell_info[0].phy_cfg.dl_cfg.tm;
pdsch_ack.nof_cc = nof_active_cc;
pdsch_ack.ack_nack_feedback_mode = ue.cell_info[0].phy_cfg.ul_cfg.pucch.ack_nack_feedback_mode;
pdsch_ack.simul_cqi_ack = ue.cell_info[0].phy_cfg.ul_cfg.pucch.simul_cqi_ack;
}
inline void phy_ue_db::_set_common_config_rnti(uint16_t rnti, srsran::phy_cfg_t& phy_cfg) const
{
// Set common parameters
phy_cfg.dl_cfg.pdsch.rnti = rnti;
phy_cfg.ul_cfg.pucch.rnti = rnti;
phy_cfg.ul_cfg.pusch.rnti = rnti;
phy_cfg.ul_cfg.pusch.meas_time_en = true;
phy_cfg.ul_cfg.pusch.meas_epre_en = phy_args->pusch_meas_epre;
phy_cfg.ul_cfg.pusch.meas_ta_en = phy_args->pusch_meas_ta;
phy_cfg.ul_cfg.pusch.meas_evm_en = phy_args->pusch_meas_evm;
phy_cfg.ul_cfg.pusch.max_nof_iterations = phy_args->pusch_max_its;
phy_cfg.ul_cfg.pucch.threshold_format1 = SRSRAN_PUCCH_DEFAULT_THRESHOLD_FORMAT1;
phy_cfg.ul_cfg.pucch.threshold_data_valid_format1a = SRSRAN_PUCCH_DEFAULT_THRESHOLD_FORMAT1A;
phy_cfg.ul_cfg.pucch.threshold_data_valid_format2 = SRSRAN_PUCCH_DEFAULT_THRESHOLD_FORMAT2;
phy_cfg.ul_cfg.pucch.threshold_data_valid_format3 = SRSRAN_PUCCH_DEFAULT_THRESHOLD_FORMAT3;
phy_cfg.ul_cfg.pucch.threshold_dmrs_detection = SRSRAN_PUCCH_DEFAULT_THRESHOLD_DMRS;
phy_cfg.ul_cfg.pucch.meas_ta_en = phy_args->pucch_meas_ta;
}
inline uint32_t phy_ue_db::_get_ue_cc_idx(uint16_t rnti, uint32_t enb_cc_idx) const
{
uint32_t ue_cc_idx = 0;
const common_ue& ue = ue_db.at(rnti);
for (; ue_cc_idx < SRSRAN_MAX_CARRIERS; ue_cc_idx++) {
const cell_info_t& scell_info = ue.cell_info[ue_cc_idx];
if (scell_info.enb_cc_idx == enb_cc_idx and
(scell_info.state == cell_state_primary or scell_info.state == cell_state_secondary_active)) {
return ue_cc_idx;
}
}
return ue_cc_idx;
}
uint32_t phy_ue_db::_get_uci_enb_cc_idx(uint32_t tti, uint16_t rnti) const
{
// Find the lowest index available PUSCH grant
for (const cell_info_t& cell_info : ue_db.at(rnti).cell_info) {
if (cell_info.is_grant_available[tti]) {
return cell_info.enb_cc_idx;
}
}
return (uint32_t)cell_cfg_list->size();
}
inline int phy_ue_db::_assert_rnti(uint16_t rnti) const
{
if (not ue_db.count(rnti)) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_enb_cc(uint16_t rnti, uint32_t enb_cc_idx) const
{
// Assert RNTI exist
if (_assert_rnti(rnti) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Check Component Carrier is part of UE SCell map
if (_get_ue_cc_idx(rnti, enb_cc_idx) == SRSRAN_MAX_CARRIERS) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
bool phy_ue_db::ue_has_cell(uint16_t rnti, uint32_t enb_cc_idx) const
{
return _assert_enb_cc(rnti, enb_cc_idx) == SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_enb_pcell(uint16_t rnti, uint32_t enb_cc_idx) const
{
if (_assert_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Check cell is PCell
const cell_info_t& cell_info = ue_db.at(rnti).cell_info[_get_ue_cc_idx(rnti, enb_cc_idx)];
if (cell_info.state != cell_state_primary) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_ue_cc(uint16_t rnti, uint32_t ue_cc_idx) const
{
if (_assert_rnti(rnti) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Check the cell index is in range
if (ue_cc_idx >= SRSRAN_MAX_CARRIERS) {
return SRSRAN_ERROR;
}
const cell_info_t& cell_info = ue_db.at(rnti).cell_info.at(ue_cc_idx);
if (cell_info.state == cell_state_none) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_active_enb_cc(uint16_t rnti, uint32_t enb_cc_idx) const
{
if (_assert_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Check SCell is active, ignore PCell state
const cell_info_t& cell_info = ue_db.at(rnti).cell_info[_get_ue_cc_idx(rnti, enb_cc_idx)];
if (cell_info.state != cell_state_primary and cell_info.state != cell_state_secondary_active) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_stack() const
{
if (stack == nullptr) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_assert_cell_list_cfg() const
{
if (cell_cfg_list == nullptr) {
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
inline int phy_ue_db::_get_rnti_config(uint16_t rnti, uint32_t enb_cc_idx, srsran::phy_cfg_t& phy_cfg) const
{
srsran::phy_cfg_t default_cfg = {};
default_cfg.set_defaults();
default_cfg.dl_cfg.pdsch.rnti = rnti;
default_cfg.ul_cfg.pucch.rnti = rnti;
default_cfg.ul_cfg.pusch.rnti = rnti;
// Use default configuration for non-user C-RNTI
if (not SRSRAN_RNTI_ISUSER(rnti)) {
phy_cfg = default_cfg;
return SRSRAN_SUCCESS;
}
// Make sure the C-RNTI exists and the cell/carrier is configured
if (_assert_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Write the current configuration
uint32_t ue_cc_idx = _get_ue_cc_idx(rnti, enb_cc_idx);
phy_cfg = ue_db.at(rnti).cell_info.at(ue_cc_idx).phy_cfg;
return SRSRAN_SUCCESS;
}
void phy_ue_db::clear_tti_pending_ack(uint32_t tti)
{
std::lock_guard<std::mutex> lock(mutex);
// Iterate all UEs
for (auto& iter : ue_db) {
_clear_tti_pending_rnti(TTIMOD(tti), iter.first);
}
}
void phy_ue_db::addmod_rnti(uint16_t rnti, const phy_interface_rrc_lte::phy_rrc_cfg_list_t& phy_cfg_list)
{
std::lock_guard<std::mutex> lock(mutex);
// Create new user if did not exist
if (ue_db.count(rnti) == 0) {
_add_rnti(rnti);
}
// Get UE by reference
common_ue& ue = ue_db[rnti];
// During a reconfiguration, all parameters in phy_cfg_t shall be applied immediately except:
// - Multiple CSI request field in DCI (phy_cfg_t.dl_cfg.dci.multiple_csi_request_enabled)
// - Extended TBS tables (for 256QAM) (phy_cfg_t.dl_cfg.pdsch.use_tbs_index_alt)
// which shall be applied immediately only for UL grants and transmissions.
//
// For DL grants and transmissions, during the period between the transmission of the reconfiguration
// and the reception of the reconfigurationComplete, the values before the reconfiguration shall be used
// Store the current values for CSI and extended TBS in temporary variables
ue.stashed_multiple_csi_request_enabled = (_count_nof_configured_scell(rnti) > 0);
for (uint32_t i = 0; i < SRSRAN_MAX_CARRIERS; i++) {
ue.cell_info[i].stash_use_tbs_index_alt = ue.cell_info[i].phy_cfg.dl_cfg.pdsch.use_tbs_index_alt;
}
// Iterate PHY RRC configuration for each UE cell/carrier
uint32_t nof_cc = SRSRAN_MIN(phy_cfg_list.size(), SRSRAN_MAX_CARRIERS);
for (uint32_t ue_cc_idx = 0; ue_cc_idx < nof_cc; ue_cc_idx++) {
const phy_interface_rrc_lte::phy_rrc_cfg_t& phy_rrc_dedicated = phy_cfg_list[ue_cc_idx];
// Configured, add/modify entry in the cell_info map
cell_info_t& cell_info = ue.cell_info[ue_cc_idx];
// Configure PHY
if (cell_info.state == cell_state_primary) {
// If primary serving cell's eNb cell/carrier index changed, it applies default current config
if (cell_info.enb_cc_idx != phy_rrc_dedicated.enb_cc_idx) {
cell_info.phy_cfg.set_defaults();
_set_common_config_rnti(rnti, cell_info.phy_cfg);
}
// Apply primary serving cell configuration
cell_info.phy_cfg = phy_rrc_dedicated.phy_cfg;
_set_common_config_rnti(rnti, cell_info.phy_cfg);
} else if (phy_rrc_dedicated.configured) {
// Overwrite the secondary serving cell configuration independently of the current state. Higher layers (MAC
// and/or RRC) shall be responsible for the secondary serving cell activation/deactivation.
cell_info.phy_cfg = phy_rrc_dedicated.phy_cfg;
_set_common_config_rnti(rnti, cell_info.phy_cfg);
// Set Cell state to inactive (as configured) only if it was not configured before. Avoid losing coherence with
// MAC Activation/Deactivation states
if (cell_info.state == cell_state_t::cell_state_none) {
cell_info.state = cell_state_secondary_inactive;
}
} else {
// Cell without configuration (except PCell)
cell_info.state = cell_state_none;
}
// Set serving cell index
cell_info.enb_cc_idx = phy_rrc_dedicated.enb_cc_idx;
}
// Disable the rest of potential serving cells
for (uint32_t i = nof_cc; i < SRSRAN_MAX_CARRIERS; i++) {
ue.cell_info[i].state = cell_state_none;
}
// Enable/Disable extended CSI field in DCI according to 3GPP 36.212 R10 5.3.3.1.1 Format 0
for (uint32_t ue_cc_idx = 0; ue_cc_idx < nof_cc; ue_cc_idx++) {
ue.cell_info[ue_cc_idx].phy_cfg.dl_cfg.dci.multiple_csi_request_enabled = (_count_nof_configured_scell(rnti) > 0);
}
}
int phy_ue_db::rem_rnti(uint16_t rnti)
{
std::lock_guard<std::mutex> lock(mutex);
if (ue_db.count(rnti) == 0) {
return SRSRAN_ERROR;
}
ue_db.erase(rnti);
return SRSRAN_SUCCESS;
}
uint32_t phy_ue_db::_count_nof_configured_scell(uint16_t rnti)
{
uint32_t nof_configured_scell = 0;
for (uint32_t ue_cc_idx = 0; ue_cc_idx < SRSRAN_MAX_CARRIERS; ue_cc_idx++) {
if (ue_db[rnti].cell_info[ue_cc_idx].state == cell_state_t::cell_state_secondary_inactive ||
ue_db[rnti].cell_info[ue_cc_idx].state == cell_state_t::cell_state_secondary_active) {
nof_configured_scell++;
}
}
return nof_configured_scell;
}
int phy_ue_db::complete_config(uint16_t rnti)
{
std::lock_guard<std::mutex> lock(mutex);
// Makes sure the RNTI exists
if (_assert_rnti(rnti) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Once the reconfiguration is complete, the temporary parameters become the new ones
// Update temporary multiple CSI DCI field with the new value
ue_db[rnti].stashed_multiple_csi_request_enabled = (_count_nof_configured_scell(rnti) > 0);
// Update temporary alternate TBS value with the new one
for (uint32_t ue_cc_idx = 0; ue_cc_idx < SRSRAN_MAX_CARRIERS; ue_cc_idx++) {
ue_db[rnti].cell_info[ue_cc_idx].stash_use_tbs_index_alt =
ue_db[rnti].cell_info[ue_cc_idx].phy_cfg.dl_cfg.pdsch.use_tbs_index_alt;
}
return SRSRAN_SUCCESS;
}
int phy_ue_db::activate_deactivate_scell(uint16_t rnti, uint32_t ue_cc_idx, bool activate)
{
std::lock_guard<std::mutex> lock(mutex);
// Assert RNTI and SCell are valid
if (_assert_ue_cc(rnti, ue_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_SUCCESS;
}
cell_info_t& cell_info = ue_db[rnti].cell_info[ue_cc_idx];
// If scell is default only complain
if (activate and cell_info.state == cell_state_none) {
return SRSRAN_ERROR;
}
// Set scell state
cell_info.state = (activate) ? cell_state_secondary_active : cell_state_secondary_inactive;
return SRSRAN_SUCCESS;
}
bool phy_ue_db::is_pcell(uint16_t rnti, uint32_t enb_cc_idx) const
{
std::lock_guard<std::mutex> lock(mutex);
return _assert_enb_pcell(rnti, enb_cc_idx) == SRSRAN_SUCCESS;
}
int phy_ue_db::get_dl_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dl_cfg_t& dl_cfg) const
{
std::lock_guard<std::mutex> lock(mutex);
srsran::phy_cfg_t phy_cfg = {};
if (_get_rnti_config(rnti, enb_cc_idx, phy_cfg) < SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
dl_cfg = phy_cfg.dl_cfg;
// The DL configuration must overwrite the use_tbs_index_alt value (for 256QAM) with the temporary value
// in case we are in the middle of a reconfiguration
if (ue_db.count(rnti) && SRSRAN_RNTI_ISUSER(rnti)) {
uint32_t ue_cc_idx = _get_ue_cc_idx(rnti, enb_cc_idx);
if (ue_cc_idx == 0) {
dl_cfg.pdsch.use_tbs_index_alt = ue_db.at(rnti).cell_info[ue_cc_idx].stash_use_tbs_index_alt;
}
}
return SRSRAN_SUCCESS;
}
int phy_ue_db::get_dci_dl_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dci_cfg_t& dci_cfg) const
{
std::lock_guard<std::mutex> lock(mutex);
srsran::phy_cfg_t phy_cfg = {};
if (_get_rnti_config(rnti, enb_cc_idx, phy_cfg) < SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
dci_cfg = phy_cfg.dl_cfg.dci;
// The DCI configuration used for DL grants must overwrite the multiple_csi_request_enabled value with the
// temporary value in case we are in the middle of a reconfiguration
if (ue_db.count(rnti) && SRSRAN_RNTI_ISUSER(rnti)) {
uint32_t ue_cc_idx = _get_ue_cc_idx(rnti, enb_cc_idx);
if (ue_cc_idx == 0) {
dci_cfg.multiple_csi_request_enabled = ue_db.at(rnti).stashed_multiple_csi_request_enabled;
}
}
return SRSRAN_SUCCESS;
}
int phy_ue_db::get_ul_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_ul_cfg_t& ul_cfg) const
{
std::lock_guard<std::mutex> lock(mutex);
srsran::phy_cfg_t phy_cfg = {};
if (_get_rnti_config(rnti, enb_cc_idx, phy_cfg) < SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
ul_cfg = phy_cfg.ul_cfg;
return SRSRAN_SUCCESS;
}
int phy_ue_db::get_dci_ul_config(uint16_t rnti, uint32_t enb_cc_idx, srsran_dci_cfg_t& dci_cfg) const
{
std::lock_guard<std::mutex> lock(mutex);
srsran::phy_cfg_t phy_cfg = {};
if (_get_rnti_config(rnti, enb_cc_idx, phy_cfg) < SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
dci_cfg = phy_cfg.dl_cfg.dci;
return SRSRAN_SUCCESS;
}
bool phy_ue_db::set_ack_pending(uint32_t tti, uint32_t enb_cc_idx, const srsran_dci_dl_t& dci)
{
std::lock_guard<std::mutex> lock(mutex);
// Assert rnti and cell exits and it is active
if (_assert_active_enb_cc(dci.rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return false;
}
common_ue& ue = ue_db.at(dci.rnti);
uint32_t ue_cc_idx = _get_ue_cc_idx(dci.rnti, enb_cc_idx);
srsran_pdsch_ack_cc_t& pdsch_ack_cc = ue.pdsch_ack[tti].cc[ue_cc_idx];
pdsch_ack_cc.M = 1; ///< Hardcoded for FDD
// Fill PDSCH ACK information
srsran_pdsch_ack_m_t& pdsch_ack_m = pdsch_ack_cc.m[0]; ///< Assume FDD only
pdsch_ack_m.present = true;
pdsch_ack_m.resource.grant_cc_idx = ue_cc_idx; ///< Assumes no cross-carrier scheduling
pdsch_ack_m.resource.v_dai_dl = 0; ///< Ignore for FDD
pdsch_ack_m.resource.n_cce = dci.location.ncce;
pdsch_ack_m.resource.tpc_for_pucch = dci.tpc_pucch;
// Set TB info
for (uint32_t tb_idx = 0; tb_idx < SRSRAN_MAX_CODEWORDS; tb_idx++) {
// Count only if the TB is enabled and the TB index is valid for the DCI format
if (SRSRAN_DCI_IS_TB_EN(dci.tb[tb_idx]) and tb_idx < srsran_dci_format_max_tb(dci.format)) {
pdsch_ack_m.value[tb_idx] = 1;
pdsch_ack_m.k++;
} else {
pdsch_ack_m.value[tb_idx] = 2;
}
}
return true;
}
int phy_ue_db::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)
{
std::lock_guard<std::mutex> lock(mutex);
// Reset UCI CFG, avoid returning carrying cached information
uci_cfg = {};
// Assert Cell List configuration
if (_assert_cell_list_cfg() != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Assert eNb Cell/Carrier for the given RNTI
if (_assert_active_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Get the eNb cell/carrier index with lowest serving cell index (ue_cc_idx) that has an available grant.
uint32_t uci_enb_cc_id = _get_uci_enb_cc_idx(tti, rnti);
bool pusch_grant_available = (uci_enb_cc_id < (uint32_t)cell_cfg_list->size());
// There is a PUSCH grant available for the provided RNTI in at least one serving cell and this call is for PUCCH
if (pusch_grant_available and not is_pusch_available) {
return SRSRAN_SUCCESS;
}
// There is a PUSCH grant and enb_cc_idx with lowest ue_cc_idx with a grant
if (pusch_grant_available and uci_enb_cc_id != enb_cc_idx) {
return SRSRAN_SUCCESS;
}
// No PUSCH grant for this TTI and cell and no enb_cc_idx is not the PCell
if (not pusch_grant_available and _get_ue_cc_idx(rnti, enb_cc_idx) != 0) {
return SRSRAN_SUCCESS;
}
common_ue& ue = ue_db.at(rnti);
const srsran::phy_cfg_t& pcell_cfg = ue.cell_info[0].phy_cfg;
bool uci_required = false;
const cell_info_t& pcell_info = ue.cell_info[0];
const srsran_cell_t& pcell = cell_cfg_list->at(pcell_info.enb_cc_idx).cell;
// Check if SR opportunity (will only be used in PUCCH)
uci_cfg.is_scheduling_request_tti = (srsran_ue_ul_sr_send_tti(&pcell_cfg.ul_cfg.pucch, tti) == 1);
uci_required |= uci_cfg.is_scheduling_request_tti;
// Get pending CQI reports for this TTI, stops at first CC reporting
bool periodic_cqi_required = false;
for (uint32_t cell_idx = 0; cell_idx < SRSRAN_MAX_CARRIERS and not periodic_cqi_required; cell_idx++) {
const cell_info_t& cell_info = ue.cell_info[cell_idx];
const srsran_dl_cfg_t& dl_cfg = cell_info.phy_cfg.dl_cfg;
// According 3GPP 36.213 R10 section 7.2 UE procedure for reporting Channel State Information (CSI)
// If the UE is configured with more than one serving cell, it transmits CSI for activated serving cell(s) only.
if (cell_info.state == cell_state_primary or cell_info.state == cell_state_secondary_active) {
const srsran_cell_t& cell = cell_cfg_list->at(cell_info.enb_cc_idx).cell;
// Check if CQI report is required
periodic_cqi_required = srsran_enb_dl_gen_cqi_periodic(&cell, &dl_cfg, tti, cell_info.last_ri, &uci_cfg.cqi);
// Save SCell index for using it after
uci_cfg.cqi.scell_index = cell_idx;
}
}
uci_required |= periodic_cqi_required;
// If no periodic CQI report required, check aperiodic reporting
if ((not periodic_cqi_required) and aperiodic_cqi_request) {
// Aperiodic only supported for PCell
const srsran_dl_cfg_t& dl_cfg = pcell_info.phy_cfg.dl_cfg;
uci_required = srsran_enb_dl_gen_cqi_aperiodic(&pcell, &dl_cfg, pcell_info.last_ri, &uci_cfg.cqi);
}
// Get pending ACKs from PDSCH
srsran_dl_sf_cfg_t dl_sf_cfg = {};
dl_sf_cfg.tti = tti;
srsran_pdsch_ack_t& pdsch_ack = ue.pdsch_ack[tti];
pdsch_ack.is_pusch_available = is_pusch_available;
srsran_enb_dl_gen_ack(&pcell, &dl_sf_cfg, &pdsch_ack, &uci_cfg);
uci_required |= (srsran_uci_cfg_total_ack(&uci_cfg) > 0);
// Return whether UCI needs to be decoded
return uci_required ? 1 : SRSRAN_SUCCESS;
}
void phy_ue_db::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)
{
uint8_t stack_value = 0;
switch (cqi_cfg.type) {
case SRSRAN_CQI_TYPE_WIDEBAND:
stack_value = cqi_value.wideband.wideband_cqi;
stack->cqi_info(tti, rnti, cqi_cc_idx, stack_value);
break;
case SRSRAN_CQI_TYPE_SUBBAND_UE:
stack_value = cqi_value.subband_ue.subband_cqi;
stack->sb_cqi_info(tti,
rnti,
cqi_cc_idx,
srsran_cqi_get_sb_idx(tti, cqi_value.subband_ue.subband_label, &cqi_report_cfg, &cell),
stack_value);
break;
case SRSRAN_CQI_TYPE_SUBBAND_HL:
stack_value = cqi_value.subband_hl.wideband_cqi_cw0;
// Todo: change interface
stack->cqi_info(tti, rnti, cqi_cc_idx, stack_value);
break;
case SRSRAN_CQI_TYPE_SUBBAND_UE_DIFF:
stack_value = cqi_value.subband_ue_diff.wideband_cqi;
stack->sb_cqi_info(tti,
rnti,
cqi_cc_idx,
cqi_value.subband_ue_diff.position_subband,
stack_value + cqi_value.subband_ue_diff.subband_diff_cqi);
break;
}
}
int phy_ue_db::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)
{
std::lock_guard<std::mutex> lock(mutex);
// Assert UE RNTI database entry and eNb cell/carrier must be active
if (_assert_active_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Assert Stack
if (_assert_stack() != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Notify SR
if (uci_cfg.is_scheduling_request_tti && uci_value.scheduling_request) {
stack->sr_detected(tti, rnti);
}
// Get UE
common_ue& ue = ue_db.at(rnti);
// Get ACK info
srsran_pdsch_ack_t& pdsch_ack = ue.pdsch_ack[tti];
const srsran_cell_t& cell = cell_cfg_list->at(ue.cell_info[0].enb_cc_idx).cell;
srsran_enb_dl_get_ack(&cell, &uci_cfg, &uci_value, &pdsch_ack);
// Iterate over the ACK information
for (uint32_t ue_cc_idx = 0; ue_cc_idx < SRSRAN_MAX_CARRIERS; ue_cc_idx++) {
const srsran_pdsch_ack_cc_t& pdsch_ack_cc = pdsch_ack.cc[ue_cc_idx];
for (uint32_t m = 0; m < pdsch_ack_cc.M; m++) {
if (pdsch_ack_cc.m[m].present) {
for (uint32_t tb = 0; tb < SRSRAN_MAX_CODEWORDS; tb++) {
if (pdsch_ack_cc.m[m].value[tb] != 2) {
stack->ack_info(tti, rnti, ue.cell_info[ue_cc_idx].enb_cc_idx, tb, pdsch_ack_cc.m[m].value[tb] == 1);
}
}
}
}
}
// Assert the SCell exists and it is active
if (_assert_ue_cc(rnti, uci_cfg.cqi.scell_index) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Get CQI carrier index
cell_info_t& cqi_scell_info = ue_db.at(rnti).cell_info[uci_cfg.cqi.scell_index];
uint32_t cqi_cc_idx = cqi_scell_info.enb_cc_idx;
// Notify CQI only if CRC is valid
if (uci_value.cqi.data_crc) {
// Channel quality indicator itself
if (uci_cfg.cqi.data_enable) {
send_cqi_data(tti, rnti, cqi_cc_idx, uci_cfg.cqi, uci_value.cqi, ue.cell_info[0].phy_cfg.dl_cfg.cqi_report, cell, stack);
}
// Precoding Matrix indicator (TM4)
if (uci_cfg.cqi.pmi_present) {
uint8_t pmi_value = 0;
switch (uci_cfg.cqi.type) {
case SRSRAN_CQI_TYPE_WIDEBAND:
pmi_value = uci_value.cqi.wideband.pmi;
break;
case SRSRAN_CQI_TYPE_SUBBAND_HL:
pmi_value = uci_value.cqi.subband_hl.pmi;
break;
default:
ERROR("CQI type=%d not implemented for PMI", uci_cfg.cqi.type);
break;
}
stack->pmi_info(tti, rnti, cqi_cc_idx, pmi_value);
}
}
// Rank indicator (TM3 and TM4)
if (uci_cfg.cqi.ri_len) {
stack->ri_info(tti, rnti, cqi_cc_idx, uci_value.ri);
cqi_scell_info.last_ri = uci_value.ri;
}
return SRSRAN_SUCCESS;
}
int phy_ue_db::set_last_ul_tb(uint16_t rnti, uint32_t enb_cc_idx, uint32_t pid, srsran_ra_tb_t tb)
{
std::lock_guard<std::mutex> lock(mutex);
// Assert UE DB entry
if (_assert_active_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// Save resource allocation
ue_db.at(rnti).cell_info[_get_ue_cc_idx(rnti, enb_cc_idx)].last_tb[pid] = tb;
return SRSRAN_SUCCESS;
}
int phy_ue_db::get_last_ul_tb(uint16_t rnti, uint32_t enb_cc_idx, uint32_t pid, srsran_ra_tb_t& ra_tb) const
{
std::lock_guard<std::mutex> lock(mutex);
// Assert UE DB entry
if (_assert_active_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
return SRSRAN_ERROR;
}
// writes the latest stored UL transmission grant
ra_tb = ue_db.at(rnti).cell_info[_get_ue_cc_idx(rnti, enb_cc_idx)].last_tb[pid];
return SRSRAN_SUCCESS;
}
int phy_ue_db::set_ul_grant_available(uint32_t tti, const stack_interface_phy_lte::ul_sched_list_t& ul_sched_list)
{
int ret = SRSRAN_SUCCESS;
std::lock_guard<std::mutex> lock(mutex);
// Reset all available grants flags for the given TTI
for (auto& ue : ue_db) {
for (cell_info_t& cell_info : ue.second.cell_info) {
cell_info.is_grant_available[tti] = false;
}
}
// For each eNb Cell/Carrier grant set a flag to the corresponding RNTI
for (uint32_t enb_cc_idx = 0; enb_cc_idx < (uint32_t)ul_sched_list.size(); enb_cc_idx++) {
const stack_interface_phy_lte::ul_sched_t& ul_sched = ul_sched_list[enb_cc_idx];
for (uint32_t i = 0; i < ul_sched.nof_grants; i++) {
const stack_interface_phy_lte::ul_sched_grant_t& ul_sched_grant = ul_sched.pusch[i];
uint16_t rnti = ul_sched_grant.dci.rnti;
// Check that eNb Cell/Carrier is active for the given RNTI
if (_assert_active_enb_cc(rnti, enb_cc_idx) != SRSRAN_SUCCESS) {
ret = SRSRAN_ERROR;
srslog::fetch_basic_logger("RRC-NR").error("Error setting grant for rnti=0x%x, cc=%d\n", rnti, enb_cc_idx);
continue;
}
// Rise Grant available flag
ue_db[rnti].cell_info[_get_ue_cc_idx(rnti, enb_cc_idx)].is_grant_available[tti] = true;
}
}
return ret;
}