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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 "sched_sim_ue.h"
#include "lib/include/srslte/mac/pdu.h"
#include "sched_test_utils.h"
namespace srsenb {
using phich_t = sched_interface::ul_sched_phich_t;
bool sim_ue_ctxt_t::is_msg3_harq(uint32_t ue_cc_idx, uint32_t pid) const
{
auto& h = cc_list.at(ue_cc_idx).ul_harqs[pid];
return h.first_tti_rx == msg3_tti_rx and h.nof_txs == h.nof_retxs + 1;
}
bool sim_ue_ctxt_t::is_last_ul_retx(uint32_t ue_cc_idx, uint32_t pid, uint32_t maxharq_msg3tx) const
{
bool is_msg3 = is_msg3_harq(ue_cc_idx, pid);
auto& h = cc_list.at(ue_cc_idx).ul_harqs[pid];
return h.nof_retxs + 1 >= (is_msg3 ? maxharq_msg3tx : ue_cfg.maxharq_tx);
}
bool sim_ue_ctxt_t::is_last_dl_retx(uint32_t ue_cc_idx, uint32_t pid) const
{
auto& h = cc_list.at(ue_cc_idx).dl_harqs[pid];
return h.nof_retxs + 1 >= ue_cfg.maxharq_tx;
}
ue_sim::ue_sim(uint16_t rnti_,
const sched_interface::ue_cfg_t& ue_cfg_,
srslte::tti_point prach_tti_rx_,
uint32_t preamble_idx) :
logger(srslog::fetch_basic_logger("MAC"))
{
ctxt.rnti = rnti_;
ctxt.prach_tti_rx = prach_tti_rx_;
ctxt.preamble_idx = preamble_idx;
set_cfg(ue_cfg_);
}
void ue_sim::set_cfg(const sched_interface::ue_cfg_t& ue_cfg_)
{
ctxt.ue_cfg = ue_cfg_;
ctxt.cc_list.resize(ue_cfg_.supported_cc_list.size());
for (auto& cc : ctxt.cc_list) {
for (size_t pid = 0; pid < (FDD_HARQ_DELAY_UL_MS + FDD_HARQ_DELAY_DL_MS); ++pid) {
cc.ul_harqs[pid].pid = pid;
cc.dl_harqs[pid].pid = pid;
}
}
}
void ue_sim::bearer_cfg(uint32_t lc_id, const sched_interface::ue_bearer_cfg_t& cfg)
{
ctxt.ue_cfg.ue_bearers.at(lc_id) = cfg;
}
int ue_sim::update(const sf_output_res_t& sf_out)
{
update_conn_state(sf_out);
update_dl_harqs(sf_out);
update_ul_harqs(sf_out);
return SRSLTE_SUCCESS;
}
void ue_sim::update_dl_harqs(const sf_output_res_t& sf_out)
{
for (uint32_t cc = 0; cc < sf_out.cc_params.size(); ++cc) {
for (uint32_t i = 0; i < sf_out.dl_cc_result[cc].data.size(); ++i) {
const auto& data = sf_out.dl_cc_result[cc].data[i];
if (data.dci.rnti != ctxt.rnti) {
continue;
}
auto& h = ctxt.cc_list[data.dci.ue_cc_idx].dl_harqs[data.dci.pid];
if (h.nof_txs == 0 or h.ndi != data.dci.tb[0].ndi) {
// It is newtx
h.nof_retxs = 0;
h.ndi = data.dci.tb[0].ndi;
h.first_tti_rx = sf_out.tti_rx;
h.dci_loc = data.dci.location;
h.tbs = data.tbs[0];
} else {
// it is retx
h.nof_retxs++;
}
h.active = true;
h.last_tti_rx = sf_out.tti_rx;
h.nof_txs++;
}
}
}
void ue_sim::update_ul_harqs(const sf_output_res_t& sf_out)
{
uint32_t pid = to_tx_ul(sf_out.tti_rx).to_uint() % (FDD_HARQ_DELAY_UL_MS + FDD_HARQ_DELAY_DL_MS);
for (uint32_t cc = 0; cc < sf_out.cc_params.size(); ++cc) {
// Update UL harqs with PHICH info
for (uint32_t i = 0; i < sf_out.ul_cc_result[cc].phich.size(); ++i) {
const auto& phich = sf_out.ul_cc_result[cc].phich[i];
if (phich.rnti != ctxt.rnti) {
continue;
}
const auto *cc_cfg = ctxt.get_cc_cfg(cc), *start = &ctxt.ue_cfg.supported_cc_list[0];
uint32_t ue_cc_idx = std::distance(start, cc_cfg);
auto& ue_cc_ctxt = ctxt.cc_list[ue_cc_idx];
auto& h = ue_cc_ctxt.ul_harqs[pid];
bool is_ack = phich.phich == phich_t::ACK;
bool is_msg3 =
h.nof_txs == h.nof_retxs + 1 and ctxt.msg3_tti_rx.is_valid() and h.first_tti_rx == ctxt.msg3_tti_rx;
bool last_retx = h.nof_retxs + 1 >= (is_msg3 ? sf_out.cc_params[0].cfg.maxharq_msg3tx : ctxt.ue_cfg.maxharq_tx);
if (is_ack or last_retx) {
h.active = false;
}
}
// Update UL harqs with PUSCH grants
for (uint32_t i = 0; i < sf_out.ul_cc_result[cc].pusch.size(); ++i) {
const auto& data = sf_out.ul_cc_result[cc].pusch[i];
if (data.dci.rnti != ctxt.rnti) {
continue;
}
auto& ue_cc_ctxt = ctxt.cc_list[data.dci.ue_cc_idx];
auto& h = ue_cc_ctxt.ul_harqs[to_tx_ul(sf_out.tti_rx).to_uint() % ue_cc_ctxt.ul_harqs.size()];
if (h.nof_txs == 0 or h.ndi != data.dci.tb.ndi) {
// newtx
h.nof_retxs = 0;
h.ndi = data.dci.tb.ndi;
h.first_tti_rx = sf_out.tti_rx;
h.tbs = data.tbs;
} else {
h.nof_retxs++;
}
h.active = true;
h.last_tti_rx = sf_out.tti_rx;
h.riv = data.dci.type2_alloc.riv;
h.nof_txs++;
}
}
}
void ue_sim::update_conn_state(const sf_output_res_t& sf_out)
{
if (ctxt.conres_rx) {
return;
}
// only check for RAR/Msg3 presence for a UE's PCell
uint32_t cc = ctxt.ue_cfg.supported_cc_list[0].enb_cc_idx;
const auto& dl_cc_result = sf_out.dl_cc_result[cc];
const auto& ul_cc_result = sf_out.ul_cc_result[cc];
srslte::tti_point tti_tx_dl = to_tx_dl(sf_out.tti_rx);
if (not ctxt.rar_tti_rx.is_valid()) {
// RAR not yet found
uint32_t rar_win_size = sf_out.cc_params[cc].cfg.prach_rar_window;
srslte::tti_interval rar_window{ctxt.prach_tti_rx + 3, ctxt.prach_tti_rx + 3 + rar_win_size};
if (rar_window.contains(tti_tx_dl)) {
for (uint32_t i = 0; i < dl_cc_result.rar.size(); ++i) {
for (uint32_t j = 0; j < dl_cc_result.rar[i].msg3_grant.size(); ++j) {
const auto& data = dl_cc_result.rar[i].msg3_grant[j].data;
if (data.prach_tti == (uint32_t)ctxt.prach_tti_rx.to_uint() and data.preamble_idx == ctxt.preamble_idx) {
ctxt.rar_tti_rx = sf_out.tti_rx;
ctxt.msg3_riv = dl_cc_result.rar[i].msg3_grant[j].grant.rba;
}
}
}
}
}
if (ctxt.rar_tti_rx.is_valid() and not ctxt.msg3_tti_rx.is_valid()) {
// RAR scheduled, Msg3 not yet scheduled
srslte::tti_point expected_msg3_tti_rx = ctxt.rar_tti_rx + MSG3_DELAY_MS;
if (expected_msg3_tti_rx == sf_out.tti_rx) {
// Msg3 should exist
for (uint32_t i = 0; i < ul_cc_result.pusch.size(); ++i) {
if (ul_cc_result.pusch[i].dci.rnti == ctxt.rnti) {
ctxt.msg3_tti_rx = sf_out.tti_rx;
}
}
}
}
if (ctxt.msg3_tti_rx.is_valid() and not ctxt.msg4_tti_rx.is_valid()) {
// Msg3 scheduled, but Msg4 not yet scheduled
for (uint32_t i = 0; i < dl_cc_result.data.size(); ++i) {
if (dl_cc_result.data[i].dci.rnti == ctxt.rnti) {
for (uint32_t j = 0; j < dl_cc_result.data[i].nof_pdu_elems[0]; ++j) {
if (dl_cc_result.data[i].pdu[0][j].lcid == (uint32_t)srslte::dl_sch_lcid::CON_RES_ID) {
// ConRes found
ctxt.msg4_tti_rx = sf_out.tti_rx;
}
}
}
}
}
}
sched_sim_base::sched_sim_base(sched_interface* sched_ptr_,
const sched_interface::sched_args_t& sched_args,
const std::vector<sched_interface::cell_cfg_t>& cell_cfg_list) :
logger(srslog::fetch_basic_logger("TEST")), sched_ptr(sched_ptr_), cell_params(cell_cfg_list.size())
{
for (uint32_t cc = 0; cc < cell_params.size(); ++cc) {
cell_params[cc].set_cfg(cc, cell_cfg_list[cc], sched_args);
}
sched_ptr->cell_cfg(cell_cfg_list); // call parent cfg
}
int sched_sim_base::add_user(uint16_t rnti, const sched_interface::ue_cfg_t& ue_cfg_, uint32_t preamble_idx)
{
CONDERROR(!srslte_prach_tti_opportunity_config_fdd(
cell_params[ue_cfg_.supported_cc_list[0].enb_cc_idx].cfg.prach_config, current_tti_rx.to_uint(), -1),
"New user added in a non-PRACH TTI");
TESTASSERT(ue_db.count(rnti) == 0);
final_ue_cfg[rnti] = ue_cfg_;
auto rach_cfg = generate_rach_ue_cfg(ue_cfg_);
ue_db.insert(std::make_pair(rnti, ue_sim(rnti, rach_cfg, current_tti_rx, preamble_idx)));
CONDERROR(sched_ptr->ue_cfg(rnti, rach_cfg) != SRSLTE_SUCCESS, "Configuring new user rnti=0x%x to sched", rnti);
sched_interface::dl_sched_rar_info_t rar_info = {};
rar_info.prach_tti = current_tti_rx.to_uint();
rar_info.temp_crnti = rnti;
rar_info.msg3_size = 7;
rar_info.preamble_idx = preamble_idx;
uint32_t pcell_idx = ue_cfg_.supported_cc_list[0].enb_cc_idx;
TESTASSERT(sched_ptr->dl_rach_info(pcell_idx, rar_info) == SRSLTE_SUCCESS);
return SRSLTE_SUCCESS;
}
int sched_sim_base::ue_recfg(uint16_t rnti, const sched_interface::ue_cfg_t& ue_cfg_)
{
CONDERROR(ue_db.count(rnti) == 0, "User must already exist to be configured");
ue_db.at(rnti).set_cfg(ue_cfg_);
CONDERROR(sched_ptr->ue_cfg(rnti, ue_cfg_) != SRSLTE_SUCCESS, "Configuring new user rnti=0x%x to sched", rnti);
return SRSLTE_SUCCESS;
}
int sched_sim_base::bearer_cfg(uint16_t rnti, uint32_t lc_id, const sched_interface::ue_bearer_cfg_t& cfg)
{
ue_db.at(rnti).bearer_cfg(lc_id, cfg);
return sched_ptr->bearer_ue_cfg(rnti, lc_id, cfg);
}
int sched_sim_base::rem_user(uint16_t rnti)
{
ue_db.erase(rnti);
return sched_ptr->ue_rem(rnti);
}
void sched_sim_base::update(const sf_output_res_t& sf_out)
{
for (auto& ue_pair : ue_db) {
ue_pair.second.update(sf_out);
}
}
sim_enb_ctxt_t sched_sim_base::get_enb_ctxt() const
{
sim_enb_ctxt_t ctxt;
ctxt.cell_params = cell_params;
for (auto& ue_pair : ue_db) {
ctxt.ue_db.insert(std::make_pair(ue_pair.first, &ue_pair.second.get_ctxt()));
}
return ctxt;
}
int sched_sim_base::set_default_tti_events(const sim_ue_ctxt_t& ue_ctxt, ue_tti_events& pending_events)
{
pending_events.cc_list.clear();
pending_events.cc_list.resize(cell_params.size());
pending_events.tti_rx = current_tti_rx;
for (uint32_t enb_cc_idx = 0; enb_cc_idx < pending_events.cc_list.size(); ++enb_cc_idx) {
auto& cc_feedback = pending_events.cc_list[enb_cc_idx];
if (ue_ctxt.enb_to_ue_cc_idx(enb_cc_idx) < 0) {
continue;
}
cc_feedback.configured = true;
cc_feedback.ue_cc_idx = ue_ctxt.enb_to_ue_cc_idx(enb_cc_idx);
for (uint32_t pid = 0; pid < SRSLTE_FDD_NOF_HARQ; ++pid) {
auto& dl_h = ue_ctxt.cc_list[cc_feedback.ue_cc_idx].dl_harqs[pid];
auto& ul_h = ue_ctxt.cc_list[cc_feedback.ue_cc_idx].ul_harqs[pid];
// Set default DL ACK
if (dl_h.active and to_tx_dl_ack(dl_h.last_tti_rx) == current_tti_rx) {
cc_feedback.dl_pid = pid;
cc_feedback.dl_ack = true; // default is ACK
}
// Set default UL ACK
if (ul_h.active and to_tx_ul(ul_h.last_tti_rx) == current_tti_rx) {
cc_feedback.ul_pid = pid;
cc_feedback.ul_ack = true;
}
// Set default DL CQI
if (srslte_cqi_periodic_send(&ue_ctxt.ue_cfg.supported_cc_list[cc_feedback.ue_cc_idx].dl_cfg.cqi_report,
current_tti_rx.to_uint(),
SRSLTE_FDD)) {
cc_feedback.dl_cqi = 28;
}
// TODO: UL CQI
}
}
return SRSLTE_SUCCESS;
}
int sched_sim_base::apply_tti_events(sim_ue_ctxt_t& ue_ctxt, const ue_tti_events& events)
{
for (uint32_t enb_cc_idx = 0; enb_cc_idx < events.cc_list.size(); ++enb_cc_idx) {
const auto& cc_feedback = events.cc_list[enb_cc_idx];
if (not cc_feedback.configured) {
continue;
}
if (cc_feedback.dl_pid >= 0) {
auto& h = ue_ctxt.cc_list[cc_feedback.ue_cc_idx].dl_harqs[cc_feedback.dl_pid];
if (cc_feedback.dl_ack) {
logger.info("DL ACK rnti=0x%x tti_dl_tx=%u pid=%d",
ue_ctxt.rnti,
to_tx_dl(h.last_tti_rx).to_uint(),
cc_feedback.dl_pid);
}
// update scheduler
if (sched_ptr->dl_ack_info(
events.tti_rx.to_uint(), ue_ctxt.rnti, enb_cc_idx, cc_feedback.tb, cc_feedback.dl_ack) < 0) {
logger.error("The ACKed DL Harq pid=%d does not exist.", cc_feedback.dl_pid);
error_counter++;
}
// update UE sim context
if (cc_feedback.dl_ack or ue_ctxt.is_last_dl_retx(cc_feedback.ue_cc_idx, cc_feedback.dl_pid)) {
h.active = false;
}
}
if (cc_feedback.ul_pid >= 0) {
auto& h = ue_ctxt.cc_list[cc_feedback.ue_cc_idx].ul_harqs[cc_feedback.ul_pid];
if (cc_feedback.ul_ack) {
logger.info("UL ACK rnti=0x%x tti_ul_tx=%u pid=%d",
ue_ctxt.rnti,
to_tx_ul(h.last_tti_rx).to_uint(),
cc_feedback.ul_pid);
}
// update scheduler
if (sched_ptr->ul_crc_info(events.tti_rx.to_uint(), ue_ctxt.rnti, enb_cc_idx, cc_feedback.ul_ack) < 0) {
logger.error("The ACKed UL Harq pid=%d does not exist.", cc_feedback.ul_pid);
error_counter++;
}
}
if (cc_feedback.dl_cqi >= 0) {
sched_ptr->dl_cqi_info(events.tti_rx.to_uint(), ue_ctxt.rnti, enb_cc_idx, cc_feedback.dl_cqi);
}
if (cc_feedback.ul_snr >= 0) {
sched_ptr->ul_snr_info(events.tti_rx.to_uint(), ue_ctxt.rnti, enb_cc_idx, cc_feedback.ul_snr, 0);
}
}
if (not ue_ctxt.conres_rx and ue_ctxt.msg3_tti_rx.is_valid() and to_tx_ul(ue_ctxt.msg3_tti_rx) <= events.tti_rx) {
uint32_t enb_cc_idx = ue_ctxt.ue_cfg.supported_cc_list[0].enb_cc_idx;
auto& cc_feedback = events.cc_list[enb_cc_idx];
// Schedule Msg4 when Msg3 is received
if (cc_feedback.ul_pid >= 0 and cc_feedback.ul_ack) {
sched_interface::ue_cfg_t ue_cfg = generate_setup_ue_cfg(final_ue_cfg[ue_ctxt.rnti]);
TESTASSERT(ue_recfg(ue_ctxt.rnti, ue_cfg) == SRSLTE_SUCCESS);
uint32_t lcid = RB_ID_SRB0; // Use SRB0 to schedule Msg4
TESTASSERT(sched_ptr->dl_rlc_buffer_state(ue_ctxt.rnti, lcid, 50, 0) == SRSLTE_SUCCESS);
TESTASSERT(sched_ptr->dl_mac_buffer_state(ue_ctxt.rnti, (uint32_t)srslte::dl_sch_lcid::CON_RES_ID, 1) ==
SRSLTE_SUCCESS);
}
// Perform DRB config when Msg4 is received
if (cc_feedback.dl_pid >= 0 and cc_feedback.dl_ack) {
ue_ctxt.conres_rx = true;
TESTASSERT(ue_recfg(ue_ctxt.rnti, final_ue_cfg[ue_ctxt.rnti]) == SRSLTE_SUCCESS);
}
}
return SRSLTE_SUCCESS;
}
void sched_sim_base::new_tti(srslte::tti_point tti_rx)
{
current_tti_rx = tti_rx;
for (auto& ue : ue_db) {
ue_tti_events events;
set_default_tti_events(ue.second.get_ctxt(), events);
set_external_tti_events(ue.second.get_ctxt(), events);
apply_tti_events(ue.second.get_ctxt(), events);
}
}
} // namespace srsenb