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/**
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*
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* \section COPYRIGHT
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*
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* Copyright 2013-2015 Software Radio Systems Limited
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*
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* \section LICENSE
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*
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* This file is part of the srsUE library.
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*
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* srsUE is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Affero General Public License as
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* published by the Free Software Foundation, either version 3 of
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* the License, or (at your option) any later version.
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*
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* srsUE is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Affero General Public License for more details.
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*
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* A copy of the GNU Affero General Public License can be found in
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* the LICENSE file in the top-level directory of this distribution
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* and at http://www.gnu.org/licenses/.
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*
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*/
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#include "srsue/hdr/ue.h"
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#include "srslte/srslte.h"
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#include <pthread.h>
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#include <iostream>
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#include <string>
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#include <algorithm>
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#include <iterator>
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using namespace srslte;
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namespace srsue{
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ue::ue()
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:started(false)
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{
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}
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ue::~ue()
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{
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for (uint32_t i = 0; i < phy_log.size(); i++) {
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delete(phy_log[i]);
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}
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}
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bool ue::init(all_args_t *args_)
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{
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args = args_;
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if (!args->log.filename.compare("stdout")) {
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logger = &logger_stdout;
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} else {
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logger_file.init(args->log.filename, args->log.file_max_size);
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logger_file.log("\n\n");
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logger_file.log(get_build_string().c_str());
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logger = &logger_file;
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}
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rf_log.init("RF ", logger);
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// Create array of pointers to phy_logs
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for (int i=0;i<args->expert.phy.nof_phy_threads;i++) {
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srslte::log_filter *mylog = new srslte::log_filter;
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char tmp[16];
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sprintf(tmp, "PHY%d",i);
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mylog->init(tmp, logger, true);
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phy_log.push_back(mylog);
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}
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mac_log.init("MAC ", logger, true);
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rlc_log.init("RLC ", logger);
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pdcp_log.init("PDCP", logger);
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rrc_log.init("RRC ", logger);
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nas_log.init("NAS ", logger);
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gw_log.init("GW ", logger);
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usim_log.init("USIM", logger);
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// Init logs
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rf_log.set_level(srslte::LOG_LEVEL_INFO);
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rf_log.info("Starting UE\n");
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for (int i=0;i<args->expert.phy.nof_phy_threads;i++) {
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((srslte::log_filter*) phy_log[i])->set_level(level(args->log.phy_level));
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}
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/* here we add a log layer to handle logging from the phy library*/
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srslte::log_filter *lib_log = new srslte::log_filter;
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char tmp[16];
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sprintf(tmp, "PHY_LIB");
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lib_log->init(tmp, logger, true);
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phy_log.push_back(lib_log);
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((srslte::log_filter*) phy_log[args->expert.phy.nof_phy_threads])->set_level(level(args->log.phy_lib_level));
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mac_log.set_level(level(args->log.mac_level));
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rlc_log.set_level(level(args->log.rlc_level));
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pdcp_log.set_level(level(args->log.pdcp_level));
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rrc_log.set_level(level(args->log.rrc_level));
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nas_log.set_level(level(args->log.nas_level));
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gw_log.set_level(level(args->log.gw_level));
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usim_log.set_level(level(args->log.usim_level));
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for (int i=0;i<args->expert.phy.nof_phy_threads + 1;i++) {
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((srslte::log_filter*) phy_log[i])->set_hex_limit(args->log.phy_hex_limit);
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}
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mac_log.set_hex_limit(args->log.mac_hex_limit);
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rlc_log.set_hex_limit(args->log.rlc_hex_limit);
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pdcp_log.set_hex_limit(args->log.pdcp_hex_limit);
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rrc_log.set_hex_limit(args->log.rrc_hex_limit);
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nas_log.set_hex_limit(args->log.nas_hex_limit);
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gw_log.set_hex_limit(args->log.gw_hex_limit);
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usim_log.set_hex_limit(args->log.usim_hex_limit);
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// Set up pcap and trace
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if(args->pcap.enable) {
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mac_pcap.open(args->pcap.filename.c_str());
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mac.start_pcap(&mac_pcap);
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}
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if(args->pcap.nas_enable) {
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nas_pcap.open(args->pcap.nas_filename.c_str());
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nas.start_pcap(&nas_pcap);
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}
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if(args->trace.enable) {
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phy.start_trace();
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radio.start_trace();
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}
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// Init layers
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// PHY inits in background, start before radio
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args->expert.phy.nof_rx_ant = args->rf.nof_rx_ant;
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phy.init(&radio, &mac, &rrc, phy_log, &args->expert.phy);
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/* Start Radio */
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char *dev_name = NULL;
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if (args->rf.device_name.compare("auto")) {
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dev_name = (char*) args->rf.device_name.c_str();
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}
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char *dev_args = NULL;
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if (args->rf.device_args.compare("auto")) {
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dev_args = (char*) args->rf.device_args.c_str();
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}
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printf("Opening RF device with %d RX antennas...\n", args->rf.nof_rx_ant);
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if(!radio.init_multi(args->rf.nof_rx_ant, dev_args, dev_name)) {
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printf("Failed to find device %s with args %s\n",
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args->rf.device_name.c_str(), args->rf.device_args.c_str());
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return false;
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}
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// Set RF options
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if (args->rf.time_adv_nsamples.compare("auto")) {
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radio.set_tx_adv(atoi(args->rf.time_adv_nsamples.c_str()));
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}
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if (args->rf.burst_preamble.compare("auto")) {
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radio.set_burst_preamble(atof(args->rf.burst_preamble.c_str()));
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}
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if (args->rf.continuous_tx.compare("auto")) {
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printf("set continuous %s\n", args->rf.continuous_tx.c_str());
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radio.set_continuous_tx(args->rf.continuous_tx.compare("yes")?false:true);
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}
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radio.set_manual_calibration(&args->rf_cal);
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// Set PHY options
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if (args->rf.tx_gain > 0) {
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args->expert.phy.ul_pwr_ctrl_en = false;
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} else {
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args->expert.phy.ul_pwr_ctrl_en = true;
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}
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if (args->rf.rx_gain < 0) {
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radio.start_agc(false);
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} else {
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radio.set_rx_gain(args->rf.rx_gain);
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}
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if (args->rf.tx_gain > 0) {
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radio.set_tx_gain(args->rf.tx_gain);
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} else {
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radio.set_tx_gain(args->rf.rx_gain);
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std::cout << std::endl <<
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"Warning: TX gain was not set. " <<
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"Using open-loop power control (not working properly)" << std::endl << std::endl;
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}
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radio.register_error_handler(rf_msg);
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radio.set_freq_offset(args->rf.freq_offset);
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mac.init(&phy, &rlc, &rrc, &mac_log);
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rlc.init(&pdcp, &rrc, this, &rlc_log, &mac, 0 /* RB_ID_SRB0 */);
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pdcp.init(&rlc, &rrc, &gw, &pdcp_log, 0 /* RB_ID_SRB0 */, SECURITY_DIRECTION_UPLINK);
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usim.init(&args->usim, &usim_log);
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srslte_nas_config_t nas_cfg(1, args->apn); /* RB_ID_SRB1 */
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nas.init(&usim, &rrc, &gw, &nas_log, nas_cfg);
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gw.init(&pdcp, &nas, &gw_log, 3 /* RB_ID_DRB1 */);
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gw.set_netmask(args->expert.ip_netmask);
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rrc.init(&phy, &mac, &rlc, &pdcp, &nas, &usim, &gw, &mac, &rrc_log);
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// Get current band from provided EARFCN
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args->rrc.supported_bands[0] = srslte_band_get_band(args->rf.dl_earfcn);
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args->rrc.nof_supported_bands = 1;
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args->rrc.ue_category = atoi(args->ue_category_str.c_str());
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rrc.set_args(&args->rrc);
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// Currently EARFCN list is set to only one frequency as indicated in ue.conf
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std::vector<uint32_t> earfcn_list;
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earfcn_list.push_back(args->rf.dl_earfcn);
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phy.set_earfcn(earfcn_list);
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if (args->rf.dl_freq > 0 && args->rf.ul_freq > 0) {
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phy.force_freq(args->rf.dl_freq, args->rf.ul_freq);
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}
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printf("Waiting PHY to initialize...\n");
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phy.wait_initialize();
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phy.configure_ul_params();
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// Enable AGC once PHY is initialized
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if (args->rf.rx_gain < 0) {
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phy.set_agc_enable(true);
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}
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printf("...\n");
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started = true;
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return true;
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}
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void ue::pregenerate_signals(bool enable)
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{
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phy.enable_pregen_signals(enable);
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}
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void ue::stop()
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{
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if(started)
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{
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usim.stop();
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nas.stop();
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rrc.stop();
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// Caution here order of stop is very important to avoid locks
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// Stop RLC and PDCP before GW to avoid locking on queue
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rlc.stop();
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pdcp.stop();
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gw.stop();
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// PHY must be stopped before radio otherwise it will lock on rf_recv()
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mac.stop();
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phy.stop();
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radio.stop();
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usleep(1e5);
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if(args->pcap.enable) {
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mac_pcap.close();
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}
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if(args->pcap.nas_enable) {
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nas_pcap.close();
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}
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if(args->trace.enable) {
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phy.write_trace(args->trace.phy_filename);
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radio.write_trace(args->trace.radio_filename);
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}
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started = false;
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}
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}
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bool ue::attach() {
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return nas.attach_request();
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}
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bool ue::deattach() {
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return nas.deattach_request();
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}
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bool ue::is_attached()
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{
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return rrc.is_connected();
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}
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void ue::start_plot() {
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phy.start_plot();
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}
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void ue::print_pool() {
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byte_buffer_pool::get_instance()->print_all_buffers();
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}
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bool ue::get_metrics(ue_metrics_t &m)
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{
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m.rf = rf_metrics;
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bzero(&rf_metrics, sizeof(rf_metrics_t));
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rf_metrics.rf_error = false; // Reset error flag
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if(EMM_STATE_REGISTERED == nas.get_state()) {
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if(RRC_STATE_CONNECTED == rrc.get_state()) {
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phy.get_metrics(m.phy);
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mac.get_metrics(m.mac);
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rlc.get_metrics(m.rlc);
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gw.get_metrics(m.gw);
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return true;
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}
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}
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return false;
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}
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void ue::radio_overflow() {
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phy.radio_overflow();
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}
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void ue::print_mbms()
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{
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rrc.print_mbms();
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}
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void ue::mbms_service_start(uint32_t serv, uint32_t port)
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{
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rrc.mbms_service_start(serv, port);
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}
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void ue::rf_msg(srslte_rf_error_t error)
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{
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ue_base *ue = ue_base::get_instance(LTE);
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ue->handle_rf_msg(error);
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if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_OVERFLOW) {
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ue->radio_overflow();
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} else
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if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_RX) {
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ue->stop();
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ue->cleanup();
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exit(-1);
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}
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}
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} // namespace srsue
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