/* * Copyright 2013-2019 Software Radio Systems Limited * * This file is part of srsLTE. * * srsLTE 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. * * srsLTE 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 SRSUE_TTCN3_SYSSIM_H #define SRSUE_TTCN3_SYSSIM_H #include "dut_utils.h" #include "srslte/common/netsource_handler.h" #include "srslte/common/pdu_queue.h" #include "srslte/upper/pdcp.h" #include "srslte/upper/rlc.h" #include "ttcn3_ip_ctrl_interface.h" #include "ttcn3_ip_sock_interface.h" #include "ttcn3_srb_interface.h" #include "ttcn3_sys_interface.h" #include "ttcn3_ue.h" #include "ttcn3_ut_interface.h" #include #include #define TTCN3_CRNTI (0x1001) class ttcn3_syssim : public thread, public syssim_interface_phy, public syssim_interface, public rrc_interface_rlc, public rlc_interface_pdcp, public rrc_interface_pdcp, public srslte::pdu_queue::process_callback { public: ttcn3_syssim(srslte::logger_file* logger_file_) : mac_msg_ul(20, &ss_mac_log), mac_msg_dl(20, &ss_mac_log), timers(8), pdus(128), logger(logger_file_), logger_file(logger_file_), pool(byte_buffer_pool::get_instance()), thread("TTCN3_SYSSIM"), rlc(&ss_rlc_log), pdcp(&ss_pdcp_log){}; ~ttcn3_syssim(){}; void init(const all_args_t& args_) { args = args_; // Make sure to get SS logging as well if (args.log.filename == "stdout") { logger = &logger_stdout; } // init and configure logging log.init("SS ", logger); ut_log.init("UT ", logger); sys_log.init("SYS ", logger); ip_sock_log.init("IP_S", logger); ip_ctrl_log.init("IP_C", logger); srb_log.init("SRB ", logger); ss_mac_log.init("SS-MAC", logger); ss_rlc_log.init("SS-RLC", logger); ss_pdcp_log.init("SS-PDCP", logger); log.set_level(args.log.all_level); ut_log.set_level(args.log.all_level); sys_log.set_level(args.log.all_level); ip_sock_log.set_level(args.log.all_level); ip_ctrl_log.set_level(args.log.all_level); srb_log.set_level(args.log.all_level); ss_mac_log.set_level(args.log.all_level); ss_rlc_log.set_level(args.log.all_level); ss_pdcp_log.set_level(args.log.all_level); log.set_hex_limit(args.log.all_hex_limit); ut_log.set_hex_limit(args.log.all_hex_limit); sys_log.set_hex_limit(args.log.all_hex_limit); ip_sock_log.set_hex_limit(args.log.all_hex_limit); ip_ctrl_log.set_hex_limit(args.log.all_hex_limit); srb_log.set_hex_limit(args.log.all_hex_limit); ss_mac_log.set_hex_limit(args.log.all_hex_limit); ss_rlc_log.set_hex_limit(args.log.all_hex_limit); ss_pdcp_log.set_hex_limit(args.log.all_hex_limit); // init system interfaces to tester ut.init(this, &ut_log, "0.0.0.0", 2222); sys.init(this, &sys_log, "0.0.0.0", 2223); ip_sock.init(&ip_sock_log, "0.0.0.0", 2224); ip_ctrl.init(&ip_ctrl_log, "0.0.0.0", 2225); srb.init(this, &srb_log, "0.0.0.0", 2226); ut.start(-2); sys.start(-2); ip_sock.start(-2); ip_ctrl.start(-2); srb.start(-2); pdus.init(this, &log); rlc.init(&pdcp, this, &timers, 0 /* RB_ID_SRB0 */); pdcp.init(&rlc, this, nullptr); } void stop() { running = false; if (ue != NULL) { ue->stop(); } // Stopping system interface ut.stop(); sys.stop(); ip_sock.stop(); ip_ctrl.stop(); srb.stop(); } void reset() { rlc.reset(); pdcp.reset(); cells.clear(); pcell = {}; } // Called from UT before starting testcase void tc_start(const char* name) { if (ue == nullptr) { // strip testsuite name std::string tc_name = get_tc_name(name); // Make a copy of the UE args for this run all_args_t local_args = args; // set up logging if (args.log.filename == "stdout") { logger = &logger_stdout; } else { logger_file->init(get_filename_with_tc_name(local_args.log.filename, run_id, tc_name).c_str(), -1); logger = logger_file; } log.info("Initializing UE ID=%d for TC=%s\n", run_id, tc_name.c_str()); log.console("Initializing UE ID=%d for TC=%s\n", run_id, tc_name.c_str()); // Patch UE config local_args.stack.pcap.filename = get_filename_with_tc_name(args.stack.pcap.filename, run_id, tc_name); local_args.stack.pcap.nas_filename = get_filename_with_tc_name(args.stack.pcap.nas_filename, run_id, tc_name); // bring up UE ue = std::unique_ptr(new ttcn3_ue()); if (ue->init(local_args, logger, this, tc_name)) { ue->stop(); ue.reset(nullptr); std::string err("Couldn't initialize UE.\n"); log.error("%s\n", err.c_str()); log.console("%s\n", err.c_str()); return; } // Start simulator thread running = true; start(); } else { log.error("UE hasn't been deallocated properly because TC didn't finish correctly.\n"); log.console("UE hasn't been deallocated properly because TC didn't finish correctly.\n"); } } void tc_end() { if (ue != NULL) { // ask periodic thread to stop running = false; log.info("Deinitializing UE ID=%d\n", run_id); log.console("Deinitializing UE ID=%d\n", run_id); ue->stop(); // wait until SS main thread has terminated before resetting UE wait_thread_finish(); ue.reset(); // Reset SS' RLC and PDCP reset(); logger_file->stop(); run_id++; } else { log.error("UE is not allocated. Nothing needs to be done.\n"); log.console("UE is not allocated. Nothing needs to be done.\n"); } } void power_off_ue() { // only return after new UE instance is up and running } void switch_on_ue() { if (ue != nullptr) { log.info("Switching on UE ID=%d\n", run_id); log.console("Switching on UE ID=%d\n", run_id); // Trigger attach procedure ue->switch_on(); } else { log.error("UE not initialized. Can't switch UE on.\n"); } } void switch_off_ue() { if (ue != nullptr) { log.info("Switching off UE ID=%d\n", run_id); log.console("Switching off UE ID=%d\n", run_id); ue->switch_off(); } else { log.error("UE not initialized. Can't switch UE off.\n"); } } void enable_data() { if (ue) { log.info("Enabling data services on UE ID=%d\n", run_id); ue->enable_data(); } } void disable_data() { if (ue) { log.info("Disabling data services on UE ID=%d\n", run_id); ue->disable_data(); } } // Interface for PHY void prach_indication(uint32_t preamble_index_, const uint32_t& cell_id) { // store TTI for providing UL grant for Msg3 transmission prach_tti = tti; prach_preamble_index = preamble_index_; // update active pcell (chosen by UE) in syssim for (auto& cell : cells) { if (cell.cell.id == cell_id) { pcell = cell; break; } } } void send_rar(uint32_t preamble_index) { log.info("Sending RAR for RAPID=%d\n", preamble_index); // Prepare RAR grant uint8_t grant_buffer[64] = {}; srslte_dci_rar_grant_t rar_grant = {}; rar_grant.tpc_pusch = 3; srslte_dci_rar_pack(&rar_grant, grant_buffer); // Create MAC PDU and add RAR subheader srslte::rar_pdu rar_pdu; rar_buffer.clear(); const int rar_pdu_len = 64; rar_pdu.init_tx(&rar_buffer, rar_pdu_len); rar_pdu.set_backoff(11); // Backoff of 480ms to prevent UE from PRACHing too fast if (rar_pdu.new_subh()) { rar_pdu.get()->set_rapid(preamble_index); rar_pdu.get()->set_ta_cmd(0); rar_pdu.get()->set_temp_crnti(crnti); rar_pdu.get()->set_sched_grant(grant_buffer); } rar_pdu.write_packet(rar_buffer.msg); rar_buffer.N_bytes = rar_pdu_len; // Prepare grant and pass all to MAC mac_interface_phy_lte::mac_grant_dl_t dl_grant = {}; dl_grant.pid = get_pid(tti); dl_grant.rnti = 0x1; // must be a valid RAR-RNTI dl_grant.tb[0].tbs = rar_buffer.N_bytes; dl_grant.tb[0].ndi = get_ndi_for_new_dl_tx(tti); // send grant and pass payload to TB data (grant contains length) ue->new_tb(dl_grant, rar_buffer.msg); // reset last PRACH transmission tti prach_tti = -1; } void send_msg3_grant() { log.info("Sending Msg3 grant for C-RNTI=%d\n", crnti); mac_interface_phy_lte::mac_grant_ul_t ul_grant = {}; ul_grant.tb.tbs = 32; ul_grant.tb.ndi_present = true; ul_grant.tb.ndi = get_ndi_for_new_ul_tx(tti); ul_grant.rnti = crnti; ul_grant.pid = get_pid(tti); ue->new_grant_ul(ul_grant); } void sr_req(uint32_t tti_tx) { log.info("Received SR from PHY\n"); // Provide new UL grant to UE mac_interface_phy_lte::mac_grant_ul_t ul_grant = {}; ul_grant.tb.tbs = 100; // FIXME: reasonable size? ul_grant.tb.ndi_present = true; ul_grant.tb.ndi = get_ndi_for_new_ul_tx(tti); ul_grant.rnti = crnti; ul_grant.pid = get_pid(tti); ue->new_grant_ul(ul_grant); } void tx_pdu(const uint8_t* payload, const int len, const uint32_t tx_tti) { if (payload == NULL) { ss_mac_log.error("Received NULL as PDU payload. Dropping.\n"); return; } // Parse MAC mac_msg_ul.init_rx(len, true); mac_msg_ul.parse_packet((uint8_t*)payload); while (mac_msg_ul.next()) { assert(mac_msg_ul.get()); if (mac_msg_ul.get()->is_sdu()) { // Route logical channel ss_mac_log.info_hex(mac_msg_ul.get()->get_sdu_ptr(), mac_msg_ul.get()->get_payload_size(), "PDU: rnti=0x%x, lcid=%d, %d bytes\n", 0xdead, mac_msg_ul.get()->get_sdu_lcid(), mac_msg_ul.get()->get_payload_size()); // Push PDU to our own RLC (needed to handle status reporting, etc. correctly ss_mac_log.info_hex(mac_msg_ul.get()->get_sdu_ptr(), mac_msg_ul.get()->get_payload_size(), "Route PDU to LCID=%d (%d B)\n", mac_msg_ul.get()->get_sdu_lcid(), mac_msg_ul.get()->get_payload_size()); rlc.write_pdu( mac_msg_ul.get()->get_sdu_lcid(), mac_msg_ul.get()->get_sdu_ptr(), mac_msg_ul.get()->get_payload_size()); // Save contention resolution if lcid == 0 if (mac_msg_ul.get()->get_sdu_lcid() == 0) { int nbytes = srslte::sch_subh::MAC_CE_CONTRES_LEN; if (mac_msg_ul.get()->get_payload_size() >= (uint32_t)nbytes) { uint8_t* ue_cri_ptr = (uint8_t*)&conres_id; uint8_t* pkt_ptr = mac_msg_ul.get()->get_sdu_ptr(); // Warning here: we want to include the for (int i = 0; i < nbytes; i++) { ue_cri_ptr[nbytes - i - 1] = pkt_ptr[i]; } ss_mac_log.info_hex(ue_cri_ptr, nbytes, "Contention resolution ID:\n"); } else { ss_mac_log.error("Received CCCH UL message of invalid size=%d bytes\n", mac_msg_ul.get()->get_payload_size()); } } } } mac_msg_ul.reset(); /* Process CE after all SDUs because we need to update BSR after */ bool bsr_received = false; while (mac_msg_ul.next()) { assert(mac_msg_ul.get()); if (!mac_msg_ul.get()->is_sdu()) { // Process MAC Control Element bsr_received |= process_ce(mac_msg_ul.get()); } } } bool process_ce(srslte::sch_subh* subh) { uint16_t rnti = dl_rnti; uint32_t buff_size[4] = {0, 0, 0, 0}; float phr = 0; int32_t idx = 0; uint16_t old_rnti = 0; bool is_bsr = false; switch (subh->ce_type()) { case srslte::sch_subh::PHR_REPORT: phr = subh->get_phr(); ss_mac_log.info("CE: Received PHR from rnti=0x%x, value=%.0f\n", rnti, phr); #if 0 //sched->ul_phr(rnti, (int) phr); //metrics_phr(phr); #endif break; case srslte::sch_subh::CRNTI: old_rnti = subh->get_c_rnti(); ss_mac_log.info("CE: Received C-RNTI from temp_rnti=0x%x, rnti=0x%x\n", rnti, old_rnti); #if 0 if (sched->ue_exists(old_rnti)) { rrc->upd_user(rnti, old_rnti); rnti = old_rnti; } else { Error("Updating user C-RNTI: rnti=0x%x already released\n", old_rnti); } #endif break; case srslte::sch_subh::TRUNC_BSR: case srslte::sch_subh::SHORT_BSR: idx = subh->get_bsr(buff_size); if (idx == -1) { ss_mac_log.error("Invalid Index Passed to lc groups\n"); break; } #if 0 for (uint32_t i=0;iul_bsr(rnti, lc_groups[idx][i], buff_size[idx]); } #endif ss_mac_log.info("CE: Received %s BSR rnti=0x%x, lcg=%d, value=%d\n", subh->ce_type() == srslte::sch_subh::SHORT_BSR ? "Short" : "Trunc", rnti, idx, buff_size[idx]); is_bsr = true; break; case srslte::sch_subh::LONG_BSR: subh->get_bsr(buff_size); #if 0 for (idx=0;idx<4;idx++) { for (uint32_t i=0;iul_bsr(rnti, lc_groups[idx][i], buff_size[idx]); } } #endif is_bsr = true; ss_mac_log.info("CE: Received Long BSR rnti=0x%x, value=%d,%d,%d,%d\n", rnti, buff_size[0], buff_size[1], buff_size[2], buff_size[3]); break; case srslte::sch_subh::PADDING: ss_mac_log.debug("CE: Received padding for rnti=0x%x\n", rnti); break; default: ss_mac_log.error("CE: Invalid lcid=0x%x\n", subh->ce_type()); break; } return is_bsr; } uint32_t get_pid(const uint32_t tti) { return tti % (2 * FDD_HARQ_DELAY_MS); } bool get_ndi_for_new_ul_tx(const uint32_t tti_) { // toggle NDI to always create new Tx const uint32_t pid = get_pid(tti_); last_ul_ndi[pid] = !last_ul_ndi[pid]; log.info("UL-PID=%d NDI=%s\n", pid, last_ul_ndi[pid] ? "1" : "0"); return last_ul_ndi[pid]; } bool get_ndi_for_new_dl_tx(const uint32_t tti_) { // toggle NDI to always create new Tx const uint32_t pid = get_pid(tti_); last_dl_ndi[pid] = !last_dl_ndi[pid]; log.info("DL-PID=%d NDI=%s\n", pid, last_dl_ndi[pid] ? "1" : "0"); return last_dl_ndi[pid]; } void run_thread() { uint32_t sib_idx = 0; while (running) { log.debug("SYSSIM-TTI=%d\n", tti); ue->set_current_tti(tti); dl_rnti = ue->get_dl_sched_rnti(tti); if (SRSLTE_RNTI_ISSI(dl_rnti)) { // deliver SIBs one after another mac_interface_phy_lte::mac_grant_dl_t dl_grant = {}; dl_grant.pid = get_pid(tti); dl_grant.rnti = dl_rnti; dl_grant.tb[0].tbs = sibs[sib_idx]->N_bytes; dl_grant.tb[0].ndi = get_ndi_for_new_dl_tx(tti); ue->new_tb(dl_grant, sibs[sib_idx]->msg); sib_idx = (sib_idx + 1) % sibs.size(); } else if (SRSLTE_RNTI_ISRAR(dl_rnti)) { if (prach_tti != -1) { rar_tti = (prach_tti + 3) % 10240; if (tti == rar_tti) { send_rar(prach_preamble_index); } } } else if (SRSLTE_RNTI_ISPA(dl_rnti)) { log.debug("Searching for paging RNTI\n"); // PCH will be triggered from SYSSIM after receiving Paging } else if (SRSLTE_RNTI_ISUSER(dl_rnti)) { // check if this is for contention resolution after PRACH/RAR if (dl_rnti == crnti) { log.debug("Searching for C-RNTI=%d\n", crnti); if (rar_tti != -1) { msg3_tti = (rar_tti + 3) % 10240; if (tti == msg3_tti) { send_msg3_grant(); rar_tti = -1; } } } if (dl_rnti != 0) { log.debug("Searching for RNTI=%d\n", dl_rnti); // look for DL data to be send in each bearer and provide grant accordingly for (int lcid = 0; lcid < SRSLTE_N_RADIO_BEARERS; lcid++) { uint32_t buf_state = rlc.get_buffer_state(lcid); if (buf_state > 0) { log.debug("LCID=%d, buffer_state=%d\n", lcid, buf_state); const uint32_t mac_header_size = 10; // Add MAC header (10 B for all subheaders, etc) if (tmp_rlc_buffer.get_tailroom() > (buf_state + mac_header_size)) { uint32_t pdu_size = rlc.read_pdu(lcid, tmp_rlc_buffer.msg, buf_state); tx_payload_buffer.clear(); mac_msg_dl.init_tx(&tx_payload_buffer, pdu_size + mac_header_size, false); // check if this is Msg4 that needs to contain the contention resolution ID CE if (msg3_tti != -1) { if (lcid == 0) { if (mac_msg_dl.new_subh()) { if (mac_msg_dl.get()->set_con_res_id(conres_id)) { log.info("CE: Added Contention Resolution ID=0x%lx\n", conres_id); } else { log.error("CE: Setting Contention Resolution ID CE\n"); } } else { log.error("CE: Setting Contention Resolution ID CE. No space for a subheader\n"); } msg3_tti = -1; } } // Add payload if (mac_msg_dl.new_subh()) { int n = mac_msg_dl.get()->set_sdu(lcid, pdu_size, tmp_rlc_buffer.msg); if (n == -1) { log.error("Error while adding SDU (%d B) to MAC PDU\n", pdu_size); mac_msg_dl.del_subh(); } } uint8_t* mac_pdu_ptr = mac_msg_dl.write_packet(&log); if (mac_pdu_ptr != nullptr) { log.info_hex(mac_pdu_ptr, mac_msg_dl.get_pdu_len(), "DL MAC PDU (%d B):\n", mac_msg_dl.get_pdu_len()); // Prepare MAC grant for CCCH mac_interface_phy_lte::mac_grant_dl_t dl_grant = {}; dl_grant.pid = get_pid(tti); dl_grant.rnti = dl_rnti; dl_grant.tb[0].tbs = mac_msg_dl.get_pdu_len(); dl_grant.tb[0].ndi_present = true; dl_grant.tb[0].ndi = get_ndi_for_new_dl_tx(tti); ue->new_tb(dl_grant, (const uint8_t*)mac_pdu_ptr); } else { log.error("Error writing DL MAC PDU\n"); } mac_msg_dl.reset(); } else { log.error("Can't fit RLC PDU into buffer (%d > %d)\n", buf_state, tmp_rlc_buffer.get_tailroom()); } } } // Check if we need to provide a UL grant as well } } else { log.debug("Not handling RNTI=%d\n", dl_rnti); } usleep(1000); tti = (tti + 1) % 10240; } log.info("Leaving main thread.\n"); log.console("Leaving main thread.\n"); } uint32_t get_tti() { return tti; } void process_pdu(uint8_t* buff, uint32_t len, pdu_queue::channel_t channel) { log.info("%s\n", __PRETTY_FUNCTION__); } void set_cell_config(std::string name, uint32_t earfcn_, srslte_cell_t cell_, const float power) { // check if cell already exists if (not syssim_has_cell(name)) { // insert new cell log.info("Adding cell %s with cellId=%d and power=%.2f dBm\n", name.c_str(), cell_.id, power); syssim_cell_t cell = {}; cell.name = name; cell.cell = cell_; cell.initial_power = power; cell.earfcn = earfcn_; cells.push_back(cell); } else { // cell is already there log.info("Cell already there, reconfigure\n"); } update_cell_map(); } bool syssim_has_cell(std::string cell_name) { for (uint32_t i = 0; i < cells.size(); ++i) { if (cells[i].name == cell_name) { return true; } } return false; } void set_cell_attenuation(std::string cell_name, const float value) { if (not syssim_has_cell(cell_name)) { log.error("Can't set cell power. Cell not found.\n"); } // update cell's power for (uint32_t i = 0; i < cells.size(); ++i) { if (cells[i].name == cell_name) { cells[i].attenuation = value; break; } } update_cell_map(); } void update_cell_map() { // Find cell with highest power and select as serving cell if (ue != NULL) { // convert syssim cell list to phy cell list lte_ttcn3_phy::cell_list_t phy_cells; for (uint32_t i = 0; i < cells.size(); ++i) { lte_ttcn3_phy::cell_t phy_cell = {}; phy_cell.info = cells[i].cell; phy_cell.power = cells[i].initial_power - cells[i].attenuation; phy_cell.earfcn = cells[i].earfcn; log.debug("Configuring cell %d with PCI=%d with TxPower=%f\n", i, phy_cell.info.id, phy_cell.power); phy_cells.push_back(phy_cell); } // SYSSIM defines what cells the UE can connect to ue->set_cell_map(phy_cells); } else { log.error("Can't configure cell. UE not initialized.\n"); } } void add_bcch_pdu(unique_byte_buffer_t pdu) { sibs.push_back(std::move(pdu)); } void add_ccch_pdu(unique_byte_buffer_t pdu) { // Add to SRB0 Tx queue rlc.write_sdu(0, std::move(pdu)); } void add_dcch_pdu(uint32_t lcid, unique_byte_buffer_t pdu) { // push to PDCP and create DL grant for it log.info("Writing PDU (%d B) to LCID=%d\n", pdu->N_bytes, lcid); pdcp.write_sdu(lcid, std::move(pdu)); } void add_pch_pdu(unique_byte_buffer_t pdu) { log.info("Received PCH PDU (%d B)\n", pdu->N_bytes); // Prepare MAC grant for PCH mac_interface_phy_lte::mac_grant_dl_t dl_grant = {}; dl_grant.pid = get_pid(tti); dl_grant.rnti = SRSLTE_PRNTI; dl_grant.tb[0].tbs = pdu->N_bytes; dl_grant.tb[0].ndi_present = true; dl_grant.tb[0].ndi = get_ndi_for_new_dl_tx(tti); ue->new_tb(dl_grant, (const uint8_t*)pdu->msg); } srslte::timers::timer* timer_get(uint32_t timer_id) { return timers.get(timer_id); } uint32_t timer_get_unique_id() { return timers.get_unique_id(); } void timer_release_id(uint32_t timer_id) { timers.release_id(timer_id); } void step_timer() { timers.step_all(); } void add_srb(uint32_t lcid, pdcp_config_t pdcp_config) { pdcp.add_bearer(lcid, pdcp_config); rlc.add_bearer(lcid, srslte::rlc_config_t::srb_config(lcid)); } void del_srb(uint32_t lcid) { // Only delete SRB1/2 if (lcid > 0) { pdcp.del_bearer(lcid); rlc.del_bearer(lcid); } // Reset HARQ to generate new transmissions if (lcid == 0) { log.info("Resetting UL/DL NDI counters\n"); memset(last_dl_ndi, 0, sizeof(last_dl_ndi)); memset(last_ul_ndi, 0, sizeof(last_ul_ndi)); } } // RRC interface for PDCP, PDCP calls RRC to push RRC SDU void write_pdu(uint32_t lcid, unique_byte_buffer_t pdu) { log.info_hex(pdu->msg, pdu->N_bytes, "RRC SDU received for LCID=%d (%d B)\n", lcid, pdu->N_bytes); // We don't handle RRC, prepend LCID pdu->msg--; *pdu->msg = lcid; pdu->N_bytes++; // prepend pcell PCID pdu->msg--; *pdu->msg = static_cast(pcell.cell.id); pdu->N_bytes++; // push content to Titan srb.tx(std::move(pdu)); } // Not supported right now void write_pdu_bcch_bch(unique_byte_buffer_t pdu) { log.error("%s not implemented.\n", __FUNCTION__); } void write_pdu_bcch_dlsch(unique_byte_buffer_t pdu) { log.error("%s not implemented.\n", __FUNCTION__); } void write_pdu_pcch(unique_byte_buffer_t pdu) { log.error("%s not implemented.\n", __FUNCTION__); } void write_pdu_mch(uint32_t lcid, unique_byte_buffer_t pdu) { log.error("%s not implemented.\n", __FUNCTION__); } void max_retx_attempted() { log.debug("max_retx_attempted\n"); } std::string get_rb_name(uint32_t lcid) { if (lcid < rb_id_vec.size()) { return rb_id_vec.at(lcid); } return std::string("RB"); }; void write_sdu(uint32_t lcid, unique_byte_buffer_t sdu, bool blocking = true) { log.info_hex(sdu->msg, sdu->N_bytes, "Received SDU on LCID=%d\n", lcid); uint8_t* mac_pdu_ptr; mac_pdu_ptr = mac_msg_dl.write_packet(&log); log.info_hex(mac_pdu_ptr, mac_msg_dl.get_pdu_len(), "DL MAC PDU:\n"); // Prepare MAC grant for CCCH mac_interface_phy_lte::mac_grant_dl_t dl_grant = {}; dl_grant.pid = get_pid(tti); dl_grant.rnti = dl_rnti; dl_grant.tb[0].tbs = mac_msg_dl.get_pdu_len(); dl_grant.tb[0].ndi_present = true; dl_grant.tb[0].ndi = get_ndi_for_new_dl_tx(tti); ue->new_tb(dl_grant, (const uint8_t*)mac_pdu_ptr); } bool rb_is_um(uint32_t lcid) { return false; } int set_as_security(const uint32_t lcid, std::array k_rrc_enc, std::array k_rrc_int, std::array k_up_enc, const srslte::CIPHERING_ALGORITHM_ID_ENUM cipher_algo, const srslte::INTEGRITY_ALGORITHM_ID_ENUM integ_algo) { pdcp.config_security(lcid, k_rrc_enc.data(), k_rrc_int.data(), k_up_enc.data(), cipher_algo, integ_algo); pdcp.enable_integrity(lcid); pdcp.enable_encryption(lcid); return 0; } private: // SYS interface ttcn3_ut_interface ut; ttcn3_sys_interface sys; ttcn3_ip_sock_interface ip_sock; ttcn3_ip_ctrl_interface ip_ctrl; ttcn3_srb_interface srb; // Logging stuff srslte::logger_stdout logger_stdout; srslte::logger_file* logger_file = nullptr; srslte::logger* logger = nullptr; srslte::log_filter log; srslte::log_filter ut_log; srslte::log_filter sys_log; srslte::log_filter ip_sock_log; srslte::log_filter ip_ctrl_log; srslte::log_filter srb_log; srslte::log_filter ss_mac_log; srslte::log_filter ss_rlc_log; srslte::log_filter ss_pdcp_log; all_args_t args = {}; bool running = false; srslte::byte_buffer_pool* pool = nullptr; // Simulator vars unique_ptr ue = nullptr; uint32_t run_id = 0; std::vector sibs; int32_t tti = 0; int32_t prach_tti = -1; int32_t rar_tti = -1; int32_t msg3_tti = -1; uint32_t prach_preamble_index = 0; uint16_t dl_rnti = 0; uint16_t crnti = TTCN3_CRNTI; srslte::timers timers; bool last_dl_ndi[2 * FDD_HARQ_DELAY_MS] = {}; bool last_ul_ndi[2 * FDD_HARQ_DELAY_MS] = {}; // Map between the cellId (name) used by 3GPP test suite and srsLTE cell struct typedef struct { std::string name; srslte_cell_t cell; float initial_power; float attenuation; uint32_t earfcn; } syssim_cell_t; std::vector cells; syssim_cell_t pcell = {}; srslte::pdu_queue pdus; srslte::sch_pdu mac_msg_dl, mac_msg_ul; // buffer for DL transmissions srslte::byte_buffer_t rar_buffer; srslte::byte_buffer_t tmp_rlc_buffer; // Used to buffer RLC PDU srslte::byte_buffer_t tx_payload_buffer; // Used to buffer final MAC PDU uint64_t conres_id = 0; // Simulator objects srslte::rlc rlc; srslte::pdcp pdcp; std::vector rb_id_vec = { "SRB0", "SRB1", "SRB2", "DRB1", "DRB2", "DRB3", "DRB4", "DRB5", "DRB6", "DRB7", "DRB8"}; }; #endif // SRSUE_TTCN3_SYSSIM_H