/** * * \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. * */ #include "srsepc/hdr/hss/hss.h" #include "srsepc/hdr/mme/mme.h" #include "srsepc/hdr/spgw/spgw.h" #include "srsran/build_info.h" #include "srsran/common/bcd_helpers.h" #include "srsran/common/common_helper.h" #include "srsran/common/config_file.h" #include "srsran/common/crash_handler.h" #include "srsran/srslog/srslog.h" #include "srsran/srsran.h" #include "srsran/support/emergency_handlers.h" #include "srsran/support/signal_handler.h" #include #include using namespace std; using namespace srsepc; namespace bpo = boost::program_options; typedef struct { std::string nas_level; int nas_hex_limit; std::string s1ap_level; int s1ap_hex_limit; std::string mme_gtpc_level; int mme_gtpc_hex_limit; std::string spgw_gtpc_level; int spgw_gtpc_hex_limit; std::string gtpu_level; int gtpu_hex_limit; std::string spgw_level; int spgw_hex_limit; std::string hss_level; int hss_hex_limit; std::string all_level; int all_hex_limit; std::string filename; } log_args_t; typedef struct { mme_args_t mme_args; hss_args_t hss_args; spgw_args_t spgw_args; log_args_t log_args; } all_args_t; static srslog::sink* log_sink = nullptr; static std::atomic running = {true}; /********************************************************************** * Program arguments processing ***********************************************************************/ string config_file; void parse_args(all_args_t* args, int argc, char* argv[]) { string mme_name; string mme_code; string mme_group; string tac; string mcc; string mnc; string mme_bind_addr; string mme_apn; string encryption_algo; string integrity_algo; uint16_t paging_timer = 0; uint32_t max_paging_queue = 0; string spgw_bind_addr; string sgi_if_addr; string sgi_if_name; string dns_addr; string full_net_name; string short_net_name; bool request_imeisv; string hss_db_file; string hss_auth_algo; string log_filename; // Command line only options bpo::options_description general("General options"); // clang-format off general.add_options() ("help,h", "Produce help message") ("version,v", "Print version information and exit") ; // Command line or config file options bpo::options_description common("Configuration options"); common.add_options() ("mme.mme_code", bpo::value(&mme_code)->default_value("0x01"), "MME Code") ("mme.name", bpo::value(&mme_name)->default_value("srsmme01"), "MME Name") ("mme.mme_group", bpo::value(&mme_group)->default_value("0x01"), "Cell ID") ("mme.tac", bpo::value(&tac)->default_value("0x0"), "Tracking Area Code") ("mme.mcc", bpo::value(&mcc)->default_value("001"), "Mobile Country Code") ("mme.mnc", bpo::value(&mnc)->default_value("01"), "Mobile Network Code") ("mme.mme_bind_addr", bpo::value(&mme_bind_addr)->default_value("127.0.0.1"), "IP address of MME for S1 connection") ("mme.dns_addr", bpo::value(&dns_addr)->default_value("8.8.8.8"), "IP address of the DNS server for the UEs") ("mme.full_net_name", bpo::value(&full_net_name)->default_value("Software Radio Systems RAN"), "Full name of the network") ("mme.short_net_name", bpo::value(&short_net_name)->default_value("srsRAN"), "Short name of the network") ("mme.apn", bpo::value(&mme_apn)->default_value(""), "Set Access Point Name (APN) for data services") ("mme.encryption_algo", bpo::value(&encryption_algo)->default_value("EEA0"), "Set preferred encryption algorithm for NAS layer ") ("mme.integrity_algo", bpo::value(&integrity_algo)->default_value("EIA1"), "Set preferred integrity protection algorithm for NAS") ("mme.paging_timer", bpo::value(&paging_timer)->default_value(2), "Set paging timer value in seconds (T3413)") ("mme.request_imeisv", bpo::value(&request_imeisv)->default_value(false), "Enable IMEISV request in Security mode command") ("hss.db_file", bpo::value(&hss_db_file)->default_value("ue_db.csv"), ".csv file that stores UE's keys") ("spgw.gtpu_bind_addr", bpo::value(&spgw_bind_addr)->default_value("127.0.0.1"), "IP address of SP-GW for the S1-U connection") ("spgw.sgi_if_addr", bpo::value(&sgi_if_addr)->default_value("176.16.0.1"), "IP address of TUN interface for the SGi connection") ("spgw.sgi_if_name", bpo::value(&sgi_if_name)->default_value("srs_spgw_sgi"), "Name of TUN interface for the SGi connection") ("spgw.max_paging_queue", bpo::value(&max_paging_queue)->default_value(100), "Max number of packets in paging queue") ("pcap.enable", bpo::value(&args->mme_args.s1ap_args.pcap_enable)->default_value(false), "Enable S1AP PCAP") ("pcap.filename", bpo::value(&args->mme_args.s1ap_args.pcap_filename)->default_value("/tmp/epc.pcap"), "PCAP filename") ("log.nas_level", bpo::value(&args->log_args.nas_level), "MME NAS log level") ("log.nas_hex_limit", bpo::value(&args->log_args.nas_hex_limit), "MME NAS log hex dump limit") ("log.s1ap_level", bpo::value(&args->log_args.s1ap_level), "MME S1AP log level") ("log.s1ap_hex_limit", bpo::value(&args->log_args.s1ap_hex_limit), "MME S1AP log hex dump limit") ("log.mme_gtpc_level", bpo::value(&args->log_args.mme_gtpc_level), "MME GTPC log level") ("log.mme_gtpc_hex_limit", bpo::value(&args->log_args.mme_gtpc_hex_limit), "MME GTPC log hex dump limit") ("log.spgw_gtpc_level", bpo::value(&args->log_args.spgw_gtpc_level), "SPGW GTPC log level") ("log.spgw_gtpc_hex_limit", bpo::value(&args->log_args.spgw_gtpc_hex_limit), "SPGW GTPC log hex dump limit") ("log.gtpu_level", bpo::value(&args->log_args.gtpu_level), "GTP-U log level") ("log.gtpu_hex_limit", bpo::value(&args->log_args.gtpu_hex_limit), "GTP-U log hex dump limit") ("log.spgw_level", bpo::value(&args->log_args.spgw_level), "SPGW log level") ("log.spgw_hex_limit", bpo::value(&args->log_args.spgw_hex_limit), "SPGW log hex dump limit") ("log.hss_level", bpo::value(&args->log_args.hss_level), "HSS log level") ("log.hss_hex_limit", bpo::value(&args->log_args.hss_hex_limit), "HSS log hex dump limit") ("log.all_level", bpo::value(&args->log_args.all_level)->default_value("info"), "ALL log level") ("log.all_hex_limit", bpo::value(&args->log_args.all_hex_limit)->default_value(32), "ALL log hex dump limit") ("log.filename", bpo::value(&args->log_args.filename)->default_value("/tmp/epc.log"),"Log filename") ; // Positional options - config file location bpo::options_description position("Positional options"); position.add_options() ("config_file", bpo::value< string >(&config_file), "MME configuration file") ; // clang-format on bpo::positional_options_description p; p.add("config_file", -1); // these options are allowed on the command line bpo::options_description cmdline_options; cmdline_options.add(common).add(position).add(general); // parse the command line and store result in vm bpo::variables_map vm; try { bpo::store(bpo::command_line_parser(argc, argv).options(cmdline_options).positional(p).run(), vm); bpo::notify(vm); } catch (bpo::error& e) { cerr << e.what() << endl; exit(1); } // help option was given - print usage and exit if (vm.count("help")) { cout << "Usage: " << argv[0] << " [OPTIONS] config_file" << endl << endl; cout << common << endl << general << endl; exit(0); } // if no config file given, check users home path if (!vm.count("config_file")) { if (!config_exists(config_file, "epc.conf")) { cout << "Failed to read EPC configuration file " << config_file << " - exiting" << endl; exit(1); } } // Parsing Config File cout << "Reading configuration file " << config_file << "..." << endl; ifstream conf(config_file.c_str(), ios::in); if (conf.fail()) { cout << "Failed to read configuration file " << config_file << " - exiting" << endl; exit(1); } // parse config file and handle errors gracefully try { bpo::store(bpo::parse_config_file(conf, common), vm); bpo::notify(vm); } catch (const boost::program_options::error& e) { cerr << e.what() << endl; exit(1); } // Concert hex strings { std::stringstream sstr; sstr << std::hex << vm["mme.mme_group"].as(); sstr >> args->mme_args.s1ap_args.mme_group; } { std::stringstream sstr; sstr << std::hex << vm["mme.mme_code"].as(); uint16_t tmp; // Need intermediate uint16_t as uint8_t is treated as char sstr >> tmp; args->mme_args.s1ap_args.mme_code = tmp; } { std::stringstream sstr; sstr << std::hex << vm["mme.tac"].as(); sstr >> args->mme_args.s1ap_args.tac; } // Convert MCC/MNC strings if (!srsran::string_to_mcc(mcc, &args->mme_args.s1ap_args.mcc)) { cout << "Error parsing mme.mcc:" << mcc << " - must be a 3-digit string." << endl; } if (!srsran::string_to_mnc(mnc, &args->mme_args.s1ap_args.mnc)) { cout << "Error parsing mme.mnc:" << mnc << " - must be a 2 or 3-digit string." << endl; } // Convert MCC/MNC strings if (!srsran::string_to_mcc(mcc, &args->hss_args.mcc)) { cout << "Error parsing mme.mcc:" << mcc << " - must be a 3-digit string." << endl; } if (!srsran::string_to_mnc(mnc, &args->hss_args.mnc)) { cout << "Error parsing mme.mnc:" << mnc << " - must be a 2 or 3-digit string." << endl; } std::transform(encryption_algo.begin(), encryption_algo.end(), encryption_algo.begin(), ::tolower); if (encryption_algo == "eea0") { args->mme_args.s1ap_args.encryption_algo = srsran::CIPHERING_ALGORITHM_ID_EEA0; } else if (encryption_algo == "eea1") { args->mme_args.s1ap_args.encryption_algo = srsran::CIPHERING_ALGORITHM_ID_128_EEA1; } else if (encryption_algo == "eea2") { args->mme_args.s1ap_args.encryption_algo = srsran::CIPHERING_ALGORITHM_ID_128_EEA2; } else if (encryption_algo == "eea3") { args->mme_args.s1ap_args.encryption_algo = srsran::CIPHERING_ALGORITHM_ID_128_EEA3; } else { args->mme_args.s1ap_args.encryption_algo = srsran::CIPHERING_ALGORITHM_ID_EEA0; cout << "Error parsing mme.encryption_algo:" << encryption_algo << " - must be EEA0, EEA1, EEA2 or EEA3." << endl; cout << "Using default mme.encryption_algo: EEA0" << endl; } std::transform(integrity_algo.begin(), integrity_algo.end(), integrity_algo.begin(), ::tolower); if (integrity_algo == "eia0") { args->mme_args.s1ap_args.integrity_algo = srsran::INTEGRITY_ALGORITHM_ID_EIA0; cout << "Warning parsing mme.integrity_algo:" << encryption_algo << " - EIA0 will not supported by UEs use EIA1 or EIA2" << endl; } else if (integrity_algo == "eia1") { args->mme_args.s1ap_args.integrity_algo = srsran::INTEGRITY_ALGORITHM_ID_128_EIA1; } else if (integrity_algo == "eia2") { args->mme_args.s1ap_args.integrity_algo = srsran::INTEGRITY_ALGORITHM_ID_128_EIA2; } else if (integrity_algo == "eia3") { args->mme_args.s1ap_args.integrity_algo = srsran::INTEGRITY_ALGORITHM_ID_128_EIA3; } else { args->mme_args.s1ap_args.integrity_algo = srsran::INTEGRITY_ALGORITHM_ID_128_EIA1; cout << "Error parsing mme.integrity_algo:" << encryption_algo << " - must be EIA0, EIA1, EIA2 or EIA3." << endl; cout << "Using default mme.integrity_algo: EIA1" << endl; } args->mme_args.s1ap_args.mme_bind_addr = mme_bind_addr; args->mme_args.s1ap_args.mme_name = mme_name; args->mme_args.s1ap_args.dns_addr = dns_addr; args->mme_args.s1ap_args.full_net_name = full_net_name; args->mme_args.s1ap_args.short_net_name = short_net_name; args->mme_args.s1ap_args.mme_apn = mme_apn; args->mme_args.s1ap_args.paging_timer = paging_timer; args->mme_args.s1ap_args.request_imeisv = request_imeisv; args->spgw_args.gtpu_bind_addr = spgw_bind_addr; args->spgw_args.sgi_if_addr = sgi_if_addr; args->spgw_args.sgi_if_name = sgi_if_name; args->spgw_args.max_paging_queue = max_paging_queue; args->hss_args.db_file = hss_db_file; // Apply all_level to any unset layers if (vm.count("log.all_level")) { if (!vm.count("log.nas_level")) { args->log_args.nas_level = args->log_args.all_level; } if (!vm.count("log.s1ap_level")) { args->log_args.s1ap_level = args->log_args.all_level; } if (!vm.count("log.mme_gtpc_level")) { args->log_args.mme_gtpc_level = args->log_args.all_level; } if (!vm.count("log.spgw_gtpc_level")) { args->log_args.spgw_gtpc_level = args->log_args.all_level; } if (!vm.count("log.gtpu_level")) { args->log_args.gtpu_level = args->log_args.all_level; } if (!vm.count("log.spgw_level")) { args->log_args.spgw_level = args->log_args.all_level; } if (!vm.count("log.hss_level")) { args->log_args.hss_level = args->log_args.all_level; } } // Apply all_hex_limit to any unset layers if (vm.count("log.all_hex_limit")) { if (!vm.count("log.s1ap_hex_limit")) { args->log_args.s1ap_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.mme_gtpc_hex_limit")) { args->log_args.mme_gtpc_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.spgw_gtpc_hex_limit")) { args->log_args.spgw_gtpc_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.gtpu_hex_limit")) { args->log_args.gtpu_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.spgw_hex_limit")) { args->log_args.spgw_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.hss_hex_limit")) { args->log_args.hss_hex_limit = args->log_args.all_hex_limit; } if (!vm.count("log.nas_hex_limit")) { args->log_args.nas_hex_limit = args->log_args.all_hex_limit; } } // Check user database if (!config_exists(args->hss_args.db_file, "user_db.csv")) { cout << "Failed to read HSS user database file " << args->hss_args.db_file << " - exiting" << endl; exit(1); } return; } std::string get_build_mode() { return std::string(srsran_get_build_mode()); } std::string get_build_info() { if (std::string(srsran_get_build_info()).find(" ") != std::string::npos) { return std::string(srsran_get_version()); } return std::string(srsran_get_build_info()); } std::string get_build_string() { std::stringstream ss; ss << "Built in " << get_build_mode() << " mode using " << get_build_info() << "." << std::endl; return ss.str(); } static void emergency_cleanup_handler(void* data) { srslog::flush(); if (log_sink) { log_sink->flush(); } } static void signal_handler() { running = false; } int main(int argc, char* argv[]) { srsran_register_signal_handler(signal_handler); add_emergency_cleanup_handler(emergency_cleanup_handler, nullptr); // print build info cout << endl << get_build_string() << endl; cout << endl << "--- Software Radio Systems EPC ---" << endl << endl; srsran_debug_handle_crash(argc, argv); all_args_t args; parse_args(&args, argc, argv); // Setup logging. log_sink = (args.log_args.filename == "stdout") ? srslog::create_stdout_sink() : srslog::create_file_sink(args.log_args.filename); if (!log_sink) { return SRSRAN_ERROR; } srslog::log_channel* chan = srslog::create_log_channel("main_channel", *log_sink); if (!chan) { return SRSRAN_ERROR; } srslog::set_default_sink(*log_sink); // Start the log backend. srslog::init(); if (args.log_args.filename != "stdout") { auto& epc_logger = srslog::fetch_basic_logger("EPC", false); epc_logger.info("\n\n%s\n--- Software Radio Systems EPC log ---\n\n", get_build_string().c_str()); } srsran::log_args(argc, argv, "EPC"); srslog::basic_logger& nas_logger = srslog::fetch_basic_logger("NAS", false); nas_logger.set_level(srslog::str_to_basic_level(args.log_args.nas_level)); nas_logger.set_hex_dump_max_size(args.log_args.nas_hex_limit); auto& s1ap_logger = srslog::fetch_basic_logger("S1AP", false); s1ap_logger.set_level(srslog::str_to_basic_level(args.log_args.s1ap_level)); s1ap_logger.set_hex_dump_max_size(args.log_args.s1ap_hex_limit); auto& mme_gtpc_logger = srslog::fetch_basic_logger("MME GTPC", false); mme_gtpc_logger.set_level(srslog::str_to_basic_level(args.log_args.mme_gtpc_level)); mme_gtpc_logger.set_hex_dump_max_size(args.log_args.mme_gtpc_hex_limit); auto& hss_logger = srslog::fetch_basic_logger("HSS", false); hss_logger.set_level(srslog::str_to_basic_level(args.log_args.hss_level)); hss_logger.set_hex_dump_max_size(args.log_args.hss_hex_limit); auto& spgw_gtpc_logger = srslog::fetch_basic_logger("SPGW GTPC", false); spgw_gtpc_logger.set_level(srslog::str_to_basic_level(args.log_args.spgw_gtpc_level)); spgw_gtpc_logger.set_hex_dump_max_size(args.log_args.spgw_gtpc_hex_limit); auto& gtpu_logger = srslog::fetch_basic_logger("GTPU", false); gtpu_logger.set_level(srslog::str_to_basic_level(args.log_args.gtpu_level)); gtpu_logger.set_hex_dump_max_size(args.log_args.gtpu_hex_limit); auto& spgw_logger = srslog::fetch_basic_logger("SPGW", false); spgw_logger.set_level(srslog::str_to_basic_level(args.log_args.spgw_level)); spgw_logger.set_hex_dump_max_size(args.log_args.spgw_hex_limit); hss* hss = hss::get_instance(); if (hss->init(&args.hss_args)) { cout << "Error initializing HSS" << endl; exit(1); } mme* mme = mme::get_instance(); if (mme->init(&args.mme_args)) { cout << "Error initializing MME" << endl; exit(1); } spgw* spgw = spgw::get_instance(); if (spgw->init(&args.spgw_args, hss->get_ip_to_imsi())) { cout << "Error initializing SP-GW" << endl; exit(1); } mme->start(); spgw->start(); while (running) { sleep(1); } mme->stop(); mme->cleanup(); spgw->stop(); spgw->cleanup(); hss->stop(); hss->cleanup(); cout << std::endl << "--- exiting ---" << endl; return 0; }