/** * * \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 "srsran/asn1/s1ap.h" #include #include #include #include "srsenb/hdr/stack/upper/gtpu.h" #include "srsenb/test/common/dummy_classes.h" #include "srsran/common/network_utils.h" #include "srsran/common/test_common.h" #include "srsran/upper/gtpu.h" namespace srsenb { static const size_t PDU_HEADER_SIZE = 20; class pdcp_tester : public pdcp_dummy { public: void write_sdu(uint16_t rnti, uint32_t lcid, srsran::unique_byte_buffer_t sdu, int pdcp_sn) override { last_sdu = std::move(sdu); last_pdcp_sn = pdcp_sn; last_rnti = rnti; last_lcid = lcid; } std::map get_buffered_pdus(uint16_t rnti, uint32_t lcid) override { return std::move(buffered_pdus); } void send_status_report(uint16_t rnti) override {} void send_status_report(uint16_t rnti, uint32_t lcid) override {} void push_buffered_pdu(uint32_t sn, srsran::unique_byte_buffer_t pdu) { buffered_pdus[sn] = std::move(pdu); } void clear() { last_sdu = nullptr; last_pdcp_sn = -1; last_lcid = 0; last_rnti = SRSRAN_INVALID_RNTI; } std::map buffered_pdus; srsran::unique_byte_buffer_t last_sdu; int last_pdcp_sn = -1; uint16_t last_rnti = SRSRAN_INVALID_RNTI; uint32_t last_lcid = 0; }; struct dummy_socket_manager : public srsran::socket_manager_itf { dummy_socket_manager() : srsran::socket_manager_itf(srslog::fetch_basic_logger("TEST")) {} /// Register (fd, callback). callback is called within socket thread when fd has data. bool add_socket_handler(int fd, recv_callback_t handler) final { if (s1u_fd >= 0) { return false; } s1u_fd = fd; callback = std::move(handler); return true; } /// remove registered socket fd bool remove_socket(int fd) final { if (s1u_fd < 0) { return false; } s1u_fd = -1; return true; } int s1u_fd = -1; recv_callback_t callback; }; const int GTPU_PORT = 2152; srsran::unique_byte_buffer_t encode_ipv4_packet(srsran::span data, uint32_t teid, const struct sockaddr_in& src_sockaddr_in, const struct sockaddr_in& dest_sockaddr_in) { srsran::unique_byte_buffer_t pdu = srsran::make_byte_buffer(); struct iphdr ip_pkt = {}; ip_pkt.version = 4; ip_pkt.tot_len = htons(data.size() + sizeof(struct iphdr)); ip_pkt.saddr = src_sockaddr_in.sin_addr.s_addr; ip_pkt.daddr = dest_sockaddr_in.sin_addr.s_addr; pdu->append_bytes((uint8_t*)&ip_pkt, sizeof(struct iphdr)); pdu->append_bytes(data.data(), data.size()); return pdu; } srsran::unique_byte_buffer_t encode_gtpu_packet(srsran::span data, uint32_t teid, const struct sockaddr_in& src_sockaddr_in, const struct sockaddr_in& dest_sockaddr_in) { srsran::unique_byte_buffer_t pdu = encode_ipv4_packet(data, teid, src_sockaddr_in, dest_sockaddr_in); // header srsran::gtpu_header_t header = {}; header.flags = GTPU_FLAGS_VERSION_V1 | GTPU_FLAGS_GTP_PROTOCOL; header.message_type = GTPU_MSG_DATA_PDU; header.length = pdu->N_bytes; header.teid = teid; gtpu_write_header(&header, pdu.get(), srslog::fetch_basic_logger("GTPU")); return pdu; } srsran::unique_byte_buffer_t encode_end_marker(uint32_t teid) { srsran::unique_byte_buffer_t pdu = srsran::make_byte_buffer(); // header srsran::gtpu_header_t header = {}; header.flags = GTPU_FLAGS_VERSION_V1 | GTPU_FLAGS_GTP_PROTOCOL; header.message_type = GTPU_MSG_END_MARKER; header.length = 0; header.teid = teid; gtpu_write_header(&header, pdu.get(), srslog::fetch_basic_logger("GTPU")); return pdu; } srsran::unique_byte_buffer_t read_socket(int fd) { srsran::unique_byte_buffer_t pdu = srsran::make_byte_buffer(); pdu->N_bytes = read(fd, pdu->msg, pdu->get_tailroom()); return pdu; } void test_gtpu_tunnel_manager() { const char* sgw_addr_str = "127.0.0.1"; struct sockaddr_in sgw_sockaddr = {}; srsran::net_utils::set_sockaddr(&sgw_sockaddr, sgw_addr_str, GTPU_PORT); uint32_t sgw_addr = ntohl(sgw_sockaddr.sin_addr.s_addr); const uint32_t drb1_lcid = 3; srsran::task_scheduler task_sched; gtpu_args_t gtpu_args = {}; gtpu_tunnel_manager tunnels(&task_sched, srslog::fetch_basic_logger("GTPU")); tunnels.init(gtpu_args, nullptr); TESTASSERT(tunnels.find_tunnel(0) == nullptr); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).empty()); TESTASSERT(tunnels.find_rnti_tunnels(0x46) == nullptr); // Creation of tunnels for different users and lcids const gtpu_tunnel* tun = tunnels.add_tunnel(0x46, drb1_lcid, 5, sgw_addr); TESTASSERT(tun != nullptr); TESTASSERT(tunnels.find_tunnel(tun->teid_in) == tun); const gtpu_tunnel* tun2 = tunnels.add_tunnel(0x47, drb1_lcid, 6, sgw_addr); TESTASSERT(tun2 != nullptr); TESTASSERT(tunnels.find_tunnel(tun2->teid_in) == tun2); tun2 = tunnels.add_tunnel(0x47, drb1_lcid + 1, 7, sgw_addr); TESTASSERT(tun2 != nullptr); TESTASSERT(tunnels.find_tunnel(tun2->teid_in) == tun2); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).size() == 1); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x47, drb1_lcid).size() == 1); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x47, drb1_lcid + 1).size() == 1); // TEST: Creation/Removal of indirect tunnel const gtpu_tunnel* fwd_tun = tunnels.add_tunnel(0x46, drb1_lcid, 8, sgw_addr); TESTASSERT(fwd_tun != nullptr); TESTASSERT(tunnels.find_tunnel(fwd_tun->teid_in) == fwd_tun); tunnels.setup_forwarding(tun->teid_in, fwd_tun->teid_in); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).size() == 2); // Removing a tunnel also clears any associated forwarding tunnel TESTASSERT(tunnels.remove_tunnel(tun->teid_in)); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).empty()); // TEST: Prioritization of one TEID over another const gtpu_tunnel* before_tun = tunnels.add_tunnel(0x46, drb1_lcid, 7, sgw_addr); const gtpu_tunnel* after_tun = tunnels.add_tunnel(0x46, drb1_lcid, 8, sgw_addr); TESTASSERT(before_tun != nullptr and after_tun != nullptr); tunnels.set_tunnel_priority(before_tun->teid_in, after_tun->teid_in); for (uint32_t i = 0; i < 1000; ++i) { TESTASSERT(before_tun->state == gtpu_tunnel_manager::tunnel_state::pdcp_active); TESTASSERT(after_tun->state == gtpu_tunnel_manager::tunnel_state::buffering); // while Rx packets are received, active forwarding TEID should not be removed tunnels.handle_rx_pdcp_sdu(before_tun->teid_in); } // Removing active TEID, will automatically switch TEID paths TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).size() == 2); tunnels.remove_tunnel(before_tun->teid_in); TESTASSERT(tunnels.find_rnti_lcid_tunnels(0x46, drb1_lcid).size() == 1); TESTASSERT(after_tun->state == gtpu_tunnel_manager::tunnel_state::pdcp_active); } enum class tunnel_test_event { success, wait_end_marker_timeout }; int test_gtpu_direct_tunneling(tunnel_test_event event) { std::random_device rd; std::mt19937 g(rd()); srslog::basic_logger& logger = srslog::fetch_basic_logger("TEST"); logger.info("\n\n**** Test GTPU Direct Tunneling ****\n"); uint16_t rnti = 0x46, rnti2 = 0x50; uint32_t drb1 = 3; uint32_t sgw_teidout1 = 1, sgw_teidout2 = 2; const char * sgw_addr_str = "127.0.0.1", *senb_addr_str = "127.0.1.1", *tenb_addr_str = "127.0.1.2"; struct sockaddr_in senb_sockaddr = {}, sgw_sockaddr = {}, tenb_sockaddr = {}; srsran::net_utils::set_sockaddr(&senb_sockaddr, senb_addr_str, GTPU_PORT); srsran::net_utils::set_sockaddr(&sgw_sockaddr, sgw_addr_str, GTPU_PORT); srsran::net_utils::set_sockaddr(&tenb_sockaddr, tenb_addr_str, GTPU_PORT); uint32_t tenb_addr = ntohl(tenb_sockaddr.sin_addr.s_addr); uint32_t senb_addr = ntohl(senb_sockaddr.sin_addr.s_addr); uint32_t sgw_addr = ntohl(sgw_sockaddr.sin_addr.s_addr); srsran::unique_byte_buffer_t pdu; // Initiate layers srslog::basic_logger& logger1 = srslog::fetch_basic_logger("GTPU1"); logger1.set_hex_dump_max_size(2048); srslog::basic_logger& logger2 = srslog::fetch_basic_logger("GTPU2"); logger2.set_hex_dump_max_size(2048); srsran::task_scheduler task_sched; dummy_socket_manager senb_rx_sockets, tenb_rx_sockets; srsenb::gtpu senb_gtpu(&task_sched, logger1, &senb_rx_sockets), tenb_gtpu(&task_sched, logger2, &tenb_rx_sockets); pdcp_tester senb_pdcp, tenb_pdcp; gtpu_args_t gtpu_args; gtpu_args.gtp_bind_addr = senb_addr_str; gtpu_args.mme_addr = sgw_addr_str; gtpu_args.indirect_tunnel_timeout_msec = std::uniform_int_distribution{500, 2000}(g); senb_gtpu.init(gtpu_args, &senb_pdcp); gtpu_args.gtp_bind_addr = tenb_addr_str; tenb_gtpu.init(gtpu_args, &tenb_pdcp); // create tunnels MME-SeNB and MME-TeNB uint32_t senb_teid_in = senb_gtpu.add_bearer(rnti, drb1, sgw_addr, sgw_teidout1).value(); uint32_t tenb_teid_in = tenb_gtpu.add_bearer(rnti2, drb1, sgw_addr, sgw_teidout2).value(); // Buffer PDUs in SeNB PDCP for (size_t sn = 6; sn < 10; ++sn) { std::vector data(10, sn); pdu = encode_ipv4_packet(data, senb_teid_in, sgw_sockaddr, senb_sockaddr); senb_pdcp.push_buffered_pdu(sn, std::move(pdu)); } // create direct tunnel SeNB-TeNB gtpu::bearer_props props; props.flush_before_teidin_present = true; props.flush_before_teidin = tenb_teid_in; uint32_t dl_tenb_teid_in = tenb_gtpu.add_bearer(rnti2, drb1, senb_addr, 0, &props).value(); props = {}; props.forward_from_teidin_present = true; props.forward_from_teidin = senb_teid_in; senb_gtpu.add_bearer(rnti, drb1, tenb_addr, dl_tenb_teid_in, &props); std::vector data_vec(10); std::iota(data_vec.begin(), data_vec.end(), 0); std::vector encoded_data; srsran::span pdu_view{}; // TEST: GTPU buffers incoming PDCP buffered SNs until the TEID is explicitly activated tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); TESTASSERT(tenb_pdcp.last_sdu == nullptr); tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); TESTASSERT(tenb_pdcp.last_sdu == nullptr); tenb_gtpu.set_tunnel_status(dl_tenb_teid_in, true); pdu_view = srsran::make_span(tenb_pdcp.last_sdu); TESTASSERT(std::count(pdu_view.begin() + PDU_HEADER_SIZE, pdu_view.end(), 7) == 10); TESTASSERT(tenb_pdcp.last_rnti == rnti2); TESTASSERT(tenb_pdcp.last_lcid == drb1); TESTASSERT(tenb_pdcp.last_pdcp_sn == (int)7); // TEST: verify that PDCP buffered SNs have been forwarded through SeNB->TeNB tunnel for (size_t sn = 8; sn < 10; ++sn) { tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); pdu_view = srsran::make_span(tenb_pdcp.last_sdu); TESTASSERT(std::count(pdu_view.begin() + PDU_HEADER_SIZE, pdu_view.end(), sn) == 10); TESTASSERT(tenb_pdcp.last_rnti == rnti2); TESTASSERT(tenb_pdcp.last_lcid == drb1); TESTASSERT(tenb_pdcp.last_pdcp_sn == (int)sn); } // TEST: verify that incoming DL data MME->SeNB is forwarded through SeNB->TeNB tunnel std::shuffle(data_vec.begin(), data_vec.end(), g); pdu = encode_gtpu_packet(data_vec, senb_teid_in, sgw_sockaddr, senb_sockaddr); encoded_data.assign(pdu->msg + 8u, pdu->msg + pdu->N_bytes); senb_gtpu.handle_gtpu_s1u_rx_packet(std::move(pdu), sgw_sockaddr); tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); pdu_view = srsran::make_span(tenb_pdcp.last_sdu); TESTASSERT(pdu_view.size() == encoded_data.size() and std::equal(pdu_view.begin(), pdu_view.end(), encoded_data.begin())); TESTASSERT(tenb_pdcp.last_rnti == rnti2 and tenb_pdcp.last_lcid == drb1); // TEST: verify that MME->TeNB packets are buffered until SeNB->TeNB tunnel is closed tenb_pdcp.clear(); size_t N_pdus = std::uniform_int_distribution{1, 30}(g); for (size_t i = 0; i < N_pdus; ++i) { std::fill(data_vec.begin(), data_vec.end(), i); pdu = encode_gtpu_packet(data_vec, senb_teid_in, sgw_sockaddr, tenb_sockaddr); tenb_gtpu.handle_gtpu_s1u_rx_packet(std::move(pdu), sgw_sockaddr); // The PDUs are being buffered TESTASSERT(tenb_pdcp.last_sdu == nullptr); } // PDUs coming from SeNB-TeNB tunnel are forwarded std::iota(data_vec.begin(), data_vec.end(), 0); std::shuffle(data_vec.begin(), data_vec.end(), g); pdu = encode_gtpu_packet(data_vec, senb_teid_in, sgw_sockaddr, senb_sockaddr); encoded_data.assign(pdu->msg + 8u, pdu->msg + pdu->N_bytes); senb_gtpu.handle_gtpu_s1u_rx_packet(std::move(pdu), sgw_sockaddr); tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); TESTASSERT(tenb_pdcp.last_sdu->N_bytes == encoded_data.size() and memcmp(tenb_pdcp.last_sdu->msg, encoded_data.data(), encoded_data.size()) == 0); tenb_pdcp.clear(); TESTASSERT(tenb_pdcp.last_sdu == nullptr); if (event == tunnel_test_event::wait_end_marker_timeout) { // TEST: EndMarker does not reach TeNB, but there is a timeout that will resume the new GTPU tunnel for (size_t i = 0; i < gtpu_args.indirect_tunnel_timeout_msec + 1; ++i) { task_sched.tic(); } } else { // TEST: EndMarker is forwarded via MME->SeNB->TeNB, and TeNB buffered PDUs are flushed pdu = encode_end_marker(senb_teid_in); senb_gtpu.handle_gtpu_s1u_rx_packet(std::move(pdu), sgw_sockaddr); tenb_gtpu.handle_gtpu_s1u_rx_packet(read_socket(tenb_rx_sockets.s1u_fd), senb_sockaddr); } srsran::span encoded_data2{tenb_pdcp.last_sdu->msg + 20u, tenb_pdcp.last_sdu->msg + 30u}; TESTASSERT(std::all_of(encoded_data2.begin(), encoded_data2.end(), [N_pdus](uint8_t b) { return b == N_pdus - 1; })); return SRSRAN_SUCCESS; } } // namespace srsenb int main(int argc, char** argv) { // Setup logging. auto& logger = srslog::fetch_basic_logger("GTPU", false); logger.set_level(srslog::basic_levels::debug); logger.set_hex_dump_max_size(-1); // Start the log backend. srsran::test_init(argc, argv); srsenb::test_gtpu_tunnel_manager(); TESTASSERT(srsenb::test_gtpu_direct_tunneling(srsenb::tunnel_test_event::success) == SRSRAN_SUCCESS); TESTASSERT(srsenb::test_gtpu_direct_tunneling(srsenb::tunnel_test_event::wait_end_marker_timeout) == SRSRAN_SUCCESS); srslog::flush(); srsran::console("Success"); }