/* * Copyright 2013-2020 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 SRSENB_S1AP_H #define SRSENB_S1AP_H #include #include "common_enb.h" #include "srslte/common/buffer_pool.h" #include "srslte/common/common.h" #include "srslte/common/logmap.h" #include "srslte/common/s1ap_pcap.h" #include "srslte/common/threads.h" #include "srslte/interfaces/enb_interfaces.h" #include "s1ap_metrics.h" #include "srslte/common/network_utils.h" #include "srslte/common/stack_procedure.h" #include "srslte/common/task_scheduler.h" #include namespace srsenb { struct ue_ctxt_t { static const uint32_t invalid_enb_id = std::numeric_limits::max(); bool mme_ue_s1ap_id_present = false; uint16_t rnti = SRSLTE_INVALID_RNTI; uint32_t enb_ue_s1ap_id = invalid_enb_id; uint32_t mme_ue_s1ap_id = 0; struct timeval init_timestamp = {}; }; class s1ap : public s1ap_interface_rrc { public: static const uint32_t ts1_reloc_prep_timeout_ms = 10000; static const uint32_t ts1_reloc_overall_timeout_ms = 10000; s1ap(srslte::task_sched_handle task_sched_); int init(s1ap_args_t args_, rrc_interface_s1ap* rrc_, srsenb::stack_interface_s1ap_lte* stack_); void stop(); void get_metrics(s1ap_metrics_t& m); // RRC interface void initial_ue(uint16_t rnti, asn1::s1ap::rrc_establishment_cause_e cause, srslte::unique_byte_buffer_t pdu) override; void initial_ue(uint16_t rnti, asn1::s1ap::rrc_establishment_cause_e cause, srslte::unique_byte_buffer_t pdu, uint32_t m_tmsi, uint8_t mmec) override; void write_pdu(uint16_t rnti, srslte::unique_byte_buffer_t pdu) override; bool user_exists(uint16_t rnti) override; void user_mod(uint16_t old_rnti, uint16_t new_rnti) override; bool user_release(uint16_t rnti, asn1::s1ap::cause_radio_network_e cause_radio) override; void ue_ctxt_setup_complete(uint16_t rnti, const asn1::s1ap::init_context_setup_resp_s& res) override; void ue_erab_setup_complete(uint16_t rnti, const asn1::s1ap::erab_setup_resp_s& res) override; bool is_mme_connected() override; bool send_ho_required(uint16_t rnti, uint32_t target_eci, srslte::plmn_id_t target_plmn, srslte::unique_byte_buffer_t rrc_container) override; bool send_enb_status_transfer_proc(uint16_t rnti, std::vector& bearer_status_list) override; bool send_ho_failure(uint32_t mme_ue_s1ap_id); bool send_ho_req_ack(const asn1::s1ap::ho_request_s& msg, uint16_t rnti, srslte::unique_byte_buffer_t ho_cmd, srslte::span > admitted_bearers); void send_ho_notify(uint16_t rnti, uint64_t target_eci) override; // void ue_capabilities(uint16_t rnti, LIBLTE_RRC_UE_EUTRA_CAPABILITY_STRUCT *caps); // Stack interface bool handle_mme_rx_msg(srslte::unique_byte_buffer_t pdu, const sockaddr_in& from, const sctp_sndrcvinfo& sri, int flags); void start_pcap(srslte::s1ap_pcap* pcap_); private: static const int MME_PORT = 36412; static const int ADDR_FAMILY = AF_INET; static const int SOCK_TYPE = SOCK_STREAM; static const int PROTO = IPPROTO_SCTP; static const int PPID = 18; static const int NONUE_STREAM_ID = 0; // args rrc_interface_s1ap* rrc = nullptr; s1ap_args_t args; srslte::log_ref s1ap_log; srslte::byte_buffer_pool* pool = nullptr; srsenb::stack_interface_s1ap_lte* stack = nullptr; srslte::task_sched_handle task_sched; srslte::socket_handler_t s1ap_socket; struct sockaddr_in mme_addr = {}; // MME address bool mme_connected = false; bool running = false; uint32_t next_enb_ue_s1ap_id = 1; // Next ENB-side UE identifier uint16_t next_ue_stream_id = 1; // Next UE SCTP stream identifier srslte::unique_timer mme_connect_timer, s1setup_timeout; // Protocol IEs sent with every UL S1AP message asn1::s1ap::tai_s tai; asn1::s1ap::eutran_cgi_s eutran_cgi; // PCAP srslte::s1ap_pcap* pcap = nullptr; asn1::s1ap::s1_setup_resp_s s1setupresponse; void build_tai_cgi(); bool connect_mme(); bool setup_s1(); bool sctp_send_s1ap_pdu(const asn1::s1ap::s1ap_pdu_c& tx_pdu, uint32_t rnti, const char* procedure_name); bool handle_s1ap_rx_pdu(srslte::byte_buffer_t* pdu); bool handle_initiatingmessage(const asn1::s1ap::init_msg_s& msg); bool handle_successfuloutcome(const asn1::s1ap::successful_outcome_s& msg); bool handle_unsuccessfuloutcome(const asn1::s1ap::unsuccessful_outcome_s& msg); bool handle_paging(const asn1::s1ap::paging_s& msg); bool handle_s1setupresponse(const asn1::s1ap::s1_setup_resp_s& msg); bool handle_dlnastransport(const asn1::s1ap::dl_nas_transport_s& msg); bool handle_initialctxtsetuprequest(const asn1::s1ap::init_context_setup_request_s& msg); bool handle_uectxtreleasecommand(const asn1::s1ap::ue_context_release_cmd_s& msg); bool handle_s1setupfailure(const asn1::s1ap::s1_setup_fail_s& msg); bool handle_erabsetuprequest(const asn1::s1ap::erab_setup_request_s& msg); bool handle_uecontextmodifyrequest(const asn1::s1ap::ue_context_mod_request_s& msg); // bool send_ue_capabilities(uint16_t rnti, LIBLTE_RRC_UE_EUTRA_CAPABILITY_STRUCT *caps) // handover bool handle_hopreparationfailure(const asn1::s1ap::ho_prep_fail_s& msg); bool handle_s1hocommand(const asn1::s1ap::ho_cmd_s& msg); bool handle_ho_request(const asn1::s1ap::ho_request_s& msg); // UE-specific data and procedures struct ue { //! TS 36.413, Section 8.4.1 - Handover Preparation Procedure class ho_prep_proc_t { public: struct ts1_reloc_prep_expired {}; ho_prep_proc_t(s1ap::ue* ue_); srslte::proc_outcome_t init(uint32_t target_eci_, srslte::plmn_id_t target_plmn_, srslte::unique_byte_buffer_t rrc_container); srslte::proc_outcome_t step() { return srslte::proc_outcome_t::yield; } srslte::proc_outcome_t react(ts1_reloc_prep_expired e); srslte::proc_outcome_t react(const asn1::s1ap::ho_prep_fail_s& msg); srslte::proc_outcome_t react(const asn1::s1ap::ho_cmd_s& msg); void then(const srslte::proc_state_t& result); const char* name() { return "HandoverPreparation"; } private: s1ap::ue* ue_ptr = nullptr; s1ap* s1ap_ptr = nullptr; uint32_t target_eci = 0; srslte::plmn_id_t target_plmn; srslte::unique_byte_buffer_t rrc_container; }; explicit ue(s1ap* s1ap_ptr_); bool send_enb_status_transfer_proc(std::vector& bearer_status_list); bool send_ulnastransport(srslte::unique_byte_buffer_t pdu); bool send_uectxtreleaserequest(const asn1::s1ap::cause_c& cause); bool send_uectxtmodifyfailure(const asn1::s1ap::cause_c& cause); bool send_uectxtmodifyresp(); bool send_uectxtreleasecomplete(); bool send_initialuemessage(asn1::s1ap::rrc_establishment_cause_e cause, srslte::unique_byte_buffer_t pdu, bool has_tmsi, uint32_t m_tmsi = 0, uint8_t mmec = 0); bool send_initial_ctxt_setup_response(const asn1::s1ap::init_context_setup_resp_s& res_); bool send_initial_ctxt_setup_failure(); bool send_erab_setup_response(const asn1::s1ap::erab_setup_resp_s& res_); bool was_uectxtrelease_requested() const { return release_requested; } ue_ctxt_t ctxt = {}; uint16_t stream_id = 1; private: bool send_ho_required(uint32_t target_eci_, srslte::plmn_id_t target_plmn_, srslte::unique_byte_buffer_t rrc_container); //! TS 36.413, Section 8.4.6 - eNB Status Transfer procedure // args s1ap* s1ap_ptr; srslte::log_ref s1ap_log; // state bool release_requested = false; srslte::unique_timer ts1_reloc_prep; ///< TS1_{RELOCprep} - max time for HO preparation srslte::unique_timer ts1_reloc_overall; ///< TS1_{RELOCOverall} public: // user procedures srslte::proc_t ho_prep_proc; }; class user_list { public: using value_type = std::unique_ptr; using iterator = std::unordered_map::iterator; using const_iterator = std::unordered_map::const_iterator; using pair_type = std::unordered_map::value_type; ue* find_ue_rnti(uint16_t rnti); ue* find_ue_enbid(uint32_t enbid); ue* find_ue_mmeid(uint32_t mmeid); ue* add_user(value_type user); void erase(ue* ue_ptr); iterator begin() { return users.begin(); } iterator end() { return users.end(); } const_iterator cbegin() const { return users.begin(); } const_iterator cend() const { return users.end(); } size_t size() const { return users.size(); } private: std::unordered_map > users; // maps ENB_S1AP_ID to user }; user_list users; // procedures class s1_setup_proc_t { public: struct s1setupresult { bool success = false; enum class cause_t { timeout, failure } cause; }; explicit s1_setup_proc_t(s1ap* s1ap_) : s1ap_ptr(s1ap_) {} srslte::proc_outcome_t init(); srslte::proc_outcome_t step() { return srslte::proc_outcome_t::yield; } srslte::proc_outcome_t react(const s1setupresult& event); void then(const srslte::proc_state_t& result) const; const char* name() const { return "MME Connection"; } private: srslte::proc_outcome_t start_mme_connection(); s1ap* s1ap_ptr = nullptr; }; ue* find_s1apmsg_user(uint32_t enb_id, uint32_t mme_id); std::string get_cause(const asn1::s1ap::cause_c& c); srslte::proc_t s1setup_proc; }; } // namespace srsenb #endif // SRSENB_S1AP_H