#pragma once #include "llarp/iwp.h" #include "llarp/iwp/establish_job.hpp" #include "router.hpp" #include "session.hpp" #include "str.hpp" #include #include #include struct llarp_link { typedef std::mutex mtx_t; typedef std::lock_guard< mtx_t > lock_t; llarp_router *router; llarp_crypto *crypto; llarp_logic *logic; llarp_ev_loop *netloop; llarp_async_iwp *iwp; llarp_threadpool *worker; llarp_link *parent = nullptr; llarp_udp_io udp; llarp::Addr addr; char keyfile[255]; uint32_t timeout_job_id; const char * name() const { return m_name; } const char *m_name; typedef std::unordered_map< llarp::Addr, llarp_link_session *, llarp::addrhash > LinkMap_t; LinkMap_t m_sessions; mtx_t m_sessions_Mutex; typedef std::unordered_map< llarp::PubKey, llarp::Addr, llarp::PubKeyHash > SessionMap_t; SessionMap_t m_Connected; mtx_t m_Connected_Mutex; bool pumpingLogic = false; typedef std::unordered_map< llarp::Addr, llarp_link_session *, llarp::addrhash > PendingSessionMap_t; PendingSessionMap_t m_PendingSessions; mtx_t m_PendingSessions_Mutex; llarp::SecretKey seckey; llarp_link(const llarp_iwp_args &args) : router(args.router) , crypto(args.crypto) , logic(args.logic) , worker(args.cryptoworker) , m_name("IWP") { strncpy(keyfile, args.keyfile, sizeof(keyfile)); iwp = llarp_async_iwp_new(crypto, logic, worker); } ~llarp_link() { llarp_async_iwp_free(iwp); } bool has_intro_from(const llarp::Addr &from) { std::unique_lock< std::mutex > lock(m_PendingSessions_Mutex); return m_PendingSessions.find(from) != m_PendingSessions.end(); } void put_intro_from(llarp_link_session *s) { std::unique_lock< std::mutex > lock(m_PendingSessions_Mutex); m_PendingSessions[s->addr] = s; } void remove_intro_from(const llarp::Addr &from) { std::unique_lock< std::mutex > lock(m_PendingSessions_Mutex); m_PendingSessions.erase(from); } // set that src address has identity pubkey void MapAddr(const llarp::Addr &src, const llarp::PubKey &identity) { lock_t lock(m_Connected_Mutex); m_Connected[identity] = src; } static bool has_session_to(llarp_link *serv, const byte_t *pubkey) { llarp::PubKey pk(pubkey); lock_t lock(serv->m_Connected_Mutex); return serv->m_Connected.find(pk) != serv->m_Connected.end(); } void TickSessions() { auto now = llarp_time_now_ms(); std::set< llarp::Addr > remove; { lock_t lock(m_sessions_Mutex); for(auto &itr : m_sessions) { llarp_link_session *s = itr.second; if(s && s->Tick(now)) remove.insert(itr.first); } } for(const auto &addr : remove) RemoveSessionByAddr(addr); } static bool sendto(llarp_link *serv, const byte_t *pubkey, llarp_buffer_t buf) { // lock_t lock(serv->m_Connected_Mutex); auto itr = serv->m_Connected.find(pubkey); if(itr != serv->m_Connected.end()) { // lock_t innerlock(serv->m_sessions_Mutex); auto inner_itr = serv->m_sessions.find(itr->second); if(inner_itr != serv->m_sessions.end()) { llarp_link_session *link = inner_itr->second; return link->sendto(buf); } } return false; } void UnmapAddr(const llarp::Addr &src) { lock_t lock(m_Connected_Mutex); // std::unordered_map< llarp::pubkey, llarp::Addr, llarp::pubkeyhash > auto itr = std::find_if( m_Connected.begin(), m_Connected.end(), [src](const std::pair< llarp::PubKey, llarp::Addr > &item) -> bool { return src == item.second; }); if(itr == std::end(m_Connected)) return; // tell router we are done with this session router->SessionClosed(itr->first); m_Connected.erase(itr); } llarp_link_session * create_session(const llarp::Addr &src) { return new llarp_link_session(this, seckey, src); } bool has_session_to(const llarp::Addr &dst) { lock_t lock(m_sessions_Mutex); return m_sessions.find(dst) != m_sessions.end(); } llarp_link_session * find_session(const llarp::Addr &addr) { lock_t lock(m_sessions_Mutex); auto itr = m_sessions.find(addr); if(itr == m_sessions.end()) return nullptr; else return itr->second; } void put_session(const llarp::Addr &src, llarp_link_session *impl) { lock_t lock(m_sessions_Mutex); m_sessions.emplace(src, impl); impl->our_router = &router->rc; } void clear_sessions() { lock_t lock(m_sessions_Mutex); auto itr = m_sessions.begin(); while(itr != m_sessions.end()) { delete itr->second; itr = m_sessions.erase(itr); } } /// safe iterate sessions void iterate_sessions(std::function< bool(llarp_link_session *) > visitor) { std::list< llarp_link_session * > slist; { lock_t lock(m_sessions_Mutex); for(const auto &itr : m_sessions) { slist.push_back(itr.second); } } for(auto s : slist) if(!visitor(s)) return; } static void handle_logic_pump(void *user) { llarp_link *self = static_cast< llarp_link * >(user); self->iterate_sessions([](llarp_link_session *s) -> bool { s->TickLogic(); return true; }); self->pumpingLogic = false; } void PumpLogic() { if(pumpingLogic) return; pumpingLogic = true; llarp_logic_queue_job(logic, {this, &handle_logic_pump}); } void RemoveSessionByAddr(const llarp::Addr &addr) { lock_t lock(m_sessions_Mutex); auto itr = m_sessions.find(addr); if(itr != m_sessions.end()) { llarp::LogDebug("removing session ", addr); UnmapAddr(addr); llarp_link_session *s = itr->second; s->done(); m_sessions.erase(itr); delete s; } } uint8_t * pubkey() { return llarp::seckey_topublic(seckey); } bool ensure_privkey() { llarp::LogDebug("ensure transport private key at ", keyfile); std::error_code ec; if(!fs::exists(keyfile, ec)) { if(!keygen(keyfile)) return false; } std::ifstream f(keyfile); if(f.is_open()) { f.read((char *)seckey.data(), seckey.size()); return true; } return false; } bool keygen(const char *fname) { crypto->encryption_keygen(seckey); llarp::LogInfo("new transport key generated"); std::ofstream f(fname); if(f.is_open()) { f.write((char *)seckey.data(), seckey.size()); return true; } return false; } static void handle_cleanup_timer(void *l, uint64_t orig, uint64_t left) { if(left) return; llarp_link *link = static_cast< llarp_link * >(l); link->timeout_job_id = 0; link->TickSessions(); link->issue_cleanup_timer(orig); } // this is called in net threadpool static void handle_recvfrom(struct llarp_udp_io *udp, const struct sockaddr *saddr, const void *buf, ssize_t sz) { llarp_link *link = static_cast< llarp_link * >(udp->user); llarp_link_session *s = link->find_session(*saddr); if(s == nullptr) { // new inbound session s = link->create_session(*saddr); } s->recv(buf, sz); } void cancel_timer() { if(timeout_job_id) { llarp_logic_cancel_call(logic, timeout_job_id); } timeout_job_id = 0; } void issue_cleanup_timer(uint64_t timeout) { timeout_job_id = llarp_logic_call_later( logic, {timeout, this, &llarp_link::handle_cleanup_timer}); } void get_our_address(struct llarp_ai *addr) { addr->rank = 1; strncpy(addr->dialect, "IWP", sizeof(addr->dialect)); memcpy(addr->enc_key, pubkey(), 32); memcpy(addr->ip.s6_addr, this->addr.addr6(), 16); addr->port = this->addr.port(); } static void after_recv(llarp_udp_io *udp) { llarp_link *self = static_cast< llarp_link * >(udp->user); self->PumpLogic(); } bool configure(struct llarp_ev_loop *netloop, const char *ifname, int af, uint16_t port) { if(!ensure_privkey()) { llarp::LogError("failed to ensure private key"); return false; } llarp::LogDebug("configure link ifname=", ifname, " af=", af, " port=", port); // bind sockaddr_in ip4addr; sockaddr_in6 ip6addr; sockaddr *addr = nullptr; switch(af) { case AF_INET: addr = (sockaddr *)&ip4addr; llarp::Zero(addr, sizeof(ip4addr)); break; case AF_INET6: addr = (sockaddr *)&ip6addr; llarp::Zero(addr, sizeof(ip6addr)); break; // TODO: AF_PACKET default: llarp::LogError(__FILE__, "unsupported address family", af); return false; } addr->sa_family = af; if(!llarp::StrEq(ifname, "*")) { if(!llarp_getifaddr(ifname, af, addr)) { llarp::LogError("failed to get address of network interface ", ifname); return false; } } else m_name = "OWP"; // outboundLink_name; switch(af) { case AF_INET: ip4addr.sin_port = htons(port); break; case AF_INET6: ip6addr.sin6_port = htons(port); break; // TODO: AF_PACKET default: return false; } this->addr = *addr; this->netloop = netloop; udp.recvfrom = &llarp_link::handle_recvfrom; udp.user = this; udp.tick = &llarp_link::after_recv; llarp::LogDebug("bind IWP link to ", addr); if(llarp_ev_add_udp(netloop, &udp, addr) == -1) { llarp::LogError("failed to bind to ", addr); return false; } return true; } bool start_link(struct llarp_logic *pLogic) { // give link implementations // link->parent = l; timeout_job_id = 0; this->logic = pLogic; // start cleanup timer issue_cleanup_timer(500); return true; } bool stop_link() { cancel_timer(); llarp_ev_close_udp(&udp); clear_sessions(); return true; } bool try_establish(struct llarp_link_establish_job *job) { llarp::Addr dst(job->ai); llarp::LogDebug("establish session to ", dst); llarp_link_session *s = find_session(dst); if(s == nullptr) { s = create_session(dst); put_session(dst, s); } else return false; s->establish_job = job; s->frame.alive(); // mark it alive s->introduce(job->ai.enc_key); return true; } void mark_session_active(llarp_link_session *s) { s->frame.alive(); } };