#include #include #include #include #include "buffer.hpp" #include "router.hpp" namespace llarp { namespace service { Endpoint::Endpoint(const std::string& name, llarp_router* r) : llarp_pathbuilder_context(r, r->dht, 2, 4), m_Router(r), m_Name(name) { m_Tag.Zero(); } bool Endpoint::SetOption(const std::string& k, const std::string& v) { if(k == "keyfile") { m_Keyfile = v; } if(k == "tag") { m_Tag = v; llarp::LogInfo("Setting tag to ", v); } if(k == "prefetch-tag") { m_PrefetchTags.insert(v); } if(k == "prefetch-addr") { Address addr; if(addr.FromString(v)) m_PrefetchAddrs.insert(addr); } if(k == "netns") { m_NetNS = v; m_OnInit.push_back(std::bind(&Endpoint::IsolateNetwork, this)); } return true; } bool Endpoint::IsolateNetwork() { llarp::LogInfo("isolating network to namespace ", m_NetNS); m_IsolatedWorker = llarp_init_isolated_net_threadpool( m_Name.c_str(), &SetupIsolatedNetwork, &RunIsolatedMainLoop, this); m_IsolatedLogic = llarp_init_single_process_logic(m_IsolatedWorker); return true; } llarp_ev_loop* Endpoint::EndpointNetLoop() { if(m_IsolatedNetLoop) return m_IsolatedNetLoop; else return m_Router->netloop; } bool Endpoint::NetworkIsIsolated() const { return m_IsolatedLogic && m_IsolatedWorker; } struct PathAlignJob { void HandleResult(Endpoint::OutboundContext* context) { if(context) { byte_t tmp[128] = {0}; memcpy(tmp, "BEEP", 4); auto buf = llarp::StackBuffer< decltype(tmp) >(tmp); buf.sz = 4; context->AsyncEncryptAndSendTo(buf, eProtocolText); } else { llarp::LogWarn("PathAlignJob timed out"); } delete this; } }; bool Endpoint::SetupIsolatedNetwork(void* user, bool failed) { return static_cast< Endpoint* >(user)->DoNetworkIsolation(failed); } bool Endpoint::HasPendingPathToService(const Address& addr) const { return m_PendingServiceLookups.find(addr) != m_PendingServiceLookups.end(); } void Endpoint::Tick(llarp_time_t now) { /// reset tx id for publish if(now - m_LastPublishAttempt >= INTROSET_PUBLISH_RETRY_INTERVAL) m_CurrentPublishTX = 0; // publish descriptors if(ShouldPublishDescriptors(now)) { std::set< Introduction > I; if(!GetCurrentIntroductions(I)) { llarp::LogWarn("could not publish descriptors for endpoint ", Name(), " because we couldn't get any introductions"); if(ShouldBuildMore()) ManualRebuild(1); return; } m_IntroSet.I.clear(); for(const auto& intro : I) m_IntroSet.I.push_back(intro); m_IntroSet.topic = m_Tag; if(!m_Identity.SignIntroSet(m_IntroSet, &m_Router->crypto)) { llarp::LogWarn("failed to sign introset for endpoint ", Name()); return; } if(PublishIntroSet(m_Router)) { llarp::LogInfo("publishing introset for endpoint ", Name()); } else { llarp::LogWarn("failed to publish intro set for endpoint ", Name()); } } // expire pending tx { std::set< service::IntroSet > empty; auto itr = m_PendingLookups.begin(); while(itr != m_PendingLookups.end()) { if(itr->second->IsTimedOut(now)) { std::unique_ptr< IServiceLookup > lookup = std::move(itr->second); llarp::LogInfo(lookup->name, " timed out txid=", lookup->txid); lookup->HandleResponse(empty); itr = m_PendingLookups.erase(itr); } else ++itr; } } // expire pending router lookups { auto itr = m_PendingRouters.begin(); while(itr != m_PendingRouters.end()) { if(itr->second.IsExpired(now)) { llarp::LogInfo("lookup for ", itr->first, " timed out"); itr = m_PendingRouters.erase(itr); } else ++itr; } } // prefetch addrs for(const auto& addr : m_PrefetchAddrs) { if(!HasPathToService(addr)) { PathAlignJob* j = new PathAlignJob(); if(!EnsurePathToService(addr, std::bind(&PathAlignJob::HandleResult, j, std::placeholders::_1), 10000)) { llarp::LogWarn("failed to ensure path to ", addr); delete j; } } } // prefetch tags for(const auto& tag : m_PrefetchTags) { auto itr = m_PrefetchedTags.find(tag); if(itr == m_PrefetchedTags.end()) { itr = m_PrefetchedTags.insert(std::make_pair(tag, CachedTagResult(tag))) .first; } for(const auto& introset : itr->second.result) { if(HasPendingPathToService(introset.A.Addr())) continue; PathAlignJob* j = new PathAlignJob(); if(!EnsurePathToService(introset.A.Addr(), std::bind(&PathAlignJob::HandleResult, j, std::placeholders::_1), 10000)) { llarp::LogWarn("failed to ensure path to ", introset.A.Addr(), " for tag ", tag.ToString()); delete j; } } itr->second.Expire(now); if(itr->second.ShouldRefresh(now)) { auto path = PickRandomEstablishedPath(); if(path) { auto job = new TagLookupJob(this, &itr->second); job->SendRequestViaPath(path, Router()); } } } // tick remote sessions { auto itr = m_RemoteSessions.begin(); while(itr != m_RemoteSessions.end()) { if(itr->second->Tick(now)) { delete itr->second; itr = m_RemoteSessions.erase(itr); } else ++itr; } } } uint64_t Endpoint::GenTXID() { uint64_t txid = llarp_randint(); while(m_PendingLookups.find(txid) != m_PendingLookups.end()) ++txid; return txid; } std::string Endpoint::Name() const { return m_Name + ":" + m_Identity.pub.Name(); } bool Endpoint::HasPathToService(const Address& addr) const { return m_RemoteSessions.find(addr) != m_RemoteSessions.end(); } void Endpoint::PutLookup(IServiceLookup* lookup, uint64_t txid) { m_PendingLookups.insert( std::make_pair(txid, std::unique_ptr< IServiceLookup >(lookup))); } bool Endpoint::HandleGotIntroMessage(const llarp::dht::GotIntroMessage* msg) { auto crypto = &m_Router->crypto; std::set< IntroSet > remote; for(const auto& introset : msg->I) { if(!introset.VerifySignature(crypto)) { llarp::LogInfo("invalid introset signature for ", introset, " on endpoint ", Name()); if(m_Identity.pub == introset.A && m_CurrentPublishTX == msg->T) { IntroSetPublishFail(); } return false; } if(m_Identity.pub == introset.A && m_CurrentPublishTX == msg->T) { llarp::LogInfo( "got introset publish confirmation for hidden service endpoint ", Name()); IntroSetPublished(); return true; } else { remote.insert(introset); } } auto itr = m_PendingLookups.find(msg->T); if(itr == m_PendingLookups.end()) { llarp::LogWarn("invalid lookup response for hidden service endpoint ", Name(), " txid=", msg->T); return true; } std::unique_ptr< IServiceLookup > lookup = std::move(itr->second); m_PendingLookups.erase(itr); lookup->HandleResponse(remote); return true; } void Endpoint::PutSenderFor(const ConvoTag& tag, const ServiceInfo& info) { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) { itr = m_Sessions.insert(std::make_pair(tag, Session{})).first; } itr->second.remote = info; itr->second.lastUsed = llarp_time_now_ms(); } bool Endpoint::GetSenderFor(const ConvoTag& tag, ServiceInfo& si) const { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) return false; si = itr->second.remote; return true; } void Endpoint::PutIntroFor(const ConvoTag& tag, const Introduction& intro) { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) { itr = m_Sessions.insert(std::make_pair(tag, Session{})).first; } itr->second.intro = intro; itr->second.lastUsed = llarp_time_now_ms(); } bool Endpoint::GetIntroFor(const ConvoTag& tag, Introduction& intro) const { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) return false; intro = itr->second.intro; return true; } bool Endpoint::GetConvoTagsForService(const ServiceInfo& info, std::set< ConvoTag >& tags) const { bool inserted = false; auto itr = m_Sessions.begin(); while(itr != m_Sessions.end()) { if(itr->second.remote == info) { inserted |= tags.insert(itr->first).second; } } return inserted; } bool Endpoint::GetCachedSessionKeyFor(const ConvoTag& tag, const byte_t*& secret) const { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) return false; secret = itr->second.sharedKey.data(); return true; } void Endpoint::PutCachedSessionKeyFor(const ConvoTag& tag, const SharedSecret& k) { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) { itr = m_Sessions.insert(std::make_pair(tag, Session{})).first; } itr->second.sharedKey = k; itr->second.lastUsed = llarp_time_now_ms(); } bool Endpoint::Start() { auto crypto = &m_Router->crypto; if(m_Keyfile.size()) { if(!m_Identity.EnsureKeys(m_Keyfile, crypto)) return false; } else { m_Identity.RegenerateKeys(crypto); } if(!m_DataHandler) { m_DataHandler = this; } // this does network isolation while(m_OnInit.size()) { if(m_OnInit.front()()) m_OnInit.pop_front(); else return false; } return true; } Endpoint::~Endpoint() { } bool Endpoint::CachedTagResult::HandleResponse( const std::set< IntroSet >& introsets) { auto now = llarp_time_now_ms(); for(const auto& introset : introsets) if(result.insert(introset).second) lastModified = now; llarp::LogInfo("Tag result for ", tag.ToString(), " got ", introsets.size(), " results from lookup, have ", result.size(), " cached last modified at ", lastModified, " is ", now - lastModified, "ms old"); return true; } void Endpoint::CachedTagResult::Expire(llarp_time_t now) { auto itr = result.begin(); while(itr != result.end()) { if(itr->HasExpiredIntros(now)) { llarp::LogInfo("Removing expired tag Entry ", itr->A.Name()); itr = result.erase(itr); lastModified = now; } else { ++itr; } } } llarp::routing::IMessage* Endpoint::CachedTagResult::BuildRequestMessage(uint64_t txid) { llarp::routing::DHTMessage* msg = new llarp::routing::DHTMessage(); msg->M.push_back(new llarp::dht::FindIntroMessage(tag, txid)); lastRequest = llarp_time_now_ms(); return msg; } bool Endpoint::PublishIntroSet(llarp_router* r) { auto path = GetEstablishedPathClosestTo(m_Identity.pub.Addr().ToRouter()); if(path) { m_CurrentPublishTX = llarp_randint(); llarp::routing::DHTMessage msg; msg.M.push_back(new llarp::dht::PublishIntroMessage( m_IntroSet, m_CurrentPublishTX, 4)); if(path->SendRoutingMessage(&msg, r)) { m_LastPublishAttempt = llarp_time_now_ms(); llarp::LogInfo(Name(), " publishing introset"); return true; } } llarp::LogWarn(Name(), " publish introset failed, no path"); return false; } void Endpoint::IntroSetPublishFail() { llarp::LogWarn("failed to publish introset for ", Name()); m_CurrentPublishTX = 0; } bool Endpoint::ShouldPublishDescriptors(llarp_time_t now) const { if(m_IntroSet.HasExpiredIntros(now)) return m_CurrentPublishTX == 0 && now - m_LastPublishAttempt >= INTROSET_PUBLISH_RETRY_INTERVAL; return m_CurrentPublishTX == 0 && now - m_LastPublish >= INTROSET_PUBLISH_INTERVAL; } void Endpoint::IntroSetPublished() { m_CurrentPublishTX = 0; m_LastPublish = llarp_time_now_ms(); llarp::LogInfo(Name(), " IntroSet publish confirmed"); } struct HiddenServiceAddressLookup : public IServiceLookup { ~HiddenServiceAddressLookup() { } Address remote; typedef std::function< bool(const IntroSet*) > HandlerFunc; HandlerFunc handle; HiddenServiceAddressLookup(Endpoint* p, HandlerFunc h, const Address& addr, uint64_t tx) : IServiceLookup(p, tx, "HSLookup"), remote(addr), handle(h) { } bool HandleResponse(const std::set< IntroSet >& results) { llarp::LogInfo("found ", results.size(), " for ", remote.ToString()); if(results.size() == 1) { llarp::LogInfo("hidden service lookup for ", remote.ToString(), " success"); handle(&*results.begin()); } else { llarp::LogInfo("no response in hidden service lookup for ", remote.ToString()); handle(nullptr); } return false; } llarp::routing::IMessage* BuildRequestMessage() { llarp::routing::DHTMessage* msg = new llarp::routing::DHTMessage(); auto FIM = new llarp::dht::FindIntroMessage(txid, remote); FIM->R = 5; msg->M.push_back(FIM); llarp::LogInfo("build request for ", remote); return msg; } }; bool Endpoint::DoNetworkIsolation(bool failed) { if(failed) return IsolationFailed(); llarp_ev_loop_alloc(&m_IsolatedNetLoop); return SetupNetworking(); } void Endpoint::RunIsolatedMainLoop(void* user) { Endpoint* self = static_cast< Endpoint* >(user); llarp_ev_loop_run_single_process(self->m_IsolatedNetLoop, self->m_IsolatedWorker, self->m_IsolatedLogic); } void Endpoint::PutNewOutboundContext(const llarp::service::IntroSet& introset) { Address addr; introset.A.CalculateAddress(addr.data()); // only add new session if it's not there if(m_RemoteSessions.find(addr) == m_RemoteSessions.end()) { OutboundContext* ctx = new OutboundContext(introset, this); m_RemoteSessions.insert(std::make_pair(addr, ctx)); llarp::LogInfo("Created New outbound context for ", addr.ToString()); } // inform pending auto itr = m_PendingServiceLookups.find(addr); if(itr != m_PendingServiceLookups.end()) { auto f = itr->second; m_PendingServiceLookups.erase(itr); f(m_RemoteSessions.at(addr)); } } bool Endpoint::HandleGotRouterMessage(const llarp::dht::GotRouterMessage* msg) { bool success = false; if(msg->R.size() == 1) { auto itr = m_PendingRouters.find(msg->R[0].pubkey); if(itr == m_PendingRouters.end()) return false; llarp_async_verify_rc* job = new llarp_async_verify_rc; job->nodedb = m_Router->nodedb; job->cryptoworker = m_Router->tp; job->diskworker = m_Router->disk; job->logic = nullptr; job->hook = nullptr; llarp_rc_clear(&job->rc); llarp_rc_copy(&job->rc, &msg->R[0]); llarp_nodedb_async_verify(job); return true; } return success; } void Endpoint::EnsureRouterIsKnown(const RouterID& router) { if(router.IsZero()) return; if(!llarp_nodedb_get_rc(m_Router->nodedb, router)) { if(m_PendingRouters.find(router) == m_PendingRouters.end()) { auto path = GetEstablishedPathClosestTo(router); routing::DHTMessage msg; auto txid = GenTXID(); msg.M.push_back( new dht::FindRouterMessage({}, dht::Key_t(router), txid)); if(path && path->SendRoutingMessage(&msg, m_Router)) { llarp::LogInfo(Name(), " looking up ", router); m_PendingRouters.insert( std::make_pair(router, RouterLookupJob(this))); } else { llarp::LogError("failed to send request for router lookup"); } } } } void Endpoint::HandlePathBuilt(path::Path* p) { p->SetDataHandler(std::bind(&Endpoint::HandleHiddenServiceFrame, this, std::placeholders::_1)); } bool Endpoint::HandleHiddenServiceFrame(const ProtocolFrame* frame) { return frame->AsyncDecryptAndVerify(EndpointLogic(), Crypto(), Worker(), m_Identity, m_DataHandler); } void Endpoint::OutboundContext::HandlePathBuilt(path::Path* p) { p->SetDataHandler( std::bind(&Endpoint::OutboundContext::HandleHiddenServiceFrame, this, std::placeholders::_1)); } bool Endpoint::OutboundContext::HandleHiddenServiceFrame( const ProtocolFrame* frame) { return m_Parent->HandleHiddenServiceFrame(frame); } bool Endpoint::OnOutboundLookup(const IntroSet* introset) { if(!introset) return false; PutNewOutboundContext(*introset); return true; } bool Endpoint::EnsurePathToService(const Address& remote, PathEnsureHook hook, llarp_time_t timeoutMS) { auto path = GetEstablishedPathClosestTo(remote.ToRouter()); if(!path) { llarp::LogWarn("No outbound path for lookup yet"); return false; } llarp::LogInfo(Name(), " Ensure Path to ", remote.ToString()); { auto itr = m_RemoteSessions.find(remote); if(itr != m_RemoteSessions.end()) { hook(itr->second); return true; } } auto itr = m_PendingServiceLookups.find(remote); if(itr != m_PendingServiceLookups.end()) { // duplicate llarp::LogWarn("duplicate pending service lookup to ", remote.ToString()); return false; } m_PendingServiceLookups.insert(std::make_pair(remote, hook)); HiddenServiceAddressLookup* job = new HiddenServiceAddressLookup( this, std::bind(&Endpoint::OnOutboundLookup, this, std::placeholders::_1), remote, GenTXID()); if(job->SendRequestViaPath(path, Router())) return true; llarp::LogError("send via path failed"); return false; } Endpoint::OutboundContext::OutboundContext(const IntroSet& intro, Endpoint* parent) : llarp_pathbuilder_context(parent->m_Router, parent->m_Router->dht, 2, 4) , currentIntroSet(intro) , m_Parent(parent) { selectedIntro.Clear(); ShiftIntroduction(); } Endpoint::OutboundContext::~OutboundContext() { } bool Endpoint::OutboundContext::OnIntroSetUpdate(const IntroSet* i) { if(i && i->IsNewerThan(currentIntroSet)) { currentIntroSet = *i; } return true; } void Endpoint::OutboundContext::ShiftIntroduction() { for(const auto& intro : currentIntroSet.I) { m_Parent->EnsureRouterIsKnown(selectedIntro.router); if(intro.expiresAt > selectedIntro.expiresAt) { selectedIntro = intro; } } ManualRebuild(2); } void Endpoint::OutboundContext::AsyncEncryptAndSendTo(llarp_buffer_t data, ProtocolType protocol) { auto path = GetPathByRouter(selectedIntro.router); if(!path) { llarp::LogError("No Path to ", selectedIntro.router, " yet"); return; } if(sequenceNo) { EncryptAndSendTo(path, data, protocol); } else { AsyncGenIntro(path, data, protocol); } } struct AsyncIntroGen { llarp_logic* logic; llarp_crypto* crypto; byte_t* sharedKey; ServiceInfo remote; const Identity& m_LocalIdentity; ProtocolMessage msg; ProtocolFrame frame; Introduction intro; const PQPubKey introPubKey; std::function< void(ProtocolFrame&) > hook; IDataHandler* handler; AsyncIntroGen(llarp_logic* l, llarp_crypto* c, byte_t* key, const ServiceInfo& r, const Identity& localident, const PQPubKey& introsetPubKey, const Introduction& us, IDataHandler* h) : logic(l) , crypto(c) , sharedKey(key) , remote(r) , m_LocalIdentity(localident) , intro(us) , introPubKey(introsetPubKey) , handler(h) { } static void Result(void* user) { AsyncIntroGen* self = static_cast< AsyncIntroGen* >(user); // put values self->handler->PutCachedSessionKeyFor(self->msg.tag, self->sharedKey); self->handler->PutIntroFor(self->msg.tag, self->msg.introReply); self->handler->PutSenderFor(self->msg.tag, self->remote); self->hook(self->frame); delete self; } static void Work(void* user) { AsyncIntroGen* self = static_cast< AsyncIntroGen* >(user); // derive ntru session key component SharedSecret K; self->crypto->pqe_encrypt(self->frame.C, K, self->introPubKey); // randomize Nounce self->frame.N.Randomize(); // compure post handshake session key byte_t tmp[64]; // K memcpy(tmp, K, 32); // PKE (A, B, N) if(!self->m_LocalIdentity.KeyExchange(self->crypto->dh_client, tmp + 32, self->remote, self->frame.N)) llarp::LogError("failed to derive x25519 shared key component"); // H (K + PKE(A, B, N)) self->crypto->shorthash(self->sharedKey, llarp::StackBuffer< decltype(tmp) >(tmp)); // randomize tag self->msg.tag.Randomize(); // set sender self->msg.sender = self->m_LocalIdentity.pub; // set our introduction self->msg.introReply = self->intro; // encrypt and sign if(self->frame.EncryptAndSign(self->crypto, self->msg, K, self->m_LocalIdentity)) llarp_logic_queue_job(self->logic, {self, &Result}); else llarp::LogError("failed to encrypt and sign"); } }; void Endpoint::OutboundContext::AsyncGenIntro(path::Path* p, llarp_buffer_t payload, ProtocolType t) { AsyncIntroGen* ex = new AsyncIntroGen( m_Parent->RouterLogic(), m_Parent->Crypto(), sharedKey, currentIntroSet.A, m_Parent->GetIdentity(), currentIntroSet.K, selectedIntro, m_Parent->m_DataHandler); ex->hook = std::bind(&Endpoint::OutboundContext::Send, this, std::placeholders::_1); ex->msg.PutBuffer(payload); ex->msg.introReply = p->intro; llarp_threadpool_queue_job(m_Parent->Worker(), {ex, &AsyncIntroGen::Work}); } void Endpoint::OutboundContext::Send(ProtocolFrame& msg) { // in this context we assume the message contents are encrypted auto now = llarp_time_now_ms(); if(currentIntroSet.HasExpiredIntros(now)) { UpdateIntroSet(); } if(selectedIntro.expiresAt <= now || now - selectedIntro.expiresAt > 1000) { ShiftIntroduction(); } // XXX: this may be a different path that that was put into the protocol // message inside the protocol frame auto path = GetPathByRouter(selectedIntro.router); if(path) { routing::PathTransferMessage transfer(msg, selectedIntro.pathID); llarp::LogDebug("sending frame via ", path->Upstream(), " to ", path->Endpoint(), " for ", Name()); if(!path->SendRoutingMessage(&transfer, m_Parent->Router())) llarp::LogError("Failed to send frame on path"); } else { llarp::LogWarn("No path to ", selectedIntro.router); } } std::string Endpoint::OutboundContext::Name() const { return "OBContext:" + m_Parent->Name() + "-" + currentIntroSet.A.Addr().ToString(); } void Endpoint::OutboundContext::UpdateIntroSet() { auto addr = currentIntroSet.A.Addr(); auto path = m_Parent->GetEstablishedPathClosestTo(addr.ToRouter()); if(path) { HiddenServiceAddressLookup* job = new HiddenServiceAddressLookup( m_Parent, std::bind(&Endpoint::OutboundContext::OnIntroSetUpdate, this, std::placeholders::_1), addr, m_Parent->GenTXID()); if(!job->SendRequestViaPath(path, m_Parent->Router())) llarp::LogError("send via path failed"); } else { llarp::LogWarn( "Cannot update introset no path for outbound session to ", currentIntroSet.A.Addr().ToString()); } } bool Endpoint::OutboundContext::Tick(llarp_time_t now) { if(selectedIntro.expiresAt >= now || selectedIntro.expiresAt - now < 30000) { UpdateIntroSet(); } m_Parent->EnsureRouterIsKnown(selectedIntro.router); // TODO: check for expiration of outbound context return false; } bool Endpoint::OutboundContext::SelectHop(llarp_nodedb* db, llarp_rc* prev, llarp_rc* cur, size_t hop) { if(hop == numHops - 1) { auto localcopy = llarp_nodedb_get_rc(db, selectedIntro.router); if(localcopy) { llarp_rc_copy(cur, localcopy); return true; } else { // we don't have it? llarp::LogError( "cannot build aligned path, don't have router for " "introduction ", selectedIntro); m_Parent->EnsureRouterIsKnown(selectedIntro.router); return false; } } else return llarp_pathbuilder_context::SelectHop(db, prev, cur, hop); } uint64_t Endpoint::GetSeqNoForConvo(const ConvoTag& tag) { auto itr = m_Sessions.find(tag); if(itr == m_Sessions.end()) return 0; return ++(itr->second.seqno); } void Endpoint::OutboundContext::EncryptAndSendTo(path::Path* p, llarp_buffer_t payload, ProtocolType t) { auto path = GetPathByRouter(selectedIntro.router); if(path) { std::set< ConvoTag > tags; if(!m_Parent->m_DataHandler->GetConvoTagsForService(currentIntroSet.A, tags)) { llarp::LogError("no open converstations with remote endpoint?"); return; } auto crypto = m_Parent->Crypto(); const byte_t* shared = nullptr; routing::PathTransferMessage msg; ProtocolFrame& f = msg.T; f.N.Randomize(); f.T = *tags.begin(); f.S = m_Parent->GetSeqNoForConvo(f.T); if(m_Parent->m_DataHandler->GetCachedSessionKeyFor(f.T, shared)) { ProtocolMessage m; m.proto = t; m.introReply = path->intro; m.sender = m_Parent->m_Identity.pub; m.PutBuffer(payload); if(!f.EncryptAndSign(crypto, m, shared, m_Parent->m_Identity)) { llarp::LogError("failed to sign"); return; } } else { llarp::LogError("No cached session key"); return; } msg.P = selectedIntro.pathID; msg.Y.Randomize(); if(!path->SendRoutingMessage(&msg, m_Parent->Router())) { llarp::LogWarn("Failed to send routing message for data"); } } else { llarp::LogError("no outbound path for sending message"); } } llarp_logic* Endpoint::RouterLogic() { return m_Router->logic; } llarp_logic* Endpoint::EndpointLogic() { return m_IsolatedLogic ? m_IsolatedLogic : m_Router->logic; } llarp_crypto* Endpoint::Crypto() { return &m_Router->crypto; } llarp_threadpool* Endpoint::Worker() { return m_Router->tp; } } // namespace service } // namespace llarp