#include #include #include #include "buffer.hpp" #include "router.hpp" namespace llarp { namespace path { TransitHop::TransitHop() { } bool TransitHop::Expired(llarp_time_t now) const { return now > ExpireTime(); } llarp_time_t TransitHop::ExpireTime() const { return started + lifetime; } TransitHopInfo::TransitHopInfo(const TransitHopInfo& other) : txID(other.txID) , rxID(other.rxID) , upstream(other.upstream) , downstream(other.downstream) { } TransitHopInfo::TransitHopInfo(const RouterID& down, const LR_CommitRecord& record) : txID(record.txid) , rxID(record.rxid) , upstream(record.nextHop) , downstream(down) { } TransitHop::TransitHop(const TransitHop& other) : info(other.info) , pathKey(other.pathKey) , started(other.started) , lifetime(other.lifetime) , version(other.version) { } bool TransitHop::SendRoutingMessage(const llarp::routing::IMessage* msg, llarp_router* r) { if(!IsEndpoint(r->pubkey())) return false; byte_t tmp[MAX_LINK_MSG_SIZE - 128]; auto buf = llarp::StackBuffer< decltype(tmp) >(tmp); if(!msg->BEncode(&buf)) { llarp::LogError("failed to encode routing message"); return false; } TunnelNonce N; N.Randomize(); buf.sz = buf.cur - buf.base; // pad to nearest MESSAGE_PAD_SIZE bytes auto dlt = buf.sz % MESSAGE_PAD_SIZE; if(dlt) { dlt = MESSAGE_PAD_SIZE - dlt; // randomize padding r->crypto.randbytes(buf.cur, dlt); buf.sz += dlt; } buf.cur = buf.base; return HandleDownstream(buf, N, r); } bool TransitHop::HandleDownstream(llarp_buffer_t buf, const TunnelNonce& Y, llarp_router* r) { RelayDownstreamMessage msg; msg.pathid = info.rxID; msg.Y = Y ^ nonceXOR; r->crypto.xchacha20(buf, pathKey, Y); msg.X = buf; llarp::LogDebug("relay ", msg.X.size(), " bytes downstream from ", info.upstream, " to ", info.downstream); return r->SendToOrQueue(info.downstream, &msg); } bool TransitHop::HandleUpstream(llarp_buffer_t buf, const TunnelNonce& Y, llarp_router* r) { r->crypto.xchacha20(buf, pathKey, Y); if(IsEndpoint(r->pubkey())) { return m_MessageParser.ParseMessageBuffer(buf, this, info.rxID, r); } else { RelayUpstreamMessage msg; msg.pathid = info.txID; msg.Y = Y ^ nonceXOR; msg.X = buf; llarp::LogDebug("relay ", msg.X.size(), " bytes upstream from ", info.downstream, " to ", info.upstream); return r->SendToOrQueue(info.upstream, &msg); } } bool TransitHop::HandleDHTMessage(const llarp::dht::IMessage* msg, llarp_router* r) { return r->dht->impl.RelayRequestForPath(info.rxID, msg); } bool TransitHop::HandlePathLatencyMessage( const llarp::routing::PathLatencyMessage* msg, llarp_router* r) { llarp::routing::PathLatencyMessage reply; reply.L = msg->T; return SendRoutingMessage(&reply, r); } bool TransitHop::HandlePathConfirmMessage( __attribute__((unused)) const llarp::routing::PathConfirmMessage* msg, __attribute__((unused)) llarp_router* r) { llarp::LogWarn("unwarranted path confirm message on ", info); return false; } bool TransitHop::HandleDataDiscardMessage( __attribute__((unused)) const llarp::routing::DataDiscardMessage* msg, __attribute__((unused)) llarp_router* r) { llarp::LogWarn("unwarranted path data discard message on ", info); return false; } bool TransitHop::HandleObtainExitMessage( const llarp::routing::ObtainExitMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandleCloseExitMessage( const llarp::routing::CloseExitMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandleUpdateExitMessage( const llarp::routing::UpdateExitMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandleRejectExitMessage( const llarp::routing::RejectExitMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandleGrantExitMessage( const llarp::routing::GrantExitMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandleTransferTrafficMessage( const llarp::routing::TransferTrafficMessage* msg, llarp_router* r) { // TODO: implement me (void)msg; (void)r; return false; } bool TransitHop::HandlePathTransferMessage( const llarp::routing::PathTransferMessage* msg, llarp_router* r) { auto path = r->paths.GetPathForTransfer(msg->P); if(!path) { llarp::routing::DataDiscardMessage discarded(msg->P, msg->S); path = r->paths.GetPathForTransfer(msg->from); return path && path->SendRoutingMessage(&discarded, r); } byte_t tmp[service::MAX_PROTOCOL_MESSAGE_SIZE]; auto buf = llarp::StackBuffer< decltype(tmp) >(tmp); if(!msg->T.BEncode(&buf)) { llarp::LogWarn("failed to transfer data message, encode failed"); return false; } // rewind0 buf.sz = buf.cur - buf.base; buf.cur = buf.base; // send return path->HandleDownstream(buf, msg->Y, r); } } // namespace path } // namespace llarp