lokinet/llarp/path/path.cpp

#include <path/path.hpp>

#include <messages/dht.hpp>
#include <messages/discard.hpp>
#include <messages/exit.hpp>
#include <messages/path_latency.hpp>
#include <messages/relay_commit.hpp>
#include <messages/transfer_traffic.hpp>
#include <path/pathbuilder.hpp>
#include <profiling.hpp>
#include <router/abstractrouter.hpp>
#include <util/buffer.hpp>
#include <util/endian.hpp>

#include <deque>

namespace llarp
{
  namespace path
  {
    std::ostream&
    TransitHopInfo::print(std::ostream& stream, int level, int spaces) const
    {
      Printer printer(stream, level, spaces);
      printer.printAttribute("tx", txID);
      printer.printAttribute("rx", rxID);
      printer.printAttribute("upstream", upstream);
      printer.printAttribute("downstream", downstream);

      return stream;
    }

    PathContext::PathContext(AbstractRouter* router)
        : m_Router(router), m_AllowTransit(false)
    {
    }

    PathContext::~PathContext()
    {
    }

    void
    PathContext::AllowTransit()
    {
      m_AllowTransit = true;
    }

    bool
    PathContext::AllowingTransit() const
    {
      return m_AllowTransit;
    }

    llarp_threadpool*
    PathContext::Worker()
    {
      return m_Router->threadpool();
    }

    Crypto*
    PathContext::Crypto()
    {
      return m_Router->crypto();
    }

    Logic*
    PathContext::Logic()
    {
      return m_Router->logic();
    }

    const SecretKey&
    PathContext::EncryptionSecretKey()
    {
      return m_Router->encryption();
    }

    bool
    PathContext::HopIsUs(const RouterID& k) const
    {
      return std::equal(m_Router->pubkey(), m_Router->pubkey() + PUBKEYSIZE,
                        k.begin());
    }

    bool
    PathContext::ForwardLRCM(const RouterID& nextHop,
                             const std::array< EncryptedFrame, 8 >& frames)
    {
      LogDebug("forwarding LRCM to ", nextHop);
      LR_CommitMessage msg;
      msg.frames = frames;
      return m_Router->SendToOrQueue(nextHop, &msg);
    }
    template < typename Map_t, typename Key_t, typename CheckValue_t,
               typename GetFunc_t >
    IHopHandler*
    MapGet(Map_t& map, const Key_t& k, CheckValue_t check, GetFunc_t get)
    {
      util::Lock lock(&map.first);
      auto range = map.second.equal_range(k);
      for(auto i = range.first; i != range.second; ++i)
      {
        if(check(i->second))
          return get(i->second);
      }
      return nullptr;
    }

    template < typename Map_t, typename Key_t, typename CheckValue_t >
    bool
    MapHas(Map_t& map, const Key_t& k, CheckValue_t check)
    {
      util::Lock lock(&map.first);
      auto range = map.second.equal_range(k);
      for(auto i = range.first; i != range.second; ++i)
      {
        if(check(i->second))
          return true;
      }
      return false;
    }

    template < typename Map_t, typename Key_t, typename Value_t >
    void
    MapPut(Map_t& map, const Key_t& k, const Value_t& v)
    {
      util::Lock lock(&map.first);
      map.second.emplace(k, v);
    }

    template < typename Map_t, typename Visit_t >
    void
    MapIter(Map_t& map, Visit_t v)
    {
      util::Lock lock(map.first);
      for(const auto& item : map.second)
        v(item);
    }

    template < typename Map_t, typename Key_t, typename Check_t >
    void
    MapDel(Map_t& map, const Key_t& k, Check_t check)
    {
      util::Lock lock(map.first);
      auto range = map.second.equal_range(k);
      for(auto i = range.first; i != range.second;)
      {
        if(check(i->second))
          i = map.second.erase(i);
        else
          ++i;
      }
    }

    void
    PathContext::AddOwnPath(PathSet* set, Path* path)
    {
      set->AddPath(path);
      MapPut(m_OurPaths, path->TXID(), set);
      MapPut(m_OurPaths, path->RXID(), set);
    }

    bool
    PathContext::HasTransitHop(const TransitHopInfo& info)
    {
      return MapHas(m_TransitPaths, info.txID,
                    [info](const std::shared_ptr< TransitHop >& hop) -> bool {
                      return info == hop->info;
                    });
    }

    IHopHandler*
    PathContext::GetByUpstream(const RouterID& remote, const PathID_t& id)
    {
      auto own = MapGet(m_OurPaths, id,
                        [](__attribute__((unused)) const PathSet* s) -> bool {
                          // TODO: is this right?
                          return true;
                        },
                        [remote, id](PathSet* p) -> IHopHandler* {
                          return p->GetByUpstream(remote, id);
                        });
      if(own)
        return own;

      return MapGet(m_TransitPaths, id,
                    [remote](const std::shared_ptr< TransitHop >& hop) -> bool {
                      return hop->info.upstream == remote;
                    },
                    [](const std::shared_ptr< TransitHop >& h) -> IHopHandler* {
                      return h.get();
                    });
    }

    bool
    PathContext::TransitHopPreviousIsRouter(const PathID_t& path,
                                            const RouterID& otherRouter)
    {
      util::Lock lock(&m_TransitPaths.first);
      auto itr = m_TransitPaths.second.find(path);
      if(itr == m_TransitPaths.second.end())
        return false;
      return itr->second->info.downstream == otherRouter;
    }

    IHopHandler*
    PathContext::GetByDownstream(const RouterID& remote, const PathID_t& id)
    {
      return MapGet(m_TransitPaths, id,
                    [remote](const std::shared_ptr< TransitHop >& hop) -> bool {
                      return hop->info.downstream == remote;
                    },
                    [](const std::shared_ptr< TransitHop >& h) -> IHopHandler* {
                      return h.get();
                    });
    }

    PathSet*
    PathContext::GetLocalPathSet(const PathID_t& id)
    {
      auto& map = m_OurPaths;
      util::Lock lock(&map.first);
      auto itr = map.second.find(id);
      if(itr != map.second.end())
      {
        return itr->second;
      }
      return nullptr;
    }

    const byte_t*
    PathContext::OurRouterID() const
    {
      return m_Router->pubkey();
    }

    AbstractRouter*
    PathContext::Router()
    {
      return m_Router;
    }

    IHopHandler*
    PathContext::GetPathForTransfer(const PathID_t& id)
    {
      RouterID us(OurRouterID());
      auto& map = m_TransitPaths;
      {
        util::Lock lock(&map.first);
        auto range = map.second.equal_range(id);
        for(auto i = range.first; i != range.second; ++i)
        {
          if(i->second->info.upstream == us)
            return i->second.get();
        }
      }
      return nullptr;
    }

    void
    PathContext::PutTransitHop(std::shared_ptr< TransitHop > hop)
    {
      MapPut(m_TransitPaths, hop->info.txID, hop);
      MapPut(m_TransitPaths, hop->info.rxID, hop);
    }

    void
    PathContext::ExpirePaths(llarp_time_t now)
    {
      util::Lock lock(&m_TransitPaths.first);
      auto& map = m_TransitPaths.second;
      auto itr  = map.begin();
      while(itr != map.end())
      {
        if(itr->second->Expired(now))
        {
          itr = map.erase(itr);
        }
        else
          ++itr;
      }

      for(auto& builder : m_PathBuilders)
      {
        if(builder)
          builder->ExpirePaths(now);
      }
    }

    void
    PathContext::BuildPaths(llarp_time_t now)
    {
      for(auto& builder : m_PathBuilders)
      {
        if(builder->ShouldBuildMore(now))
        {
          builder->BuildOne();
        }
      }
    }

    void
    PathContext::TickPaths(llarp_time_t now)
    {
      for(auto& builder : m_PathBuilders)
        builder->Tick(now, m_Router);
    }

    routing::IMessageHandler*
    PathContext::GetHandler(const PathID_t& id)
    {
      routing::IMessageHandler* h = nullptr;
      auto pathset                = GetLocalPathSet(id);
      if(pathset)
      {
        h = pathset->GetPathByID(id);
      }
      if(h)
        return h;
      RouterID us(OurRouterID());
      auto& map = m_TransitPaths;
      {
        util::Lock lock(&map.first);
        auto range = map.second.equal_range(id);
        for(auto i = range.first; i != range.second; ++i)
        {
          if(i->second->info.upstream == us)
            return i->second.get();
        }
      }
      return nullptr;
    }

    void
    PathContext::AddPathBuilder(Builder* ctx)
    {
      m_PathBuilders.push_back(ctx);
    }

    void
    PathContext::RemovePathSet(PathSet* set)
    {
      util::Lock lock(&m_OurPaths.first);
      auto& map = m_OurPaths.second;
      auto itr  = map.begin();
      while(itr != map.end())
      {
        if(itr->second == set)
          itr = map.erase(itr);
        else
          ++itr;
      }
    }

    void
    PathContext::RemovePathBuilder(Builder* ctx)
    {
      m_PathBuilders.remove(ctx);
      RemovePathSet(ctx);
    }

    std::ostream&
    TransitHop::print(std::ostream& stream, int level, int spaces) const
    {
      Printer printer(stream, level, spaces);
      printer.printAttribute("TransitHop", info);
      printer.printAttribute("started", started);
      printer.printAttribute("lifetime", lifetime);

      return stream;
    }

    PathHopConfig::PathHopConfig()
    {
    }

    PathHopConfig::~PathHopConfig()
    {
    }

    Path::Path(const std::vector< RouterContact >& h, PathSet* parent,
               PathRole startingRoles)
        : m_PathSet(parent), _role(startingRoles)
    {
      hops.resize(h.size());
      size_t hsz = h.size();
      for(size_t idx = 0; idx < hsz; ++idx)
      {
        hops[idx].rc = h[idx];
        hops[idx].txID.Randomize();
        hops[idx].rxID.Randomize();
      }

      for(size_t idx = 0; idx < hsz - 1; ++idx)
      {
        hops[idx].txID = hops[idx + 1].rxID;
      }
      // initialize parts of the introduction
      intro.router = hops[hsz - 1].rc.pubkey;
      intro.pathID = hops[hsz - 1].txID;
      EnterState(ePathBuilding, parent->Now());
    }

    void
    Path::SetBuildResultHook(BuildResultHookFunc func)
    {
      m_BuiltHook = func;
    }

    RouterID
    Path::Endpoint() const
    {
      return hops[hops.size() - 1].rc.pubkey;
    }

    PubKey
    Path::EndpointPubKey() const
    {
      return hops[hops.size() - 1].rc.pubkey;
    }

    PathID_t
    Path::TXID() const
    {
      return hops[0].txID;
    }

    PathID_t
    Path::RXID() const
    {
      return hops[0].rxID;
    }

    bool
    Path::IsReady() const
    {
      return intro.latency > 0 && _status == ePathEstablished;
    }

    bool
    Path::IsEndpoint(const RouterID& r, const PathID_t& id) const
    {
      return hops[hops.size() - 1].rc.pubkey == r
          && hops[hops.size() - 1].txID == id;
    }

    RouterID
    Path::Upstream() const
    {
      return hops[0].rc.pubkey;
    }

    std::string
    Path::HopsString() const
    {
      std::stringstream ss;
      for(const auto& hop : hops)
        ss << RouterID(hop.rc.pubkey) << " -> ";
      return ss.str();
    }

    void
    Path::EnterState(PathStatus st, llarp_time_t now)
    {
      if(st == ePathTimeout)
      {
        m_PathSet->HandlePathBuildTimeout(this);
      }
      else if(st == ePathBuilding)
      {
        LogInfo("path ", Name(), " is building");
        buildStarted = now;
      }
      else if(st == ePathEstablished && _status == ePathBuilding)
      {
        LogInfo("path ", Name(), " is built, took ", now - buildStarted, " ms");
      }
      _status = st;
    }

    util::StatusObject
    PathHopConfig::ExtractStatus() const
    {
      util::StatusObject obj{{"lifetime", lifetime},
                             {"router", rc.pubkey.ToHex()},
                             {"txid", txID.ToHex()},
                             {"rxid", rxID.ToHex()}};
      return obj;
    }

    util::StatusObject
    Path::ExtractStatus() const
    {
      auto now = llarp::time_now_ms();

      util::StatusObject obj{{"intro", intro.ExtractStatus()},
                             {"lastRecvMsg", m_LastRecvMessage},
                             {"lastLatencyTest", m_LastLatencyTestTime},
                             {"buildStarted", buildStarted},
                             {"expired", Expired(now)},
                             {"expiresSoon", ExpiresSoon(now)},
                             {"expiresAt", ExpireTime()},
                             {"ready", IsReady()},
                             {"hasExit", SupportsAnyRoles(ePathRoleExit)}};

      std::vector< util::StatusObject > hopsObj;
      std::transform(hops.begin(), hops.end(), std::back_inserter(hopsObj),
                     [](const auto& hop) -> util::StatusObject {
                       return hop.ExtractStatus();
                     });
      obj.Put("hops", hopsObj);

      switch(_status)
      {
        case ePathBuilding:
          obj.Put("status", "building");
          break;
        case ePathEstablished:
          obj.Put("status", "established");
          break;
        case ePathTimeout:
          obj.Put("status", "timeout");
          break;
        case ePathExpired:
          obj.Put("status", "expired");
          break;
        default:
          obj.Put("status", "unknown");
          break;
      }
      return obj;
    }

    void
    Path::Tick(llarp_time_t now, AbstractRouter* r)
    {
      if(Expired(now))
        return;

      if(_status == ePathBuilding)
      {
        if(now >= buildStarted)
        {
          auto dlt = now - buildStarted;
          if(dlt >= PATH_BUILD_TIMEOUT)
          {
            r->routerProfiling().MarkPathFail(this);
            EnterState(ePathTimeout, now);
            return;
          }
        }
      }

      // check to see if this path is dead
      if(_status == ePathEstablished)
      {
        auto dlt = now - m_LastLatencyTestTime;
        if(dlt > 5000 && m_LastLatencyTestID == 0)
        {
          routing::PathLatencyMessage latency;
          latency.T             = randint();
          m_LastLatencyTestID   = latency.T;
          m_LastLatencyTestTime = now;
          SendRoutingMessage(&latency, r);
          return;
        }
        if(SupportsAnyRoles(ePathRoleExit | ePathRoleSVC))
        {
          if(m_LastRecvMessage && now > m_LastRecvMessage
             && now - m_LastRecvMessage > PATH_ALIVE_TIMEOUT)
          {
            // TODO: send close exit message
            // r->routerProfiling().MarkPathFail(this);
            // EnterState(ePathTimeout, now);
            return;
          }
        }
        if(m_LastRecvMessage && now > m_LastRecvMessage
           && now - m_LastRecvMessage > PATH_ALIVE_TIMEOUT)
        {
          if(m_CheckForDead)
          {
            if(m_CheckForDead(this, dlt))
            {
              r->routerProfiling().MarkPathFail(this);
              EnterState(ePathTimeout, now);
            }
          }
          else
          {
            r->routerProfiling().MarkPathFail(this);
            EnterState(ePathTimeout, now);
          }
        }
        else if(dlt >= PATH_ALIVE_TIMEOUT && m_LastRecvMessage == 0)
        {
          r->routerProfiling().MarkPathFail(this);
          EnterState(ePathTimeout, now);
        }
      }
    }

    bool
    Path::HandleUpstream(const llarp_buffer_t& buf, const TunnelNonce& Y,
                         AbstractRouter* r)
    {
      TunnelNonce n = Y;
      for(const auto& hop : hops)
      {
        r->crypto()->xchacha20(buf, hop.shared, n);
        n ^= hop.nonceXOR;
      }
      RelayUpstreamMessage msg;
      msg.X      = buf;
      msg.Y      = Y;
      msg.pathid = TXID();
      if(r->SendToOrQueue(Upstream(), &msg))
        return true;
      LogError("send to ", Upstream(), " failed");
      return false;
    }

    bool
    Path::Expired(llarp_time_t now) const
    {
      if(_status == ePathEstablished)
        return now >= ExpireTime();
      else if(_status == ePathBuilding)
        return false;
      else
        return true;
    }

    std::string
    Path::Name() const
    {
      std::stringstream ss;
      ss << "TX=" << TXID() << " RX=" << RXID();
      if(m_PathSet)
        ss << " on " << m_PathSet->Name();
      return ss.str();
    }

    bool
    Path::HandleDownstream(const llarp_buffer_t& buf, const TunnelNonce& Y,
                           AbstractRouter* r)
    {
      TunnelNonce n = Y;
      for(const auto& hop : hops)
      {
        n ^= hop.nonceXOR;
        r->crypto()->xchacha20(buf, hop.shared, n);
      }
      if(!HandleRoutingMessage(buf, r))
        return false;
      m_LastRecvMessage = r->Now();
      return true;
    }

    bool
    Path::HandleRoutingMessage(const llarp_buffer_t& buf, AbstractRouter* r)
    {
      if(!r->ParseRoutingMessageBuffer(buf, this, RXID()))
      {
        LogWarn("Failed to parse inbound routing message");
        return false;
      }
      return true;
    }

    bool
    Path::HandleUpdateExitVerifyMessage(
        const routing::UpdateExitVerifyMessage* msg, AbstractRouter* r)
    {
      (void)r;
      if(m_UpdateExitTX && msg->T == m_UpdateExitTX)
      {
        if(m_ExitUpdated)
          return m_ExitUpdated(this);
      }
      if(m_CloseExitTX && msg->T == m_CloseExitTX)
      {
        if(m_ExitClosed)
          return m_ExitClosed(this);
      }
      return false;
    }

    bool
    Path::SendRoutingMessage(const routing::IMessage* msg, AbstractRouter* r)
    {
      std::array< byte_t, MAX_LINK_MSG_SIZE / 2 > tmp;
      llarp_buffer_t buf(tmp);
      // should help prevent bad paths with uninitialized members
      // FIXME: Why would we get uninitialized IMessages?
      if(msg->version != LLARP_PROTO_VERSION)
        return false;
      if(!msg->BEncode(&buf))
      {
        LogError("Bencode failed");
        DumpBuffer(buf);
        return false;
      }
      // make nonce
      TunnelNonce N;
      N.Randomize();
      buf.sz = buf.cur - buf.base;
      // pad smaller messages
      if(buf.sz < MESSAGE_PAD_SIZE)
      {
        // randomize padding
        r->crypto()->randbytes(buf.cur, MESSAGE_PAD_SIZE - buf.sz);
        buf.sz = MESSAGE_PAD_SIZE;
      }
      buf.cur = buf.base;
      return HandleUpstream(buf, N, r);
    }

    bool
    Path::HandlePathTransferMessage(__attribute__((unused))
                                    const routing::PathTransferMessage* msg,
                                    __attribute__((unused)) AbstractRouter* r)
    {
      LogWarn("unwarranted path transfer message on tx=", TXID(),
              " rx=", RXID());
      return false;
    }

    bool
    Path::HandleDataDiscardMessage(const routing::DataDiscardMessage* msg,
                                   AbstractRouter* r)
    {
      MarkActive(r->Now());
      if(m_DropHandler)
        return m_DropHandler(this, msg->P, msg->S);
      return true;
    }

    bool
    Path::HandlePathConfirmMessage(__attribute__((unused))
                                   const routing::PathConfirmMessage* msg,
                                   AbstractRouter* r)
    {
      auto now = r->Now();
      if(_status == ePathBuilding)
      {
        // finish initializing introduction
        intro.expiresAt = buildStarted + hops[0].lifetime;

        r->routerProfiling().MarkPathSuccess(this);

        // persist session with upstream router until the path is done
        r->PersistSessionUntil(Upstream(), intro.expiresAt);
        MarkActive(now);
        // send path latency test
        routing::PathLatencyMessage latency;
        latency.T             = randint();
        m_LastLatencyTestID   = latency.T;
        m_LastLatencyTestTime = now;
        return SendRoutingMessage(&latency, r);
      }
      LogWarn("got unwarranted path confirm message on tx=", RXID(),
              " rx=", RXID());
      return false;
    }

    bool
    Path::HandleHiddenServiceFrame(const service::ProtocolFrame* frame)
    {
      MarkActive(m_PathSet->Now());
      return m_DataHandler && m_DataHandler(this, frame);
    }

    bool
    Path::HandlePathLatencyMessage(const routing::PathLatencyMessage* msg,
                                   AbstractRouter* r)
    {
      auto now = r->Now();
      MarkActive(now);
      if(msg->L == m_LastLatencyTestID)
      {
        intro.latency       = now - m_LastLatencyTestTime;
        m_LastLatencyTestID = 0;
        EnterState(ePathEstablished, now);
        if(m_BuiltHook)
          m_BuiltHook(this);
        m_BuiltHook = nullptr;
        LogDebug("path latency is now ", intro.latency, " for ", Name());
        return true;
      }
      else
      {
        LogWarn("unwarranted path latency message via ", Upstream());
        return false;
      }
    }

    bool
    Path::HandleDHTMessage(const dht::IMessage* msg, AbstractRouter* r)
    {
      MarkActive(r->Now());
      routing::DHTMessage reply;
      if(!msg->HandleMessage(r->dht(), reply.M))
        return false;
      if(reply.M.size())
        return SendRoutingMessage(&reply, r);
      return true;
    }

    bool
    Path::HandleCloseExitMessage(const routing::CloseExitMessage* msg,
                                 AbstractRouter* r)
    {
      /// allows exits to close from their end
      if(SupportsAnyRoles(ePathRoleExit | ePathRoleSVC))
      {
        if(msg->Verify(r->crypto(), EndpointPubKey()))
        {
          LogInfo(Name(), " had its exit closed");
          _role &= ~ePathRoleExit;
          return true;
        }
        else
          LogError(Name(), " CXM from exit with bad signature");
      }
      else
        LogError(Name(), " unwarranted CXM");
      return false;
    }

    bool
    Path::SendExitRequest(const routing::ObtainExitMessage* msg,
                          AbstractRouter* r)
    {
      LogInfo(Name(), " sending exit request to ", Endpoint());
      m_ExitObtainTX = msg->T;
      return SendRoutingMessage(msg, r);
    }

    bool
    Path::SendExitClose(const routing::CloseExitMessage* msg, AbstractRouter* r)
    {
      LogInfo(Name(), " closing exit to ", Endpoint());
      // mark as not exit anymore
      _role &= ~ePathRoleExit;
      return SendRoutingMessage(msg, r);
    }

    bool
    Path::HandleObtainExitMessage(const routing::ObtainExitMessage* msg,
                                  AbstractRouter* r)
    {
      (void)msg;
      (void)r;
      LogError(Name(), " got unwarranted OXM");
      return false;
    }

    bool
    Path::HandleUpdateExitMessage(const routing::UpdateExitMessage* msg,
                                  AbstractRouter* r)
    {
      (void)msg;
      (void)r;
      LogError(Name(), " got unwarranted UXM");
      return false;
    }

    bool
    Path::HandleRejectExitMessage(const routing::RejectExitMessage* msg,
                                  AbstractRouter* r)
    {
      if(m_ExitObtainTX && msg->T == m_ExitObtainTX)
      {
        if(!msg->Verify(r->crypto(), EndpointPubKey()))
        {
          LogError(Name(), "RXM invalid signature");
          return false;
        }
        LogInfo(Name(), " ", Endpoint(), " Rejected exit");
        MarkActive(r->Now());
        return InformExitResult(msg->B);
      }
      LogError(Name(), " got unwarranted RXM");
      return false;
    }

    bool
    Path::HandleGrantExitMessage(const routing::GrantExitMessage* msg,
                                 AbstractRouter* r)
    {
      if(m_ExitObtainTX && msg->T == m_ExitObtainTX)
      {
        if(!msg->Verify(r->crypto(), EndpointPubKey()))
        {
          LogError(Name(), " GXM signature failed");
          return false;
        }
        // we now can send exit traffic
        _role |= ePathRoleExit;
        LogInfo(Name(), " ", Endpoint(), " Granted exit");
        MarkActive(r->Now());
        return InformExitResult(0);
      }
      LogError(Name(), " got unwarranted GXM");
      return false;
    }

    bool
    Path::InformExitResult(llarp_time_t B)
    {
      bool result = true;
      for(const auto& hook : m_ObtainedExitHooks)
        result &= hook(this, B);
      m_ObtainedExitHooks.clear();
      return result;
    }

    bool
    Path::HandleTransferTrafficMessage(
        const routing::TransferTrafficMessage* msg, AbstractRouter* r)
    {
      // check if we can handle exit data
      if(!SupportsAnyRoles(ePathRoleExit | ePathRoleSVC))
        return false;
      MarkActive(r->Now());
      // handle traffic if we have a handler
      if(!m_ExitTrafficHandler)
        return false;
      bool sent = msg->X.size() > 0;
      for(const auto& pkt : msg->X)
      {
        if(pkt.size() <= 8)
          return false;
        uint64_t counter = bufbe64toh(pkt.data());
        m_ExitTrafficHandler(
            this, llarp_buffer_t(pkt.data() + 8, pkt.size() - 8), counter);
      }
      return sent;
    }

  }  // namespace path
}  // namespace llarp