lokinet/llarp/handlers/tun.cpp

#include <algorithm>
// harmless on other platforms
#define __USE_MINGW_ANSI_STDIO 1
#include <handlers/tun.hpp>
#include <sys/types.h>
#ifndef _WIN32
#include <sys/socket.h>
#include <netdb.h>
#endif

#include <dns/dns.hpp>
#include <ev/ev.hpp>
#include <router/abstractrouter.hpp>
#include <service/context.hpp>
#include <util/meta/memfn.hpp>
#include <util/thread/logic.hpp>
#include <nodedb.hpp>

#include <util/str.hpp>

namespace llarp
{
  namespace handlers
  {
    void
    TunEndpoint::FlushToUser(std::function< bool(net::IPPacket &) > send)
    {
      m_ExitMap.ForEachValue([](const auto &exit) { exit->FlushDownstream(); });
      // flush network to user
      m_NetworkToUserPktQueue.Process(send);
    }

    bool
    TunEndpoint::ShouldFlushNow(llarp_time_t now) const
    {
      static constexpr auto FlushInterval = 25ms;
      return now >= m_LastFlushAt + FlushInterval;
    }

    void
    TunEndpoint::tunifTick(llarp_tun_io *tun)
    {
      auto *self     = static_cast< TunEndpoint * >(tun->user);
      const auto now = self->Now();
      if(self->ShouldFlushNow(now))
      {
        self->m_LastFlushAt = now;
        LogicCall(self->m_router->logic(), [self]() { self->Flush(); });
      }
    }

    TunEndpoint::TunEndpoint(const std::string &nickname, AbstractRouter *r,
                             service::Context *parent, bool lazyVPN)
        : service::Endpoint(nickname, r, parent)
        , m_UserToNetworkPktQueue(nickname + "_sendq", r->netloop(),
                                  r->netloop())
        , m_NetworkToUserPktQueue(nickname + "_recvq", r->netloop(),
                                  r->netloop())
        , m_Resolver(std::make_shared< dns::Proxy >(
              r->netloop(), r->logic(), r->netloop(), r->logic(), this))
    {
      if(not lazyVPN)
      {
        tunif.reset(new llarp_tun_io());
        std::fill(tunif->ifaddr, tunif->ifaddr + sizeof(tunif->ifaddr), 0);
        std::fill(tunif->ifname, tunif->ifname + sizeof(tunif->ifname), 0);
        tunif->netmask        = 0;
        tunif->get_fd_promise = nullptr;
        tunif->user           = this;
        // eh this shouldn't do anything on windows anyway
        tunif->tick         = &tunifTick;
        tunif->before_write = &tunifBeforeWrite;
        tunif->recvpkt      = &tunifRecvPkt;
      }
    }

    util::StatusObject
    TunEndpoint::ExtractStatus() const
    {
      auto obj      = service::Endpoint::ExtractStatus();
      obj["ifaddr"] = m_OurRange.ToString();

      std::vector< std::string > resolvers;
      for(const auto &addr : m_UpstreamResolvers)
        resolvers.emplace_back(addr.ToString());
      obj["ustreamResolvers"] = resolvers;
      obj["localResolver"]    = m_LocalResolverAddr.ToString();
      util::StatusObject ips{};
      for(const auto &item : m_IPActivity)
      {
        util::StatusObject ipObj{{"lastActive", to_json(item.second)}};
        std::string remoteStr;
        AlignedBuffer< 32 > addr = m_IPToAddr.at(item.first);
        if(m_SNodes.at(addr))
          remoteStr = RouterID(addr.as_array()).ToString();
        else
          remoteStr = service::Address(addr.as_array()).ToString();
        ipObj["remote"]    = remoteStr;
        std::string ipaddr = item.first.ToString();
        ips[ipaddr]        = ipObj;
      }
      obj["addrs"]  = ips;
      obj["ourIP"]  = m_OurIP.ToString();
      obj["nextIP"] = m_NextIP.ToString();
      obj["maxIP"]  = m_MaxIP.ToString();
      return obj;
    }

    bool
    TunEndpoint::SetOption(const std::string &k, const std::string &v)
    {
      if(k == "reachable")
      {
        if(IsFalseValue(v))
        {
          m_PublishIntroSet = false;
          LogInfo(Name(), " setting to be not reachable by default");
        }
        else if(IsTrueValue(v))
        {
          m_PublishIntroSet = true;
          LogInfo(Name(), " setting to be reachable by default");
        }
        else
        {
          LogError(Name(), " config option reachable = '", v,
                   "' does not make sense");
          return false;
        }
      }
      if(k == "isolate-network" && IsTrueValue(v.c_str()))
      {
#if defined(__linux__)
        LogInfo(Name(), " isolating network...");
        if(!SpawnIsolatedNetwork())
        {
          LogError(Name(), " failed to spawn isolated network");
          return false;
        }
        LogInfo(Name(), " booyeah network isolation succeeded");
        return true;
#else
        LogError(Name(),
                 " network isolation is not supported on your platform");
        return false;
#endif
      }
      if(k == "strict-connect")
      {
        RouterID connect;
        if(!connect.FromString(v))
        {
          LogError(Name(), " invalid snode for strict-connect: ", v);
          return false;
        }

        RouterContact rc;
        if(!m_router->nodedb()->Get(connect, rc))
        {
          LogError(Name(), " we don't have the RC for ", v,
                   " so we can't use it in strict-connect");
          return false;
        }
        for(const auto &ai : rc.addrs)
        {
          m_StrictConnectAddrs.emplace_back(ai);
          LogInfo(Name(), " added ", m_StrictConnectAddrs.back(),
                  " to strict connect");
        }
        return true;
      }
      // Name won't be set because we need to read the config before we can read
      // the keyfile
      if(k == "exit-node")
      {
        IPRange exitRange;
        llarp::RouterID exitRouter;
        std::string routerStr;
        const auto pos = v.find(",");
        if(pos != std::string::npos)
        {
          auto range_str = v.substr(1 + pos);
          if(!exitRange.FromString(range_str))
          {
            LogError("bad exit range: '", range_str, "'");
            return false;
          }
          routerStr = v.substr(0, pos);
        }
        else
        {
          routerStr = v;
        }
        routerStr = str(TrimWhitespace(routerStr));
        if(!(exitRouter.FromString(routerStr)
             || HexDecode(routerStr.c_str(), exitRouter.begin(),
                          exitRouter.size())))
        {
          llarp::LogError(Name(), " bad exit router key: ", routerStr);
          return false;
        }
        auto exit = std::make_shared< llarp::exit::ExitSession >(
            exitRouter,
            util::memFn(&TunEndpoint::QueueInboundPacketForExit, this),
            m_router, numPaths, numHops, ShouldBundleRC());
        m_ExitMap.Insert(exitRange, exit);
        llarp::LogInfo(Name(), " using exit at ", exitRouter, " for ",
                       exitRange);
      }
      if(k == "local-dns")
      {
        std::string resolverAddr = v;
        uint16_t dnsport         = 53;
        auto pos                 = v.find(":");
        if(pos != std::string::npos)
        {
          resolverAddr = v.substr(0, pos);
          dnsport      = std::atoi(v.substr(pos + 1).c_str());
        }
        m_LocalResolverAddr = llarp::Addr(resolverAddr, dnsport);
        // this field is ignored on all other platforms
        tunif->dnsaddr = m_LocalResolverAddr.ton();
        llarp::LogInfo(Name(), " binding DNS server to ", m_LocalResolverAddr);
      }
      if(k == "upstream-dns")
      {
        std::string resolverAddr = v;
        uint16_t dnsport         = 53;
        auto pos                 = v.find(":");
        if(pos != std::string::npos)
        {
          resolverAddr = v.substr(0, pos);
          dnsport      = std::atoi(v.substr(pos + 1).c_str());
        }
        m_UpstreamResolvers.emplace_back(resolverAddr, dnsport);
        llarp::LogInfo(Name(), " adding upstream DNS server ", resolverAddr,
                       ":", dnsport);
      }
      if(k == "mapaddr")
      {
        auto pos = v.find(":");
        if(pos == std::string::npos)
        {
          llarp::LogError("Cannot map address ", v,
                          " invalid format, missing colon (:), expects "
                          "address.loki:ip.address.goes.here");
          return false;
        }
        service::Address addr;
        auto addr_str = v.substr(0, pos);
        if(!addr.FromString(addr_str))
        {
          llarp::LogError(Name() + " cannot map invalid address ", addr_str);
          return false;
        }
        auto ip_str = v.substr(pos + 1);
        huint32_t ip;
        huint128_t ipv6;
        if(ip.FromString(ip_str))
        {
          ipv6 = net::IPPacket::ExpandV4(ip);
        }
        else if(ipv6.FromString(ip_str))
        {
        }
        else
        {
          llarp::LogError(Name(), "failed to map ", ip_str,
                          " failed to parse IP");
          return false;
        }
        return MapAddress(addr, ipv6, false);
      }
      if(k == "ifname" && tunif)
      {
        if(v.length() >= sizeof(tunif->ifname))
        {
          llarp::LogError(Name() + " ifname '", v, "' is too long");
          return false;
        }
        strncpy(tunif->ifname, v.c_str(), sizeof(tunif->ifname) - 1);
        llarp::LogInfo(Name() + " setting ifname to ", tunif->ifname);
        return true;
      }
      if(k == "ifaddr" && tunif)
      {
        std::string addr;
        m_UseV6  = addr.find(":") != std::string::npos;
        auto pos = v.find("/");
        if(pos != std::string::npos)
        {
          int num;
          std::string part = v.substr(pos + 1);
#if defined(ANDROID) || defined(RPI)
          num = atoi(part.c_str());
#else
          num = std::stoi(part);
#endif
          if(num > 0)
          {
            tunif->netmask = num;
            addr           = v.substr(0, pos);
          }
          else
          {
            llarp::LogError("bad ifaddr value: ", v);
            return false;
          }
        }
        else
        {
          if(m_UseV6)
            tunif->netmask = 128;
          else
            tunif->netmask = 32;
          addr = v;
        }
        llarp::LogInfo(Name() + " set ifaddr to ", addr, " with netmask ",
                       tunif->netmask);
        strncpy(tunif->ifaddr, addr.c_str(), sizeof(tunif->ifaddr) - 1);
        return true;
      }
      return Endpoint::SetOption(k, v);
    }

    bool
    TunEndpoint::HasLocalIP(const huint128_t &ip) const
    {
      return m_IPToAddr.find(ip) != m_IPToAddr.end();
    }

    bool
    TunEndpoint::QueueOutboundTraffic(llarp::net::IPPacket &&pkt)
    {
      return m_NetworkToUserPktQueue.EmplaceIf(
          [](llarp::net::IPPacket &) -> bool { return true; }, std::move(pkt));
    }

    void
    TunEndpoint::Flush()
    {
      static const auto func = [](auto self) {
        self->FlushSend();
        self->m_ExitMap.ForEachValue(
            [](const auto &exit) { exit->FlushUpstream(); });
        self->Pump(self->Now());
      };
      if(NetworkIsIsolated())
      {
        LogicCall(RouterLogic(), std::bind(func, shared_from_this()));
      }
      else
      {
        func(this);
      }
    }

    static bool
    is_random_snode(const dns::Message &msg)
    {
      return msg.questions[0].IsName("random.snode");
    }

    static bool
    is_localhost_loki(const dns::Message &msg)
    {
      return msg.questions[0].IsName("localhost.loki");
    }

    template <>
    bool
    TunEndpoint::FindAddrForIP(service::Address &addr, huint128_t ip)
    {
      auto itr = m_IPToAddr.find(ip);
      if(itr != m_IPToAddr.end() and not m_SNodes[itr->second])
      {
        addr = service::Address(itr->second.as_array());
        return true;
      }
      return false;
    }

    template <>
    bool
    TunEndpoint::FindAddrForIP(RouterID &addr, huint128_t ip)
    {
      auto itr = m_IPToAddr.find(ip);
      if(itr != m_IPToAddr.end() and m_SNodes[itr->second])
      {
        addr = RouterID(itr->second.as_array());
        return true;
      }
      return false;
    }

    static dns::Message &
    clear_dns_message(dns::Message &msg)
    {
      msg.authorities.resize(0);
      msg.additional.resize(0);
      msg.answers.resize(0);
      msg.hdr_fields &= ~dns::flags_RCODENameError;
      return msg;
    }

    bool
    TunEndpoint::HandleHookedDNSMessage(
        dns::Message msg, std::function< void(dns::Message) > reply)
    {
      // llarp::LogInfo("Tun.HandleHookedDNSMessage ", msg.questions[0].qname, "
      // of type", msg.questions[0].qtype);
      std::string qname;
      if(msg.answers.size() > 0)
      {
        const auto &answer = msg.answers[0];
        if(answer.HasCNameForTLD(".snode"))
        {
          dns::Name_t qname;
          llarp_buffer_t buf(answer.rData);
          if(not dns::DecodeName(&buf, qname, true))
            return false;
          RouterID addr;
          if(not addr.FromString(qname))
            return false;
          auto replyMsg =
              std::make_shared< dns::Message >(clear_dns_message(msg));
          return EnsurePathToSNode(
              addr.as_array(), [=](const RouterID &, exit::BaseSession_ptr s) {
                SendDNSReply(addr, s, replyMsg, reply, true, false);
              });
        }
        else if(answer.HasCNameForTLD(".loki"))
        {
          dns::Name_t qname;
          llarp_buffer_t buf(answer.rData);
          if(not dns::DecodeName(&buf, qname, true))
            return false;
          service::Address addr;
          if(not addr.FromString(qname))
            return false;
          clear_dns_message(msg);
          if(HasAddress(addr))
          {
            huint128_t ip = ObtainIPForAddr(addr, false);
            msg.AddINReply(ip, false);
            reply(msg);
            return true;
          }
          else
          {
            auto replyMsg = std::make_shared< dns::Message >(std::move(msg));
            using service::Address;
            using service::OutboundContext;
            return EnsurePathToService(
                addr,
                [=](const Address &, OutboundContext *ctx) {
                  SendDNSReply(addr, ctx, replyMsg, reply, false, false);
                },
                2s);
          }
        }
      }
      if(msg.questions.size() != 1)
      {
        llarp::LogWarn("bad number of dns questions: ", msg.questions.size());
        return false;
      }
      qname = msg.questions[0].Name();

      if(msg.questions[0].qtype == dns::qTypeMX)
      {
        // mx record
        service::Address addr;
        if(addr.FromString(qname, ".loki") || addr.FromString(qname, ".snode")
           || is_random_snode(msg) || is_localhost_loki(msg))
          msg.AddMXReply(qname, 1);
        else
          msg.AddNXReply();
        reply(msg);
      }
      else if(msg.questions[0].qtype == dns::qTypeCNAME)
      {
        if(is_random_snode(msg))
        {
          RouterID random;
          if(Router()->GetRandomGoodRouter(random))
            msg.AddCNAMEReply(random.ToString(), 1);
          else
            msg.AddNXReply();
        }
        else if(is_localhost_loki(msg))
        {
          size_t counter = 0;
          context->ForEachService(
              [&](const std::string &,
                  const std::shared_ptr< service::Endpoint > &service) -> bool {
                const service::Address addr = service->GetIdentity().pub.Addr();
                msg.AddCNAMEReply(addr.ToString(), 1);
                ++counter;
                return true;
              });
          if(counter == 0)
            msg.AddNXReply();
        }
        else
          msg.AddNXReply();
        reply(msg);
      }
      else if(msg.questions[0].qtype == dns::qTypeA
              || msg.questions[0].qtype == dns::qTypeAAAA)
      {
        const bool isV6 = msg.questions[0].qtype == dns::qTypeAAAA;
        const bool isV4 = msg.questions[0].qtype == dns::qTypeA;
        llarp::service::Address addr;
        if(isV6 && !SupportsV6())
        { // empty reply but not a NXDOMAIN so that client can retry IPv4
        }
        // on MacOS this is a typeA query
        else if(is_random_snode(msg))
        {
          RouterID random;
          if(Router()->GetRandomGoodRouter(random))
            msg.AddCNAMEReply(random.ToString(), 1);
          else
            msg.AddNXReply();
        }
        else if(is_localhost_loki(msg))
        {
          size_t counter = 0;
          context->ForEachService(
              [&](const std::string &,
                  const std::shared_ptr< service::Endpoint > &service) -> bool {
                if(!service->HasIfAddr())
                  return true;
                huint128_t ip = service->GetIfAddr();
                if(ip.h)
                {
                  msg.AddINReply(ip, isV6);
                  ++counter;
                }
                return true;
              });
          if(counter == 0)
            msg.AddNXReply();
        }
        else if(addr.FromString(qname, ".loki"))
        {
          if(isV4 && SupportsV6())
          {
            msg.hdr_fields |= dns::flags_QR | dns::flags_AA | dns::flags_RA;
          }
          else if(HasAddress(addr))
          {
            huint128_t ip = ObtainIPForAddr(addr, false);
            msg.AddINReply(ip, isV6);
          }
          else
          {
            auto replyMsg = std::make_shared< dns::Message >(msg);
            using service::Address;
            using service::OutboundContext;
            return EnsurePathToService(
                addr,
                [=](const Address &, OutboundContext *ctx) {
                  SendDNSReply(addr, ctx, replyMsg, reply, false,
                               isV6 || !isV4);
                },
                2s);
          }
        }
        else if(addr.FromString(qname, ".snode"))
        {
          if(isV4 && SupportsV6())
          {
            msg.hdr_fields |= dns::flags_QR | dns::flags_AA | dns::flags_RA;
          }
          else
          {
            auto replyMsg = std::make_shared< dns::Message >(std::move(msg));
            return EnsurePathToSNode(
                addr.as_array(),
                [=](const RouterID &, exit::BaseSession_ptr s) {
                  SendDNSReply(addr, s, replyMsg, reply, true, isV6);
                });
          }
        }
        else
          msg.AddNXReply();

        reply(msg);
      }
      else if(msg.questions[0].qtype == dns::qTypePTR)
      {
        // reverse dns
        huint128_t ip = {0};
        if(!dns::DecodePTR(msg.questions[0].qname, ip))
        {
          msg.AddNXReply();
          reply(msg);
          return true;
        }
        RouterID snodeAddr;
        if(FindAddrForIP(snodeAddr, ip))
        {
          msg.AddAReply(snodeAddr.ToString());
          reply(msg);
          return true;
        }
        service::Address lokiAddr;
        if(FindAddrForIP(lokiAddr, ip))
        {
          msg.AddAReply(lokiAddr.ToString());
          reply(msg);
          return true;
        }
        msg.AddNXReply();
        reply(msg);
        return true;
      }
      else
      {
        msg.AddNXReply();
        reply(msg);
      }
      return true;
    }

    void
    TunEndpoint::ResetInternalState()
    {
      service::Endpoint::ResetInternalState();
      m_ExitMap.ForEachValue(
          [](const auto &exit) { exit->ResetInternalState(); });
    }

    bool
    TunEndpoint::SupportsV6() const
    {
      return m_UseV6;
    }

    // FIXME: pass in which question it should be addressing
    bool
    TunEndpoint::ShouldHookDNSMessage(const dns::Message &msg) const
    {
      llarp::service::Address addr;
      if(msg.questions.size() == 1)
      {
        /// hook every .loki
        if(msg.questions[0].HasTLD(".loki"))
          return true;
        /// hook every .snode
        if(msg.questions[0].HasTLD(".snode"))
          return true;
        // hook any ranges we own
        if(msg.questions[0].qtype == llarp::dns::qTypePTR)
        {
          huint128_t ip = {0};
          if(!dns::DecodePTR(msg.questions[0].qname, ip))
            return false;
          return m_OurRange.Contains(ip);
        }
      }
      for(const auto &answer : msg.answers)
      {
        if(answer.HasCNameForTLD(".loki"))
          return true;
        if(answer.HasCNameForTLD(".snode"))
          return true;
      }
      return false;
    }

    bool
    TunEndpoint::MapAddress(const service::Address &addr, huint128_t ip,
                            bool SNode)
    {
      auto itr = m_IPToAddr.find(ip);
      if(itr != m_IPToAddr.end())
      {
        llarp::LogWarn(ip, " already mapped to ",
                       service::Address(itr->second.as_array()).ToString());
        return false;
      }
      llarp::LogInfo(Name() + " map ", addr.ToString(), " to ", ip);

      m_IPToAddr[ip]   = addr;
      m_AddrToIP[addr] = ip;
      m_SNodes[addr]   = SNode;
      MarkIPActiveForever(ip);
      return true;
    }

    bool
    TunEndpoint::Start()
    {
      if(!Endpoint::Start())
      {
        llarp::LogWarn("Couldn't start endpoint");
        return false;
      }
      const auto blacklist = SnodeBlacklist();
      m_ExitMap.ForEachValue([blacklist](const auto &exit) {
        for(const auto &snode : blacklist)
          exit->BlacklistSnode(snode);
      });
      return SetupNetworking();
    }

    bool
    TunEndpoint::IsSNode() const
    {
      // TODO : implement me
      return false;
    }

    bool
    TunEndpoint::SetupTun()
    {
      lazy_vpn vpn;
      huint32_t ip;
      auto loop = EndpointNetLoop();
      if(tunif == nullptr)
      {
        llarp::LogInfo(Name(), " waiting for vpn to start");
        vpn   = m_LazyVPNPromise.get_future().get();
        vpnif = vpn.io;
        if(vpnif == nullptr)
        {
          llarp::LogError(Name(), " failed to recieve vpn interface");
          return false;
        }
        llarp::LogInfo(Name(), " got vpn interface");
        auto self = shared_from_this();
        // function to queue a packet to send to vpn interface
        auto sendpkt = [self](net::IPPacket &pkt) -> bool {
          // drop if no endpoint
          auto impl = self->GetVPNImpl();
          // drop if no vpn interface
          if(impl == nullptr)
            return true;
          // drop if queue to vpn not enabled
          if(not impl->reader.queue.enabled())
            return true;
          // drop if queue to vpn full
          if(impl->reader.queue.full())
            return true;
          // queue to reader
          impl->reader.queue.pushBack(pkt);
          return false;
        };
        // event loop ticker
        auto ticker = [self, sendpkt]() {
          TunEndpoint *ep    = self.get();
          const bool running = not ep->IsStopped();
          auto impl          = ep->GetVPNImpl();
          if(impl)
          {
            /// get packets from vpn
            while(not impl->writer.queue.empty())
            {
              // queue it to be sent over lokinet
              auto pkt = impl->writer.queue.popFront();
              if(running)
                ep->m_UserToNetworkPktQueue.Emplace(pkt);
            }
          }

          // process packets queued from vpn
          if(running)
          {
            ep->Flush();
            ep->FlushToUser(sendpkt);
          }
          // if impl has a tick function call it
          if(impl && impl->parent && impl->parent->tick)
            impl->parent->tick(impl->parent);
        };
        if(not loop->add_ticker(ticker))
        {
          llarp::LogError(Name(), " failed to add vpn to event loop");
          if(vpnif->injected)
            vpnif->injected(vpnif, false);
          return false;
        }
      }
      else
      {
        if(!llarp_ev_add_tun(loop.get(), tunif.get()))
        {
          llarp::LogError(Name(),
                          " failed to set up tun interface: ", tunif->ifaddr,
                          " on ", tunif->ifname);
          return false;
        }
      }
      const char *ifname;
      const char *ifaddr;
      unsigned char netmask;
      if(tunif)
      {
        ifname  = tunif->ifname;
        ifaddr  = tunif->ifaddr;
        netmask = tunif->netmask;
      }
      else
      {
        ifname  = vpn.info.ifname;
        ifaddr  = vpn.info.ifaddr;
        netmask = vpn.info.netmask;
      }
      if(ip.FromString(ifaddr))
      {
        m_OurIP                 = net::IPPacket::ExpandV4(ip);
        m_OurRange.netmask_bits = netmask_ipv6_bits(netmask + 96);
      }
      else if(m_OurIP.FromString(ifaddr))
      {
        m_OurRange.netmask_bits = netmask_ipv6_bits(netmask);
        m_UseV6                 = true;
      }
      else
      {
        LogError(Name(), " invalid interface address given, ifaddr=", ifaddr);
        if(vpnif && vpnif->injected)
          vpnif->injected(vpnif, false);
        return false;
      }

      m_NextIP        = m_OurIP;
      m_OurRange.addr = m_OurIP;
      m_MaxIP         = m_OurRange.HighestAddr();
      llarp::LogInfo(Name(), " set ", ifname, " to have address ", m_OurIP);
      llarp::LogInfo(Name(), " allocated up to ", m_MaxIP, " on range ",
                     m_OurRange);

      const service::Address ourAddr = m_Identity.pub.Addr();

      if(not MapAddress(ourAddr, GetIfAddr(), false))
      {
        return false;
      }

      if(m_OnUp)
      {
        m_OnUp->NotifyAsync(NotifyParams());
      }
      if(vpnif && vpnif->injected)
      {
        vpnif->injected(vpnif, true);
      }

      return HasAddress(ourAddr);
    }

    std::unordered_map< std::string, std::string >
    TunEndpoint::NotifyParams() const
    {
      auto env = Endpoint::NotifyParams();
      env.emplace("IP_ADDR", m_OurIP.ToString());
      env.emplace("IF_ADDR", m_OurRange.ToString());
      if(tunif)
        env.emplace("IF_NAME", tunif->ifname);
      std::string strictConnect;
      for(const auto &addr : m_StrictConnectAddrs)
        strictConnect += addr.ToString() + " ";
      env.emplace("STRICT_CONNECT_ADDRS", strictConnect);
      return env;
    }

    bool
    TunEndpoint::SetupNetworking()
    {
      llarp::LogInfo("Set Up networking for ", Name());
      if(!SetupTun())
      {
        llarp::LogError(Name(), " failed to set up network interface");
        return false;
      }
      if(!m_Resolver->Start(m_LocalResolverAddr, m_UpstreamResolvers))
      {
        // downgrade DNS server failure to a warning
        llarp::LogWarn(Name(), " failed to start dns server");
        // return false;
      }
      return true;
    }

    void
    TunEndpoint::Tick(llarp_time_t now)
    {
      m_ExitMap.ForEachValue([&](const auto &exit) {
        this->EnsureRouterIsKnown(exit->Endpoint());
        exit->Tick(now);
      });
      Endpoint::Tick(now);
    }

    bool
    TunEndpoint::Stop()
    {
      m_ExitMap.ForEachValue([](const auto &exit) { exit->Stop(); });
      return llarp::service::Endpoint::Stop();
    }

    void
    TunEndpoint::FlushSend()
    {
      m_UserToNetworkPktQueue.Process([&](net::IPPacket &pkt) {
        std::function< bool(const llarp_buffer_t &) > sendFunc;

        huint128_t dst;
        if(pkt.IsV4())
          dst = net::IPPacket::ExpandV4(pkt.dstv4());
        else
          dst = pkt.dstv6();

        auto itr = m_IPToAddr.find(dst);
        if(itr == m_IPToAddr.end())
        {
          const auto exits = m_ExitMap.FindAll(dst);
          for(const auto &exit : exits)
          {
            if(pkt.IsV4() && !llarp::IsIPv4Bogon(pkt.dstv4()))
            {
              pkt.UpdateIPv4Address({0}, xhtonl(pkt.dstv4()));
              exit->QueueUpstreamTraffic(std::move(pkt),
                                         llarp::routing::ExitPadSize);
            }
            else if(pkt.IsV6())
            {
              pkt.UpdateIPv6Address({0}, pkt.dstv6());
              exit->QueueUpstreamTraffic(std::move(pkt),
                                         llarp::routing::ExitPadSize);
            }
          }
          return;
        }
        if(m_SNodes.at(itr->second))
        {
          sendFunc = std::bind(&TunEndpoint::SendToSNodeOrQueue, this,
                               itr->second.as_array(), std::placeholders::_1);
        }
        else
        {
          sendFunc = std::bind(&TunEndpoint::SendToServiceOrQueue, this,
                               service::Address(itr->second.as_array()),
                               std::placeholders::_1, pkt.ServiceProtocol());
        }
        // prepare packet for insertion into network
        // this includes clearing IP addresses, recalculating checksums, etc
        if(pkt.IsV4())
          pkt.UpdateIPv4Address({0}, {0});
        else
          pkt.UpdateIPv6Address({0}, {0});

        if(sendFunc && sendFunc(pkt.Buffer()))
        {
          MarkIPActive(dst);
          return;
        }
        llarp::LogWarn(Name(), " did not flush packets");
      });
    }

    bool
    TunEndpoint::HandleWriteIPPacket(
        const llarp_buffer_t &b, std::function< huint128_t(void) > getFromIP)
    {
      // llarp::LogInfo("got packet from ", msg->sender.Addr());
      auto themIP = getFromIP();
      // llarp::LogInfo("themIP ", themIP);
      auto usIP = m_OurIP;
      ManagedBuffer buf(b);
      return m_NetworkToUserPktQueue.EmplaceIf(
          [buf, themIP, usIP](net::IPPacket &pkt) -> bool {
            // load
            if(!pkt.Load(buf))
              return false;
            // filter out:
            // - packets smaller than minimal IPv4 header
            // - non-IPv4 packets
            // - packets with weird src/dst addresses
            //   (0.0.0.0/8 but not 0.0.0.0)
            // - packets with 0 src but non-0 dst and oposite
            if(pkt.IsV4())
            {
              auto hdr = pkt.Header();
              if(pkt.sz < sizeof(*hdr)
                 || (hdr->saddr != 0 && *(byte_t *)&(hdr->saddr) == 0)
                 || (hdr->daddr != 0 && *(byte_t *)&(hdr->daddr) == 0)
                 || ((hdr->saddr == 0) != (hdr->daddr == 0)))
              {
                return false;
              }
              pkt.UpdateIPv4Address(xhtonl(net::IPPacket::TruncateV6(themIP)),
                                    xhtonl(net::IPPacket::TruncateV6(usIP)));
            }
            else if(pkt.IsV6())
            {
              pkt.UpdateIPv6Address(themIP, usIP);
            }
            return true;
          });
    }

    huint128_t
    TunEndpoint::GetIfAddr() const
    {
      return m_OurIP;
    }

    huint128_t
    TunEndpoint::ObtainIPForAddr(const AlignedBuffer< 32 > &ident, bool snode)
    {
      llarp_time_t now  = Now();
      huint128_t nextIP = {0};
      {
        // previously allocated address
        auto itr = m_AddrToIP.find(ident);
        if(itr != m_AddrToIP.end())
        {
          // mark ip active
          MarkIPActive(itr->second);
          return itr->second;
        }
      }
      // allocate new address
      if(m_NextIP < m_MaxIP)
      {
        do
        {
          nextIP = ++m_NextIP;
        } while(m_IPToAddr.find(nextIP) != m_IPToAddr.end()
                && m_NextIP < m_MaxIP);
        if(nextIP < m_MaxIP)
        {
          m_AddrToIP[ident]  = nextIP;
          m_IPToAddr[nextIP] = ident;
          m_SNodes[ident]    = snode;
          llarp::LogInfo(Name(), " mapped ", ident, " to ", nextIP);
          MarkIPActive(nextIP);
          return nextIP;
        }
      }

      // we are full
      // expire least active ip
      // TODO: prevent DoS
      std::pair< huint128_t, llarp_time_t > oldest = {huint128_t{0}, 0s};

      // find oldest entry
      auto itr = m_IPActivity.begin();
      while(itr != m_IPActivity.end())
      {
        if(itr->second <= now)
        {
          if((now - itr->second) > oldest.second)
          {
            oldest.first  = itr->first;
            oldest.second = itr->second;
          }
        }
        ++itr;
      }
      // remap address
      m_IPToAddr[oldest.first] = ident;
      m_AddrToIP[ident]        = oldest.first;
      m_SNodes[ident]          = snode;
      nextIP                   = oldest.first;

      // mark ip active
      m_IPActivity[nextIP] = std::max(m_IPActivity[nextIP], now);

      return nextIP;
    }

    bool
    TunEndpoint::HasRemoteForIP(huint128_t ip) const
    {
      return m_IPToAddr.find(ip) != m_IPToAddr.end();
    }

    void
    TunEndpoint::MarkIPActive(huint128_t ip)
    {
      llarp::LogDebug(Name(), " address ", ip, " is active");
      m_IPActivity[ip] = std::max(Now(), m_IPActivity[ip]);
    }

    void
    TunEndpoint::MarkIPActiveForever(huint128_t ip)
    {
      m_IPActivity[ip] = std::numeric_limits< llarp_time_t >::max();
    }

    void
    TunEndpoint::TickTun(__attribute__((unused)) llarp_time_t now)
    {
      // called in the isolated thread
    }

    void
    TunEndpoint::tunifBeforeWrite(llarp_tun_io *tun)
    {
      // called in the isolated network thread
      auto *self      = static_cast< TunEndpoint * >(tun->user);
      auto _pkts      = std::move(self->m_TunPkts);
      self->m_TunPkts = std::vector< net::IPPacket >();

      LogicCall(self->EndpointLogic(), [tun, self, pkts = std::move(_pkts)]() {
        for(auto &pkt : pkts)
        {
          self->m_UserToNetworkPktQueue.Emplace(pkt);
        }
        self->FlushToUser([self, tun](net::IPPacket &pkt) -> bool {
          if(!llarp_ev_tun_async_write(tun, pkt.Buffer()))
          {
            llarp::LogWarn(self->Name(), " packet dropped");
            return true;
          }
          return false;
        });
      });
    }

    void
    TunEndpoint::tunifRecvPkt(llarp_tun_io *tun, const llarp_buffer_t &b)
    {
      // called for every packet read from user in isolated network thread
      auto *self = static_cast< TunEndpoint * >(tun->user);
      net::IPPacket pkt;
      if(not pkt.Load(b))
        return;
      self->m_TunPkts.emplace_back(pkt);
    }

    TunEndpoint::~TunEndpoint() = default;

  }  // namespace handlers
}  // namespace llarp