#ifndef LLARP_HANDLERS_EXIT_HPP #define LLARP_HANDLERS_EXIT_HPP #include #include #include #include namespace llarp { struct AbstractRouter; namespace handlers { struct ExitEndpoint : public dns::IQueryHandler, public util::IStateful { ExitEndpoint(const std::string& name, AbstractRouter* r); ~ExitEndpoint(); void Tick(llarp_time_t now); bool SetOption(const std::string& k, const std::string& v); std::string Name() const; util::StatusObject ExtractStatus() const override; bool ShouldHookDNSMessage(const dns::Message& msg) const override; bool HandleHookedDNSMessage(dns::Message&& msg, std::function< void(dns::Message) >) override; bool AllocateNewExit(const PubKey pk, const PathID_t& path, bool permitInternet); exit::Endpoint* FindEndpointByPath(const PathID_t& path); exit::Endpoint* FindEndpointByIP(huint32_t ip); bool UpdateEndpointPath(const PubKey& remote, const PathID_t& next); /// handle ip packet from outside void OnInetPacket(const llarp_buffer_t& buf); AbstractRouter* GetRouter(); llarp_time_t Now() const; Crypto* GetCrypto(); template < typename Stats > void CalculateTrafficStats(Stats& stats) { auto itr = m_ActiveExits.begin(); while(itr != m_ActiveExits.end()) { stats[itr->first].first += itr->second->TxRate(); stats[itr->first].second += itr->second->RxRate(); ++itr; } } /// DO NOT CALL ME void DelEndpointInfo(const PathID_t& path); /// DO NOT CALL ME void RemoveExit(const exit::Endpoint* ep); bool QueueOutboundTraffic(const llarp_buffer_t& buf); /// sets up networking and starts traffic bool Start(); bool Stop(); bool ShouldRemove() const; bool HasLocalMappedAddrFor(const PubKey& pk) const; huint32_t GetIfAddr() const; void Flush(); private: huint32_t GetIPForIdent(const PubKey pk); huint32_t AllocateNewAddress(); /// obtain ip for service node session, creates a new session if one does /// not existing already huint32_t ObtainServiceNodeIP(const RouterID& router); bool QueueSNodePacket(const llarp_buffer_t& buf, huint32_t from); void MarkIPActive(huint32_t ip); void KickIdentOffExit(const PubKey& pk); AbstractRouter* m_Router; dns::Proxy m_Resolver; bool m_ShouldInitTun; std::string m_Name; bool m_PermitExit; std::unordered_map< PathID_t, PubKey, PathID_t::Hash > m_Paths; std::unordered_map< PubKey, exit::Endpoint*, PubKey::Hash > m_ChosenExits; std::unordered_multimap< PubKey, std::unique_ptr< exit::Endpoint >, PubKey::Hash > m_ActiveExits; using KeyMap_t = std::unordered_map< PubKey, huint32_t, PubKey::Hash >; KeyMap_t m_KeyToIP; using SNodes_t = std::set< PubKey >; /// set of pubkeys we treat as snodes SNodes_t m_SNodeKeys; using SNodeSessions_t = std::unordered_map< RouterID, std::unique_ptr< exit::SNodeSession >, RouterID::Hash >; /// snode sessions we are talking to directly SNodeSessions_t m_SNodeSessions; std::unordered_map< huint32_t, PubKey, huint32_t::Hash > m_IPToKey; huint32_t m_IfAddr; huint32_t m_HigestAddr; huint32_t m_NextAddr; IPRange m_OurRange; std::unordered_map< huint32_t, llarp_time_t, huint32_t::Hash > m_IPActivity; llarp_tun_io m_Tun; Addr m_LocalResolverAddr; std::vector< Addr > m_UpstreamResolvers; using Pkt_t = net::IPv4Packet; using PacketQueue_t = util::CoDelQueue< Pkt_t, Pkt_t::GetTime, Pkt_t::PutTime, Pkt_t::CompareOrder, Pkt_t::GetNow, util::NullMutex, util::NullLock, 5, 100, 1024 >; /// internet to llarp packet queue PacketQueue_t m_InetToNetwork; }; } // namespace handlers } // namespace llarp #endif