/* * Copyright (c) 2013-2024, The PurpleI2P Project * * This file is part of Purple i2pd project and licensed under BSD3 * * See full license text in LICENSE file at top of project tree */ #include #include #include "Config.h" #include "Crypto.h" #include "Ed25519.h" #include "Timestamp.h" #include "I2NPProtocol.h" #include "NetDb.hpp" #include "FS.h" #include "util.h" #include "version.h" #include "Log.h" #include "Family.h" #include "ECIESX25519AEADRatchetSession.h" #include "Transports.h" #include "Tunnel.h" #include "RouterContext.h" namespace i2p { RouterContext context; RouterContext::RouterContext (): m_LastUpdateTime (0), m_AcceptsTunnels (true), m_IsFloodfill (false), m_ShareRatio (100), m_Status (eRouterStatusUnknown), m_StatusV6 (eRouterStatusUnknown), m_Error (eRouterErrorNone), m_ErrorV6 (eRouterErrorNone), m_Testing (false), m_TestingV6 (false), m_NetID (I2PD_NET_ID), m_PublishReplyToken (0), m_IsHiddenMode (false) { } void RouterContext::Init () { srand (i2p::util::GetMillisecondsSinceEpoch () % 1000); m_StartupTime = i2p::util::GetMonotonicSeconds (); if (!Load ()) CreateNewRouter (); m_Decryptor = m_Keys.CreateDecryptor (nullptr); m_TunnelDecryptor = m_Keys.CreateDecryptor (nullptr); UpdateRouterInfo (); i2p::crypto::InitNoiseNState (m_InitialNoiseState, GetIdentity ()->GetEncryptionPublicKey ()); m_ECIESSession = std::make_shared(m_InitialNoiseState); } void RouterContext::Start () { if (!m_Service) { m_Service.reset (new RouterService); m_Service->Start (); m_PublishTimer.reset (new boost::asio::deadline_timer (m_Service->GetService ())); ScheduleInitialPublish (); m_CongestionUpdateTimer.reset (new boost::asio::deadline_timer (m_Service->GetService ())); ScheduleCongestionUpdate (); m_CleanupTimer.reset (new boost::asio::deadline_timer (m_Service->GetService ())); ScheduleCleanupTimer (); } } void RouterContext::Stop () { if (m_Service) { if (m_PublishTimer) m_PublishTimer->cancel (); if (m_CongestionUpdateTimer) m_CongestionUpdateTimer->cancel (); m_Service->Stop (); } } std::shared_ptr RouterContext::CopyRouterInfoBuffer () const { std::lock_guard l(m_RouterInfoMutex); return m_RouterInfo.CopyBuffer (); } void RouterContext::CreateNewRouter () { m_Keys = i2p::data::PrivateKeys::CreateRandomKeys (i2p::data::SIGNING_KEY_TYPE_EDDSA_SHA512_ED25519, i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD); SaveKeys (); NewRouterInfo (); } void RouterContext::NewRouterInfo () { i2p::data::LocalRouterInfo routerInfo; routerInfo.SetRouterIdentity (GetIdentity ()); uint16_t port; i2p::config::GetOption("port", port); if (!port) port = SelectRandomPort (); bool ipv4; i2p::config::GetOption("ipv4", ipv4); bool ipv6; i2p::config::GetOption("ipv6", ipv6); bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); bool ssu2; i2p::config::GetOption("ssu2.enabled", ssu2); bool ygg; i2p::config::GetOption("meshnets.yggdrasil", ygg); bool nat; i2p::config::GetOption("nat", nat); if ((ntcp2 || ygg) && !m_NTCP2Keys) NewNTCP2Keys (); if (ssu2 && !m_SSU2Keys) NewSSU2Keys (); bool ntcp2Published = false; if (ntcp2) { i2p::config::GetOption("ntcp2.published", ntcp2Published); if (ntcp2Published) { std::string ntcp2proxy; i2p::config::GetOption("ntcp2.proxy", ntcp2proxy); if (!ntcp2proxy.empty ()) ntcp2Published = false; } } bool ssu2Published = false; if (ssu2) i2p::config::GetOption("ssu2.published", ssu2Published); uint8_t caps = 0; if (ipv4) { std::string host; if (!nat) // we have no NAT so set external address from local address i2p::config::GetOption("address4", host); if (host.empty ()) i2p::config::GetOption("host", host); if (ntcp2) { uint16_t ntcp2Port; i2p::config::GetOption ("ntcp2.port", ntcp2Port); if (!ntcp2Port) ntcp2Port = port; if (ntcp2Published && ntcp2Port) { boost::asio::ip::address addr; if (!host.empty ()) addr = boost::asio::ip::address::from_string (host); if (!addr.is_v4()) addr = boost::asio::ip::address_v4 (); routerInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, addr, ntcp2Port); } else { // add non-published NTCP2 address uint8_t addressCaps = i2p::data::RouterInfo::AddressCaps::eV4; if (ipv6) addressCaps |= i2p::data::RouterInfo::AddressCaps::eV6; routerInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, ntcp2Port, addressCaps); } } if (ssu2) { uint16_t ssu2Port; i2p::config::GetOption ("ssu2.port", ssu2Port); if (!ssu2Port) ssu2Port = port; if (ssu2Published && ssu2Port) { boost::asio::ip::address addr; if (!host.empty ()) addr = boost::asio::ip::address::from_string (host); if (!addr.is_v4()) addr = boost::asio::ip::address_v4 (); routerInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, addr, ssu2Port); } else { uint8_t addressCaps = i2p::data::RouterInfo::AddressCaps::eV4; if (ipv6) addressCaps |= i2p::data::RouterInfo::AddressCaps::eV6; routerInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, ssu2Port, addressCaps); } } } if (ipv6) { std::string host; i2p::config::GetOption("address6", host); if (host.empty () && !ipv4) i2p::config::GetOption("host", host); // use host for ipv6 only if ipv4 is not presented if (ntcp2) { uint16_t ntcp2Port; i2p::config::GetOption ("ntcp2.port", ntcp2Port); if (!ntcp2Port) ntcp2Port = port; if (ntcp2Published && ntcp2Port) { std::string ntcp2Host; if (!i2p::config::IsDefault ("ntcp2.addressv6")) i2p::config::GetOption ("ntcp2.addressv6", ntcp2Host); else ntcp2Host = host; boost::asio::ip::address addr; if (!ntcp2Host.empty ()) addr = boost::asio::ip::address::from_string (ntcp2Host); if (!addr.is_v6()) addr = boost::asio::ip::address_v6 (); routerInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, addr, ntcp2Port); } else { if (!ipv4) // no other ntcp2 addresses yet routerInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, ntcp2Port, i2p::data::RouterInfo::AddressCaps::eV6); } } if (ssu2) { uint16_t ssu2Port; i2p::config::GetOption ("ssu2.port", ssu2Port); if (!ssu2Port) ssu2Port = port; if (ssu2Published && ssu2Port) { boost::asio::ip::address addr; if (!host.empty ()) addr = boost::asio::ip::address::from_string (host); if (!addr.is_v6()) addr = boost::asio::ip::address_v6 (); routerInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, addr, ssu2Port); } else { if (!ipv4) // no other ssu2 addresses yet routerInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, ssu2Port, i2p::data::RouterInfo::AddressCaps::eV6); } } } if (ygg) { auto yggaddr = i2p::util::net::GetYggdrasilAddress (); if (!yggaddr.is_unspecified ()) routerInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, yggaddr, port); } routerInfo.UpdateCaps (caps); // caps + L routerInfo.SetProperty ("netId", std::to_string (m_NetID)); routerInfo.SetProperty ("router.version", I2P_VERSION); routerInfo.CreateBuffer (m_Keys); m_RouterInfo.SetRouterIdentity (GetIdentity ()); m_RouterInfo.Update (routerInfo.GetBuffer (), routerInfo.GetBufferLen ()); m_RouterInfo.SetUnreachable (false); } uint16_t RouterContext::SelectRandomPort () const { uint16_t port; do { port = rand () % (30777 - 9111) + 9111; // I2P network ports range } while(i2p::util::net::IsPortInReservedRange(port)); return port; } void RouterContext::UpdateRouterInfo () { { std::lock_guard l(m_RouterInfoMutex); m_RouterInfo.CreateBuffer (m_Keys); } m_RouterInfo.SaveToFile (i2p::fs::DataDirPath (ROUTER_INFO)); m_LastUpdateTime = i2p::util::GetSecondsSinceEpoch (); } void RouterContext::NewNTCP2Keys () { m_NTCP2StaticKeys.reset (new i2p::crypto::X25519Keys ()); m_NTCP2StaticKeys->GenerateKeys (); m_NTCP2Keys.reset (new NTCP2PrivateKeys ()); m_NTCP2StaticKeys->GetPrivateKey (m_NTCP2Keys->staticPrivateKey); memcpy (m_NTCP2Keys->staticPublicKey, m_NTCP2StaticKeys->GetPublicKey (), 32); RAND_bytes (m_NTCP2Keys->iv, 16); // save std::ofstream fk (i2p::fs::DataDirPath (NTCP2_KEYS), std::ofstream::binary | std::ofstream::out); fk.write ((char *)m_NTCP2Keys.get (), sizeof (NTCP2PrivateKeys)); } void RouterContext::NewSSU2Keys () { m_SSU2StaticKeys.reset (new i2p::crypto::X25519Keys ()); m_SSU2StaticKeys->GenerateKeys (); m_SSU2Keys.reset (new SSU2PrivateKeys ()); m_SSU2StaticKeys->GetPrivateKey (m_SSU2Keys->staticPrivateKey); memcpy (m_SSU2Keys->staticPublicKey, m_SSU2StaticKeys->GetPublicKey (), 32); RAND_bytes (m_SSU2Keys->intro, 32); // save std::ofstream fk (i2p::fs::DataDirPath (SSU2_KEYS), std::ofstream::binary | std::ofstream::out); fk.write ((char *)m_SSU2Keys.get (), sizeof (SSU2PrivateKeys)); } void RouterContext::SetTesting (bool testing) { if (testing != m_Testing) { m_Testing = testing; if (m_Testing) m_Error = eRouterErrorNone; } } void RouterContext::SetTestingV6 (bool testing) { if (testing != m_TestingV6) { m_TestingV6 = testing; if (m_TestingV6) m_ErrorV6 = eRouterErrorNone; } } void RouterContext::SetStatus (RouterStatus status) { SetTesting (false); if (status != m_Status) { LogPrint(eLogInfo, "Router: network status v4 changed ", ROUTER_STATUS_NAMES[m_Status], " -> ", ROUTER_STATUS_NAMES[status]); m_Status = status; switch (m_Status) { case eRouterStatusOK: SetReachable (true, false); // ipv4 break; case eRouterStatusFirewalled: SetUnreachable (true, false); // ipv4 break; default: ; } } } void RouterContext::SetStatusV6 (RouterStatus status) { SetTestingV6 (false); if (status != m_StatusV6) { LogPrint(eLogInfo, "Router: network status v6 changed ", ROUTER_STATUS_NAMES[m_StatusV6], " -> ", ROUTER_STATUS_NAMES[status]); m_StatusV6 = status; switch (m_StatusV6) { case eRouterStatusOK: SetReachable (false, true); // ipv6 break; case eRouterStatusFirewalled: SetUnreachable (false, true); // ipv6 break; default: ; } } } void RouterContext::UpdatePort (int port) { auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; bool updated = false; for (auto& address : *addresses) { if (address && address->port != port) { address->port = port; updated = true; } } if (updated) UpdateRouterInfo (); } void RouterContext::PublishNTCP2Address (std::shared_ptr address, int port, bool publish) const { if (!address) return; if (!port && !address->port) port = SelectRandomPort (); if (port) address->port = port; address->published = publish; memcpy (address->i, m_NTCP2Keys->iv, 16); } void RouterContext::PublishNTCP2Address (int port, bool publish, bool v4, bool v6, bool ygg) { if (!m_NTCP2Keys) return; auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; bool updated = false; if (v4) { auto addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V4Idx]; if (addr && (addr->port != port || addr->published != publish)) { PublishNTCP2Address (addr, port, publish); updated = true; } } if (v6) { auto addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V6Idx]; if (addr && (addr->port != port || addr->published != publish)) { PublishNTCP2Address (addr, port, publish); updated = true; } } if (ygg) { auto addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V6MeshIdx]; if (addr && (addr->port != port || addr->published != publish)) { PublishNTCP2Address (addr, port, publish); updated = true; } } if (updated) UpdateRouterInfo (); } void RouterContext::UpdateNTCP2Keys () { if (!m_NTCP2Keys) return; auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; for (auto& it: *addresses) { if (it && it->IsNTCP2 ()) { it->s = m_NTCP2Keys->staticPublicKey; memcpy (it->i, m_NTCP2Keys->iv, 16); } } } void RouterContext::PublishSSU2Address (int port, bool publish, bool v4, bool v6) { if (!m_SSU2Keys) return; auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; int newPort = 0; if (!port) { for (const auto& address : *addresses) if (address && address->port) { newPort = address->port; break; } if (!newPort) newPort = SelectRandomPort (); } bool updated = false; for (auto& address : *addresses) { if (address && address->IsSSU2 () && (!address->port || address->port != port || address->published != publish) && ((v4 && address->IsV4 ()) || (v6 && address->IsV6 ()))) { if (port) address->port = port; else if (!address->port) address->port = newPort; address->published = publish; if (publish) address->caps |= (i2p::data::RouterInfo::eSSUIntroducer | i2p::data::RouterInfo::eSSUTesting); else address->caps &= ~(i2p::data::RouterInfo::eSSUIntroducer | i2p::data::RouterInfo::eSSUTesting); updated = true; } } if (updated) UpdateRouterInfo (); } void RouterContext::UpdateSSU2Keys () { if (!m_SSU2Keys) return; auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; for (auto& it: *addresses) { if (it && it->IsSSU2 ()) { it->s = m_SSU2Keys->staticPublicKey; it->i = m_SSU2Keys->intro; } } } void RouterContext::UpdateAddress (const boost::asio::ip::address& host) { auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; bool updated = false; if (host.is_v4 ()) { auto addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V4Idx]; if (addr && addr->host != host) { addr->host = host; updated = true; } addr = (*addresses)[i2p::data::RouterInfo::eSSU2V4Idx]; if (addr && addr->host != host) { addr->host = host; updated = true; } } else if (host.is_v6 ()) { auto addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V6Idx]; if (addr && addr->host != host) { addr->host = host; updated = true; } addr = (*addresses)[i2p::data::RouterInfo::eSSU2V6Idx]; if (addr && (addr->host != host || !addr->ssu->mtu)) { addr->host = host; if (m_StatusV6 != eRouterStatusProxy) { // update MTU auto mtu = i2p::util::net::GetMTU (host); if (mtu) { LogPrint (eLogDebug, "Router: Our v6 MTU=", mtu); int maxMTU = i2p::util::net::GetMaxMTU (host.to_v6 ()); if (mtu > maxMTU) { mtu = maxMTU; LogPrint(eLogWarning, "Router: MTU dropped to upper limit of ", maxMTU, " bytes"); } addr->ssu->mtu = mtu; } } updated = true; } } auto ts = i2p::util::GetSecondsSinceEpoch (); if (updated || ts > m_LastUpdateTime + ROUTER_INFO_UPDATE_INTERVAL) UpdateRouterInfo (); } bool RouterContext::AddSSU2Introducer (const i2p::data::RouterInfo::Introducer& introducer, bool v4) { bool ret = m_RouterInfo.AddSSU2Introducer (introducer, v4); if (ret) UpdateRouterInfo (); return ret; } void RouterContext::RemoveSSU2Introducer (const i2p::data::IdentHash& h, bool v4) { if (m_RouterInfo.RemoveSSU2Introducer (h, v4)) UpdateRouterInfo (); } void RouterContext::ClearSSU2Introducers (bool v4) { auto addr = m_RouterInfo.GetSSU2Address (v4); if (addr && !addr->ssu->introducers.empty ()) { addr->ssu->introducers.clear (); UpdateRouterInfo (); } } void RouterContext::SetFloodfill (bool floodfill) { m_IsFloodfill = floodfill; if (floodfill) m_RouterInfo.UpdateFloodfillProperty (true); else { m_RouterInfo.UpdateFloodfillProperty (false); // we don't publish number of routers and leaseset for non-floodfill m_RouterInfo.DeleteProperty (i2p::data::ROUTER_INFO_PROPERTY_LEASESETS); m_RouterInfo.DeleteProperty (i2p::data::ROUTER_INFO_PROPERTY_ROUTERS); } UpdateRouterInfo (); } std::string RouterContext::GetFamily () const { return m_RouterInfo.GetProperty (i2p::data::ROUTER_INFO_PROPERTY_FAMILY); } void RouterContext::SetFamily (const std::string& family) { std::string signature; if (family.length () > 0) signature = i2p::data::CreateFamilySignature (family, GetIdentHash ()); if (signature.length () > 0) { m_RouterInfo.SetProperty (i2p::data::ROUTER_INFO_PROPERTY_FAMILY, family); m_RouterInfo.SetProperty (i2p::data::ROUTER_INFO_PROPERTY_FAMILY_SIG, signature); } else { m_RouterInfo.DeleteProperty (i2p::data::ROUTER_INFO_PROPERTY_FAMILY); m_RouterInfo.DeleteProperty (i2p::data::ROUTER_INFO_PROPERTY_FAMILY_SIG); } } void RouterContext::SetBandwidth (char L) { uint32_t limit = 0; enum { low, high, extra, unlim } type = high; /* detect parameters */ switch (L) { case i2p::data::CAPS_FLAG_LOW_BANDWIDTH1 : limit = 12; type = low; break; case i2p::data::CAPS_FLAG_LOW_BANDWIDTH2 : limit = i2p::data::LOW_BANDWIDTH_LIMIT; type = low; break; // 48 case i2p::data::CAPS_FLAG_LOW_BANDWIDTH3 : limit = 64; type = low; break; case i2p::data::CAPS_FLAG_HIGH_BANDWIDTH1 : limit = 128; type = high; break; case i2p::data::CAPS_FLAG_HIGH_BANDWIDTH2 : limit = i2p::data::HIGH_BANDWIDTH_LIMIT; type = high; break; // 256 case i2p::data::CAPS_FLAG_EXTRA_BANDWIDTH1 : limit = i2p::data::EXTRA_BANDWIDTH_LIMIT; type = extra; break; // 2048 case i2p::data::CAPS_FLAG_EXTRA_BANDWIDTH2 : limit = 1000000; type = unlim; break; // 1Gbyte/s default: limit = i2p::data::LOW_BANDWIDTH_LIMIT; type = low; // 48 } /* update caps & flags in RI */ auto caps = m_RouterInfo.GetCaps (); caps &= ~i2p::data::RouterInfo::eHighBandwidth; caps &= ~i2p::data::RouterInfo::eExtraBandwidth; switch (type) { case low : /* not set */; break; case extra : caps |= i2p::data::RouterInfo::eExtraBandwidth; break; // 'P' case unlim : caps |= i2p::data::RouterInfo::eExtraBandwidth; #if (__cplusplus >= 201703L) // C++ 17 or higher [[fallthrough]]; #endif // no break here, extra + high means 'X' case high : caps |= i2p::data::RouterInfo::eHighBandwidth; break; } m_RouterInfo.UpdateCaps (caps); UpdateRouterInfo (); m_BandwidthLimit = limit; } void RouterContext::SetBandwidth (int limit) { if (limit > 2000) { SetBandwidth('X'); } else if (limit > 256) { SetBandwidth('P'); } else if (limit > 128) { SetBandwidth('O'); } else if (limit > 64) { SetBandwidth('N'); } else if (limit > 48) { SetBandwidth('M'); } else if (limit > 12) { SetBandwidth('L'); } else { SetBandwidth('K'); } m_BandwidthLimit = limit; // set precise limit } void RouterContext::SetShareRatio (int percents) { if (percents < 0) percents = 0; if (percents > 100) percents = 100; m_ShareRatio = percents; } bool RouterContext::IsUnreachable () const { return m_RouterInfo.GetCaps () & i2p::data::RouterInfo::eUnreachable; } void RouterContext::SetUnreachable (bool v4, bool v6) { if (v4 || (v6 && !SupportsV4 ())) { // set caps uint8_t caps = m_RouterInfo.GetCaps (); caps &= ~i2p::data::RouterInfo::eReachable; caps |= i2p::data::RouterInfo::eUnreachable; if (v6 || !SupportsV6 ()) caps &= ~i2p::data::RouterInfo::eFloodfill; // can't be floodfill m_RouterInfo.UpdateCaps (caps); } uint16_t port = 0; // delete previous introducers auto addresses = m_RouterInfo.GetAddresses (); if (addresses) { for (auto& addr : *addresses) if (addr && addr->ssu && ((v4 && addr->IsV4 ()) || (v6 && addr->IsV6 ()))) { addr->published = false; addr->caps &= ~i2p::data::RouterInfo::eSSUIntroducer; // can't be introducer addr->ssu->introducers.clear (); port = addr->port; } } // unpublish NTCP2 addreeses bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); if (ntcp2) PublishNTCP2Address (port, false, v4, v6, false); // update m_RouterInfo.UpdateSupportedTransports (); UpdateRouterInfo (); } void RouterContext::SetReachable (bool v4, bool v6) { if (v4 || (v6 && !SupportsV4 ())) { // update caps uint8_t caps = m_RouterInfo.GetCaps (); caps &= ~i2p::data::RouterInfo::eUnreachable; caps |= i2p::data::RouterInfo::eReachable; if (m_IsFloodfill) caps |= i2p::data::RouterInfo::eFloodfill; m_RouterInfo.UpdateCaps (caps); } uint16_t port = 0; // delete previous introducers bool isSSU2Published; i2p::config::GetOption ("ssu2.published", isSSU2Published); auto addresses = m_RouterInfo.GetAddresses (); if (addresses) { for (auto& addr : *addresses) if (addr && addr->ssu && isSSU2Published && ((v4 && addr->IsV4 ()) || (v6 && addr->IsV6 ()))) { addr->published = true; addr->caps |= i2p::data::RouterInfo::eSSUIntroducer; addr->ssu->introducers.clear (); if (addr->port) port = addr->port; } } // publish NTCP2 bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); if (ntcp2) { bool published; i2p::config::GetOption ("ntcp2.published", published); if (published) { uint16_t ntcp2Port; i2p::config::GetOption ("ntcp2.port", ntcp2Port); if (!ntcp2Port) ntcp2Port = port; PublishNTCP2Address (ntcp2Port, true, v4, v6, false); } } // update m_RouterInfo.UpdateSupportedTransports (); UpdateRouterInfo (); } void RouterContext::SetSupportsV6 (bool supportsV6) { if (supportsV6) { // insert v6 addresses if necessary bool foundNTCP2 = false, foundSSU2 = false; uint16_t port = 0; auto addresses = m_RouterInfo.GetAddresses (); if (addresses) { for (auto& addr: *addresses) { if (addr && addr->IsV6 () && !i2p::util::net::IsYggdrasilAddress (addr->host)) { switch (addr->transportStyle) { case i2p::data::RouterInfo::eTransportNTCP2: foundNTCP2 = true; break; case i2p::data::RouterInfo::eTransportSSU2: foundSSU2 = true; break; default: ; } } if (addr) port = addr->port; } } if (!port) { i2p::config::GetOption("port", port); if (!port) port = SelectRandomPort (); } // NTCP2 bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); if (ntcp2) { if (!foundNTCP2) { uint16_t ntcp2Port; i2p::config::GetOption ("ntcp2.port", ntcp2Port); if (!ntcp2Port) ntcp2Port = port; bool added = false; bool ntcp2Published; i2p::config::GetOption("ntcp2.published", ntcp2Published); if (ntcp2Published) { std::string ntcp2Host; if (!i2p::config::IsDefault ("ntcp2.addressv6")) i2p::config::GetOption ("ntcp2.addressv6", ntcp2Host); else i2p::config::GetOption("host", ntcp2Host); if (!ntcp2Host.empty () && ntcp2Port) { auto addr = boost::asio::ip::address::from_string (ntcp2Host); if (addr.is_v6 ()) { m_RouterInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, addr, ntcp2Port); added = true; } } } if (!added) m_RouterInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, ntcp2Port, i2p::data::RouterInfo::eV6); } } else m_RouterInfo.RemoveNTCP2Address (false); // SSU2 bool ssu2; i2p::config::GetOption("ssu2.enabled", ssu2); if (ssu2) { if (!foundSSU2) { uint16_t ssu2Port; i2p::config::GetOption ("ssu2.port", ssu2Port); if (!ssu2Port) ssu2Port = port; bool added = false; bool ssu2Published; i2p::config::GetOption("ssu2.published", ssu2Published); if (ssu2Published && ssu2Port) { std::string host; i2p::config::GetOption("host", host); if (!host.empty ()) { auto addr = boost::asio::ip::address::from_string (host); if (addr.is_v6 ()) { m_RouterInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, addr, ssu2Port); added = true; } } } if (!added) m_RouterInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, ssu2Port, i2p::data::RouterInfo::eV6); } } else m_RouterInfo.RemoveSSU2Address (false); if (ntcp2 || ssu2) m_RouterInfo.EnableV6 (); } else m_RouterInfo.DisableV6 (); UpdateRouterInfo (); } void RouterContext::SetSupportsV4 (bool supportsV4) { if (supportsV4) { bool foundNTCP2 = false, foundSSU2 = false; uint16_t port = 0; auto addresses = m_RouterInfo.GetAddresses (); if (addresses) { for (auto& addr: *addresses) { if (addr && addr->IsV4 ()) { switch (addr->transportStyle) { case i2p::data::RouterInfo::eTransportNTCP2: foundNTCP2 = true; break; case i2p::data::RouterInfo::eTransportSSU2: foundSSU2 = true; break; default: ; } } if (addr && addr->port) port = addr->port; } } if (!port) { i2p::config::GetOption("port", port); if (!port) port = SelectRandomPort (); } // NTCP2 bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); if (ntcp2) { if (!foundNTCP2) { uint16_t ntcp2Port; i2p::config::GetOption ("ntcp2.port", ntcp2Port); if (!ntcp2Port) ntcp2Port = port; bool added = false; bool ntcp2Published; i2p::config::GetOption("ntcp2.published", ntcp2Published); if (ntcp2Published && ntcp2Port) { std::string host; i2p::config::GetOption("host", host); if (!host.empty ()) { auto addr = boost::asio::ip::address::from_string (host); if (addr.is_v4 ()) { m_RouterInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, addr, ntcp2Port); added = true; } } } if (!added) m_RouterInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, ntcp2Port, i2p::data::RouterInfo::eV4); } } else m_RouterInfo.RemoveNTCP2Address (true); // SSU2 bool ssu2; i2p::config::GetOption("ssu2.enabled", ssu2); if (ssu2) { if (!foundSSU2) { uint16_t ssu2Port; i2p::config::GetOption ("ssu2.port", ssu2Port); if (!ssu2Port) ssu2Port = port; bool added = false; bool ssu2Published; i2p::config::GetOption("ssu2.published", ssu2Published); std::string host; i2p::config::GetOption("host", host); if (ssu2Published && ssu2Port) { std::string host; i2p::config::GetOption("host", host); if (!host.empty ()) { auto addr = boost::asio::ip::address::from_string (host); if (addr.is_v4 ()) { m_RouterInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, addr, ssu2Port); added = true; } } } if (!added) m_RouterInfo.AddSSU2Address (m_SSU2Keys->staticPublicKey, m_SSU2Keys->intro, ssu2Port, i2p::data::RouterInfo::eV4); } } else m_RouterInfo.RemoveSSU2Address (true); if (ntcp2 || ssu2) m_RouterInfo.EnableV4 (); } else m_RouterInfo.DisableV4 (); UpdateRouterInfo (); } void RouterContext::SetSupportsMesh (bool supportsmesh, const boost::asio::ip::address_v6& host) { if (supportsmesh) { auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; m_RouterInfo.EnableMesh (); if ((*addresses)[i2p::data::RouterInfo::eNTCP2V6MeshIdx]) return; // we have mesh address already uint16_t port = 0; i2p::config::GetOption ("ntcp2.port", port); if (!port) i2p::config::GetOption("port", port); if (!port) { for (auto& addr: *addresses) { if (addr && addr->port) { port = addr->port; break; } } } if (!port) port = SelectRandomPort (); m_RouterInfo.AddNTCP2Address (m_NTCP2Keys->staticPublicKey, m_NTCP2Keys->iv, host, port); } else m_RouterInfo.DisableMesh (); UpdateRouterInfo (); } void RouterContext::SetMTU (int mtu, bool v4) { if (mtu < 1280 || mtu > 1500) return; auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; for (auto& addr: *addresses) { if (addr && addr->ssu && ((v4 && addr->IsV4 ()) || (!v4 && addr->IsV6 ()))) { addr->ssu->mtu = mtu; LogPrint (eLogDebug, "Router: MTU for ", v4 ? "ipv4" : "ipv6", " address ", addr->host.to_string(), " is set to ", mtu); } } } void RouterContext::UpdateNTCP2V6Address (const boost::asio::ip::address& host) { auto addresses = m_RouterInfo.GetAddresses (); if (!addresses) return; std::shared_ptr addr; if (i2p::util::net::IsYggdrasilAddress (host)) // yggdrasil addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V6MeshIdx]; else if (host.is_v6 ()) addr = (*addresses)[i2p::data::RouterInfo::eNTCP2V6Idx]; if (addr && addr->IsPublishedNTCP2 () && addr->host != host) { addr->host = host; UpdateRouterInfo (); } } void RouterContext::UpdateStats () { if (m_IsFloodfill) { // update routers and leasesets m_RouterInfo.SetProperty (i2p::data::ROUTER_INFO_PROPERTY_LEASESETS, std::to_string(i2p::data::netdb.GetNumLeaseSets ())); m_RouterInfo.SetProperty (i2p::data::ROUTER_INFO_PROPERTY_ROUTERS, std::to_string(i2p::data::netdb.GetNumRouters ())); UpdateRouterInfo (); } } void RouterContext::UpdateTimestamp (uint64_t ts) { if (ts > m_LastUpdateTime + ROUTER_INFO_UPDATE_INTERVAL) UpdateRouterInfo (); } bool RouterContext::Load () { { std::ifstream fk (i2p::fs::DataDirPath (ROUTER_KEYS), std::ifstream::in | std::ifstream::binary); if (!fk.is_open ()) return false; fk.seekg (0, std::ios::end); size_t len = fk.tellg(); fk.seekg (0, std::ios::beg); if (len == sizeof (i2p::data::Keys)) // old keys file format { i2p::data::Keys keys; fk.read ((char *)&keys, sizeof (keys)); m_Keys = keys; } else // new keys file format { uint8_t * buf = new uint8_t[len]; fk.read ((char *)buf, len); m_Keys.FromBuffer (buf, len); delete[] buf; } } std::shared_ptr oldIdentity; if (m_Keys.GetPublic ()->GetSigningKeyType () == i2p::data::SIGNING_KEY_TYPE_DSA_SHA1 || m_Keys.GetPublic ()->GetCryptoKeyType () == i2p::data::CRYPTO_KEY_TYPE_ELGAMAL) { // update keys LogPrint (eLogInfo, "Router: router keys are obsolete. Creating new"); oldIdentity = m_Keys.GetPublic (); m_Keys = i2p::data::PrivateKeys::CreateRandomKeys (i2p::data::SIGNING_KEY_TYPE_EDDSA_SHA512_ED25519, i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD); SaveKeys (); } // read NTCP2 keys if available std::ifstream n2k (i2p::fs::DataDirPath (NTCP2_KEYS), std::ifstream::in | std::ifstream::binary); if (n2k) { n2k.seekg (0, std::ios::end); size_t len = n2k.tellg(); n2k.seekg (0, std::ios::beg); if (len == sizeof (NTCP2PrivateKeys)) { m_NTCP2Keys.reset (new NTCP2PrivateKeys ()); n2k.read ((char *)m_NTCP2Keys.get (), sizeof (NTCP2PrivateKeys)); } n2k.close (); } // read SSU2 keys if available std::ifstream s2k (i2p::fs::DataDirPath (SSU2_KEYS), std::ifstream::in | std::ifstream::binary); if (s2k) { s2k.seekg (0, std::ios::end); size_t len = s2k.tellg(); s2k.seekg (0, std::ios::beg); if (len == sizeof (SSU2PrivateKeys)) { m_SSU2Keys.reset (new SSU2PrivateKeys ()); s2k.read ((char *)m_SSU2Keys.get (), sizeof (SSU2PrivateKeys)); } s2k.close (); } // read RouterInfo m_RouterInfo.SetRouterIdentity (oldIdentity ? oldIdentity : GetIdentity ()); i2p::data::RouterInfo routerInfo(i2p::fs::DataDirPath (ROUTER_INFO)); if (!routerInfo.IsUnreachable ()) // router.info looks good { m_RouterInfo.Update (routerInfo.GetBuffer (), routerInfo.GetBufferLen ()); if (oldIdentity) m_RouterInfo.SetRouterIdentity (GetIdentity ()); // from new keys m_RouterInfo.SetProperty ("router.version", I2P_VERSION); m_RouterInfo.DeleteProperty ("coreVersion"); // TODO: remove later } else { LogPrint (eLogError, ROUTER_INFO, " is malformed. Creating new"); NewRouterInfo (); } if (IsUnreachable ()) SetReachable (true, true); // we assume reachable until we discover firewall through peer tests bool updated = false; // create new NTCP2 keys if required bool ntcp2; i2p::config::GetOption("ntcp2.enabled", ntcp2); bool ygg; i2p::config::GetOption("meshnets.yggdrasil", ygg); if ((ntcp2 || ygg) && !m_NTCP2Keys) { NewNTCP2Keys (); UpdateNTCP2Keys (); updated = true; } // create new SSU2 keys if required bool ssu2; i2p::config::GetOption("ssu2.enabled", ssu2); if (ssu2 && !m_SSU2Keys) { NewSSU2Keys (); UpdateSSU2Keys (); updated = true; } if (m_RouterInfo.UpdateCongestion (i2p::data::RouterInfo::eLowCongestion)) updated = true; if (updated) UpdateRouterInfo (); return true; } void RouterContext::SaveKeys () { // save in the same format as .dat files std::ofstream fk (i2p::fs::DataDirPath (ROUTER_KEYS), std::ofstream::binary | std::ofstream::out); size_t len = m_Keys.GetFullLen (); uint8_t * buf = new uint8_t[len]; m_Keys.ToBuffer (buf, len); fk.write ((char *)buf, len); delete[] buf; } std::shared_ptr RouterContext::GetTunnelPool () const { return i2p::tunnel::tunnels.GetExploratoryPool (); } int RouterContext::GetCongestionLevel (bool longTerm) const { return std::max ( i2p::tunnel::tunnels.GetCongestionLevel (), i2p::transport::transports.GetCongestionLevel (longTerm) ); } void RouterContext::HandleI2NPMessage (const uint8_t * buf, size_t len) { i2p::HandleI2NPMessage (CreateI2NPMessage (buf, GetI2NPMessageLength (buf, len))); } bool RouterContext::HandleCloveI2NPMessage (I2NPMessageType typeID, const uint8_t * payload, size_t len, uint32_t msgID) { if (typeID == eI2NPTunnelTest) { // try tunnel test auto pool = GetTunnelPool (); if (pool && pool->ProcessTunnelTest (bufbe32toh (payload + TUNNEL_TEST_MSGID_OFFSET), bufbe64toh (payload + TUNNEL_TEST_TIMESTAMP_OFFSET))) return true; } auto msg = CreateI2NPMessage (typeID, payload, len, msgID); if (!msg) return false; i2p::HandleI2NPMessage (msg); return true; } void RouterContext::ProcessGarlicMessage (std::shared_ptr msg) { if (m_Service) m_Service->GetService ().post (std::bind (&RouterContext::PostGarlicMessage, this, msg)); else LogPrint (eLogError, "Router: service is NULL"); } void RouterContext::PostGarlicMessage (std::shared_ptr msg) { uint8_t * buf = msg->GetPayload (); uint32_t len = bufbe32toh (buf); if (len > msg->GetLength ()) { LogPrint (eLogWarning, "Router: garlic message length ", len, " exceeds I2NP message length ", msg->GetLength ()); return; } buf += 4; if (!HandleECIESx25519TagMessage (buf, len)) // try tag first { // then Noise_N one-time decryption if (m_ECIESSession) m_ECIESSession->HandleNextMessage (buf, len); else LogPrint (eLogError, "Router: Session is not set for ECIES router"); } } void RouterContext::ProcessDeliveryStatusMessage (std::shared_ptr msg) { if (m_Service) m_Service->GetService ().post (std::bind (&RouterContext::PostDeliveryStatusMessage, this, msg)); else LogPrint (eLogError, "Router: service is NULL"); } void RouterContext::PostDeliveryStatusMessage (std::shared_ptr msg) { if (m_PublishReplyToken == bufbe32toh (msg->GetPayload () + DELIVERY_STATUS_MSGID_OFFSET)) { LogPrint (eLogInfo, "Router: Publishing confirmed. reply token=", m_PublishReplyToken); m_PublishExcluded.clear (); m_PublishReplyToken = 0; SchedulePublish (); } else i2p::garlic::GarlicDestination::ProcessDeliveryStatusMessage (msg); } void RouterContext::SubmitECIESx25519Key (const uint8_t * key, uint64_t tag) { if (m_Service) { struct { uint8_t k[32]; uint64_t t; } data; memcpy (data.k, key, 32); data.t = tag; m_Service->GetService ().post ([this,data](void) { AddECIESx25519Key (data.k, data.t); }); } else LogPrint (eLogError, "Router: service is NULL"); } uint32_t RouterContext::GetUptime () const { return i2p::util::GetMonotonicSeconds () - m_StartupTime; } bool RouterContext::Decrypt (const uint8_t * encrypted, uint8_t * data, i2p::data::CryptoKeyType preferredCrypto) const { return m_Decryptor ? m_Decryptor->Decrypt (encrypted, data) : false; } bool RouterContext::DecryptTunnelBuildRecord (const uint8_t * encrypted, uint8_t * data) { return DecryptECIESTunnelBuildRecord (encrypted, data, ECIES_BUILD_REQUEST_RECORD_CLEAR_TEXT_SIZE); } bool RouterContext::DecryptECIESTunnelBuildRecord (const uint8_t * encrypted, uint8_t * data, size_t clearTextSize) { // m_InitialNoiseState is h = SHA256(h || hepk) m_CurrentNoiseState = m_InitialNoiseState; m_CurrentNoiseState.MixHash (encrypted, 32); // h = SHA256(h || sepk) uint8_t sharedSecret[32]; if (!m_TunnelDecryptor->Decrypt (encrypted, sharedSecret)) { LogPrint (eLogWarning, "Router: Incorrect ephemeral public key"); return false; } m_CurrentNoiseState.MixKey (sharedSecret); encrypted += 32; uint8_t nonce[12]; memset (nonce, 0, 12); if (!i2p::crypto::AEADChaCha20Poly1305 (encrypted, clearTextSize, m_CurrentNoiseState.m_H, 32, m_CurrentNoiseState.m_CK + 32, nonce, data, clearTextSize, false)) // decrypt { LogPrint (eLogWarning, "Router: Tunnel record AEAD decryption failed"); return false; } m_CurrentNoiseState.MixHash (encrypted, clearTextSize + 16); // h = SHA256(h || ciphertext) return true; } bool RouterContext::DecryptTunnelShortRequestRecord (const uint8_t * encrypted, uint8_t * data) { return DecryptECIESTunnelBuildRecord (encrypted, data, SHORT_REQUEST_RECORD_CLEAR_TEXT_SIZE); } i2p::crypto::X25519Keys& RouterContext::GetNTCP2StaticKeys () { if (!m_NTCP2StaticKeys) { if (!m_NTCP2Keys) NewNTCP2Keys (); auto x = new i2p::crypto::X25519Keys (m_NTCP2Keys->staticPrivateKey, m_NTCP2Keys->staticPublicKey); if (!m_NTCP2StaticKeys) m_NTCP2StaticKeys.reset (x); else delete x; } return *m_NTCP2StaticKeys; } i2p::crypto::X25519Keys& RouterContext::GetSSU2StaticKeys () { if (!m_SSU2StaticKeys) { if (!m_SSU2Keys) NewSSU2Keys (); auto x = new i2p::crypto::X25519Keys (m_SSU2Keys->staticPrivateKey, m_SSU2Keys->staticPublicKey); if (!m_SSU2StaticKeys) m_SSU2StaticKeys.reset (x); else delete x; } return *m_SSU2StaticKeys; } void RouterContext::ScheduleInitialPublish () { if (m_PublishTimer) { m_PublishTimer->expires_from_now (boost::posix_time::seconds(ROUTER_INFO_INITIAL_PUBLISH_INTERVAL)); m_PublishTimer->async_wait (std::bind (&RouterContext::HandleInitialPublishTimer, this, std::placeholders::_1)); } else LogPrint (eLogError, "Router: Publish timer is NULL"); } void RouterContext::HandleInitialPublishTimer (const boost::system::error_code& ecode) { if (ecode != boost::asio::error::operation_aborted) { if (m_RouterInfo.IsReachableBy (i2p::data::RouterInfo::eAllTransports)) HandlePublishTimer (ecode); else { UpdateTimestamp (i2p::util::GetSecondsSinceEpoch ()); ScheduleInitialPublish (); } } } void RouterContext::SchedulePublish () { if (m_PublishTimer) { m_PublishTimer->cancel (); m_PublishTimer->expires_from_now (boost::posix_time::seconds(ROUTER_INFO_PUBLISH_INTERVAL + rand () % ROUTER_INFO_PUBLISH_INTERVAL_VARIANCE)); m_PublishTimer->async_wait (std::bind (&RouterContext::HandlePublishTimer, this, std::placeholders::_1)); } else LogPrint (eLogError, "Router: Publish timer is NULL"); } void RouterContext::HandlePublishTimer (const boost::system::error_code& ecode) { if (ecode != boost::asio::error::operation_aborted) { UpdateTimestamp (i2p::util::GetSecondsSinceEpoch ()); if (!m_IsHiddenMode) { m_PublishExcluded.clear (); m_PublishReplyToken = 0; if (IsFloodfill ()) { UpdateStats (); // for floodfill m_PublishExcluded.insert (i2p::context.GetIdentHash ()); // don't publish to ourselves } Publish (); SchedulePublishResend (); } else SchedulePublish (); } } void RouterContext::Publish () { if (!i2p::transport::transports.IsOnline ()) return; if (m_PublishExcluded.size () > ROUTER_INFO_MAX_PUBLISH_EXCLUDED_FLOODFILLS) { LogPrint (eLogError, "Router: Couldn't publish our RouterInfo to ", ROUTER_INFO_MAX_PUBLISH_EXCLUDED_FLOODFILLS, " closest routers. Try again"); m_PublishExcluded.clear (); UpdateTimestamp (i2p::util::GetSecondsSinceEpoch ()); } auto floodfill = i2p::data::netdb.GetClosestFloodfill (i2p::context.GetIdentHash (), m_PublishExcluded); if (floodfill) { uint32_t replyToken; RAND_bytes ((uint8_t *)&replyToken, 4); LogPrint (eLogInfo, "Router: Publishing our RouterInfo to ", i2p::data::GetIdentHashAbbreviation(floodfill->GetIdentHash ()), ". reply token=", replyToken); auto onDrop = [this]() { if (m_Service) m_Service->GetService ().post ([this]() { HandlePublishResendTimer (boost::system::error_code ()); }); }; if (i2p::transport::transports.IsConnected (floodfill->GetIdentHash ()) || // already connected (floodfill->IsReachableFrom (i2p::context.GetRouterInfo ()) && // are we able to connect !i2p::transport::transports.RoutesRestricted ())) // and routes not restricted { // send directly auto msg = CreateDatabaseStoreMsg (i2p::context.GetSharedRouterInfo (), replyToken); msg->onDrop = onDrop; i2p::transport::transports.SendMessage (floodfill->GetIdentHash (), msg); } else { // otherwise through exploratory auto exploratoryPool = i2p::tunnel::tunnels.GetExploratoryPool (); auto outbound = exploratoryPool ? exploratoryPool->GetNextOutboundTunnel (nullptr, floodfill->GetCompatibleTransports (false)) : nullptr; auto inbound = exploratoryPool ? exploratoryPool->GetNextInboundTunnel (nullptr, floodfill->GetCompatibleTransports (true)) : nullptr; if (inbound && outbound) { // encrypt for floodfill auto msg = CreateDatabaseStoreMsg (i2p::context.GetSharedRouterInfo (), replyToken, inbound); msg->onDrop = onDrop; outbound->SendTunnelDataMsgTo (floodfill->GetIdentHash (), 0, i2p::garlic::WrapECIESX25519MessageForRouter (msg, floodfill->GetIdentity ()->GetEncryptionPublicKey ())); } else LogPrint (eLogInfo, "Router: Can't publish our RouterInfo. No tunnles. Try again in ", ROUTER_INFO_CONFIRMATION_TIMEOUT, " seconds"); } m_PublishExcluded.insert (floodfill->GetIdentHash ()); m_PublishReplyToken = replyToken; } else LogPrint (eLogInfo, "Router: Can't find floodfill to publish our RouterInfo"); } void RouterContext::SchedulePublishResend () { if (m_PublishTimer) { m_PublishTimer->cancel (); m_PublishTimer->expires_from_now (boost::posix_time::seconds(ROUTER_INFO_CONFIRMATION_TIMEOUT)); m_PublishTimer->async_wait (std::bind (&RouterContext::HandlePublishResendTimer, this, std::placeholders::_1)); } else LogPrint (eLogError, "Router: Publish timer is NULL"); } void RouterContext::HandlePublishResendTimer (const boost::system::error_code& ecode) { if (ecode != boost::asio::error::operation_aborted) { i2p::context.UpdateTimestamp (i2p::util::GetSecondsSinceEpoch ()); Publish (); SchedulePublishResend (); } } void RouterContext::ScheduleCongestionUpdate () { if (m_CongestionUpdateTimer) { m_CongestionUpdateTimer->cancel (); m_CongestionUpdateTimer->expires_from_now (boost::posix_time::seconds(ROUTER_INFO_CONGESTION_UPDATE_INTERVAL)); m_CongestionUpdateTimer->async_wait (std::bind (&RouterContext::HandleCongestionUpdateTimer, this, std::placeholders::_1)); } else LogPrint (eLogError, "Router: Congestion update timer is NULL"); } void RouterContext::HandleCongestionUpdateTimer (const boost::system::error_code& ecode) { if (ecode != boost::asio::error::operation_aborted) { auto c = i2p::data::RouterInfo::eLowCongestion; if (!AcceptsTunnels () || !m_ShareRatio) c = i2p::data::RouterInfo::eRejectAll; else { int congestionLevel = GetCongestionLevel (true); if (congestionLevel > CONGESTION_LEVEL_HIGH) c = i2p::data::RouterInfo::eHighCongestion; else if (congestionLevel > CONGESTION_LEVEL_MEDIUM) c = i2p::data::RouterInfo::eMediumCongestion; } if (m_RouterInfo.UpdateCongestion (c)) UpdateRouterInfo (); ScheduleCongestionUpdate (); } } void RouterContext::ScheduleCleanupTimer () { if (m_CleanupTimer) { m_CleanupTimer->cancel (); m_CleanupTimer->expires_from_now (boost::posix_time::minutes(ROUTER_INFO_CLEANUP_INTERVAL)); m_CleanupTimer->async_wait (std::bind (&RouterContext::HandleCleanupTimer, this, std::placeholders::_1)); } else LogPrint (eLogError, "Router: Cleanup timer is NULL"); } void RouterContext::HandleCleanupTimer (const boost::system::error_code& ecode) { if (ecode != boost::asio::error::operation_aborted) { CleanupExpiredTags (); ScheduleCleanupTimer (); } } }