// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2020 The Bitcoin Core developers // Copyright (c) 2014-2023 The Dash Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #if defined(HAVE_CONFIG_H) #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // for fDIP0001ActiveAtTip #include #include #include #include #include #ifdef WIN32 #include #else #include #endif #if HAVE_DECL_GETIFADDRS && HAVE_DECL_FREEIFADDRS #include #endif #ifdef USE_POLL #include #endif #ifdef USE_EPOLL #include #endif #ifdef USE_KQUEUE #include #endif #include #include #include #include #include /** Maximum number of block-relay-only anchor connections */ static constexpr size_t MAX_BLOCK_RELAY_ONLY_ANCHORS = 2; static_assert (MAX_BLOCK_RELAY_ONLY_ANCHORS <= static_cast(MAX_BLOCK_RELAY_ONLY_CONNECTIONS), "MAX_BLOCK_RELAY_ONLY_ANCHORS must not exceed MAX_BLOCK_RELAY_ONLY_CONNECTIONS."); /** Anchor IP address database file name */ const char* const ANCHORS_DATABASE_FILENAME = "anchors.dat"; // How often to dump addresses to peers.dat static constexpr std::chrono::minutes DUMP_PEERS_INTERVAL{15}; /** Number of DNS seeds to query when the number of connections is low. */ static constexpr int DNSSEEDS_TO_QUERY_AT_ONCE = 3; /** How long to delay before querying DNS seeds * * If we have more than THRESHOLD entries in addrman, then it's likely * that we got those addresses from having previously connected to the P2P * network, and that we'll be able to successfully reconnect to the P2P * network via contacting one of them. So if that's the case, spend a * little longer trying to connect to known peers before querying the * DNS seeds. */ static constexpr std::chrono::seconds DNSSEEDS_DELAY_FEW_PEERS{11}; static constexpr std::chrono::minutes DNSSEEDS_DELAY_MANY_PEERS{5}; static constexpr int DNSSEEDS_DELAY_PEER_THRESHOLD = 1000; // "many" vs "few" peers /** The default timeframe for -maxuploadtarget. 1 day. */ static constexpr std::chrono::seconds MAX_UPLOAD_TIMEFRAME{60 * 60 * 24}; // A random time period (0 to 1 seconds) is added to feeler connections to prevent synchronization. static constexpr auto FEELER_SLEEP_WINDOW{1s}; /** Used to pass flags to the Bind() function */ enum BindFlags { BF_NONE = 0, BF_EXPLICIT = (1U << 0), BF_REPORT_ERROR = (1U << 1), /** * Do not call AddLocal() for our special addresses, e.g., for incoming * Tor connections, to prevent gossiping them over the network. */ BF_DONT_ADVERTISE = (1U << 2), }; #ifndef USE_WAKEUP_PIPE // The set of sockets cannot be modified while waiting // The sleep time needs to be small to avoid new sockets stalling static const uint64_t SELECT_TIMEOUT_MILLISECONDS = 50; #else // select() is woken up through the wakeup pipe whenever a new node is added, so we can wait much longer. // We are however still somewhat limited in how long we can sleep as there is periodic work (cleanup) to be done in // the socket handler thread static const uint64_t SELECT_TIMEOUT_MILLISECONDS = 500; #endif const std::string NET_MESSAGE_COMMAND_OTHER = "*other*"; constexpr const CConnman::CFullyConnectedOnly CConnman::FullyConnectedOnly; constexpr const CConnman::CAllNodes CConnman::AllNodes; static const uint64_t RANDOMIZER_ID_NETGROUP = 0x6c0edd8036ef4036ULL; // SHA256("netgroup")[0:8] static const uint64_t RANDOMIZER_ID_LOCALHOSTNONCE = 0xd93e69e2bbfa5735ULL; // SHA256("localhostnonce")[0:8] static const uint64_t RANDOMIZER_ID_ADDRCACHE = 0x1cf2e4ddd306dda9ULL; // SHA256("addrcache")[0:8] // // Global state variables // bool fDiscover = true; bool fListen = true; Mutex g_maplocalhost_mutex; std::map mapLocalHost GUARDED_BY(g_maplocalhost_mutex); static bool vfLimited[NET_MAX] GUARDED_BY(g_maplocalhost_mutex) = {}; std::string strSubVersion; void CConnman::AddAddrFetch(const std::string& strDest) { LOCK(m_addr_fetches_mutex); m_addr_fetches.push_back(strDest); } uint16_t GetListenPort() { return static_cast(gArgs.GetArg("-port", Params().GetDefaultPort())); } // find 'best' local address for a particular peer bool GetLocal(CService& addr, const CNetAddr *paddrPeer) { if (!fListen) return false; int nBestScore = -1; int nBestReachability = -1; { LOCK(g_maplocalhost_mutex); for (const auto& entry : mapLocalHost) { int nScore = entry.second.nScore; int nReachability = entry.first.GetReachabilityFrom(paddrPeer); if (nReachability > nBestReachability || (nReachability == nBestReachability && nScore > nBestScore)) { addr = CService(entry.first, entry.second.nPort); nBestReachability = nReachability; nBestScore = nScore; } } } return nBestScore >= 0; } //! Convert the serialized seeds into usable address objects. static std::vector ConvertSeeds(const std::vector &vSeedsIn) { // It'll only connect to one or two seed nodes because once it connects, // it'll get a pile of addresses with newer timestamps. // Seed nodes are given a random 'last seen time' of between one and two // weeks ago. const int64_t nOneWeek = 7*24*60*60; std::vector vSeedsOut; FastRandomContext rng; CDataStream s(vSeedsIn, SER_NETWORK, PROTOCOL_VERSION | ADDRV2_FORMAT); while (!s.eof()) { CService endpoint; s >> endpoint; CAddress addr{endpoint, GetDesirableServiceFlags(NODE_NONE)}; addr.nTime = GetTime() - rng.randrange(nOneWeek) - nOneWeek; LogPrint(BCLog::NET, "Added hardcoded seed: %s\n", addr.ToString()); vSeedsOut.push_back(addr); } return vSeedsOut; } // get best local address for a particular peer as a CAddress // Otherwise, return the unroutable 0.0.0.0 but filled in with // the normal parameters, since the IP may be changed to a useful // one by discovery. CAddress GetLocalAddress(const CNetAddr *paddrPeer, ServiceFlags nLocalServices) { CAddress ret(CService(CNetAddr(),GetListenPort()), nLocalServices); CService addr; if (GetLocal(addr, paddrPeer)) { ret = CAddress(addr, nLocalServices); } ret.nTime = GetAdjustedTime(); return ret; } static int GetnScore(const CService& addr) { LOCK(g_maplocalhost_mutex); const auto it = mapLocalHost.find(addr); return (it != mapLocalHost.end()) ? it->second.nScore : 0; } // Is our peer's addrLocal potentially useful as an external IP source? bool IsPeerAddrLocalGood(CNode *pnode) { CService addrLocal = pnode->GetAddrLocal(); return fDiscover && pnode->addr.IsRoutable() && addrLocal.IsRoutable() && IsReachable(addrLocal.GetNetwork()); } std::optional GetLocalAddrForPeer(CNode *pnode) { CAddress addrLocal = GetLocalAddress(&pnode->addr, pnode->GetLocalServices()); if (gArgs.GetBoolArg("-addrmantest", false)) { // use IPv4 loopback during addrmantest addrLocal = CAddress(CService(LookupNumeric("127.0.0.1", GetListenPort())), pnode->GetLocalServices()); } // If discovery is enabled, sometimes give our peer the address it // tells us that it sees us as in case it has a better idea of our // address than we do. FastRandomContext rng; if (IsPeerAddrLocalGood(pnode) && (!addrLocal.IsRoutable() || rng.randbits((GetnScore(addrLocal) > LOCAL_MANUAL) ? 3 : 1) == 0)) { addrLocal.SetIP(pnode->GetAddrLocal()); } if (addrLocal.IsRoutable() || gArgs.GetBoolArg("-addrmantest", false)) { LogPrint(BCLog::NET, "Advertising address %s to peer=%d\n", addrLocal.ToString(), pnode->GetId()); return addrLocal; } // Address is unroutable. Don't advertise. return std::nullopt; } // learn a new local address bool AddLocal(const CService& addr, int nScore) { if (!addr.IsRoutable() && Params().RequireRoutableExternalIP()) return false; if (!fDiscover && nScore < LOCAL_MANUAL) return false; if (!IsReachable(addr)) return false; LogPrintf("AddLocal(%s,%i)\n", addr.ToString(), nScore); { LOCK(g_maplocalhost_mutex); const auto [it, is_newly_added] = mapLocalHost.emplace(addr, LocalServiceInfo()); LocalServiceInfo &info = it->second; if (is_newly_added || nScore >= info.nScore) { info.nScore = nScore + (is_newly_added ? 0 : 1); info.nPort = addr.GetPort(); } } return true; } bool AddLocal(const CNetAddr &addr, int nScore) { return AddLocal(CService(addr, GetListenPort()), nScore); } void RemoveLocal(const CService& addr) { LOCK(g_maplocalhost_mutex); LogPrintf("RemoveLocal(%s)\n", addr.ToString()); mapLocalHost.erase(addr); } void SetReachable(enum Network net, bool reachable) { if (net == NET_UNROUTABLE || net == NET_INTERNAL) return; LOCK(g_maplocalhost_mutex); vfLimited[net] = !reachable; } bool IsReachable(enum Network net) { LOCK(g_maplocalhost_mutex); return !vfLimited[net]; } bool IsReachable(const CNetAddr &addr) { return IsReachable(addr.GetNetwork()); } /** vote for a local address */ bool SeenLocal(const CService& addr) { LOCK(g_maplocalhost_mutex); const auto it = mapLocalHost.find(addr); if (it == mapLocalHost.end()) return false; ++it->second.nScore; return true; } /** check whether a given address is potentially local */ bool IsLocal(const CService& addr) { LOCK(g_maplocalhost_mutex); return mapLocalHost.count(addr) > 0; } CNode* CConnman::FindNode(const CNetAddr& ip, bool fExcludeDisconnecting) { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (fExcludeDisconnecting && pnode->fDisconnect) { continue; } if (static_cast(pnode->addr) == ip) { return pnode; } } return nullptr; } CNode* CConnman::FindNode(const CSubNet& subNet, bool fExcludeDisconnecting) { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (fExcludeDisconnecting && pnode->fDisconnect) { continue; } if (subNet.Match(static_cast(pnode->addr))) { return pnode; } } return nullptr; } CNode* CConnman::FindNode(const std::string& addrName, bool fExcludeDisconnecting) { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (fExcludeDisconnecting && pnode->fDisconnect) { continue; } if (pnode->GetAddrName() == addrName) { return pnode; } } return nullptr; } CNode* CConnman::FindNode(const CService& addr, bool fExcludeDisconnecting) { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (fExcludeDisconnecting && pnode->fDisconnect) { continue; } if (static_cast(pnode->addr) == addr) { return pnode; } } return nullptr; } bool CConnman::CheckIncomingNonce(uint64_t nonce) { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (!pnode->fSuccessfullyConnected && !pnode->IsInboundConn() && pnode->GetLocalNonce() == nonce) return false; } return true; } /** Get the bind address for a socket as CAddress */ static CAddress GetBindAddress(SOCKET sock) { CAddress addr_bind; struct sockaddr_storage sockaddr_bind; socklen_t sockaddr_bind_len = sizeof(sockaddr_bind); if (sock != INVALID_SOCKET) { if (!getsockname(sock, (struct sockaddr*)&sockaddr_bind, &sockaddr_bind_len)) { addr_bind.SetSockAddr((const struct sockaddr*)&sockaddr_bind); } else { LogPrint(BCLog::NET, "Warning: getsockname failed\n"); } } return addr_bind; } CNode* CConnman::ConnectNode(CAddress addrConnect, const char *pszDest, bool fCountFailure, ConnectionType conn_type) { assert(conn_type != ConnectionType::INBOUND); if (pszDest == nullptr) { bool fAllowLocal = Params().AllowMultiplePorts() && addrConnect.GetPort() != GetListenPort(); if (!fAllowLocal && IsLocal(addrConnect)) { return nullptr; } // Look for an existing connection CNode* pnode = FindNode(static_cast(addrConnect)); if (pnode) { LogPrintf("Failed to open new connection, already connected\n"); return nullptr; } } /// debug print if (fLogIPs) { LogPrint(BCLog::NET, "trying connection %s lastseen=%.1fhrs\n", pszDest ? pszDest : addrConnect.ToString(), pszDest ? 0.0 : (double)(GetAdjustedTime() - addrConnect.nTime)/3600.0); } else { LogPrint(BCLog::NET, "trying connection lastseen=%.1fhrs\n", pszDest ? 0.0 : (double)(GetAdjustedTime() - addrConnect.nTime)/3600.0); } // Resolve const uint16_t default_port{pszDest != nullptr ? Params().GetDefaultPort(pszDest) : Params().GetDefaultPort()}; if (pszDest) { std::vector resolved; if (Lookup(pszDest, resolved, default_port, fNameLookup && !HaveNameProxy(), 256) && !resolved.empty()) { addrConnect = CAddress(resolved[GetRand(resolved.size())], NODE_NONE); if (!addrConnect.IsValid()) { LogPrint(BCLog::NET, "Resolver returned invalid address %s for %s\n", addrConnect.ToString(), pszDest); return nullptr; } // It is possible that we already have a connection to the IP/port pszDest resolved to. // In that case, drop the connection that was just created, and return the existing CNode instead. // Also store the name we used to connect in that CNode, so that future FindNode() calls to that // name catch this early. LOCK(cs_vNodes); CNode* pnode = FindNode(static_cast(addrConnect)); if (pnode) { pnode->MaybeSetAddrName(std::string(pszDest)); LogPrintf("Failed to open new connection, already connected\n"); return nullptr; } } } // Connect bool connected = false; std::unique_ptr sock; proxyType proxy; CAddress addr_bind; assert(!addr_bind.IsValid()); if (addrConnect.IsValid()) { bool proxyConnectionFailed = false; if (addrConnect.GetNetwork() == NET_I2P && m_i2p_sam_session.get() != nullptr) { i2p::Connection conn; if (m_i2p_sam_session->Connect(addrConnect, conn, proxyConnectionFailed)) { connected = true; sock = std::move(conn.sock); addr_bind = CAddress{conn.me, NODE_NONE}; } } else if (GetProxy(addrConnect.GetNetwork(), proxy)) { sock = CreateSock(proxy.proxy); if (!sock) { return nullptr; } connected = ConnectThroughProxy(proxy, addrConnect.ToStringIP(), addrConnect.GetPort(), *sock, nConnectTimeout, proxyConnectionFailed); } else { // no proxy needed (none set for target network) sock = CreateSock(addrConnect); if (!sock) { return nullptr; } connected = ConnectSocketDirectly(addrConnect, *sock, nConnectTimeout, conn_type == ConnectionType::MANUAL); } if (!proxyConnectionFailed) { // If a connection to the node was attempted, and failure (if any) is not caused by a problem connecting to // the proxy, mark this as an attempt. addrman.Attempt(addrConnect, fCountFailure); } } else if (pszDest && GetNameProxy(proxy)) { sock = CreateSock(proxy.proxy); if (!sock) { return nullptr; } std::string host; uint16_t port{default_port}; SplitHostPort(std::string(pszDest), port, host); bool proxyConnectionFailed; connected = ConnectThroughProxy(proxy, host, port, *sock, nConnectTimeout, proxyConnectionFailed); } if (!connected) { return nullptr; } // Add node NodeId id = GetNewNodeId(); uint64_t nonce = GetDeterministicRandomizer(RANDOMIZER_ID_LOCALHOSTNONCE).Write(id).Finalize(); if (!addr_bind.IsValid()) { addr_bind = GetBindAddress(sock->Get()); } CNode* pnode = new CNode(id, nLocalServices, sock->Release(), addrConnect, CalculateKeyedNetGroup(addrConnect), nonce, addr_bind, pszDest ? pszDest : "", conn_type); pnode->AddRef(); statsClient.inc("peers.connect", 1.0f); // We're making a new connection, harvest entropy from the time (and our peer count) RandAddEvent((uint32_t)id); return pnode; } void CNode::CloseSocketDisconnect(CConnman* connman) { AssertLockHeld(connman->cs_vNodes); fDisconnect = true; LOCK(cs_hSocket); if (hSocket == INVALID_SOCKET) { return; } fHasRecvData = false; fCanSendData = false; connman->mapSocketToNode.erase(hSocket); connman->mapReceivableNodes.erase(GetId()); connman->mapSendableNodes.erase(GetId()); { LOCK(connman->cs_mapNodesWithDataToSend); if (connman->mapNodesWithDataToSend.erase(GetId()) != 0) { // See comment in PushMessage Release(); } } connman->UnregisterEvents(this); LogPrint(BCLog::NET, "disconnecting peer=%d\n", id); CloseSocket(hSocket); statsClient.inc("peers.disconnect", 1.0f); } void CConnman::AddWhitelistPermissionFlags(NetPermissionFlags& flags, const CNetAddr &addr) const { for (const auto& subnet : vWhitelistedRange) { if (subnet.m_subnet.Match(addr)) NetPermissions::AddFlag(flags, subnet.m_flags); } } bool CNode::IsBlockRelayOnly() const { bool ignores_incoming_txs{gArgs.GetBoolArg("-blocksonly", DEFAULT_BLOCKSONLY)}; // Stop processing non-block data early if // 1) We are in blocks only mode and peer has no relay permission // 2) This peer is a block-relay-only peer return (ignores_incoming_txs && !HasPermission(PF_RELAY)) || !RelayAddrsWithConn(); } std::string CNode::ConnectionTypeAsString() const { switch (m_conn_type) { case ConnectionType::INBOUND: return "inbound"; case ConnectionType::MANUAL: return "manual"; case ConnectionType::FEELER: return "feeler"; case ConnectionType::OUTBOUND_FULL_RELAY: return "outbound-full-relay"; case ConnectionType::BLOCK_RELAY: return "block-relay-only"; case ConnectionType::ADDR_FETCH: return "addr-fetch"; } // no default case, so the compiler can warn about missing cases assert(false); } std::string CNode::GetAddrName() const { LOCK(cs_addrName); return addrName; } void CNode::MaybeSetAddrName(const std::string& addrNameIn) { LOCK(cs_addrName); if (addrName.empty()) { addrName = addrNameIn; } } CService CNode::GetAddrLocal() const { LOCK(cs_addrLocal); return addrLocal; } void CNode::SetAddrLocal(const CService& addrLocalIn) { LOCK(cs_addrLocal); if (addrLocal.IsValid()) { error("Addr local already set for node: %i. Refusing to change from %s to %s", id, addrLocal.ToString(), addrLocalIn.ToString()); } else { addrLocal = addrLocalIn; } } std::string CNode::GetLogString() const { return fLogIPs ? addr.ToString() : strprintf("%d", id); } Network CNode::ConnectedThroughNetwork() const { return IsInboundConn() && m_inbound_onion ? NET_ONION : addr.GetNetClass(); } #undef X #define X(name) stats.name = name void CNode::copyStats(CNodeStats &stats, const std::vector &m_asmap) { stats.nodeid = this->GetId(); X(nServices); X(addr); X(addrBind); stats.m_network = ConnectedThroughNetwork(); stats.m_mapped_as = addr.GetMappedAS(m_asmap); if (RelayAddrsWithConn()) { LOCK(m_tx_relay->cs_filter); stats.fRelayTxes = m_tx_relay->fRelayTxes; } else { stats.fRelayTxes = false; } X(nLastSend); X(nLastRecv); X(nTimeConnected); X(nTimeOffset); stats.addrName = GetAddrName(); X(nVersion); { LOCK(cs_SubVer); X(cleanSubVer); } stats.fInbound = IsInboundConn(); stats.m_manual_connection = IsManualConn(); X(nStartingHeight); { LOCK(cs_vSend); X(mapSendBytesPerMsgCmd); X(nSendBytes); } { LOCK(cs_vRecv); X(mapRecvBytesPerMsgCmd); X(nRecvBytes); } X(m_legacyWhitelisted); X(m_permissionFlags); // It is common for nodes with good ping times to suddenly become lagged, // due to a new block arriving or other large transfer. // Merely reporting pingtime might fool the caller into thinking the node was still responsive, // since pingtime does not update until the ping is complete, which might take a while. // So, if a ping is taking an unusually long time in flight, // the caller can immediately detect that this is happening. int64_t nPingUsecWait = 0; if ((0 != nPingNonceSent) && (0 != nPingUsecStart)) { nPingUsecWait = GetTimeMicros() - nPingUsecStart; } // Raw ping time is in microseconds, but show it to user as whole seconds (Dash users should be well used to small numbers with many decimal places by now :) stats.m_ping_usec = nPingUsecTime; stats.m_min_ping_usec = nMinPingUsecTime; stats.m_ping_wait_usec = nPingUsecWait; // Leave string empty if addrLocal invalid (not filled in yet) CService addrLocalUnlocked = GetAddrLocal(); stats.addrLocal = addrLocalUnlocked.IsValid() ? addrLocalUnlocked.ToString() : ""; { LOCK(cs_mnauth); X(verifiedProRegTxHash); X(verifiedPubKeyHash); } X(m_masternode_connection); stats.m_conn_type_string = ConnectionTypeAsString(); } #undef X bool CNode::ReceiveMsgBytes(Span msg_bytes, bool& complete) { complete = false; int64_t nTimeMicros = GetTimeMicros(); LOCK(cs_vRecv); nLastRecv = nTimeMicros / 1000000; nRecvBytes += msg_bytes.size(); while (msg_bytes.size() > 0) { // absorb network data int handled = m_deserializer->Read(msg_bytes); if (handled < 0) { // Serious header problem, disconnect from the peer. return false; } if (m_deserializer->Complete()) { // decompose a transport agnostic CNetMessage from the deserializer uint32_t out_err_raw_size{0}; std::optional result{m_deserializer->GetMessage(nTimeMicros, out_err_raw_size)}; if (!result) { // Message deserialization failed. Drop the message but don't disconnect the peer. // store the size of the corrupt message mapRecvBytesPerMsgCmd.find(NET_MESSAGE_COMMAND_OTHER)->second += out_err_raw_size; continue; } //store received bytes per message command //to prevent a memory DOS, only allow valid commands mapMsgCmdSize::iterator i = mapRecvBytesPerMsgCmd.find(result->m_command); if (i == mapRecvBytesPerMsgCmd.end()) i = mapRecvBytesPerMsgCmd.find(NET_MESSAGE_COMMAND_OTHER); assert(i != mapRecvBytesPerMsgCmd.end()); i->second += result->m_raw_message_size; statsClient.count("bandwidth.message." + std::string(result->m_command) + ".bytesReceived", result->m_raw_message_size, 1.0f); // push the message to the process queue, vRecvMsg.push_back(std::move(*result)); complete = true; } } return true; } void CNode::SetSendVersion(int nVersionIn) { // Send version may only be changed in the version message, and // only one version message is allowed per session. We can therefore // treat this value as const and even atomic as long as it's only used // once a version message has been successfully processed. Any attempt to // set this twice is an error. if (nSendVersion != 0) { error("Send version already set for node: %i. Refusing to change from %i to %i", id, nSendVersion, nVersionIn); } else { nSendVersion = nVersionIn; } } int CNode::GetSendVersion() const { // The send version should always be explicitly set to // INIT_PROTO_VERSION rather than using this value until SetSendVersion // has been called. if (nSendVersion == 0) { error("Requesting unset send version for node: %i. Using %i", id, INIT_PROTO_VERSION); return INIT_PROTO_VERSION; } return nSendVersion; } int V1TransportDeserializer::readHeader(Span msg_bytes) { // copy data to temporary parsing buffer unsigned int nRemaining = CMessageHeader::HEADER_SIZE - nHdrPos; unsigned int nCopy = std::min(nRemaining, msg_bytes.size()); memcpy(&hdrbuf[nHdrPos], msg_bytes.data(), nCopy); nHdrPos += nCopy; // if header incomplete, exit if (nHdrPos < CMessageHeader::HEADER_SIZE) return nCopy; // deserialize to CMessageHeader try { hdrbuf >> hdr; } catch (const std::exception&) { LogPrint(BCLog::NET, "HEADER ERROR - UNABLE TO DESERIALIZE, peer=%d\n", m_node_id); return -1; } // Check start string, network magic if (memcmp(hdr.pchMessageStart, m_chain_params.MessageStart(), CMessageHeader::MESSAGE_START_SIZE) != 0) { LogPrint(BCLog::NET, "HEADER ERROR - MESSAGESTART (%s, %u bytes), received %s, peer=%d\n", hdr.GetCommand(), hdr.nMessageSize, HexStr(hdr.pchMessageStart), m_node_id); return -1; } // reject messages larger than MAX_SIZE or MAX_PROTOCOL_MESSAGE_LENGTH if (hdr.nMessageSize > MAX_SIZE || hdr.nMessageSize > MAX_PROTOCOL_MESSAGE_LENGTH) { LogPrint(BCLog::NET, "HEADER ERROR - SIZE (%s, %u bytes), peer=%d\n", hdr.GetCommand(), hdr.nMessageSize, m_node_id); return -1; } // switch state to reading message data in_data = true; return nCopy; } int V1TransportDeserializer::readData(Span msg_bytes) { unsigned int nRemaining = hdr.nMessageSize - nDataPos; unsigned int nCopy = std::min(nRemaining, msg_bytes.size()); if (vRecv.size() < nDataPos + nCopy) { // Allocate up to 256 KiB ahead, but never more than the total message size. vRecv.resize(std::min(hdr.nMessageSize, nDataPos + nCopy + 256 * 1024)); } hasher.Write(msg_bytes.first(nCopy)); memcpy(&vRecv[nDataPos], msg_bytes.data(), nCopy); nDataPos += nCopy; return nCopy; } const uint256& V1TransportDeserializer::GetMessageHash() const { assert(Complete()); if (data_hash.IsNull()) hasher.Finalize(data_hash); return data_hash; } std::optional V1TransportDeserializer::GetMessage(int64_t time, uint32_t& out_err_raw_size) { // decompose a single CNetMessage from the TransportDeserializer std::optional msg(std::move(vRecv)); // store command string, time, and sizes msg->m_command = hdr.GetCommand(); msg->m_time = time; msg->m_message_size = hdr.nMessageSize; msg->m_raw_message_size = hdr.nMessageSize + CMessageHeader::HEADER_SIZE; uint256 hash = GetMessageHash(); // We just received a message off the wire, harvest entropy from the time (and the message checksum) RandAddEvent(ReadLE32(hash.begin())); // Check checksum and header command string if (memcmp(hash.begin(), hdr.pchChecksum, CMessageHeader::CHECKSUM_SIZE) != 0) { LogPrint(BCLog::NET, "CHECKSUM ERROR (%s, %u bytes), expected %s was %s, peer=%d\n", SanitizeString(msg->m_command), msg->m_message_size, HexStr(Span{hash}.first(CMessageHeader::CHECKSUM_SIZE)), HexStr(hdr.pchChecksum), m_node_id); out_err_raw_size = msg->m_raw_message_size; msg.reset(); } else if (!hdr.IsCommandValid()) { LogPrint(BCLog::NET, "HEADER ERROR - COMMAND (%s, %u bytes), peer=%d\n", hdr.GetCommand(), msg->m_message_size, m_node_id); out_err_raw_size = msg->m_raw_message_size; msg.reset(); } // Always reset the network deserializer (prepare for the next message) Reset(); return msg; } void V1TransportSerializer::prepareForTransport(CSerializedNetMsg& msg, std::vector& header) { // create dbl-sha256 checksum uint256 hash = Hash(msg.data); // create header CMessageHeader hdr(Params().MessageStart(), msg.command.c_str(), msg.data.size()); memcpy(hdr.pchChecksum, hash.begin(), CMessageHeader::CHECKSUM_SIZE); // serialize header header.reserve(CMessageHeader::HEADER_SIZE); CVectorWriter{SER_NETWORK, INIT_PROTO_VERSION, header, 0, hdr}; } size_t CConnman::SocketSendData(CNode *pnode) EXCLUSIVE_LOCKS_REQUIRED(pnode->cs_vSend) { auto it = pnode->vSendMsg.begin(); size_t nSentSize = 0; while (it != pnode->vSendMsg.end()) { const auto &data = *it; assert(data.size() > pnode->nSendOffset); int nBytes = 0; { LOCK(pnode->cs_hSocket); if (pnode->hSocket == INVALID_SOCKET) break; nBytes = send(pnode->hSocket, reinterpret_cast(data.data()) + pnode->nSendOffset, data.size() - pnode->nSendOffset, MSG_NOSIGNAL | MSG_DONTWAIT); } if (nBytes > 0) { pnode->nLastSend = GetSystemTimeInSeconds(); pnode->nSendBytes += nBytes; pnode->nSendOffset += nBytes; nSentSize += nBytes; if (pnode->nSendOffset == data.size()) { pnode->nSendOffset = 0; pnode->nSendSize -= data.size(); pnode->fPauseSend = pnode->nSendSize > nSendBufferMaxSize; it++; } else { // could not send full message; stop sending more pnode->fCanSendData = false; break; } } else { if (nBytes < 0) { // error int nErr = WSAGetLastError(); if (nErr != WSAEWOULDBLOCK && nErr != WSAEMSGSIZE && nErr != WSAEINTR && nErr != WSAEINPROGRESS) { LogPrintf("socket send error %s (peer=%d)\n", NetworkErrorString(nErr), pnode->GetId()); pnode->fDisconnect = true; } } // couldn't send anything at all pnode->fCanSendData = false; break; } } if (it == pnode->vSendMsg.end()) { assert(pnode->nSendOffset == 0); assert(pnode->nSendSize == 0); } pnode->vSendMsg.erase(pnode->vSendMsg.begin(), it); pnode->nSendMsgSize = pnode->vSendMsg.size(); return nSentSize; } struct NodeEvictionCandidate { NodeId id; int64_t nTimeConnected; int64_t nMinPingUsecTime; int64_t nLastBlockTime; int64_t nLastTXTime; bool fRelevantServices; bool fRelayTxes; bool fBloomFilter; uint64_t nKeyedNetGroup; bool prefer_evict; }; static bool ReverseCompareNodeMinPingTime(const NodeEvictionCandidate& a, const NodeEvictionCandidate& b) { return a.nMinPingUsecTime > b.nMinPingUsecTime; } static bool ReverseCompareNodeTimeConnected(const NodeEvictionCandidate& a, const NodeEvictionCandidate& b) { return a.nTimeConnected > b.nTimeConnected; } static bool CompareNetGroupKeyed(const NodeEvictionCandidate &a, const NodeEvictionCandidate &b) { return a.nKeyedNetGroup < b.nKeyedNetGroup; } static bool CompareNodeBlockTime(const NodeEvictionCandidate &a, const NodeEvictionCandidate &b) { // There is a fall-through here because it is common for a node to have many peers which have not yet relayed a block. if (a.nLastBlockTime != b.nLastBlockTime) return a.nLastBlockTime < b.nLastBlockTime; if (a.fRelevantServices != b.fRelevantServices) return b.fRelevantServices; return a.nTimeConnected > b.nTimeConnected; } static bool CompareNodeTXTime(const NodeEvictionCandidate &a, const NodeEvictionCandidate &b) { // There is a fall-through here because it is common for a node to have more than a few peers that have not yet relayed txn. if (a.nLastTXTime != b.nLastTXTime) return a.nLastTXTime < b.nLastTXTime; if (a.fRelayTxes != b.fRelayTxes) return b.fRelayTxes; if (a.fBloomFilter != b.fBloomFilter) return a.fBloomFilter; return a.nTimeConnected > b.nTimeConnected; } //! Sort an array by the specified comparator, then erase the last K elements. template static void EraseLastKElements(std::vector &elements, Comparator comparator, size_t k) { std::sort(elements.begin(), elements.end(), comparator); size_t eraseSize = std::min(k, elements.size()); elements.erase(elements.end() - eraseSize, elements.end()); } /** Try to find a connection to evict when the node is full. * Extreme care must be taken to avoid opening the node to attacker * triggered network partitioning. * The strategy used here is to protect a small number of peers * for each of several distinct characteristics which are difficult * to forge. In order to partition a node the attacker must be * simultaneously better at all of them than honest peers. */ bool CConnman::AttemptToEvictConnection() { std::vector vEvictionCandidates; { LOCK(cs_vNodes); for (const CNode* node : vNodes) { if (node->HasPermission(PF_NOBAN)) continue; if (!node->IsInboundConn()) continue; if (node->fDisconnect) continue; if (fMasternodeMode) { // This handles eviction protected nodes. Nodes are always protected for a short time after the connection // was accepted. This short time is meant for the VERSION/VERACK exchange and the possible MNAUTH that might // follow when the incoming connection is from another masternode. When a message other than MNAUTH // is received after VERSION/VERACK, the protection is lifted immediately. bool isProtected = GetSystemTimeInSeconds() - node->nTimeConnected < INBOUND_EVICTION_PROTECTION_TIME; if (node->nTimeFirstMessageReceived != 0 && !node->fFirstMessageIsMNAUTH) { isProtected = false; } // if MNAUTH was valid, the node is always protected (and at the same time not accounted when // checking incoming connection limits) if (!node->GetVerifiedProRegTxHash().IsNull()) { isProtected = true; } if (isProtected) { continue; } } bool peer_relay_txes = false; bool peer_filter_not_null = false; if (node->RelayAddrsWithConn()) { LOCK(node->m_tx_relay->cs_filter); peer_relay_txes = node->m_tx_relay->fRelayTxes; peer_filter_not_null = node->m_tx_relay->pfilter != nullptr; } NodeEvictionCandidate candidate = {node->GetId(), node->nTimeConnected, node->nMinPingUsecTime, node->nLastBlockTime, node->nLastTXTime, HasAllDesirableServiceFlags(node->nServices), peer_relay_txes, peer_filter_not_null, node->nKeyedNetGroup, node->m_prefer_evict}; vEvictionCandidates.push_back(candidate); } } // Protect connections with certain characteristics // Deterministically select 4 peers to protect by netgroup. // An attacker cannot predict which netgroups will be protected EraseLastKElements(vEvictionCandidates, CompareNetGroupKeyed, 4); // Protect the 8 nodes with the lowest minimum ping time. // An attacker cannot manipulate this metric without physically moving nodes closer to the target. EraseLastKElements(vEvictionCandidates, ReverseCompareNodeMinPingTime, 8); // Protect 4 nodes that most recently sent us novel transactions accepted into our mempool. // An attacker cannot manipulate this metric without performing useful work. EraseLastKElements(vEvictionCandidates, CompareNodeTXTime, 4); // Protect 4 nodes that most recently sent us novel blocks. // An attacker cannot manipulate this metric without performing useful work. EraseLastKElements(vEvictionCandidates, CompareNodeBlockTime, 4); // Protect the half of the remaining nodes which have been connected the longest. // This replicates the non-eviction implicit behavior, and precludes attacks that start later. EraseLastKElements(vEvictionCandidates, ReverseCompareNodeTimeConnected, vEvictionCandidates.size() / 2); if (vEvictionCandidates.empty()) return false; // If any remaining peers are preferred for eviction consider only them. // This happens after the other preferences since if a peer is really the best by other criteria (esp relaying blocks) // then we probably don't want to evict it no matter what. if (std::any_of(vEvictionCandidates.begin(),vEvictionCandidates.end(),[](NodeEvictionCandidate const &n){return n.prefer_evict;})) { vEvictionCandidates.erase(std::remove_if(vEvictionCandidates.begin(),vEvictionCandidates.end(), [](NodeEvictionCandidate const &n){return !n.prefer_evict;}),vEvictionCandidates.end()); } // Identify the network group with the most connections and youngest member. // (vEvictionCandidates is already sorted by reverse connect time) uint64_t naMostConnections; unsigned int nMostConnections = 0; int64_t nMostConnectionsTime = 0; std::map > mapNetGroupNodes; for (const NodeEvictionCandidate &node : vEvictionCandidates) { std::vector &group = mapNetGroupNodes[node.nKeyedNetGroup]; group.push_back(node); int64_t grouptime = group[0].nTimeConnected; if (group.size() > nMostConnections || (group.size() == nMostConnections && grouptime > nMostConnectionsTime)) { nMostConnections = group.size(); nMostConnectionsTime = grouptime; naMostConnections = node.nKeyedNetGroup; } } // Reduce to the network group with the most connections vEvictionCandidates = std::move(mapNetGroupNodes[naMostConnections]); // Disconnect from the network group with the most connections NodeId evicted = vEvictionCandidates.front().id; LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (pnode->GetId() == evicted) { pnode->fDisconnect = true; return true; } } return false; } void CConnman::AcceptConnection(const ListenSocket& hListenSocket) { struct sockaddr_storage sockaddr; socklen_t len = sizeof(sockaddr); SOCKET hSocket = accept(hListenSocket.socket, (struct sockaddr*)&sockaddr, &len); CAddress addr; if (hSocket == INVALID_SOCKET) { const int nErr = WSAGetLastError(); if (nErr != WSAEWOULDBLOCK) { LogPrintf("socket error accept failed: %s\n", NetworkErrorString(nErr)); } return; } if (!addr.SetSockAddr((const struct sockaddr*)&sockaddr)) { LogPrintf("Warning: Unknown socket family\n"); } const CAddress addr_bind = GetBindAddress(hSocket); NetPermissionFlags permissionFlags = NetPermissionFlags::PF_NONE; hListenSocket.AddSocketPermissionFlags(permissionFlags); CreateNodeFromAcceptedSocket(hSocket, permissionFlags, addr_bind, addr); } void CConnman::CreateNodeFromAcceptedSocket(SOCKET hSocket, NetPermissionFlags permissionFlags, const CAddress& addr_bind, const CAddress& addr) { int nInbound = 0; int nVerifiedInboundMasternodes = 0; int nMaxInbound = nMaxConnections - m_max_outbound; AddWhitelistPermissionFlags(permissionFlags, addr); bool legacyWhitelisted = false; if (NetPermissions::HasFlag(permissionFlags, NetPermissionFlags::PF_ISIMPLICIT)) { NetPermissions::ClearFlag(permissionFlags, PF_ISIMPLICIT); if (gArgs.GetBoolArg("-whitelistforcerelay", DEFAULT_WHITELISTFORCERELAY)) NetPermissions::AddFlag(permissionFlags, PF_FORCERELAY); if (gArgs.GetBoolArg("-whitelistrelay", DEFAULT_WHITELISTRELAY)) NetPermissions::AddFlag(permissionFlags, PF_RELAY); NetPermissions::AddFlag(permissionFlags, PF_MEMPOOL); NetPermissions::AddFlag(permissionFlags, PF_NOBAN); legacyWhitelisted = true; } { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (pnode->IsInboundConn()) { nInbound++; if (!pnode->GetVerifiedProRegTxHash().IsNull()) { nVerifiedInboundMasternodes++; } } } } std::string strDropped; if (fLogIPs) { strDropped = strprintf("connection from %s dropped", addr.ToString()); } else { strDropped = "connection dropped"; } if (!fNetworkActive) { LogPrintf("%s: not accepting new connections\n", strDropped); CloseSocket(hSocket); return; } if (!IsSelectableSocket(hSocket)) { LogPrintf("%s: non-selectable socket\n", strDropped); CloseSocket(hSocket); return; } // According to the internet TCP_NODELAY is not carried into accepted sockets // on all platforms. Set it again here just to be sure. SetSocketNoDelay(hSocket); // Don't accept connections from banned peers. bool banned = m_banman->IsBanned(addr); if (!NetPermissions::HasFlag(permissionFlags, NetPermissionFlags::PF_NOBAN) && banned) { LogPrint(BCLog::NET, "%s (banned)\n", strDropped); CloseSocket(hSocket); return; } // Only accept connections from discouraged peers if our inbound slots aren't (almost) full. bool discouraged = m_banman->IsDiscouraged(addr); if (!NetPermissions::HasFlag(permissionFlags, NetPermissionFlags::PF_NOBAN) && nInbound + 1 >= nMaxInbound && discouraged) { LogPrint(BCLog::NET, "connection from %s dropped (discouraged)\n", addr.ToString()); CloseSocket(hSocket); return; } // Evict connections until we are below nMaxInbound. In case eviction protection resulted in nodes to not be evicted // before, they might get evicted in batches now (after the protection timeout). // We don't evict verified MN connections and also don't take them into account when checking limits. We can do this // because we know that such connections are naturally limited by the total number of MNs, so this is not usable // for attacks. while (nInbound - nVerifiedInboundMasternodes >= nMaxInbound) { if (!AttemptToEvictConnection()) { // No connection to evict, disconnect the new connection LogPrint(BCLog::NET, "failed to find an eviction candidate - connection dropped (full)\n"); CloseSocket(hSocket); return; } nInbound--; } // don't accept incoming connections until blockchain is synced if(fMasternodeMode && !::masternodeSync->IsBlockchainSynced()) { LogPrint(BCLog::NET, "AcceptConnection -- blockchain is not synced yet, skipping inbound connection attempt\n"); CloseSocket(hSocket); return; } NodeId id = GetNewNodeId(); uint64_t nonce = GetDeterministicRandomizer(RANDOMIZER_ID_LOCALHOSTNONCE).Write(id).Finalize(); ServiceFlags nodeServices = nLocalServices; if (NetPermissions::HasFlag(permissionFlags, PF_BLOOMFILTER)) { nodeServices = static_cast(nodeServices | NODE_BLOOM); } const bool inbound_onion = std::find(m_onion_binds.begin(), m_onion_binds.end(), addr_bind) != m_onion_binds.end(); CNode* pnode = new CNode(id, nodeServices, hSocket, addr, CalculateKeyedNetGroup(addr), nonce, addr_bind, "", ConnectionType::INBOUND, inbound_onion); pnode->AddRef(); pnode->m_permissionFlags = permissionFlags; // If this flag is present, the user probably expect that RPC and QT report it as whitelisted (backward compatibility) pnode->m_legacyWhitelisted = legacyWhitelisted; pnode->m_prefer_evict = discouraged; m_msgproc->InitializeNode(pnode); if (fLogIPs) { LogPrint(BCLog::NET_NETCONN, "connection from %s accepted, sock=%d, peer=%d\n", addr.ToString(), hSocket, pnode->GetId()); } else { LogPrint(BCLog::NET_NETCONN, "connection accepted, sock=%d, peer=%d\n", hSocket, pnode->GetId()); } { LOCK(cs_vNodes); vNodes.push_back(pnode); mapSocketToNode.emplace(hSocket, pnode); RegisterEvents(pnode); WakeSelect(); } // We received a new connection, harvest entropy from the time (and our peer count) RandAddEvent((uint32_t)id); } void CConnman::DisconnectNodes() { { LOCK(cs_vNodes); if (!fNetworkActive) { // Disconnect any connected nodes for (CNode* pnode : vNodes) { if (!pnode->fDisconnect) { LogPrint(BCLog::NET, "Network not active, dropping peer=%d\n", pnode->GetId()); pnode->fDisconnect = true; } } } // Disconnect unused nodes for (auto it = vNodes.begin(); it != vNodes.end(); ) { CNode* pnode = *it; if (pnode->fDisconnect) { // If we were the ones who initiated the disconnect, we must assume that the other side wants to see // pending messages. If the other side initiated the disconnect (or disconnected after we've shutdown // the socket), we can be pretty sure that they are not interested in any pending messages anymore and // thus can immediately close the socket. if (!pnode->fOtherSideDisconnected) { if (pnode->nDisconnectLingerTime == 0) { // let's not immediately close the socket but instead wait for at least 100ms so that there is a // chance to flush all/some pending data. Otherwise the other side might not receive REJECT messages // that were pushed right before setting fDisconnect=true // Flushing must happen in two places to ensure data can be received by the other side: // 1. vSendMsg must be empty and all messages sent via send(). This is ensured by SocketHandler() // being called before DisconnectNodes and also by the linger time // 2. Internal socket send buffers must be flushed. This is ensured solely by the linger time pnode->nDisconnectLingerTime = GetTimeMillis() + 100; } if (GetTimeMillis() < pnode->nDisconnectLingerTime) { // everything flushed to the kernel? if (!pnode->fSocketShutdown && pnode->nSendMsgSize == 0) { LOCK(pnode->cs_hSocket); if (pnode->hSocket != INVALID_SOCKET) { // Give the other side a chance to detect the disconnect as early as possible (recv() will return 0) ::shutdown(pnode->hSocket, SD_SEND); } pnode->fSocketShutdown = true; } ++it; continue; } } if (fLogIPs) { LogPrintf("ThreadSocketHandler -- removing node: peer=%d addr=%s nRefCount=%d fInbound=%d m_masternode_connection=%d m_masternode_iqr_connection=%d\n", pnode->GetId(), pnode->addr.ToString(), pnode->GetRefCount(), pnode->IsInboundConn(), pnode->m_masternode_connection, pnode->m_masternode_iqr_connection); } else { LogPrintf("ThreadSocketHandler -- removing node: peer=%d nRefCount=%d fInbound=%d m_masternode_connection=%d m_masternode_iqr_connection=%d\n", pnode->GetId(), pnode->GetRefCount(), pnode->IsInboundConn(), pnode->m_masternode_connection, pnode->m_masternode_iqr_connection); } // remove from vNodes it = vNodes.erase(it); // release outbound grant (if any) pnode->grantOutbound.Release(); // close socket and cleanup pnode->CloseSocketDisconnect(this); // hold in disconnected pool until all refs are released pnode->Release(); vNodesDisconnected.push_back(pnode); } else { ++it; } } } { // Delete disconnected nodes std::list vNodesDisconnectedCopy = vNodesDisconnected; for (auto it = vNodesDisconnected.begin(); it != vNodesDisconnected.end(); ) { CNode* pnode = *it; // wait until threads are done using it bool fDelete = false; if (pnode->GetRefCount() <= 0) { { TRY_LOCK(pnode->cs_inventory, lockInv); if (lockInv) { TRY_LOCK(pnode->cs_vSend, lockSend); if (lockSend) { fDelete = true; } } } if (fDelete) { it = vNodesDisconnected.erase(it); DeleteNode(pnode); } } if (!fDelete) { ++it; } } } } void CConnman::NotifyNumConnectionsChanged() { size_t vNodesSize; { LOCK(cs_vNodes); vNodesSize = vNodes.size(); } // If we had zero connections before and new connections now or if we just dropped // to zero connections reset the sync process if its outdated. if ((vNodesSize > 0 && nPrevNodeCount == 0) || (vNodesSize == 0 && nPrevNodeCount > 0)) { ::masternodeSync->Reset(); } if(vNodesSize != nPrevNodeCount) { nPrevNodeCount = vNodesSize; if(clientInterface) clientInterface->NotifyNumConnectionsChanged(vNodesSize); CalculateNumConnectionsChangedStats(); } } void CConnman::CalculateNumConnectionsChangedStats() { if (!gArgs.GetBoolArg("-statsenabled", DEFAULT_STATSD_ENABLE)) { return; } // count various node attributes for statsD int fullNodes = 0; int spvNodes = 0; int inboundNodes = 0; int outboundNodes = 0; int ipv4Nodes = 0; int ipv6Nodes = 0; int torNodes = 0; mapMsgCmdSize mapRecvBytesMsgStats; mapMsgCmdSize mapSentBytesMsgStats; for (const std::string &msg : getAllNetMessageTypes()) { mapRecvBytesMsgStats[msg] = 0; mapSentBytesMsgStats[msg] = 0; } mapRecvBytesMsgStats[NET_MESSAGE_COMMAND_OTHER] = 0; mapSentBytesMsgStats[NET_MESSAGE_COMMAND_OTHER] = 0; auto vNodesCopy = CopyNodeVector(CConnman::FullyConnectedOnly); for (auto pnode : vNodesCopy) { { LOCK(pnode->cs_vRecv); for (const mapMsgCmdSize::value_type &i : pnode->mapRecvBytesPerMsgCmd) mapRecvBytesMsgStats[i.first] += i.second; } { LOCK(pnode->cs_vSend); for (const mapMsgCmdSize::value_type &i : pnode->mapSendBytesPerMsgCmd) mapSentBytesMsgStats[i.first] += i.second; } if(pnode->fClient) spvNodes++; else fullNodes++; if(pnode->IsInboundConn()) inboundNodes++; else outboundNodes++; if(pnode->addr.IsIPv4()) ipv4Nodes++; if(pnode->addr.IsIPv6()) ipv6Nodes++; if(pnode->addr.IsTor()) torNodes++; if(pnode->nPingUsecTime > 0) statsClient.timing("peers.ping_us", pnode->nPingUsecTime, 1.0f); } ReleaseNodeVector(vNodesCopy); for (const std::string &msg : getAllNetMessageTypes()) { statsClient.gauge("bandwidth.message." + msg + ".totalBytesReceived", mapRecvBytesMsgStats[msg], 1.0f); statsClient.gauge("bandwidth.message." + msg + ".totalBytesSent", mapSentBytesMsgStats[msg], 1.0f); } statsClient.gauge("peers.totalConnections", nPrevNodeCount, 1.0f); statsClient.gauge("peers.spvNodeConnections", spvNodes, 1.0f); statsClient.gauge("peers.fullNodeConnections", fullNodes, 1.0f); statsClient.gauge("peers.inboundConnections", inboundNodes, 1.0f); statsClient.gauge("peers.outboundConnections", outboundNodes, 1.0f); statsClient.gauge("peers.ipv4Connections", ipv4Nodes, 1.0f); statsClient.gauge("peers.ipv6Connections", ipv6Nodes, 1.0f); statsClient.gauge("peers.torConnections", torNodes, 1.0f); } void CConnman::InactivityCheck(CNode *pnode) const { int64_t nTime = GetSystemTimeInSeconds(); if (nTime - pnode->nTimeConnected > m_peer_connect_timeout) { if (pnode->nLastRecv == 0 || pnode->nLastSend == 0) { LogPrint(BCLog::NET, "socket no message in first %i seconds, %d %d from %d\n", m_peer_connect_timeout, pnode->nLastRecv != 0, pnode->nLastSend != 0, pnode->GetId()); pnode->fDisconnect = true; } else if (nTime - pnode->nLastSend > TIMEOUT_INTERVAL) { LogPrintf("socket sending timeout: %is\n", nTime - pnode->nLastSend); pnode->fDisconnect = true; } else if (nTime - pnode->nLastRecv > TIMEOUT_INTERVAL) { LogPrintf("socket receive timeout: %is\n", nTime - pnode->nLastRecv); pnode->fDisconnect = true; } else if (pnode->nPingNonceSent && pnode->nPingUsecStart + TIMEOUT_INTERVAL * 1000000 < GetTimeMicros()) { LogPrintf("ping timeout: %fs\n", 0.000001 * (GetTimeMicros() - pnode->nPingUsecStart)); pnode->fDisconnect = true; } else if (!pnode->fSuccessfullyConnected) { LogPrint(BCLog::NET, "version handshake timeout from %d\n", pnode->GetId()); pnode->fDisconnect = true; } } } bool CConnman::GenerateSelectSet(std::set &recv_set, std::set &send_set, std::set &error_set) { for (const ListenSocket& hListenSocket : vhListenSocket) { recv_set.insert(hListenSocket.socket); } { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { bool select_recv = !pnode->fHasRecvData; bool select_send = !pnode->fCanSendData; LOCK(pnode->cs_hSocket); if (pnode->hSocket == INVALID_SOCKET) continue; error_set.insert(pnode->hSocket); if (select_send) { send_set.insert(pnode->hSocket); } if (select_recv) { recv_set.insert(pnode->hSocket); } } } #ifdef USE_WAKEUP_PIPE // We add a pipe to the read set so that the select() call can be woken up from the outside // This is done when data is added to send buffers (vSendMsg) or when new peers are added // This is currently only implemented for POSIX compliant systems. This means that Windows will fall back to // timing out after 50ms and then trying to send. This is ok as we assume that heavy-load daemons are usually // run on Linux and friends. recv_set.insert(wakeupPipe[0]); #endif return !recv_set.empty() || !send_set.empty() || !error_set.empty(); } #ifdef USE_KQUEUE void CConnman::SocketEventsKqueue(std::set &recv_set, std::set &send_set, std::set &error_set, bool fOnlyPoll) { const size_t maxEvents = 64; struct kevent events[maxEvents]; struct timespec timeout; timeout.tv_sec = fOnlyPoll ? 0 : SELECT_TIMEOUT_MILLISECONDS / 1000; timeout.tv_nsec = (fOnlyPoll ? 0 : SELECT_TIMEOUT_MILLISECONDS % 1000) * 1000 * 1000; wakeupSelectNeeded = true; int n = kevent(kqueuefd, nullptr, 0, events, maxEvents, &timeout); wakeupSelectNeeded = false; if (n == -1) { LogPrintf("kevent wait error\n"); } else if (n > 0) { for (int i = 0; i < n; i++) { auto& event = events[i]; if ((event.flags & EV_ERROR) || (event.flags & EV_EOF)) { error_set.insert((SOCKET)event.ident); continue; } if (event.filter == EVFILT_READ) { recv_set.insert((SOCKET)event.ident); } if (event.filter == EVFILT_WRITE) { send_set.insert((SOCKET)event.ident); } } } } #endif #ifdef USE_EPOLL void CConnman::SocketEventsEpoll(std::set &recv_set, std::set &send_set, std::set &error_set, bool fOnlyPoll) { const size_t maxEvents = 64; epoll_event events[maxEvents]; wakeupSelectNeeded = true; int n = epoll_wait(epollfd, events, maxEvents, fOnlyPoll ? 0 : SELECT_TIMEOUT_MILLISECONDS); wakeupSelectNeeded = false; for (int i = 0; i < n; i++) { auto& e = events[i]; if((e.events & EPOLLERR) || (e.events & EPOLLHUP)) { error_set.insert((SOCKET)e.data.fd); continue; } if (e.events & EPOLLIN) { recv_set.insert((SOCKET)e.data.fd); } if (e.events & EPOLLOUT) { send_set.insert((SOCKET)e.data.fd); } } } #endif #ifdef USE_POLL void CConnman::SocketEventsPoll(std::set &recv_set, std::set &send_set, std::set &error_set, bool fOnlyPoll) { std::set recv_select_set, send_select_set, error_select_set; if (!GenerateSelectSet(recv_select_set, send_select_set, error_select_set)) { if (!fOnlyPoll) interruptNet.sleep_for(std::chrono::milliseconds(SELECT_TIMEOUT_MILLISECONDS)); return; } std::unordered_map pollfds; for (SOCKET socket_id : recv_select_set) { pollfds[socket_id].fd = socket_id; pollfds[socket_id].events |= POLLIN; } for (SOCKET socket_id : send_select_set) { pollfds[socket_id].fd = socket_id; pollfds[socket_id].events |= POLLOUT; } for (SOCKET socket_id : error_select_set) { pollfds[socket_id].fd = socket_id; // These flags are ignored, but we set them for clarity pollfds[socket_id].events |= POLLERR|POLLHUP; } std::vector vpollfds; vpollfds.reserve(pollfds.size()); for (auto it : pollfds) { vpollfds.push_back(std::move(it.second)); } wakeupSelectNeeded = true; int r = poll(vpollfds.data(), vpollfds.size(), fOnlyPoll ? 0 : SELECT_TIMEOUT_MILLISECONDS); wakeupSelectNeeded = false; if (r < 0) { return; } if (interruptNet) return; for (struct pollfd pollfd_entry : vpollfds) { if (pollfd_entry.revents & POLLIN) recv_set.insert(pollfd_entry.fd); if (pollfd_entry.revents & POLLOUT) send_set.insert(pollfd_entry.fd); if (pollfd_entry.revents & (POLLERR|POLLHUP)) error_set.insert(pollfd_entry.fd); } } #endif void CConnman::SocketEventsSelect(std::set &recv_set, std::set &send_set, std::set &error_set, bool fOnlyPoll) { std::set recv_select_set, send_select_set, error_select_set; if (!GenerateSelectSet(recv_select_set, send_select_set, error_select_set)) { interruptNet.sleep_for(std::chrono::milliseconds(SELECT_TIMEOUT_MILLISECONDS)); return; } // // Find which sockets have data to receive // struct timeval timeout; timeout.tv_sec = 0; timeout.tv_usec = fOnlyPoll ? 0 : SELECT_TIMEOUT_MILLISECONDS * 1000; // frequency to poll pnode->vSend fd_set fdsetRecv; fd_set fdsetSend; fd_set fdsetError; FD_ZERO(&fdsetRecv); FD_ZERO(&fdsetSend); FD_ZERO(&fdsetError); SOCKET hSocketMax = 0; for (SOCKET hSocket : recv_select_set) { FD_SET(hSocket, &fdsetRecv); hSocketMax = std::max(hSocketMax, hSocket); } for (SOCKET hSocket : send_select_set) { FD_SET(hSocket, &fdsetSend); hSocketMax = std::max(hSocketMax, hSocket); } for (SOCKET hSocket : error_select_set) { FD_SET(hSocket, &fdsetError); hSocketMax = std::max(hSocketMax, hSocket); } wakeupSelectNeeded = true; int nSelect = select(hSocketMax + 1, &fdsetRecv, &fdsetSend, &fdsetError, &timeout); wakeupSelectNeeded = false; if (interruptNet) return; if (nSelect == SOCKET_ERROR) { int nErr = WSAGetLastError(); LogPrintf("socket select error %s\n", NetworkErrorString(nErr)); for (unsigned int i = 0; i <= hSocketMax; i++) FD_SET(i, &fdsetRecv); FD_ZERO(&fdsetSend); FD_ZERO(&fdsetError); if (!interruptNet.sleep_for(std::chrono::milliseconds(SELECT_TIMEOUT_MILLISECONDS))) return; } for (SOCKET hSocket : recv_select_set) { if (FD_ISSET(hSocket, &fdsetRecv)) { recv_set.insert(hSocket); } } for (SOCKET hSocket : send_select_set) { if (FD_ISSET(hSocket, &fdsetSend)) { send_set.insert(hSocket); } } for (SOCKET hSocket : error_select_set) { if (FD_ISSET(hSocket, &fdsetError)) { error_set.insert(hSocket); } } } void CConnman::SocketEvents(std::set &recv_set, std::set &send_set, std::set &error_set, bool fOnlyPoll) { switch (socketEventsMode) { #ifdef USE_KQUEUE case SOCKETEVENTS_KQUEUE: SocketEventsKqueue(recv_set, send_set, error_set, fOnlyPoll); break; #endif #ifdef USE_EPOLL case SOCKETEVENTS_EPOLL: SocketEventsEpoll(recv_set, send_set, error_set, fOnlyPoll); break; #endif #ifdef USE_POLL case SOCKETEVENTS_POLL: SocketEventsPoll(recv_set, send_set, error_set, fOnlyPoll); break; #endif case SOCKETEVENTS_SELECT: SocketEventsSelect(recv_set, send_set, error_set, fOnlyPoll); break; default: assert(false); } } void CConnman::SocketHandler() { bool fOnlyPoll = false; { // check if we have work to do and thus should avoid waiting for events LOCK2(cs_vNodes, cs_mapNodesWithDataToSend); if (!mapReceivableNodes.empty()) { fOnlyPoll = true; } else if (!mapSendableNodes.empty() && !mapNodesWithDataToSend.empty()) { // we must check if at least one of the nodes with pending messages is also sendable, as otherwise a single // node would be able to make the network thread busy with polling for (auto& p : mapNodesWithDataToSend) { if (mapSendableNodes.count(p.first)) { fOnlyPoll = true; break; } } } } std::set recv_set, send_set, error_set; SocketEvents(recv_set, send_set, error_set, fOnlyPoll); #ifdef USE_WAKEUP_PIPE // drain the wakeup pipe if (recv_set.count(wakeupPipe[0])) { char buf[128]; while (true) { int r = read(wakeupPipe[0], buf, sizeof(buf)); if (r <= 0) { break; } } } #endif if (interruptNet) return; // // Accept new connections // for (const ListenSocket& hListenSocket : vhListenSocket) { if (recv_set.count(hListenSocket.socket) > 0) { AcceptConnection(hListenSocket); } } std::vector vErrorNodes; std::vector vReceivableNodes; std::vector vSendableNodes; { LOCK(cs_vNodes); for (auto hSocket : error_set) { auto it = mapSocketToNode.find(hSocket); if (it == mapSocketToNode.end()) { continue; } it->second->AddRef(); vErrorNodes.emplace_back(it->second); } for (auto hSocket : recv_set) { if (error_set.count(hSocket)) { // no need to handle it twice continue; } auto it = mapSocketToNode.find(hSocket); if (it == mapSocketToNode.end()) { continue; } auto jt = mapReceivableNodes.emplace(it->second->GetId(), it->second); assert(jt.first->second == it->second); it->second->fHasRecvData = true; } for (auto hSocket : send_set) { auto it = mapSocketToNode.find(hSocket); if (it == mapSocketToNode.end()) { continue; } auto jt = mapSendableNodes.emplace(it->second->GetId(), it->second); assert(jt.first->second == it->second); it->second->fCanSendData = true; } // collect nodes that have a receivable socket // also clean up mapReceivableNodes from nodes that were receivable in the last iteration but aren't anymore vReceivableNodes.reserve(mapReceivableNodes.size()); for (auto it = mapReceivableNodes.begin(); it != mapReceivableNodes.end(); ) { if (!it->second->fHasRecvData) { it = mapReceivableNodes.erase(it); } else { // Implement the following logic: // * If there is data to send, try sending data. As this only // happens when optimistic write failed, we choose to first drain the // write buffer in this case before receiving more. This avoids // needlessly queueing received data, if the remote peer is not themselves // receiving data. This means properly utilizing TCP flow control signalling. // * Otherwise, if there is space left in the receive buffer (!fPauseRecv), try // receiving data (which should succeed as the socket signalled as receivable). if (!it->second->fPauseRecv && it->second->nSendMsgSize == 0 && !it->second->fDisconnect) { it->second->AddRef(); vReceivableNodes.emplace_back(it->second); } ++it; } } // collect nodes that have data to send and have a socket with non-empty write buffers // also clean up mapNodesWithDataToSend from nodes that had messages to send in the last iteration // but don't have any in this iteration LOCK(cs_mapNodesWithDataToSend); vSendableNodes.reserve(mapNodesWithDataToSend.size()); for (auto it = mapNodesWithDataToSend.begin(); it != mapNodesWithDataToSend.end(); ) { if (it->second->nSendMsgSize == 0) { // See comment in PushMessage it->second->Release(); it = mapNodesWithDataToSend.erase(it); } else { if (it->second->fCanSendData) { it->second->AddRef(); vSendableNodes.emplace_back(it->second); } ++it; } } } for (CNode* pnode : vErrorNodes) { if (interruptNet) { break; } // let recv() return errors and then handle it SocketRecvData(pnode); } for (CNode* pnode : vReceivableNodes) { if (interruptNet) { break; } if (pnode->fPauseRecv) { continue; } SocketRecvData(pnode); } for (CNode* pnode : vSendableNodes) { if (interruptNet) { break; } // Send data size_t bytes_sent = WITH_LOCK(pnode->cs_vSend, return SocketSendData(pnode)); if (bytes_sent) RecordBytesSent(bytes_sent); } ReleaseNodeVector(vErrorNodes); ReleaseNodeVector(vReceivableNodes); ReleaseNodeVector(vSendableNodes); if (interruptNet) { return; } { LOCK(cs_vNodes); // remove nodes from mapSendableNodes, so that the next iteration knows that there is no work to do // (even if there are pending messages to be sent) for (auto it = mapSendableNodes.begin(); it != mapSendableNodes.end(); ) { if (!it->second->fCanSendData) { LogPrint(BCLog::NET, "%s -- remove mapSendableNodes, peer=%d\n", __func__, it->second->GetId()); it = mapSendableNodes.erase(it); } else { ++it; } } } } size_t CConnman::SocketRecvData(CNode *pnode) { // typical socket buffer is 8K-64K uint8_t pchBuf[0x10000]; int nBytes = 0; { LOCK(pnode->cs_hSocket); if (pnode->hSocket == INVALID_SOCKET) return 0; nBytes = recv(pnode->hSocket, (char*)pchBuf, sizeof(pchBuf), MSG_DONTWAIT); if (nBytes < (int)sizeof(pchBuf)) { pnode->fHasRecvData = false; } } if (nBytes > 0) { bool notify = false; if (!pnode->ReceiveMsgBytes(Span(pchBuf, nBytes), notify)) { LOCK(cs_vNodes); pnode->CloseSocketDisconnect(this); } RecordBytesRecv(nBytes); if (notify) { size_t nSizeAdded = 0; auto it(pnode->vRecvMsg.begin()); for (; it != pnode->vRecvMsg.end(); ++it) { // vRecvMsg contains only completed CNetMessage // the single possible partially deserialized message are held by TransportDeserializer nSizeAdded += it->m_raw_message_size; } { LOCK(pnode->cs_vProcessMsg); pnode->vProcessMsg.splice(pnode->vProcessMsg.end(), pnode->vRecvMsg, pnode->vRecvMsg.begin(), it); pnode->nProcessQueueSize += nSizeAdded; pnode->fPauseRecv = pnode->nProcessQueueSize > nReceiveFloodSize; } WakeMessageHandler(); } } else if (nBytes == 0) { // socket closed gracefully if (!pnode->fDisconnect) { LogPrint(BCLog::NET, "socket closed for peer=%d\n", pnode->GetId()); } LOCK(cs_vNodes); pnode->fOtherSideDisconnected = true; // avoid lingering pnode->CloseSocketDisconnect(this); } else if (nBytes < 0) { // error int nErr = WSAGetLastError(); if (nErr != WSAEWOULDBLOCK && nErr != WSAEMSGSIZE && nErr != WSAEINTR && nErr != WSAEINPROGRESS) { if (!pnode->fDisconnect){ LogPrint(BCLog::NET, "socket recv error for peer=%d: %s\n", pnode->GetId(), NetworkErrorString(nErr)); } LOCK(cs_vNodes); pnode->fOtherSideDisconnected = true; // avoid lingering pnode->CloseSocketDisconnect(this); } } if (nBytes < 0) { return 0; } return (size_t)nBytes; } void CConnman::ThreadSocketHandler() { int64_t nLastCleanupNodes = 0; while (!interruptNet) { // Handle sockets before we do the next round of disconnects. This allows us to flush send buffers one last time // before actually closing sockets. Receiving is however skipped in case a peer is pending to be disconnected SocketHandler(); if (GetTimeMillis() - nLastCleanupNodes > 1000) { ForEachNode(AllNodes, [&](CNode* pnode) { InactivityCheck(pnode); }); nLastCleanupNodes = GetTimeMillis(); } DisconnectNodes(); NotifyNumConnectionsChanged(); } } void CConnman::WakeMessageHandler() { { LOCK(mutexMsgProc); fMsgProcWake = true; } condMsgProc.notify_one(); } void CConnman::WakeSelect() { #ifdef USE_WAKEUP_PIPE if (wakeupPipe[1] == -1) { return; } char buf{0}; if (write(wakeupPipe[1], &buf, sizeof(buf)) != 1) { LogPrint(BCLog::NET, "write to wakeupPipe failed\n"); } #endif wakeupSelectNeeded = false; } void CConnman::ThreadDNSAddressSeed() { FastRandomContext rng; std::vector seeds = Params().DNSSeeds(); Shuffle(seeds.begin(), seeds.end(), rng); int seeds_right_now = 0; // Number of seeds left before testing if we have enough connections int found = 0; if (gArgs.GetBoolArg("-forcednsseed", DEFAULT_FORCEDNSSEED)) { // When -forcednsseed is provided, query all. seeds_right_now = seeds.size(); } else if (addrman.size() == 0) { // If we have no known peers, query all. // This will occur on the first run, or if peers.dat has been // deleted. seeds_right_now = seeds.size(); } // goal: only query DNS seed if address need is acute // * If we have a reasonable number of peers in addrman, spend // some time trying them first. This improves user privacy by // creating fewer identifying DNS requests, reduces trust by // giving seeds less influence on the network topology, and // reduces traffic to the seeds. // * When querying DNS seeds query a few at once, this ensures // that we don't give DNS seeds the ability to eclipse nodes // that query them. // * If we continue having problems, eventually query all the // DNS seeds, and if that fails too, also try the fixed seeds. // (done in ThreadOpenConnections) const std::chrono::seconds seeds_wait_time = (addrman.size() >= DNSSEEDS_DELAY_PEER_THRESHOLD ? DNSSEEDS_DELAY_MANY_PEERS : DNSSEEDS_DELAY_FEW_PEERS); for (const std::string& seed : seeds) { if (seeds_right_now == 0) { seeds_right_now += DNSSEEDS_TO_QUERY_AT_ONCE; if (addrman.size() > 0) { LogPrintf("Waiting %d seconds before querying DNS seeds.\n", seeds_wait_time.count()); std::chrono::seconds to_wait = seeds_wait_time; while (to_wait.count() > 0) { // if sleeping for the MANY_PEERS interval, wake up // early to see if we have enough peers and can stop // this thread entirely freeing up its resources std::chrono::seconds w = std::min(DNSSEEDS_DELAY_FEW_PEERS, to_wait); if (!interruptNet.sleep_for(w)) return; to_wait -= w; int nRelevant = 0; { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (pnode->fSuccessfullyConnected && !pnode->IsOutboundOrBlockRelayConn() && !pnode->m_masternode_probe_connection) ++nRelevant; } } if (nRelevant >= 2) { if (found > 0) { LogPrintf("%d addresses found from DNS seeds\n", found); LogPrintf("P2P peers available. Finished DNS seeding.\n"); } else { LogPrintf("P2P peers available. Skipped DNS seeding.\n"); } return; } } } } if (interruptNet) return; // hold off on querying seeds if P2P network deactivated if (!fNetworkActive) { LogPrintf("Waiting for network to be reactivated before querying DNS seeds.\n"); do { if (!interruptNet.sleep_for(std::chrono::seconds{1})) return; } while (!fNetworkActive); } LogPrintf("Loading addresses from DNS seed %s\n", seed); if (HaveNameProxy()) { AddAddrFetch(seed); } else { std::vector vIPs; std::vector vAdd; ServiceFlags requiredServiceBits = GetDesirableServiceFlags(NODE_NONE); std::string host = strprintf("x%x.%s", requiredServiceBits, seed); CNetAddr resolveSource; if (!resolveSource.SetInternal(host)) { continue; } unsigned int nMaxIPs = 256; // Limits number of IPs learned from a DNS seed if (LookupHost(host, vIPs, nMaxIPs, true)) { for (const CNetAddr& ip : vIPs) { int nOneDay = 24*3600; CAddress addr = CAddress(CService(ip, Params().GetDefaultPort()), requiredServiceBits); addr.nTime = GetTime() - 3*nOneDay - rng.randrange(4*nOneDay); // use a random age between 3 and 7 days old vAdd.push_back(addr); found++; } addrman.Add(vAdd, resolveSource); } else { // We now avoid directly using results from DNS Seeds which do not support service bit filtering, // instead using them as a addrfetch to get nodes with our desired service bits. AddAddrFetch(seed); } } --seeds_right_now; } LogPrintf("%d addresses found from DNS seeds\n", found); } void CConnman::DumpAddresses() { int64_t nStart = GetTimeMillis(); CAddrDB adb; adb.Write(addrman); LogPrint(BCLog::NET, "Flushed %d addresses to peers.dat %dms\n", addrman.size(), GetTimeMillis() - nStart); } void CConnman::ProcessAddrFetch() { std::string strDest; { LOCK(m_addr_fetches_mutex); if (m_addr_fetches.empty()) return; strDest = m_addr_fetches.front(); m_addr_fetches.pop_front(); } CAddress addr; CSemaphoreGrant grant(*semOutbound, true); if (grant) { OpenNetworkConnection(addr, false, &grant, strDest.c_str(), ConnectionType::ADDR_FETCH); } } bool CConnman::GetTryNewOutboundPeer() { return m_try_another_outbound_peer; } void CConnman::SetTryNewOutboundPeer(bool flag) { m_try_another_outbound_peer = flag; LogPrint(BCLog::NET, "net: setting try another outbound peer=%s\n", flag ? "true" : "false"); } // Return the number of peers we have over our outbound connection limit // Exclude peers that are marked for disconnect, or are going to be // disconnected soon (eg ADDR_FETCH and FEELER) // Also exclude peers that haven't finished initial connection handshake yet // (so that we don't decide we're over our desired connection limit, and then // evict some peer that has finished the handshake) int CConnman::GetExtraOutboundCount() { int nOutbound = 0; { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { // don't count outbound masternodes if (pnode->m_masternode_connection) { continue; } if (pnode->fSuccessfullyConnected && !pnode->fDisconnect && pnode->IsOutboundOrBlockRelayConn() && !pnode->m_masternode_probe_connection) { ++nOutbound; } } } return std::max(nOutbound - m_max_outbound_full_relay - m_max_outbound_block_relay, 0); } void CConnman::ThreadOpenConnections(const std::vector connect) { FastRandomContext rng; // Connect to specific addresses if (!connect.empty()) { for (int64_t nLoop = 0;; nLoop++) { ProcessAddrFetch(); for (const std::string& strAddr : connect) { CAddress addr(CService(), NODE_NONE); OpenNetworkConnection(addr, false, nullptr, strAddr.c_str(), ConnectionType::MANUAL); for (int i = 0; i < 10 && i < nLoop; i++) { if (!interruptNet.sleep_for(std::chrono::milliseconds(500))) return; } } if (!interruptNet.sleep_for(std::chrono::milliseconds(500))) return; } } // Initiate network connections int64_t nStart = GetTime(); // Minimum time before next feeler connection (in microseconds). int64_t nNextFeeler = PoissonNextSend(nStart*1000*1000, FEELER_INTERVAL); while (!interruptNet) { ProcessAddrFetch(); if (!interruptNet.sleep_for(std::chrono::milliseconds(500))) return; CSemaphoreGrant grant(*semOutbound); if (interruptNet) return; // Add seed nodes if DNS seeds are all down (an infrastructure attack?). // Note that we only do this if we started with an empty peers.dat, // (in which case we will query DNS seeds immediately) *and* the DNS // seeds have not returned any results. if (addrman.size() == 0 && (GetTime() - nStart > 60)) { static bool done = false; if (!done) { LogPrintf("Adding fixed seed nodes as DNS doesn't seem to be available.\n"); CNetAddr local; local.SetInternal("fixedseeds"); addrman.Add(ConvertSeeds(Params().FixedSeeds()), local); done = true; } } // // Choose an address to connect to based on most recently seen // CAddress addrConnect; // Only connect out to one peer per network group (/16 for IPv4). // This is only done for mainnet and testnet int nOutboundFullRelay = 0; int nOutboundBlockRelay = 0; std::set > setConnected; if (!Params().AllowMultipleAddressesFromGroup()) { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (pnode->IsFullOutboundConn() && !pnode->m_masternode_connection) nOutboundFullRelay++; if (pnode->IsBlockOnlyConn()) nOutboundBlockRelay++; // Netgroups for inbound and manual peers are not excluded because our goal here // is to not use multiple of our limited outbound slots on a single netgroup // but inbound and manual peers do not use our outbound slots. Inbound peers // also have the added issue that they could be attacker controlled and used // to prevent us from connecting to particular hosts if we used them here. switch (pnode->m_conn_type) { case ConnectionType::INBOUND: case ConnectionType::MANUAL: break; case ConnectionType::OUTBOUND_FULL_RELAY: case ConnectionType::BLOCK_RELAY: case ConnectionType::ADDR_FETCH: case ConnectionType::FEELER: setConnected.insert(pnode->addr.GetGroup(addrman.m_asmap)); } // no default case, so the compiler can warn about missing cases } } std::set setConnectedMasternodes; { LOCK(cs_vNodes); for (CNode* pnode : vNodes) { auto verifiedProRegTxHash = pnode->GetVerifiedProRegTxHash(); if (!verifiedProRegTxHash.IsNull()) { setConnectedMasternodes.emplace(verifiedProRegTxHash); } } } ConnectionType conn_type = ConnectionType::OUTBOUND_FULL_RELAY; int64_t nTime = GetTimeMicros(); bool fFeeler = false; // Determine what type of connection to open. Opening // OUTBOUND_FULL_RELAY connections gets the highest priority until we // meet our full-relay capacity. Then we open BLOCK_RELAY connection // until we hit our block-relay-only peer limit. // GetTryNewOutboundPeer() gets set when a stale tip is detected, so we // try opening an additional OUTBOUND_FULL_RELAY connection. If none of // these conditions are met, check the nNextFeeler timer to decide if // we should open a FEELER. if (nOutboundFullRelay < m_max_outbound_full_relay) { // OUTBOUND_FULL_RELAY } else if (nOutboundBlockRelay < m_max_outbound_block_relay) { conn_type = ConnectionType::BLOCK_RELAY; } else if (GetTryNewOutboundPeer()) { // OUTBOUND_FULL_RELAY } else if (nTime > nNextFeeler) { nNextFeeler = PoissonNextSend(nTime, FEELER_INTERVAL); conn_type = ConnectionType::FEELER; fFeeler = true; } else { // skip to next iteration of while loop continue; } addrman.ResolveCollisions(); auto mnList = deterministicMNManager->GetListAtChainTip(); int64_t nANow = GetAdjustedTime(); int nTries = 0; while (!interruptNet) { // If we didn't find an appropriate destination after trying 100 addresses fetched from addrman, // stop this loop, and let the outer loop run again (which sleeps, adds seed nodes, recalculates // already-connected network ranges, ...) before trying new addrman addresses. nTries++; if (nTries > 100) break; CAddrInfo addr = addrman.SelectTriedCollision(); // SelectTriedCollision returns an invalid address if it is empty. if (!fFeeler || !addr.IsValid()) { addr = addrman.Select(fFeeler); } auto dmn = mnList.GetMNByService(addr); bool isMasternode = dmn != nullptr; // Require outbound connections, other than feelers, to be to distinct network groups if (!fFeeler && setConnected.count(addr.GetGroup(addrman.m_asmap))) { break; } // if we selected an invalid address, restart if (!addr.IsValid() || setConnected.count(addr.GetGroup(addrman.m_asmap))) break; // don't try to connect to masternodes that we already have a connection to (most likely inbound) if (isMasternode && setConnectedMasternodes.count(dmn->proTxHash)) break; // if we selected a local address, restart (local addresses are allowed in regtest and devnet) bool fAllowLocal = Params().AllowMultiplePorts() && addrConnect.GetPort() != GetListenPort(); if (!fAllowLocal && IsLocal(addrConnect)) { break; } if (!IsReachable(addr)) continue; // only consider very recently tried nodes after 30 failed attempts if (nANow - addr.nLastTry < 600 && nTries < 30) continue; // for non-feelers, require all the services we'll want, // for feelers, only require they be a full node (only because most // SPV clients don't have a good address DB available) if (!isMasternode && !fFeeler && !HasAllDesirableServiceFlags(addr.nServices)) { continue; } else if (!isMasternode && fFeeler && !MayHaveUsefulAddressDB(addr.nServices)) { continue; } // Do not allow non-default ports, unless after 50 invalid // addresses selected already. This is to prevent malicious peers // from advertising themselves as a service on another host and // port, causing a DoS attack as nodes around the network attempt // to connect to it fruitlessly. if ((!isMasternode || !Params().AllowMultiplePorts()) && addr.GetPort() != Params().GetDefaultPort(addr.GetNetwork()) && addr.GetPort() != GetListenPort() && nTries < 50) { continue; } addrConnect = addr; break; } if (addrConnect.IsValid()) { if (fFeeler) { // Add small amount of random noise before connection to avoid synchronization. if (!interruptNet.sleep_for(rng.rand_uniform_duration(FEELER_SLEEP_WINDOW))) { return; } if (fLogIPs) { LogPrint(BCLog::NET, "Making feeler connection to %s\n", addrConnect.ToString()); } else { LogPrint(BCLog::NET, "Making feeler connection\n"); } } OpenNetworkConnection(addrConnect, (int)setConnected.size() >= std::min(nMaxConnections - 1, 2), &grant, nullptr, conn_type); } } } std::vector CConnman::GetCurrentBlockRelayOnlyConns() const { std::vector ret; LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (pnode->IsBlockRelayOnly()) { ret.push_back(pnode->addr); } } return ret; } std::vector CConnman::GetAddedNodeInfo() { std::vector ret; std::list lAddresses(0); { LOCK(cs_vAddedNodes); ret.reserve(vAddedNodes.size()); std::copy(vAddedNodes.cbegin(), vAddedNodes.cend(), std::back_inserter(lAddresses)); } // Build a map of all already connected addresses (by IP:port and by name) to inbound/outbound and resolved CService std::map mapConnected; std::map> mapConnectedByName; { LOCK(cs_vNodes); for (const CNode* pnode : vNodes) { if (pnode->addr.IsValid()) { mapConnected[pnode->addr] = pnode->IsInboundConn(); } std::string addrName = pnode->GetAddrName(); if (!addrName.empty()) { mapConnectedByName[std::move(addrName)] = std::make_pair(pnode->IsInboundConn(), static_cast(pnode->addr)); } } } for (const std::string& strAddNode : lAddresses) { CService service(LookupNumeric(strAddNode, Params().GetDefaultPort(strAddNode))); AddedNodeInfo addedNode{strAddNode, CService(), false, false}; if (service.IsValid()) { // strAddNode is an IP:port auto it = mapConnected.find(service); if (it != mapConnected.end()) { addedNode.resolvedAddress = service; addedNode.fConnected = true; addedNode.fInbound = it->second; } } else { // strAddNode is a name auto it = mapConnectedByName.find(strAddNode); if (it != mapConnectedByName.end()) { addedNode.resolvedAddress = it->second.second; addedNode.fConnected = true; addedNode.fInbound = it->second.first; } } ret.emplace_back(std::move(addedNode)); } return ret; } void CConnman::ThreadOpenAddedConnections() { while (true) { CSemaphoreGrant grant(*semAddnode); std::vector vInfo = GetAddedNodeInfo(); bool tried = false; for (const AddedNodeInfo& info : vInfo) { if (!info.fConnected) { if (!grant.TryAcquire()) { // If we've used up our semaphore and need a new one, let's not wait here since while we are waiting // the addednodeinfo state might change. break; } tried = true; CAddress addr(CService(), NODE_NONE); OpenNetworkConnection(addr, false, &grant, info.strAddedNode.c_str(), ConnectionType::MANUAL); if (!interruptNet.sleep_for(std::chrono::milliseconds(500))) return; } } // Retry every 60 seconds if a connection was attempted, otherwise two seconds if (!interruptNet.sleep_for(std::chrono::seconds(tried ? 60 : 2))) return; } } void CConnman::ThreadOpenMasternodeConnections() { // Connecting to specific addresses, no masternode connections available if (gArgs.IsArgSet("-connect") && gArgs.GetArgs("-connect").size() > 0) return; assert(::mmetaman != nullptr); auto& chainParams = Params(); bool didConnect = false; while (!interruptNet) { auto sleepTime = std::chrono::milliseconds(1000); if (didConnect) { sleepTime = std::chrono::milliseconds(100); } if (!interruptNet.sleep_for(sleepTime)) return; didConnect = false; if (!fNetworkActive || !::masternodeSync->IsBlockchainSynced()) continue; std::set connectedNodes; std::map connectedProRegTxHashes; ForEachNode([&](const CNode* pnode) { auto verifiedProRegTxHash = pnode->GetVerifiedProRegTxHash(); connectedNodes.emplace(pnode->addr); if (!verifiedProRegTxHash.IsNull()) { connectedProRegTxHashes.emplace(verifiedProRegTxHash, pnode->IsInboundConn()); } }); auto mnList = deterministicMNManager->GetListAtChainTip(); if (interruptNet) return; int64_t nANow = GetTime().count(); constexpr const auto &_func_ = __func__; // NOTE: Process only one pending masternode at a time MasternodeProbeConn isProbe = MasternodeProbeConn::IsNotConnection; const auto getPendingQuorumNodes = [&]() { LockAssertion lock(cs_vPendingMasternodes); std::vector ret; for (const auto& group : masternodeQuorumNodes) { for (const auto& proRegTxHash : group.second) { auto dmn = mnList.GetMN(proRegTxHash); if (!dmn) { continue; } const auto& addr2 = dmn->pdmnState->addr; if (connectedNodes.count(addr2) && !connectedProRegTxHashes.count(proRegTxHash)) { // we probably connected to it before it became a masternode // or maybe we are still waiting for mnauth (void)ForNode(addr2, [&](CNode* pnode) { if (pnode->nTimeFirstMessageReceived != 0 && GetSystemTimeInSeconds() - pnode->nTimeFirstMessageReceived > 5) { // clearly not expecting mnauth to take that long even if it wasn't the first message // we received (as it should normally), disconnect LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- dropping non-mnauth connection to %s, service=%s\n", _func_, proRegTxHash.ToString(), addr2.ToString(false)); pnode->fDisconnect = true; return true; } return false; }); // either way - it's not ready, skip it for now continue; } if (!connectedNodes.count(addr2) && !IsMasternodeOrDisconnectRequested(addr2) && !connectedProRegTxHashes.count(proRegTxHash)) { int64_t lastAttempt = mmetaman->GetMetaInfo(dmn->proTxHash)->GetLastOutboundAttempt(); // back off trying connecting to an address if we already tried recently if (nANow - lastAttempt < chainParams.LLMQConnectionRetryTimeout()) { continue; } ret.emplace_back(dmn); } } } return ret; }; const auto getPendingProbes = [&]() { LockAssertion lock(cs_vPendingMasternodes); std::vector ret; for (auto it = masternodePendingProbes.begin(); it != masternodePendingProbes.end(); ) { auto dmn = mnList.GetMN(*it); if (!dmn) { it = masternodePendingProbes.erase(it); continue; } bool connectedAndOutbound = connectedProRegTxHashes.count(dmn->proTxHash) && !connectedProRegTxHashes[dmn->proTxHash]; if (connectedAndOutbound) { // we already have an outbound connection to this MN so there is no theed to probe it again mmetaman->GetMetaInfo(dmn->proTxHash)->SetLastOutboundSuccess(nANow); it = masternodePendingProbes.erase(it); continue; } ++it; int64_t lastAttempt = mmetaman->GetMetaInfo(dmn->proTxHash)->GetLastOutboundAttempt(); // back off trying connecting to an address if we already tried recently if (nANow - lastAttempt < chainParams.LLMQConnectionRetryTimeout()) { continue; } ret.emplace_back(dmn); } return ret; }; auto getConnectToDmn = [&]() -> CDeterministicMNCPtr { // don't hold lock while calling OpenMasternodeConnection as cs_main is locked deep inside LOCK2(cs_vNodes, cs_vPendingMasternodes); if (!vPendingMasternodes.empty()) { auto dmn = mnList.GetValidMN(vPendingMasternodes.front()); vPendingMasternodes.erase(vPendingMasternodes.begin()); if (dmn && !connectedNodes.count(dmn->pdmnState->addr) && !IsMasternodeOrDisconnectRequested(dmn->pdmnState->addr)) { LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- opening pending masternode connection to %s, service=%s\n", _func_, dmn->proTxHash.ToString(), dmn->pdmnState->addr.ToString(false)); return dmn; } } if (const auto pending = getPendingQuorumNodes(); !pending.empty()) { // not-null auto dmn = pending[GetRand(pending.size())]; LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- opening quorum connection to %s, service=%s\n", _func_, dmn->proTxHash.ToString(), dmn->pdmnState->addr.ToString(false)); return dmn; } if (const auto pending = getPendingProbes(); !pending.empty()) { // not-null auto dmn = pending[GetRand(pending.size())]; masternodePendingProbes.erase(dmn->proTxHash); isProbe = MasternodeProbeConn::IsConnection; LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- probing masternode %s, service=%s\n", _func_, dmn->proTxHash.ToString(), dmn->pdmnState->addr.ToString(false)); return dmn; } return nullptr; }; CDeterministicMNCPtr connectToDmn = getConnectToDmn(); if (connectToDmn == nullptr) { continue; } didConnect = true; mmetaman->GetMetaInfo(connectToDmn->proTxHash)->SetLastOutboundAttempt(nANow); OpenMasternodeConnection(CAddress(connectToDmn->pdmnState->addr, NODE_NETWORK), isProbe); // should be in the list now if connection was opened bool connected = ForNode(connectToDmn->pdmnState->addr, CConnman::AllNodes, [&](CNode* pnode) { if (pnode->fDisconnect) { return false; } return true; }); if (!connected) { LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- connection failed for masternode %s, service=%s\n", __func__, connectToDmn->proTxHash.ToString(), connectToDmn->pdmnState->addr.ToString(false)); // Will take a few consequent failed attempts to PoSe-punish a MN. if (mmetaman->GetMetaInfo(connectToDmn->proTxHash)->OutboundFailedTooManyTimes()) { LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- failed to connect to masternode %s too many times\n", __func__, connectToDmn->proTxHash.ToString()); } } } } // if successful, this moves the passed grant to the constructed node void CConnman::OpenNetworkConnection(const CAddress& addrConnect, bool fCountFailure, CSemaphoreGrant *grantOutbound, const char *pszDest, ConnectionType conn_type, MasternodeConn masternode_connection, MasternodeProbeConn masternode_probe_connection) { assert(conn_type != ConnectionType::INBOUND); // // Initiate outbound network connection // if (interruptNet) { return; } if (!fNetworkActive) { return; } auto getIpStr = [&]() { if (fLogIPs) { return addrConnect.ToString(false); } else { return std::string("new peer"); } }; if (!pszDest) { // banned, discouraged or exact match? if ((m_banman && (m_banman->IsDiscouraged(addrConnect) || m_banman->IsBanned(addrConnect))) || FindNode(addrConnect.ToStringIPPort())) return; // local and not a connection to itself? bool fAllowLocal = Params().AllowMultiplePorts() && addrConnect.GetPort() != GetListenPort(); if (!fAllowLocal && IsLocal(addrConnect)) return; // Search for IP:PORT match: // - if multiple ports for the same IP are allowed, // - for probe connections // Search for IP-only match otherwise bool searchIPPort = Params().AllowMultiplePorts() || masternode_probe_connection == MasternodeProbeConn::IsConnection; bool skip = searchIPPort ? FindNode(static_cast(addrConnect)) : FindNode(static_cast(addrConnect)); if (skip) { LogPrintf("CConnman::%s -- Failed to open new connection to %s, already connected\n", __func__, getIpStr()); return; } } else if (FindNode(std::string(pszDest))) return; LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- connecting to %s\n", __func__, getIpStr()); CNode* pnode = ConnectNode(addrConnect, pszDest, fCountFailure, conn_type); if (!pnode) { LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- ConnectNode failed for %s\n", __func__, getIpStr()); return; } { LOCK(pnode->cs_hSocket); LogPrint(BCLog::NET_NETCONN, "CConnman::%s -- successfully connected to %s, sock=%d, peer=%d\n", __func__, getIpStr(), pnode->hSocket, pnode->GetId()); } if (grantOutbound) grantOutbound->MoveTo(pnode->grantOutbound); if (masternode_connection == MasternodeConn::IsConnection) pnode->m_masternode_connection = true; if (masternode_probe_connection == MasternodeProbeConn::IsConnection) pnode->m_masternode_probe_connection = true; { LOCK2(cs_vNodes, pnode->cs_hSocket); mapSocketToNode.emplace(pnode->hSocket, pnode); } m_msgproc->InitializeNode(pnode); { LOCK(cs_vNodes); vNodes.push_back(pnode); RegisterEvents(pnode); WakeSelect(); } } void CConnman::OpenMasternodeConnection(const CAddress &addrConnect, MasternodeProbeConn probe) { OpenNetworkConnection(addrConnect, false, nullptr, nullptr, ConnectionType::OUTBOUND_FULL_RELAY, MasternodeConn::IsConnection, probe); } void CConnman::ThreadMessageHandler() { int64_t nLastSendMessagesTimeMasternodes = 0; while (!flagInterruptMsgProc) { std::vector vNodesCopy = CopyNodeVector(); bool fMoreWork = false; bool fSkipSendMessagesForMasternodes = true; if (GetTimeMillis() - nLastSendMessagesTimeMasternodes >= 100) { fSkipSendMessagesForMasternodes = false; nLastSendMessagesTimeMasternodes = GetTimeMillis(); } for (CNode* pnode : vNodesCopy) { if (pnode->fDisconnect) continue; // Receive messages bool fMoreNodeWork = m_msgproc->ProcessMessages(pnode, flagInterruptMsgProc); fMoreWork |= (fMoreNodeWork && !pnode->fPauseSend); if (flagInterruptMsgProc) return; // Send messages if (!fSkipSendMessagesForMasternodes || !pnode->m_masternode_connection) { LOCK(pnode->cs_sendProcessing); m_msgproc->SendMessages(pnode); } if (flagInterruptMsgProc) return; } ReleaseNodeVector(vNodesCopy); WAIT_LOCK(mutexMsgProc, lock); if (!fMoreWork) { condMsgProc.wait_until(lock, std::chrono::steady_clock::now() + std::chrono::milliseconds(100), [this]() EXCLUSIVE_LOCKS_REQUIRED(mutexMsgProc) { return fMsgProcWake; }); } fMsgProcWake = false; } } void CConnman::ThreadI2PAcceptIncoming() { static constexpr auto err_wait_begin = 1s; static constexpr auto err_wait_cap = 5min; auto err_wait = err_wait_begin; bool advertising_listen_addr = false; i2p::Connection conn; while (!interruptNet) { if (!m_i2p_sam_session->Listen(conn)) { if (advertising_listen_addr && conn.me.IsValid()) { RemoveLocal(conn.me); advertising_listen_addr = false; } interruptNet.sleep_for(err_wait); if (err_wait < err_wait_cap) { err_wait *= 2; } continue; } if (!advertising_listen_addr) { AddLocal(conn.me, LOCAL_MANUAL); advertising_listen_addr = true; } if (!m_i2p_sam_session->Accept(conn)) { continue; } CreateNodeFromAcceptedSocket(conn.sock->Release(), NetPermissionFlags::PF_NONE, CAddress{conn.me, NODE_NONE}, CAddress{conn.peer, NODE_NONE}); } } bool CConnman::BindListenPort(const CService& addrBind, bilingual_str& strError, NetPermissionFlags permissions) { int nOne = 1; // Create socket for listening for incoming connections struct sockaddr_storage sockaddr; socklen_t len = sizeof(sockaddr); if (!addrBind.GetSockAddr((struct sockaddr*)&sockaddr, &len)) { strError = strprintf(Untranslated("Error: Bind address family for %s not supported"), addrBind.ToString()); LogPrintf("%s\n", strError.original); return false; } std::unique_ptr sock = CreateSock(addrBind); if (!sock) { strError = strprintf(Untranslated("Error: Couldn't open socket for incoming connections (socket returned error %s)"), NetworkErrorString(WSAGetLastError())); LogPrintf("%s\n", strError.original); return false; } // Allow binding if the port is still in TIME_WAIT state after // the program was closed and restarted. setsockopt(sock->Get(), SOL_SOCKET, SO_REUSEADDR, (sockopt_arg_type)&nOne, sizeof(int)); // some systems don't have IPV6_V6ONLY but are always v6only; others do have the option // and enable it by default or not. Try to enable it, if possible. if (addrBind.IsIPv6()) { #ifdef IPV6_V6ONLY setsockopt(sock->Get(), IPPROTO_IPV6, IPV6_V6ONLY, (sockopt_arg_type)&nOne, sizeof(int)); #endif #ifdef WIN32 int nProtLevel = PROTECTION_LEVEL_UNRESTRICTED; setsockopt(sock->Get(), IPPROTO_IPV6, IPV6_PROTECTION_LEVEL, (const char*)&nProtLevel, sizeof(int)); #endif } if (::bind(sock->Get(), (struct sockaddr*)&sockaddr, len) == SOCKET_ERROR) { int nErr = WSAGetLastError(); if (nErr == WSAEADDRINUSE) strError = strprintf(_("Unable to bind to %s on this computer. %s is probably already running."), addrBind.ToString(), PACKAGE_NAME); else strError = strprintf(_("Unable to bind to %s on this computer (bind returned error %s)"), addrBind.ToString(), NetworkErrorString(nErr)); LogPrintf("%s\n", strError.original); return false; } LogPrintf("Bound to %s\n", addrBind.ToString()); // Listen for incoming connections if (listen(sock->Get(), SOMAXCONN) == SOCKET_ERROR) { strError = strprintf(_("Error: Listening for incoming connections failed (listen returned error %s)"), NetworkErrorString(WSAGetLastError())); LogPrintf("%s\n", strError.original); return false; } #ifdef USE_KQUEUE if (socketEventsMode == SOCKETEVENTS_KQUEUE) { struct kevent event; EV_SET(&event, sock->Get(), EVFILT_READ, EV_ADD, 0, 0, nullptr); if (kevent(kqueuefd, &event, 1, nullptr, 0, nullptr) != 0) { strError = strprintf(_("Error: failed to add socket to kqueuefd (kevent returned error %s)"), NetworkErrorString(WSAGetLastError())); LogPrintf("%s\n", strError.original); return false; } } #endif #ifdef USE_EPOLL if (socketEventsMode == SOCKETEVENTS_EPOLL) { epoll_event event; event.data.fd = sock->Get(); event.events = EPOLLIN; if (epoll_ctl(epollfd, EPOLL_CTL_ADD, sock->Get(), &event) != 0) { strError = strprintf(_("Error: failed to add socket to epollfd (epoll_ctl returned error %s)"), NetworkErrorString(WSAGetLastError())); LogPrintf("%s\n", strError.original); return false; } } #endif vhListenSocket.push_back(ListenSocket(sock->Release(), permissions)); return true; } void Discover() { if (!fDiscover) return; #ifdef WIN32 // Get local host IP char pszHostName[256] = ""; if (gethostname(pszHostName, sizeof(pszHostName)) != SOCKET_ERROR) { std::vector vaddr; if (LookupHost(pszHostName, vaddr, 0, true)) { for (const CNetAddr &addr : vaddr) { if (AddLocal(addr, LOCAL_IF)) LogPrintf("%s: %s - %s\n", __func__, pszHostName, addr.ToString()); } } } #elif (HAVE_DECL_GETIFADDRS && HAVE_DECL_FREEIFADDRS) // Get local host ip struct ifaddrs* myaddrs; if (getifaddrs(&myaddrs) == 0) { for (struct ifaddrs* ifa = myaddrs; ifa != nullptr; ifa = ifa->ifa_next) { if (ifa->ifa_addr == nullptr) continue; if ((ifa->ifa_flags & IFF_UP) == 0) continue; if (strcmp(ifa->ifa_name, "lo") == 0) continue; if (strcmp(ifa->ifa_name, "lo0") == 0) continue; if (ifa->ifa_addr->sa_family == AF_INET) { struct sockaddr_in* s4 = (struct sockaddr_in*)(ifa->ifa_addr); CNetAddr addr(s4->sin_addr); if (AddLocal(addr, LOCAL_IF)) LogPrintf("%s: IPv4 %s: %s\n", __func__, ifa->ifa_name, addr.ToString()); } else if (ifa->ifa_addr->sa_family == AF_INET6) { struct sockaddr_in6* s6 = (struct sockaddr_in6*)(ifa->ifa_addr); CNetAddr addr(s6->sin6_addr); if (AddLocal(addr, LOCAL_IF)) LogPrintf("%s: IPv6 %s: %s\n", __func__, ifa->ifa_name, addr.ToString()); } } freeifaddrs(myaddrs); } #endif } void CConnman::SetNetworkActive(bool active) { LogPrint(BCLog::NET, "SetNetworkActive: %s\n", active); if (fNetworkActive == active) { return; } fNetworkActive = active; // Always call the Reset() if the network gets enabled/disabled to make sure the sync process // gets a reset if its outdated.. ::masternodeSync->Reset(); uiInterface.NotifyNetworkActiveChanged(fNetworkActive); } CConnman::CConnman(uint64_t nSeed0In, uint64_t nSeed1In, CAddrMan& addrman_in) : addrman(addrman_in), nSeed0(nSeed0In), nSeed1(nSeed1In) { SetTryNewOutboundPeer(false); Options connOptions; Init(connOptions); } NodeId CConnman::GetNewNodeId() { return nLastNodeId.fetch_add(1, std::memory_order_relaxed); } bool CConnman::Bind(const CService &addr, unsigned int flags, NetPermissionFlags permissions) { if (!(flags & BF_EXPLICIT) && !IsReachable(addr)) { return false; } bilingual_str strError; if (!BindListenPort(addr, strError, permissions)) { if ((flags & BF_REPORT_ERROR) && clientInterface) { clientInterface->ThreadSafeMessageBox(strError, "", CClientUIInterface::MSG_ERROR); } return false; } if (addr.IsRoutable() && fDiscover && !(flags & BF_DONT_ADVERTISE) && !NetPermissions::HasFlag(permissions, NetPermissionFlags::PF_NOBAN)) { AddLocal(addr, LOCAL_BIND); } return true; } bool CConnman::InitBinds( const std::vector& binds, const std::vector& whiteBinds, const std::vector& onion_binds) { bool fBound = false; for (const auto& addrBind : binds) { fBound |= Bind(addrBind, (BF_EXPLICIT | BF_REPORT_ERROR), NetPermissionFlags::PF_NONE); } for (const auto& addrBind : whiteBinds) { fBound |= Bind(addrBind.m_service, (BF_EXPLICIT | BF_REPORT_ERROR), addrBind.m_flags); } if (binds.empty() && whiteBinds.empty()) { struct in_addr inaddr_any; inaddr_any.s_addr = htonl(INADDR_ANY); struct in6_addr inaddr6_any = IN6ADDR_ANY_INIT; fBound |= Bind(CService(inaddr6_any, GetListenPort()), BF_NONE, NetPermissionFlags::PF_NONE); fBound |= Bind(CService(inaddr_any, GetListenPort()), !fBound ? BF_REPORT_ERROR : BF_NONE, NetPermissionFlags::PF_NONE); } for (const auto& addr_bind : onion_binds) { fBound |= Bind(addr_bind, BF_EXPLICIT | BF_DONT_ADVERTISE, NetPermissionFlags::PF_NONE); } return fBound; } bool CConnman::Start(CScheduler& scheduler, const Options& connOptions) { Init(connOptions); #ifdef USE_KQUEUE if (socketEventsMode == SOCKETEVENTS_KQUEUE) { kqueuefd = kqueue(); if (kqueuefd == -1) { LogPrintf("kqueue failed\n"); return false; } } #endif #ifdef USE_EPOLL if (socketEventsMode == SOCKETEVENTS_EPOLL) { epollfd = epoll_create1(0); if (epollfd == -1) { LogPrintf("epoll_create1 failed\n"); return false; } } #endif if (fListen && !InitBinds(connOptions.vBinds, connOptions.vWhiteBinds, connOptions.onion_binds)) { if (clientInterface) { clientInterface->ThreadSafeMessageBox( _("Failed to listen on any port. Use -listen=0 if you want this."), "", CClientUIInterface::MSG_ERROR); } return false; } proxyType i2p_sam; if (GetProxy(NET_I2P, i2p_sam)) { m_i2p_sam_session = std::make_unique(GetDataDir() / "i2p_private_key", i2p_sam.proxy, &interruptNet); } for (const auto& strDest : connOptions.vSeedNodes) { AddAddrFetch(strDest); } if (clientInterface) { clientInterface->InitMessage(_("Loading P2P addresses...").translated); } // Load addresses from peers.dat int64_t nStart = GetTimeMillis(); { CAddrDB adb; if (adb.Read(addrman)) LogPrintf("Loaded %i addresses from peers.dat %dms\n", addrman.size(), GetTimeMillis() - nStart); else { addrman.Clear(); // Addrman can be in an inconsistent state after failure, reset it LogPrintf("Recreating peers.dat\n"); DumpAddresses(); } } if (m_use_addrman_outgoing) { // Load addresses from anchors.dat m_anchors = ReadAnchors(GetDataDir() / ANCHORS_DATABASE_FILENAME); if (m_anchors.size() > MAX_BLOCK_RELAY_ONLY_ANCHORS) { m_anchors.resize(MAX_BLOCK_RELAY_ONLY_ANCHORS); } LogPrintf("%i block-relay-only anchors will be tried for connections.\n", m_anchors.size()); } uiInterface.InitMessage(_("Starting network threads...").translated); fAddressesInitialized = true; if (semOutbound == nullptr) { // initialize semaphore semOutbound = std::make_unique(std::min(m_max_outbound, nMaxConnections)); } if (semAddnode == nullptr) { // initialize semaphore semAddnode = std::make_unique(nMaxAddnode); } // // Start threads // assert(m_msgproc); InterruptSocks5(false); interruptNet.reset(); flagInterruptMsgProc = false; { LOCK(mutexMsgProc); fMsgProcWake = false; } #ifdef USE_WAKEUP_PIPE if (pipe(wakeupPipe) != 0) { wakeupPipe[0] = wakeupPipe[1] = -1; LogPrint(BCLog::NET, "pipe() for wakeupPipe failed\n"); } else { int fFlags = fcntl(wakeupPipe[0], F_GETFL, 0); if (fcntl(wakeupPipe[0], F_SETFL, fFlags | O_NONBLOCK) == -1) { LogPrint(BCLog::NET, "fcntl for O_NONBLOCK on wakeupPipe failed\n"); } fFlags = fcntl(wakeupPipe[1], F_GETFL, 0); if (fcntl(wakeupPipe[1], F_SETFL, fFlags | O_NONBLOCK) == -1) { LogPrint(BCLog::NET, "fcntl for O_NONBLOCK on wakeupPipe failed\n"); } #ifdef USE_KQUEUE if (socketEventsMode == SOCKETEVENTS_KQUEUE) { struct kevent event; EV_SET(&event, wakeupPipe[0], EVFILT_READ, EV_ADD, 0, 0, nullptr); int r = kevent(kqueuefd, &event, 1, nullptr, 0, nullptr); if (r != 0) { LogPrint(BCLog::NET, "%s -- kevent(%d, %d, %d, ...) failed. error: %s\n", __func__, kqueuefd, EV_ADD, wakeupPipe[0], NetworkErrorString(WSAGetLastError())); return false; } } #endif #ifdef USE_EPOLL if (socketEventsMode == SOCKETEVENTS_EPOLL) { epoll_event event; event.events = EPOLLIN; event.data.fd = wakeupPipe[0]; int r = epoll_ctl(epollfd, EPOLL_CTL_ADD, wakeupPipe[0], &event); if (r != 0) { LogPrint(BCLog::NET, "%s -- epoll_ctl(%d, %d, %d, ...) failed. error: %s\n", __func__, epollfd, EPOLL_CTL_ADD, wakeupPipe[0], NetworkErrorString(WSAGetLastError())); return false; } } #endif } #endif // Send and receive from sockets, accept connections threadSocketHandler = std::thread(&util::TraceThread, "net", [this] { ThreadSocketHandler(); }); if (!gArgs.GetBoolArg("-dnsseed", true)) LogPrintf("DNS seeding disabled\n"); else threadDNSAddressSeed = std::thread(&util::TraceThread, "dnsseed", [this] { ThreadDNSAddressSeed(); }); // Initiate manual connections threadOpenAddedConnections = std::thread(&util::TraceThread, "addcon", [this] { ThreadOpenAddedConnections(); }); if (connOptions.m_use_addrman_outgoing && !connOptions.m_specified_outgoing.empty()) { if (clientInterface) { clientInterface->ThreadSafeMessageBox( _("Cannot provide specific connections and have addrman find outgoing connections at the same."), "", CClientUIInterface::MSG_ERROR); } return false; } if (connOptions.m_use_addrman_outgoing || !connOptions.m_specified_outgoing.empty()) { threadOpenConnections = std::thread( &util::TraceThread, "opencon", [this, connect = connOptions.m_specified_outgoing] { ThreadOpenConnections(connect); }); } // Initiate masternode connections threadOpenMasternodeConnections = std::thread(&util::TraceThread, "mncon", [this] { ThreadOpenMasternodeConnections(); }); // Process messages threadMessageHandler = std::thread(&util::TraceThread, "msghand", [this] { ThreadMessageHandler(); }); if (connOptions.m_i2p_accept_incoming && m_i2p_sam_session.get() != nullptr) { threadI2PAcceptIncoming = std::thread(&util::TraceThread, "i2paccept", [this] { ThreadI2PAcceptIncoming(); }); } // Dump network addresses scheduler.scheduleEvery([this] { DumpAddresses(); }, DUMP_PEERS_INTERVAL); return true; } class CNetCleanup { public: CNetCleanup() {} ~CNetCleanup() { #ifdef WIN32 // Shutdown Windows Sockets WSACleanup(); #endif } }; static CNetCleanup instance_of_cnetcleanup; void CExplicitNetCleanup::callCleanup() { // Explicit call to destructor of CNetCleanup because it's not implicitly called // when the wallet is restarted from within the wallet itself. CNetCleanup tmp; } void CConnman::Interrupt() { { LOCK(mutexMsgProc); flagInterruptMsgProc = true; } condMsgProc.notify_all(); interruptNet(); InterruptSocks5(true); if (semOutbound) { for (int i=0; ipost(); } } if (semAddnode) { for (int i=0; ipost(); } } } void CConnman::StopThreads() { if (threadI2PAcceptIncoming.joinable()) { threadI2PAcceptIncoming.join(); } if (threadMessageHandler.joinable()) threadMessageHandler.join(); if (threadOpenMasternodeConnections.joinable()) threadOpenMasternodeConnections.join(); if (threadOpenConnections.joinable()) threadOpenConnections.join(); if (threadOpenAddedConnections.joinable()) threadOpenAddedConnections.join(); if (threadDNSAddressSeed.joinable()) threadDNSAddressSeed.join(); if (threadSocketHandler.joinable()) threadSocketHandler.join(); } void CConnman::StopNodes() { if (fAddressesInitialized) { DumpAddresses(); fAddressesInitialized = false; if (m_use_addrman_outgoing) { // Anchor connections are only dumped during clean shutdown. std::vector anchors_to_dump = GetCurrentBlockRelayOnlyConns(); if (anchors_to_dump.size() > MAX_BLOCK_RELAY_ONLY_ANCHORS) { anchors_to_dump.resize(MAX_BLOCK_RELAY_ONLY_ANCHORS); } DumpAnchors(GetDataDir() / ANCHORS_DATABASE_FILENAME, anchors_to_dump); } } { LOCK(cs_vNodes); // Close sockets for (CNode *pnode : vNodes) pnode->CloseSocketDisconnect(this); } for (ListenSocket& hListenSocket : vhListenSocket) if (hListenSocket.socket != INVALID_SOCKET) { #ifdef USE_KQUEUE if (socketEventsMode == SOCKETEVENTS_KQUEUE) { struct kevent event; EV_SET(&event, hListenSocket.socket, EVFILT_READ, EV_DELETE, 0, 0, nullptr); kevent(kqueuefd, &event, 1, nullptr, 0, nullptr); } #endif #ifdef USE_EPOLL if (socketEventsMode == SOCKETEVENTS_EPOLL) { epoll_ctl(epollfd, EPOLL_CTL_DEL, hListenSocket.socket, nullptr); } #endif if (!CloseSocket(hListenSocket.socket)) LogPrintf("CloseSocket(hListenSocket) failed with error %s\n", NetworkErrorString(WSAGetLastError())); } // clean up some globals (to help leak detection) std::vector nodes; WITH_LOCK(cs_vNodes, nodes.swap(vNodes)); for (CNode* pnode : nodes) { DeleteNode(pnode); } for (CNode* pnode : vNodesDisconnected) { DeleteNode(pnode); } mapSocketToNode.clear(); { LOCK(cs_vNodes); mapReceivableNodes.clear(); } { LOCK(cs_mapNodesWithDataToSend); mapNodesWithDataToSend.clear(); } vNodesDisconnected.clear(); vhListenSocket.clear(); semOutbound.reset(); semAddnode.reset(); #ifdef USE_KQUEUE if (socketEventsMode == SOCKETEVENTS_KQUEUE && kqueuefd != -1) { #ifdef USE_WAKEUP_PIPE struct kevent event; EV_SET(&event, wakeupPipe[0], EVFILT_READ, EV_DELETE, 0, 0, nullptr); kevent(kqueuefd, &event, 1, nullptr, 0, nullptr); #endif close(kqueuefd); } kqueuefd = -1; #endif #ifdef USE_EPOLL if (socketEventsMode == SOCKETEVENTS_EPOLL && epollfd != -1) { #ifdef USE_WAKEUP_PIPE epoll_ctl(epollfd, EPOLL_CTL_DEL, wakeupPipe[0], nullptr); #endif close(epollfd); } epollfd = -1; #endif #ifdef USE_WAKEUP_PIPE if (wakeupPipe[0] != -1) close(wakeupPipe[0]); if (wakeupPipe[1] != -1) close(wakeupPipe[1]); wakeupPipe[0] = wakeupPipe[1] = -1; #endif } void CConnman::DeleteNode(CNode* pnode) { assert(pnode); m_msgproc->FinalizeNode(*pnode); delete pnode; } CConnman::~CConnman() { Interrupt(); Stop(); } std::vector CConnman::GetAddresses(size_t max_addresses, size_t max_pct, std::optional network) { std::vector addresses = addrman.GetAddr(max_addresses, max_pct, network); if (m_banman) { addresses.erase(std::remove_if(addresses.begin(), addresses.end(), [this](const CAddress& addr){return m_banman->IsDiscouraged(addr) || m_banman->IsBanned(addr);}), addresses.end()); } return addresses; } std::vector CConnman::GetAddresses(CNode& requestor, size_t max_addresses, size_t max_pct) { auto local_socket_bytes = requestor.addrBind.GetAddrBytes(); uint64_t cache_id = GetDeterministicRandomizer(RANDOMIZER_ID_ADDRCACHE) .Write(requestor.addr.GetNetwork()) .Write(local_socket_bytes.data(), local_socket_bytes.size()) .Finalize(); const auto current_time = GetTime(); auto r = m_addr_response_caches.emplace(cache_id, CachedAddrResponse{}); CachedAddrResponse& cache_entry = r.first->second; if (cache_entry.m_cache_entry_expiration < current_time) { // If emplace() added new one it has expiration 0. cache_entry.m_addrs_response_cache = GetAddresses(max_addresses, max_pct, /* network */ std::nullopt); // Choosing a proper cache lifetime is a trade-off between the privacy leak minimization // and the usefulness of ADDR responses to honest users. // // Longer cache lifetime makes it more difficult for an attacker to scrape // enough AddrMan data to maliciously infer something useful. // By the time an attacker scraped enough AddrMan records, most of // the records should be old enough to not leak topology info by // e.g. analyzing real-time changes in timestamps. // // It takes only several hundred requests to scrape everything from an AddrMan containing 100,000 nodes, // so ~24 hours of cache lifetime indeed makes the data less inferable by the time // most of it could be scraped (considering that timestamps are updated via // ADDR self-announcements and when nodes communicate). // We also should be robust to those attacks which may not require scraping *full* victim's AddrMan // (because even several timestamps of the same handful of nodes may leak privacy). // // On the other hand, longer cache lifetime makes ADDR responses // outdated and less useful for an honest requestor, e.g. if most nodes // in the ADDR response are no longer active. // // However, the churn in the network is known to be rather low. Since we consider // nodes to be "terrible" (see IsTerrible()) if the timestamps are older than 30 days, // max. 24 hours of "penalty" due to cache shouldn't make any meaningful difference // in terms of the freshness of the response. cache_entry.m_cache_entry_expiration = current_time + std::chrono::hours(21) + GetRandMillis(std::chrono::hours(6)); } return cache_entry.m_addrs_response_cache; } bool CConnman::AddNode(const std::string& strNode) { LOCK(cs_vAddedNodes); for (const std::string& it : vAddedNodes) { if (strNode == it) return false; } vAddedNodes.push_back(strNode); return true; } bool CConnman::RemoveAddedNode(const std::string& strNode) { LOCK(cs_vAddedNodes); for(std::vector::iterator it = vAddedNodes.begin(); it != vAddedNodes.end(); ++it) { if (strNode == *it) { vAddedNodes.erase(it); return true; } } return false; } bool CConnman::AddPendingMasternode(const uint256& proTxHash) { LOCK(cs_vPendingMasternodes); if (std::find(vPendingMasternodes.begin(), vPendingMasternodes.end(), proTxHash) != vPendingMasternodes.end()) { return false; } vPendingMasternodes.push_back(proTxHash); return true; } void CConnman::SetMasternodeQuorumNodes(Consensus::LLMQType llmqType, const uint256& quorumHash, const std::set& proTxHashes) { LOCK(cs_vPendingMasternodes); auto it = masternodeQuorumNodes.emplace(std::make_pair(llmqType, quorumHash), proTxHashes); if (!it.second) { it.first->second = proTxHashes; } } void CConnman::SetMasternodeQuorumRelayMembers(Consensus::LLMQType llmqType, const uint256& quorumHash, const std::set& proTxHashes) { { LOCK(cs_vPendingMasternodes); auto it = masternodeQuorumRelayMembers.emplace(std::make_pair(llmqType, quorumHash), proTxHashes); if (!it.second) { it.first->second = proTxHashes; } } // Update existing connections ForEachNode([&](CNode* pnode) { auto verifiedProRegTxHash = pnode->GetVerifiedProRegTxHash(); if (!verifiedProRegTxHash.IsNull() && !pnode->m_masternode_iqr_connection && IsMasternodeQuorumRelayMember(verifiedProRegTxHash)) { // Tell our peer that we're interested in plain LLMQ recovered signatures. // Otherwise the peer would only announce/send messages resulting from QRECSIG, // e.g. InstantSend locks or ChainLocks. SPV and regular full nodes should not send // this message as they are usually only interested in the higher level messages. const CNetMsgMaker msgMaker(pnode->GetSendVersion()); PushMessage(pnode, msgMaker.Make(NetMsgType::QSENDRECSIGS, true)); pnode->m_masternode_iqr_connection = true; } }); } bool CConnman::HasMasternodeQuorumNodes(Consensus::LLMQType llmqType, const uint256& quorumHash) { LOCK(cs_vPendingMasternodes); return masternodeQuorumNodes.count(std::make_pair(llmqType, quorumHash)); } std::set CConnman::GetMasternodeQuorums(Consensus::LLMQType llmqType) { LOCK(cs_vPendingMasternodes); std::set result; for (const auto& p : masternodeQuorumNodes) { if (p.first.first != llmqType) { continue; } result.emplace(p.first.second); } return result; } std::set CConnman::GetMasternodeQuorumNodes(Consensus::LLMQType llmqType, const uint256& quorumHash) const { LOCK2(cs_vNodes, cs_vPendingMasternodes); auto it = masternodeQuorumNodes.find(std::make_pair(llmqType, quorumHash)); if (it == masternodeQuorumNodes.end()) { return {}; } const auto& proRegTxHashes = it->second; std::set nodes; for (const auto pnode : vNodes) { if (pnode->fDisconnect) { continue; } auto verifiedProRegTxHash = pnode->GetVerifiedProRegTxHash(); if (!pnode->qwatch && (verifiedProRegTxHash.IsNull() || !proRegTxHashes.count(verifiedProRegTxHash))) { continue; } nodes.emplace(pnode->GetId()); } return nodes; } void CConnman::RemoveMasternodeQuorumNodes(Consensus::LLMQType llmqType, const uint256& quorumHash) { LOCK(cs_vPendingMasternodes); masternodeQuorumNodes.erase(std::make_pair(llmqType, quorumHash)); masternodeQuorumRelayMembers.erase(std::make_pair(llmqType, quorumHash)); } bool CConnman::IsMasternodeQuorumNode(const CNode* pnode) { // Let's see if this is an outgoing connection to an address that is known to be a masternode // We however only need to know this if the node did not authenticate itself as a MN yet uint256 assumedProTxHash; if (pnode->GetVerifiedProRegTxHash().IsNull() && !pnode->IsInboundConn()) { auto mnList = deterministicMNManager->GetListAtChainTip(); auto dmn = mnList.GetMNByService(pnode->addr); if (dmn == nullptr) { // This is definitely not a masternode return false; } assumedProTxHash = dmn->proTxHash; } LOCK(cs_vPendingMasternodes); for (const auto& p : masternodeQuorumNodes) { if (!pnode->GetVerifiedProRegTxHash().IsNull()) { if (p.second.count(pnode->GetVerifiedProRegTxHash())) { return true; } } else if (!assumedProTxHash.IsNull()) { if (p.second.count(assumedProTxHash)) { return true; } } } return false; } bool CConnman::IsMasternodeQuorumRelayMember(const uint256& protxHash) { if (protxHash.IsNull()) { return false; } LOCK(cs_vPendingMasternodes); for (const auto& p : masternodeQuorumRelayMembers) { if (p.second.count(protxHash)) { return true; } } return false; } void CConnman::AddPendingProbeConnections(const std::set &proTxHashes) { LOCK(cs_vPendingMasternodes); masternodePendingProbes.insert(proTxHashes.begin(), proTxHashes.end()); } size_t CConnman::GetNodeCount(NumConnections flags) { LOCK(cs_vNodes); int nNum = 0; for (const auto& pnode : vNodes) { if (pnode->fDisconnect) { continue; } if ((flags & CONNECTIONS_VERIFIED) && pnode->GetVerifiedProRegTxHash().IsNull()) { continue; } if (flags & (pnode->IsInboundConn() ? CONNECTIONS_IN : CONNECTIONS_OUT)) { nNum++; } else if (flags == CONNECTIONS_VERIFIED) { nNum++; } } return nNum; } size_t CConnman::GetMaxOutboundNodeCount() { return m_max_outbound; } void CConnman::GetNodeStats(std::vector& vstats) { vstats.clear(); LOCK(cs_vNodes); vstats.reserve(vNodes.size()); for (CNode* pnode : vNodes) { if (pnode->fDisconnect) { continue; } vstats.emplace_back(); pnode->copyStats(vstats.back(), addrman.m_asmap); } } bool CConnman::DisconnectNode(const std::string& strNode) { LOCK(cs_vNodes); if (CNode* pnode = FindNode(strNode)) { pnode->fDisconnect = true; return true; } return false; } bool CConnman::DisconnectNode(const CSubNet& subnet) { bool disconnected = false; LOCK(cs_vNodes); for (CNode* pnode : vNodes) { if (subnet.Match(pnode->addr)) { pnode->fDisconnect = true; disconnected = true; } } return disconnected; } bool CConnman::DisconnectNode(const CNetAddr& addr) { return DisconnectNode(CSubNet(addr)); } bool CConnman::DisconnectNode(NodeId id) { LOCK(cs_vNodes); for(CNode* pnode : vNodes) { if (id == pnode->GetId()) { pnode->fDisconnect = true; return true; } } return false; } void CConnman::RelayTransaction(const CTransaction& tx) { uint256 hash = tx.GetHash(); int nInv = MSG_TX; if (::dstxManager->GetDSTX(hash)) { nInv = MSG_DSTX; } CInv inv(nInv, hash); RelayInv(inv); } void CConnman::RelayInv(CInv &inv, const int minProtoVersion) { LOCK(cs_vNodes); for (const auto& pnode : vNodes) { if (pnode->nVersion < minProtoVersion || !pnode->CanRelay()) continue; pnode->PushInventory(inv); } } void CConnman::RelayInvFiltered(CInv &inv, const CTransaction& relatedTx, const int minProtoVersion) { LOCK(cs_vNodes); for (const auto& pnode : vNodes) { if (pnode->nVersion < minProtoVersion || !pnode->CanRelay() || !pnode->RelayAddrsWithConn()) { continue; } { LOCK(pnode->m_tx_relay->cs_filter); if (!pnode->m_tx_relay->fRelayTxes) { continue; } if (pnode->m_tx_relay->pfilter && !pnode->m_tx_relay->pfilter->IsRelevantAndUpdate(relatedTx)) { continue; } } pnode->PushInventory(inv); } } void CConnman::RelayInvFiltered(CInv &inv, const uint256& relatedTxHash, const int minProtoVersion) { LOCK(cs_vNodes); for (const auto& pnode : vNodes) { if (pnode->nVersion < minProtoVersion || !pnode->CanRelay() || !pnode->RelayAddrsWithConn()) { continue; } { LOCK(pnode->m_tx_relay->cs_filter); if (!pnode->m_tx_relay->fRelayTxes) { continue; } if (pnode->m_tx_relay->pfilter && !pnode->m_tx_relay->pfilter->contains(relatedTxHash)) { continue; } } pnode->PushInventory(inv); } } void CConnman::RecordBytesRecv(uint64_t bytes) { LOCK(cs_totalBytesRecv); nTotalBytesRecv += bytes; statsClient.count("bandwidth.bytesReceived", bytes, 0.1f); statsClient.gauge("bandwidth.totalBytesReceived", nTotalBytesRecv, 0.01f); } void CConnman::RecordBytesSent(uint64_t bytes) { LOCK(cs_totalBytesSent); nTotalBytesSent += bytes; statsClient.count("bandwidth.bytesSent", bytes, 0.01f); statsClient.gauge("bandwidth.totalBytesSent", nTotalBytesSent, 0.01f); const auto now = GetTime(); if (nMaxOutboundCycleStartTime + MAX_UPLOAD_TIMEFRAME < now) { // timeframe expired, reset cycle nMaxOutboundCycleStartTime = now; nMaxOutboundTotalBytesSentInCycle = 0; } nMaxOutboundTotalBytesSentInCycle += bytes; } uint64_t CConnman::GetMaxOutboundTarget() { LOCK(cs_totalBytesSent); return nMaxOutboundLimit; } std::chrono::seconds CConnman::GetMaxOutboundTimeframe() { return MAX_UPLOAD_TIMEFRAME; } std::chrono::seconds CConnman::GetMaxOutboundTimeLeftInCycle() { LOCK(cs_totalBytesSent); if (nMaxOutboundLimit == 0) return 0s; if (nMaxOutboundCycleStartTime.count() == 0) return MAX_UPLOAD_TIMEFRAME; const std::chrono::seconds cycleEndTime = nMaxOutboundCycleStartTime + MAX_UPLOAD_TIMEFRAME; const auto now = GetTime(); return (cycleEndTime < now) ? 0s : cycleEndTime - now; } bool CConnman::OutboundTargetReached(bool historicalBlockServingLimit) { LOCK(cs_totalBytesSent); if (nMaxOutboundLimit == 0) return false; if (historicalBlockServingLimit) { // keep a large enough buffer to at least relay each block once const std::chrono::seconds timeLeftInCycle = GetMaxOutboundTimeLeftInCycle(); const uint64_t buffer = timeLeftInCycle / std::chrono::minutes{10} * MaxBlockSize(fDIP0001ActiveAtTip); if (buffer >= nMaxOutboundLimit || nMaxOutboundTotalBytesSentInCycle >= nMaxOutboundLimit - buffer) return true; } else if (nMaxOutboundTotalBytesSentInCycle >= nMaxOutboundLimit) return true; return false; } uint64_t CConnman::GetOutboundTargetBytesLeft() { LOCK(cs_totalBytesSent); if (nMaxOutboundLimit == 0) return 0; return (nMaxOutboundTotalBytesSentInCycle >= nMaxOutboundLimit) ? 0 : nMaxOutboundLimit - nMaxOutboundTotalBytesSentInCycle; } uint64_t CConnman::GetTotalBytesRecv() { LOCK(cs_totalBytesRecv); return nTotalBytesRecv; } uint64_t CConnman::GetTotalBytesSent() { LOCK(cs_totalBytesSent); return nTotalBytesSent; } ServiceFlags CConnman::GetLocalServices() const { return nLocalServices; } unsigned int CConnman::GetReceiveFloodSize() const { return nReceiveFloodSize; } CNode::CNode(NodeId idIn, ServiceFlags nLocalServicesIn, SOCKET hSocketIn, const CAddress& addrIn, uint64_t nKeyedNetGroupIn, uint64_t nLocalHostNonceIn, const CAddress& addrBindIn, const std::string& addrNameIn, ConnectionType conn_type_in, bool inbound_onion) : nTimeConnected(GetSystemTimeInSeconds()), addr(addrIn), addrBind(addrBindIn), nKeyedNetGroup(nKeyedNetGroupIn), id(idIn), nLocalHostNonce(nLocalHostNonceIn), m_conn_type(conn_type_in), nLocalServices(nLocalServicesIn), m_inbound_onion(inbound_onion) { hSocket = hSocketIn; addrName = addrNameIn == "" ? addr.ToStringIPPort() : addrNameIn; hashContinue = uint256(); if (conn_type_in != ConnectionType::BLOCK_RELAY) { m_addr_known = std::make_unique(5000, 0.001); } for (const std::string &msg : getAllNetMessageTypes()) mapRecvBytesPerMsgCmd[msg] = 0; mapRecvBytesPerMsgCmd[NET_MESSAGE_COMMAND_OTHER] = 0; if (fLogIPs) { LogPrint(BCLog::NET, "Added connection to %s peer=%d\n", addrName, id); } else { LogPrint(BCLog::NET, "Added connection peer=%d\n", id); } m_deserializer = std::make_unique(V1TransportDeserializer(Params(), GetId(), SER_NETWORK, INIT_PROTO_VERSION)); m_serializer = std::make_unique(V1TransportSerializer()); } CNode::~CNode() { CloseSocket(hSocket); } bool CConnman::NodeFullyConnected(const CNode* pnode) { return pnode && pnode->fSuccessfullyConnected && !pnode->fDisconnect; } void CConnman::PushMessage(CNode* pnode, CSerializedNetMsg&& msg) { size_t nMessageSize = msg.data.size(); LogPrint(BCLog::NET, "sending %s (%d bytes) peer=%d\n", SanitizeString(msg.command), nMessageSize, pnode->GetId()); // make sure we use the appropriate network transport format std::vector serializedHeader; pnode->m_serializer->prepareForTransport(msg, serializedHeader); size_t nTotalSize = nMessageSize + serializedHeader.size(); statsClient.count("bandwidth.message." + SanitizeString(msg.command.c_str()) + ".bytesSent", nTotalSize, 1.0f); statsClient.inc("message.sent." + SanitizeString(msg.command.c_str()), 1.0f); { LOCK(pnode->cs_vSend); bool hasPendingData = !pnode->vSendMsg.empty(); //log total amount of bytes per command pnode->mapSendBytesPerMsgCmd[msg.command] += nTotalSize; pnode->nSendSize += nTotalSize; if (pnode->nSendSize > nSendBufferMaxSize) pnode->fPauseSend = true; pnode->vSendMsg.push_back(std::move(serializedHeader)); if (nMessageSize) pnode->vSendMsg.push_back(std::move(msg.data)); pnode->nSendMsgSize = pnode->vSendMsg.size(); { LOCK(cs_mapNodesWithDataToSend); // we're not holding cs_vNodes here, so there is a chance of this node being disconnected shortly before // we get here. Whoever called PushMessage still has a ref to CNode*, but will later Release() it, so we // might end up having an entry in mapNodesWithDataToSend that is not in vNodes anymore. We need to // Add/Release refs when adding/erasing mapNodesWithDataToSend. if (mapNodesWithDataToSend.emplace(pnode->GetId(), pnode).second) { pnode->AddRef(); } } // wake up select() call in case there was no pending data before (so it was not selecting this socket for sending) if (!hasPendingData && wakeupSelectNeeded) WakeSelect(); } } bool CConnman::ForNode(const CService& addr, std::function cond, std::function func) { CNode* found = nullptr; LOCK(cs_vNodes); for (auto&& pnode : vNodes) { if((CService)pnode->addr == addr) { found = pnode; break; } } return found != nullptr && cond(found) && func(found); } bool CConnman::ForNode(NodeId id, std::function cond, std::function func) { CNode* found = nullptr; LOCK(cs_vNodes); for (auto&& pnode : vNodes) { if(pnode->GetId() == id) { found = pnode; break; } } return found != nullptr && cond(found) && func(found); } bool CConnman::IsMasternodeOrDisconnectRequested(const CService& addr) { return ForNode(addr, AllNodes, [](CNode* pnode){ return pnode->m_masternode_connection || pnode->fDisconnect; }); } int64_t CConnman::PoissonNextSendInbound(int64_t now, int average_interval_seconds) { if (m_next_send_inv_to_incoming < now) { // If this function were called from multiple threads simultaneously // it would possible that both update the next send variable, and return a different result to their caller. // This is not possible in practice as only the net processing thread invokes this function. m_next_send_inv_to_incoming = PoissonNextSend(now, average_interval_seconds); } return m_next_send_inv_to_incoming; } int64_t PoissonNextSend(int64_t now, int average_interval_seconds) { return now + (int64_t)(log1p(GetRand(1ULL << 48) * -0.0000000000000035527136788 /* -1/2^48 */) * average_interval_seconds * -1000000.0 + 0.5); } std::vector CConnman::CopyNodeVector(std::function cond) { std::vector vecNodesCopy; LOCK(cs_vNodes); vecNodesCopy.reserve(vNodes.size()); for(size_t i = 0; i < vNodes.size(); ++i) { CNode* pnode = vNodes[i]; if (!cond(pnode)) continue; pnode->AddRef(); vecNodesCopy.push_back(pnode); } return vecNodesCopy; } std::vector CConnman::CopyNodeVector() { return CopyNodeVector(AllNodes); } void CConnman::ReleaseNodeVector(const std::vector& vecNodes) { for(size_t i = 0; i < vecNodes.size(); ++i) { CNode* pnode = vecNodes[i]; pnode->Release(); } } CSipHasher CConnman::GetDeterministicRandomizer(uint64_t id) const { return CSipHasher(nSeed0, nSeed1).Write(id); } uint64_t CConnman::CalculateKeyedNetGroup(const CAddress& ad) const { std::vector vchNetGroup(ad.GetGroup(addrman.m_asmap)); return GetDeterministicRandomizer(RANDOMIZER_ID_NETGROUP).Write(vchNetGroup.data(), vchNetGroup.size()).Finalize(); } void CConnman::RegisterEvents(CNode *pnode) { #ifdef USE_KQUEUE if (socketEventsMode != SOCKETEVENTS_KQUEUE) { return; } LOCK(pnode->cs_hSocket); assert(pnode->hSocket != INVALID_SOCKET); struct kevent events[2]; EV_SET(&events[0], pnode->hSocket, EVFILT_READ, EV_ADD, 0, 0, nullptr); EV_SET(&events[1], pnode->hSocket, EVFILT_WRITE, EV_ADD | EV_CLEAR, 0, 0, nullptr); int r = kevent(kqueuefd, events, 2, nullptr, 0, nullptr); if (r != 0) { LogPrint(BCLog::NET, "%s -- kevent(%d, %d, %d, ...) failed. error: %s\n", __func__, kqueuefd, EV_ADD, pnode->hSocket, NetworkErrorString(WSAGetLastError())); } #endif #ifdef USE_EPOLL if (socketEventsMode != SOCKETEVENTS_EPOLL) { return; } LOCK(pnode->cs_hSocket); assert(pnode->hSocket != INVALID_SOCKET); epoll_event e; // We're using edge-triggered mode, so it's important that we drain sockets even if no signals come in e.events = EPOLLIN | EPOLLOUT | EPOLLET | EPOLLERR | EPOLLHUP; e.data.fd = pnode->hSocket; int r = epoll_ctl(epollfd, EPOLL_CTL_ADD, pnode->hSocket, &e); if (r != 0) { LogPrint(BCLog::NET, "%s -- epoll_ctl(%d, %d, %d, ...) failed. error: %s\n", __func__, epollfd, EPOLL_CTL_ADD, pnode->hSocket, NetworkErrorString(WSAGetLastError())); } #endif } void CConnman::UnregisterEvents(CNode *pnode) { #ifdef USE_KQUEUE if (socketEventsMode != SOCKETEVENTS_KQUEUE) { return; } LOCK(pnode->cs_hSocket); if (pnode->hSocket == INVALID_SOCKET) { return; } struct kevent events[2]; EV_SET(&events[0], pnode->hSocket, EVFILT_READ, EV_DELETE, 0, 0, nullptr); EV_SET(&events[1], pnode->hSocket, EVFILT_WRITE, EV_DELETE, 0, 0, nullptr); int r = kevent(kqueuefd, events, 2, nullptr, 0, nullptr); if (r != 0) { LogPrint(BCLog::NET, "%s -- kevent(%d, %d, %d, ...) failed. error: %s\n", __func__, kqueuefd, EV_DELETE, pnode->hSocket, NetworkErrorString(WSAGetLastError())); } #endif #ifdef USE_EPOLL if (socketEventsMode != SOCKETEVENTS_EPOLL) { return; } LOCK(pnode->cs_hSocket); if (pnode->hSocket == INVALID_SOCKET) { return; } int r = epoll_ctl(epollfd, EPOLL_CTL_DEL, pnode->hSocket, nullptr); if (r != 0) { LogPrint(BCLog::NET, "%s -- epoll_ctl(%d, %d, %d, ...) failed. error: %s\n", __func__, epollfd, EPOLL_CTL_DEL, pnode->hSocket, NetworkErrorString(WSAGetLastError())); } #endif }