No OneTemporary
Actions

Size

100 KB

Subscribers

None

View Options

	diff --git a/src/net.cpp b/src/net.cpp
	index 420be771c..e35de33a8 100644
	--- a/src/net.cpp
	+++ b/src/net.cpp
	@@ -1,3038 +1,3040 @@
	// Copyright (c) 2009-2010 Satoshi Nakamoto
	// Copyright (c) 2009-2019 The Bitcoin 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 <config/bitcoin-config.h>
	#endif

	#include <net.h>

	#include <banman.h>
	#include <clientversion.h>
	#include <config.h>
	#include <consensus/consensus.h>
	#include <crypto/sha256.h>
	#include <netbase.h>
	#include <scheduler.h>
	#include <ui_interface.h>
	#include <util/strencodings.h>
	#include <util/translation.h>

	#ifdef WIN32
	#include <cstring>
	#else
	#include <fcntl.h>
	#endif

	#ifdef USE_POLL
	#include <poll.h>
	#endif

	#ifdef USE_UPNP
	#include <miniupnpc/miniupnpc.h>
	#include <miniupnpc/upnpcommands.h>
	#include <miniupnpc/upnperrors.h>
	#endif

	#include <unordered_map>

	#include <cmath>

	// How often to dump addresses to peers.dat
	static constexpr std::chrono::minutes DUMP_PEERS_INTERVAL{15};

	// We add a random period time (0 to 1 seconds) to feeler connections to prevent
	// synchronization.
	#define FEELER_SLEEP_WINDOW 1

	// MSG_NOSIGNAL is not available on some platforms, if it doesn't exist define
	// it as 0
	#if !defined(MSG_NOSIGNAL)
	#define MSG_NOSIGNAL 0
	#endif

	// MSG_DONTWAIT is not available on some platforms, if it doesn't exist define
	// it as 0
	#if !defined(MSG_DONTWAIT)
	#define MSG_DONTWAIT 0
	#endif

	/** Used to pass flags to the Bind() function */
	enum BindFlags {
	BF_NONE = 0,
	BF_EXPLICIT = (1U << 0),
	BF_REPORT_ERROR = (1U << 1),
	};

	// 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;

	const std::string NET_MESSAGE_COMMAND_OTHER = "other";

	// SHA256("netgroup")[0:8]
	static const uint64_t RANDOMIZER_ID_NETGROUP = 0x6c0edd8036ef4036ULL;
	// SHA256("localhostnonce")[0:8]
	static const uint64_t RANDOMIZER_ID_LOCALHOSTNONCE = 0xd93e69e2bbfa5735ULL;
	//
	// Global state variables
	//
	bool fDiscover = true;
	bool fListen = true;
	bool g_relay_txes = !DEFAULT_BLOCKSONLY;
	RecursiveMutex cs_mapLocalHost;
	std::map<CNetAddr, LocalServiceInfo> mapLocalHost GUARDED_BY(cs_mapLocalHost);
	static bool vfLimited[NET_MAX] GUARDED_BY(cs_mapLocalHost) = {};

	void CConnman::AddOneShot(const std::string &strDest) {
	LOCK(cs_vOneShots);
	vOneShots.push_back(strDest);
	}

	unsigned short GetListenPort() {
	return (unsigned short)(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(cs_mapLocalHost);
	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 pnSeed6 array into usable address objects.
	static std::vector<CAddress>
	convertSeed6(const std::vector<SeedSpec6> &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<CAddress> vSeedsOut;
	vSeedsOut.reserve(vSeedsIn.size());
	FastRandomContext rng;
	for (const auto &seed_in : vSeedsIn) {
	struct in6_addr ip;
	memcpy(&ip, seed_in.addr, sizeof(ip));
	CAddress addr(CService(ip, seed_in.port),
	GetDesirableServiceFlags(NODE_NONE));
	addr.nTime = GetTime() - rng.randrange(nOneWeek) - nOneWeek;
	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(cs_mapLocalHost);
	if (mapLocalHost.count(addr) == 0) {
	return 0;
	}
	return mapLocalHost[addr].nScore;
	}

	// 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());
	}

	// Pushes our own address to a peer.
	void AdvertiseLocal(CNode *pnode) {
	if (fListen && pnode->fSuccessfullyConnected) {
	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, "AdvertiseLocal: advertising address %s\n",
	addrLocal.ToString());
	pnode->PushAddress(addrLocal, rng);
	}
	}
	}

	// Learn a new local address.
	bool AddLocal(const CService &addr, int nScore) {
	if (!addr.IsRoutable()) {
	return false;
	}

	if (!fDiscover && nScore < LOCAL_MANUAL) {
	return false;
	}

	if (!IsReachable(addr)) {
	return false;
	}

	LogPrintf("AddLocal(%s,%i)\n", addr.ToString(), nScore);

	{
	LOCK(cs_mapLocalHost);
	bool fAlready = mapLocalHost.count(addr) > 0;
	LocalServiceInfo &info = mapLocalHost[addr];
	if (!fAlready \|\| nScore >= info.nScore) {
	info.nScore = nScore + (fAlready ? 1 : 0);
	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(cs_mapLocalHost);
	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(cs_mapLocalHost);
	vfLimited[net] = !reachable;
	}

	bool IsReachable(enum Network net) {
	LOCK(cs_mapLocalHost);
	return !vfLimited[net];
	}

	bool IsReachable(const CNetAddr &addr) {
	return IsReachable(addr.GetNetwork());
	}

	/** vote for a local address */
	bool SeenLocal(const CService &addr) {
	LOCK(cs_mapLocalHost);
	if (mapLocalHost.count(addr) == 0) {
	return false;
	}
	mapLocalHost[addr].nScore++;
	return true;
	}

	/** check whether a given address is potentially local */
	bool IsLocal(const CService &addr) {
	LOCK(cs_mapLocalHost);
	return mapLocalHost.count(addr) > 0;
	}

	CNode *CConnman::FindNode(const CNetAddr &ip) {
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodes) {
	if (static_cast<CNetAddr>(pnode->addr) == ip) {
	return pnode;
	}
	}
	return nullptr;
	}

	CNode *CConnman::FindNode(const CSubNet &subNet) {
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodes) {
	if (subNet.Match(static_cast<CNetAddr>(pnode->addr))) {
	return pnode;
	}
	}
	return nullptr;
	}

	CNode *CConnman::FindNode(const std::string &addrName) {
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodes) {
	if (pnode->GetAddrName() == addrName) {
	return pnode;
	}
	}
	return nullptr;
	}

	CNode *CConnman::FindNode(const CService &addr) {
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodes) {
	if (static_cast<CService>(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->fInbound &&
	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, bool manual_connection,
	bool block_relay_only) {
	if (pszDest == nullptr) {
	if (IsLocal(addrConnect)) {
	return nullptr;
	}

	// Look for an existing connection
	CNode *pnode = FindNode(static_cast<CService>(addrConnect));
	if (pnode) {
	LogPrintf("Failed to open new connection, already connected\n");
	return nullptr;
	}
	}

	/// debug print
	LogPrint(BCLog::NET, "trying connection %s lastseen=%.1fhrs\n",
	pszDest ? pszDest : addrConnect.ToString(),
	pszDest
	? 0.0
	: (double)(GetAdjustedTime() - addrConnect.nTime) / 3600.0);

	// Resolve
	const int default_port = Params().GetDefaultPort();
	if (pszDest) {
	std::vector<CService> 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<CService>(addrConnect));
	if (pnode) {
	pnode->MaybeSetAddrName(std::string(pszDest));
	LogPrintf("Failed to open new connection, already connected\n");
	return nullptr;
	}
	}
	}

	// Connect
	bool connected = false;
	SOCKET hSocket = INVALID_SOCKET;
	proxyType proxy;
	if (addrConnect.IsValid()) {
	bool proxyConnectionFailed = false;

	if (GetProxy(addrConnect.GetNetwork(), proxy)) {
	hSocket = CreateSocket(proxy.proxy);
	if (hSocket == INVALID_SOCKET) {
	return nullptr;
	}
	connected = ConnectThroughProxy(
	proxy, addrConnect.ToStringIP(), addrConnect.GetPort(), hSocket,
	nConnectTimeout, &proxyConnectionFailed);
	} else {
	// no proxy needed (none set for target network)
	hSocket = CreateSocket(addrConnect);
	if (hSocket == INVALID_SOCKET) {
	return nullptr;
	}
	connected = ConnectSocketDirectly(
	addrConnect, hSocket, nConnectTimeout, manual_connection);
	}
	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)) {
	hSocket = CreateSocket(proxy.proxy);
	if (hSocket == INVALID_SOCKET) {
	return nullptr;
	}
	std::string host;
	int port = default_port;
	SplitHostPort(std::string(pszDest), port, host);
	connected = ConnectThroughProxy(proxy, host, port, hSocket,
	nConnectTimeout, nullptr);
	}
	if (!connected) {
	CloseSocket(hSocket);
	return nullptr;
	}

	// Add node
	NodeId id = GetNewNodeId();
	uint64_t nonce = GetDeterministicRandomizer(RANDOMIZER_ID_LOCALHOSTNONCE)
	.Write(id)
	.Finalize();
	CAddress addr_bind = GetBindAddress(hSocket);
	CNode *pnode =
	new CNode(id, nLocalServices, GetBestHeight(), hSocket, addrConnect,
	CalculateKeyedNetGroup(addrConnect), nonce, addr_bind,
	pszDest ? pszDest : "", false, block_relay_only);
	pnode->AddRef();

	return pnode;
	}

	void CNode::CloseSocketDisconnect() {
	fDisconnect = true;
	LOCK(cs_hSocket);
	if (hSocket != INVALID_SOCKET) {
	LogPrint(BCLog::NET, "disconnecting peer=%d\n", id);
	CloseSocket(hSocket);
	}
	}

	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);
	}
	}
	}

	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;
	}
	}

	void CNode::copyStats(CNodeStats &stats) {
	stats.nodeid = this->GetId();
	stats.nServices = nServices;
	stats.addr = addr;
	stats.addrBind = addrBind;
	if (m_tx_relay != nullptr) {
	LOCK(m_tx_relay->cs_filter);
	stats.fRelayTxes = m_tx_relay->fRelayTxes;
	} else {
	stats.fRelayTxes = false;
	}
	stats.nLastSend = nLastSend;
	stats.nLastRecv = nLastRecv;
	stats.nTimeConnected = nTimeConnected;
	stats.nTimeOffset = nTimeOffset;
	stats.addrName = GetAddrName();
	stats.nVersion = nVersion;
	{
	LOCK(cs_SubVer);
	stats.cleanSubVer = cleanSubVer;
	}
	stats.fInbound = fInbound;
	stats.m_manual_connection = m_manual_connection;
	stats.nStartingHeight = nStartingHeight;
	{
	LOCK(cs_vSend);
	stats.mapSendBytesPerMsgCmd = mapSendBytesPerMsgCmd;
	stats.nSendBytes = nSendBytes;
	}
	{
	LOCK(cs_vRecv);
	stats.mapRecvBytesPerMsgCmd = mapRecvBytesPerMsgCmd;
	stats.nRecvBytes = nRecvBytes;
	}
	stats.m_legacyWhitelisted = m_legacyWhitelisted;
	stats.m_permissionFlags = m_permissionFlags;
	if (m_tx_relay != nullptr) {
	LOCK(m_tx_relay->cs_feeFilter);
	stats.minFeeFilter = m_tx_relay->minFeeFilter;
	} else {
	stats.minFeeFilter = Amount::zero();
	}

	// 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
	// (Bitcoin 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() : "";
	}

	static bool IsOversizedMessage(const Config &config, const CNetMessage &msg) {
	if (!msg.in_data) {
	// Header only, cannot be oversized.
	return false;
	}

	return msg.hdr.IsOversized(config);
	}

	bool CNode::ReceiveMsgBytes(const Config &config, const char *pch,
	uint32_t nBytes, bool &complete) {
	complete = false;
	int64_t nTimeMicros = GetTimeMicros();
	LOCK(cs_vRecv);
	nLastRecv = nTimeMicros / 1000000;
	nRecvBytes += nBytes;
	while (nBytes > 0) {
	// Get current incomplete message, or create a new one.
	if (vRecvMsg.empty() \|\| vRecvMsg.back().complete()) {
	vRecvMsg.push_back(CNetMessage(config.GetChainParams().NetMagic(),
	SER_NETWORK, INIT_PROTO_VERSION));
	}

	CNetMessage &msg = vRecvMsg.back();

	// Absorb network data.
	int handled;
	if (!msg.in_data) {
	handled = msg.readHeader(config, pch, nBytes);
	} else {
	handled = msg.readData(pch, nBytes);
	}

	if (handled < 0) {
	return false;
	}

	if (IsOversizedMessage(config, msg)) {
	LogPrint(BCLog::NET,
	"Oversized message from peer=%i, disconnecting\n",
	GetId());
	return false;
	}

	pch += handled;
	nBytes -= handled;

	if (msg.complete()) {
	// Store received bytes per message command to prevent a memory DOS,
	// only allow valid commands.
	mapMsgCmdSize::iterator i =
	mapRecvBytesPerMsgCmd.find(msg.hdr.pchCommand.data());
	if (i == mapRecvBytesPerMsgCmd.end()) {
	i = mapRecvBytesPerMsgCmd.find(NET_MESSAGE_COMMAND_OTHER);
	}

	assert(i != mapRecvBytesPerMsgCmd.end());
	i->second += msg.hdr.nMessageSize + CMessageHeader::HEADER_SIZE;

	msg.nTime = nTimeMicros;
	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 CNetMessage::readHeader(const Config &config, const char *pch,
	uint32_t nBytes) {
	// copy data to temporary parsing buffer
	uint32_t nRemaining = 24 - nHdrPos;
	uint32_t nCopy = std::min(nRemaining, nBytes);

	memcpy(&hdrbuf[nHdrPos], pch, nCopy);
	nHdrPos += nCopy;

	// if header incomplete, exit
	if (nHdrPos < 24) {
	return nCopy;
	}

	// deserialize to CMessageHeader
	try {
	hdrbuf >> hdr;
	} catch (const std::exception &) {
	return -1;
	}

	// Reject oversized messages
	if (hdr.IsOversized(config)) {
	LogPrint(BCLog::NET, "Oversized header detected\n");
	return -1;
	}

	// switch state to reading message data
	in_data = true;

	return nCopy;
	}

	int CNetMessage::readData(const char *pch, uint32_t nBytes) {
	unsigned int nRemaining = hdr.nMessageSize - nDataPos;
	unsigned int nCopy = std::min(nRemaining, nBytes);

	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((const uint8_t *)pch, nCopy);
	memcpy(&vRecv[nDataPos], pch, nCopy);
	nDataPos += nCopy;

	return nCopy;
	}

	const uint256 &CNetMessage::GetMessageHash() const {
	assert(complete());
	if (data_hash.IsNull()) {
	hasher.Finalize(data_hash.begin());
	}
	return data_hash;
	}

	size_t CConnman::SocketSendData(CNode *pnode) const
	EXCLUSIVE_LOCKS_REQUIRED(pnode->cs_vSend) {
	size_t nSentSize = 0;
	size_t nMsgCount = 0;

	for (const auto &data : pnode->vSendMsg) {
	assert(data.size() > pnode->nSendOffset);
	int nBytes = 0;

	{
	LOCK(pnode->cs_hSocket);
	if (pnode->hSocket == INVALID_SOCKET) {
	break;
	}

	nBytes = send(pnode->hSocket,
	reinterpret_cast<const char *>(data.data()) +
	pnode->nSendOffset,
	data.size() - pnode->nSendOffset,
	MSG_NOSIGNAL \| MSG_DONTWAIT);
	}

	if (nBytes == 0) {
	// couldn't send anything at all
	break;
	}

	if (nBytes < 0) {
	// error
	int nErr = WSAGetLastError();
	if (nErr != WSAEWOULDBLOCK && nErr != WSAEMSGSIZE &&
	nErr != WSAEINTR && nErr != WSAEINPROGRESS) {
	LogPrintf("socket send error %s\n", NetworkErrorString(nErr));
	pnode->CloseSocketDisconnect();
	}

	break;
	}

	assert(nBytes > 0);
	pnode->nLastSend = GetSystemTimeInSeconds();
	pnode->nSendBytes += nBytes;
	pnode->nSendOffset += nBytes;
	nSentSize += nBytes;
	if (pnode->nSendOffset != data.size()) {
	// could not send full message; stop sending more
	break;
	}

	pnode->nSendOffset = 0;
	pnode->nSendSize -= data.size();
	pnode->fPauseSend = pnode->nSendSize > nSendBufferMaxSize;
	nMsgCount++;
	}

	pnode->vSendMsg.erase(pnode->vSendMsg.begin(),
	pnode->vSendMsg.begin() + nMsgCount);

	if (pnode->vSendMsg.empty()) {
	assert(pnode->nSendOffset == 0);
	assert(pnode->nSendSize == 0);
	}

	return nSentSize;
	}

	struct NodeEvictionCandidate {
	NodeId id;
	int64_t nTimeConnected;
	int64_t nMinPingUsecTime;
	int64_t nLastBlockTime;
	int64_t nLastTXTime;
	bool fRelevantServices;
	bool fRelayTxes;
	bool fBloomFilter;
	CAddress addr;
	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 <typename T, typename Comparator>
	static void EraseLastKElements(std::vector<T> &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<NodeEvictionCandidate> vEvictionCandidates;
	{
	LOCK(cs_vNodes);

	for (const CNode *node : vNodes) {
	if (node->HasPermission(PF_NOBAN)) {
	continue;
	}
	if (!node->fInbound) {
	continue;
	}
	if (node->fDisconnect) {
	continue;
	}
	bool peer_relay_txes = false;
	bool peer_filter_not_null = false;
	if (node->m_tx_relay != nullptr) {
	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->addr,
	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 transactions.
	// An attacker cannot manipulate this metric without performing useful work.
	EraseLastKElements(vEvictionCandidates, CompareNodeTXTime, 4);
	// Protect 4 nodes that most recently sent us 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<uint64_t, std::vector<NodeEvictionCandidate>> mapNetGroupNodes;
	for (const NodeEvictionCandidate &node : vEvictionCandidates) {
	std::vector<NodeEvictionCandidate> &group =
	mapNetGroupNodes[node.nKeyedNetGroup];
	group.push_back(node);
	int64_t grouptime = group[0].nTimeConnected;
	size_t group_size = group.size();
	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;
	int nInbound = 0;
	int nMaxInbound = nMaxConnections - m_max_outbound;

	if (hSocket != INVALID_SOCKET) {
	if (!addr.SetSockAddr((const struct sockaddr *)&sockaddr)) {
	LogPrintf("Warning: Unknown socket family\n");
	}
	}

	NetPermissionFlags permissionFlags = NetPermissionFlags::PF_NONE;
	hListenSocket.AddSocketPermissionFlags(permissionFlags);
	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->fInbound) {
	nInbound++;
	}
	}
	}

	if (hSocket == INVALID_SOCKET) {
	int nErr = WSAGetLastError();
	if (nErr != WSAEWOULDBLOCK) {
	LogPrintf("socket error accept failed: %s\n",
	NetworkErrorString(nErr));
	}
	return;
	}

	if (!fNetworkActive) {
	LogPrintf("connection from %s dropped: not accepting new connections\n",
	addr.ToString());
	CloseSocket(hSocket);
	return;
	}

	if (!IsSelectableSocket(hSocket)) {
	LogPrintf("connection from %s dropped: non-selectable socket\n",
	addr.ToString());
	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, "connection from %s dropped (banned)\n",
	addr.ToString());
	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;
	}

	if (nInbound >= 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;
	}
	}

	NodeId id = GetNewNodeId();
	uint64_t nonce = GetDeterministicRandomizer(RANDOMIZER_ID_LOCALHOSTNONCE)
	.Write(id)
	.Finalize();
	CAddress addr_bind = GetBindAddress(hSocket);

	ServiceFlags nodeServices = nLocalServices;
	if (NetPermissions::HasFlag(permissionFlags, PF_BLOOMFILTER)) {
	nodeServices = static_cast<ServiceFlags>(nodeServices \| NODE_BLOOM);
	}
	CNode *pnode =
	new CNode(id, nodeServices, GetBestHeight(), hSocket, addr,
	CalculateKeyedNetGroup(addr), nonce, addr_bind, "", true);
	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(*config, pnode);

	LogPrint(BCLog::NET, "connection from %s accepted\n", addr.ToString());

	{
	LOCK(cs_vNodes);
	vNodes.push_back(pnode);
	}
	}

	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
	std::vector<CNode *> vNodesCopy = vNodes;
	for (CNode *pnode : vNodesCopy) {
	if (pnode->fDisconnect) {
	// remove from vNodes
	vNodes.erase(remove(vNodes.begin(), vNodes.end(), pnode),
	vNodes.end());

	// release outbound grant (if any)
	pnode->grantOutbound.Release();

	// close socket and cleanup
	pnode->CloseSocketDisconnect();

	// hold in disconnected pool until all refs are released
	pnode->Release();
	vNodesDisconnected.push_back(pnode);
	}
	}
	}
	{
	// Delete disconnected nodes
	std::list<CNode *> vNodesDisconnectedCopy = vNodesDisconnected;
	for (CNode *pnode : vNodesDisconnectedCopy) {
	// wait until threads are done using it
	if (pnode->GetRefCount() <= 0) {
	bool fDelete = false;
	{
	TRY_LOCK(pnode->cs_inventory, lockInv);
	if (lockInv) {
	TRY_LOCK(pnode->cs_vSend, lockSend);
	if (lockSend) {
	fDelete = true;
	}
	}
	}
	if (fDelete) {
	vNodesDisconnected.remove(pnode);
	DeleteNode(pnode);
	}
	}
	}
	}
	}

	void CConnman::NotifyNumConnectionsChanged() {
	size_t vNodesSize;
	{
	LOCK(cs_vNodes);
	vNodesSize = vNodes.size();
	}
	if (vNodesSize != nPrevNodeCount) {
	nPrevNodeCount = vNodesSize;
	if (clientInterface) {
	clientInterface->NotifyNumConnectionsChanged(vNodesSize);
	}
	}
	}

	void CConnman::InactivityCheck(CNode *pnode) {
	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 > (pnode->nVersion > BIP0031_VERSION
	? TIMEOUT_INTERVAL
	: 90 * 60)) {
	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<SOCKET> &recv_set,
	std::set<SOCKET> &send_set,
	std::set<SOCKET> &error_set) {
	for (const ListenSocket &hListenSocket : vhListenSocket) {
	recv_set.insert(hListenSocket.socket);
	}

	{
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodes) {
	// Implement the following logic:
	// * If there is data to send, select() for 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,
	// select() for receiving data.
	// * Hand off all complete messages to the processor, to be handled
	// without blocking here.

	bool select_recv = !pnode->fPauseRecv;
	bool select_send;
	{
	LOCK(pnode->cs_vSend);
	select_send = !pnode->vSendMsg.empty();
	}

	LOCK(pnode->cs_hSocket);
	if (pnode->hSocket == INVALID_SOCKET) {
	continue;
	}

	error_set.insert(pnode->hSocket);
	if (select_send) {
	send_set.insert(pnode->hSocket);
	continue;
	}
	if (select_recv) {
	recv_set.insert(pnode->hSocket);
	}
	}
	}

	return !recv_set.empty() \|\| !send_set.empty() \|\| !error_set.empty();
	}

	#ifdef USE_POLL
	void CConnman::SocketEvents(std::set<SOCKET> &recv_set,
	std::set<SOCKET> &send_set,
	std::set<SOCKET> &error_set) {
	std::set<SOCKET> 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;
	}

	std::unordered_map<SOCKET, struct pollfd> 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<struct pollfd> vpollfds;
	vpollfds.reserve(pollfds.size());
	for (auto it : pollfds) {
	vpollfds.push_back(std::move(it.second));
	}

	if (poll(vpollfds.data(), vpollfds.size(), SELECT_TIMEOUT_MILLISECONDS) <
	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);
	}
	}
	}
	#else
	void CConnman::SocketEvents(std::set<SOCKET> &recv_set,
	std::set<SOCKET> &send_set,
	std::set<SOCKET> &error_set) {
	std::set<SOCKET> 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;
	// frequency to poll pnode->vSend
	timeout.tv_usec = SELECT_TIMEOUT_MILLISECONDS * 1000;

	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);
	}

	int nSelect =
	select(hSocketMax + 1, &fdsetRecv, &fdsetSend, &fdsetError, &timeout);

	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);
	}
	}
	}
	#endif

	void CConnman::SocketHandler() {
	std::set<SOCKET> recv_set, send_set, error_set;
	SocketEvents(recv_set, send_set, error_set);

	if (interruptNet) {
	return;
	}

	//
	// Accept new connections
	//
	for (const ListenSocket &hListenSocket : vhListenSocket) {
	if (hListenSocket.socket != INVALID_SOCKET &&
	recv_set.count(hListenSocket.socket) > 0) {
	AcceptConnection(hListenSocket);
	}
	}

	//
	// Service each socket
	//
	std::vector<CNode *> vNodesCopy;
	{
	LOCK(cs_vNodes);
	vNodesCopy = vNodes;
	for (CNode *pnode : vNodesCopy) {
	pnode->AddRef();
	}
	}
	for (CNode *pnode : vNodesCopy) {
	if (interruptNet) {
	return;
	}

	//
	// Receive
	//
	bool recvSet = false;
	bool sendSet = false;
	bool errorSet = false;
	{
	LOCK(pnode->cs_hSocket);
	if (pnode->hSocket == INVALID_SOCKET) {
	continue;
	}
	recvSet = recv_set.count(pnode->hSocket) > 0;
	sendSet = send_set.count(pnode->hSocket) > 0;
	errorSet = error_set.count(pnode->hSocket) > 0;
	}
	if (recvSet \|\| errorSet) {
	// typical socket buffer is 8K-64K
	char pchBuf[0x10000];
	int32_t nBytes = 0;
	{
	LOCK(pnode->cs_hSocket);
	if (pnode->hSocket == INVALID_SOCKET) {
	continue;
	}
	nBytes =
	recv(pnode->hSocket, pchBuf, sizeof(pchBuf), MSG_DONTWAIT);
	}
	if (nBytes > 0) {
	bool notify = false;
	if (!pnode->ReceiveMsgBytes(*config, pchBuf, nBytes, notify)) {
	pnode->CloseSocketDisconnect();
	}
	RecordBytesRecv(nBytes);
	if (notify) {
	size_t nSizeAdded = 0;
	auto it(pnode->vRecvMsg.begin());
	for (; it != pnode->vRecvMsg.end(); ++it) {
	if (!it->complete()) {
	break;
	}
	nSizeAdded +=
	it->vRecv.size() + CMessageHeader::HEADER_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\n");
	+ LogPrint(BCLog::NET, "socket closed for peer=%d\n",
	+ pnode->GetId());
	}
	pnode->CloseSocketDisconnect();
	} else if (nBytes < 0) {
	// error
	int nErr = WSAGetLastError();
	if (nErr != WSAEWOULDBLOCK && nErr != WSAEMSGSIZE &&
	nErr != WSAEINTR && nErr != WSAEINPROGRESS) {
	if (!pnode->fDisconnect) {
	- LogPrintf("socket recv error %s\n",
	- NetworkErrorString(nErr));
	+ LogPrint(BCLog::NET,
	+ "socket recv error for peer=%d: %s\n",
	+ pnode->GetId(), NetworkErrorString(nErr));
	}
	pnode->CloseSocketDisconnect();
	}
	}
	}

	//
	// Send
	//
	if (sendSet) {
	LOCK(pnode->cs_vSend);
	size_t nBytes = SocketSendData(pnode);
	if (nBytes) {
	RecordBytesSent(nBytes);
	}
	}

	InactivityCheck(pnode);
	}
	{
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodesCopy) {
	pnode->Release();
	}
	}
	}

	void CConnman::ThreadSocketHandler() {
	while (!interruptNet) {
	DisconnectNodes();
	NotifyNumConnectionsChanged();
	SocketHandler();
	}
	}

	void CConnman::WakeMessageHandler() {
	{
	LOCK(mutexMsgProc);
	fMsgProcWake = true;
	}
	condMsgProc.notify_one();
	}

	#ifdef USE_UPNP
	static CThreadInterrupt g_upnp_interrupt;
	static std::thread g_upnp_thread;
	static void ThreadMapPort() {
	std::string port = strprintf("%u", GetListenPort());
	const char *multicastif = nullptr;
	const char *minissdpdpath = nullptr;
	struct UPNPDev *devlist = nullptr;
	char lanaddr[64];

	#ifndef UPNPDISCOVER_SUCCESS
	/* miniupnpc 1.5 */
	devlist = upnpDiscover(2000, multicastif, minissdpdpath, 0);
	#elif MINIUPNPC_API_VERSION < 14
	/* miniupnpc 1.6 */
	int error = 0;
	devlist = upnpDiscover(2000, multicastif, minissdpdpath, 0, 0, &error);
	#else
	/* miniupnpc 1.9.20150730 */
	int error = 0;
	devlist = upnpDiscover(2000, multicastif, minissdpdpath, 0, 0, 2, &error);
	#endif

	struct UPNPUrls urls;
	struct IGDdatas data;
	int r;

	r = UPNP_GetValidIGD(devlist, &urls, &data, lanaddr, sizeof(lanaddr));
	if (r == 1) {
	if (fDiscover) {
	char externalIPAddress[40];
	r = UPNP_GetExternalIPAddress(
	urls.controlURL, data.first.servicetype, externalIPAddress);
	if (r != UPNPCOMMAND_SUCCESS) {
	LogPrintf("UPnP: GetExternalIPAddress() returned %d\n", r);
	} else {
	if (externalIPAddress[0]) {
	CNetAddr resolved;
	if (LookupHost(externalIPAddress, resolved, false)) {
	LogPrintf("UPnP: ExternalIPAddress = %s\n",
	resolved.ToString());
	AddLocal(resolved, LOCAL_UPNP);
	}
	} else {
	LogPrintf("UPnP: GetExternalIPAddress failed.\n");
	}
	}
	}

	std::string strDesc = "Bitcoin " + FormatFullVersion();

	do {
	#ifndef UPNPDISCOVER_SUCCESS
	/* miniupnpc 1.5 */
	r = UPNP_AddPortMapping(urls.controlURL, data.first.servicetype,
	port.c_str(), port.c_str(), lanaddr,
	strDesc.c_str(), "TCP", 0);
	#else
	/* miniupnpc 1.6 */
	r = UPNP_AddPortMapping(urls.controlURL, data.first.servicetype,
	port.c_str(), port.c_str(), lanaddr,
	strDesc.c_str(), "TCP", 0, "0");
	#endif

	if (r != UPNPCOMMAND_SUCCESS) {
	LogPrintf(
	"AddPortMapping(%s, %s, %s) failed with code %d (%s)\n",
	port, port, lanaddr, r, strupnperror(r));
	} else {
	LogPrintf("UPnP Port Mapping successful.\n");
	}
	} while (g_upnp_interrupt.sleep_for(std::chrono::minutes(20)));

	r = UPNP_DeletePortMapping(urls.controlURL, data.first.servicetype,
	port.c_str(), "TCP", 0);
	LogPrintf("UPNP_DeletePortMapping() returned: %d\n", r);
	freeUPNPDevlist(devlist);
	devlist = nullptr;
	FreeUPNPUrls(&urls);
	} else {
	LogPrintf("No valid UPnP IGDs found\n");
	freeUPNPDevlist(devlist);
	devlist = nullptr;
	if (r != 0) {
	FreeUPNPUrls(&urls);
	}
	}
	}

	void StartMapPort() {
	if (!g_upnp_thread.joinable()) {
	assert(!g_upnp_interrupt);
	g_upnp_thread = std::thread(
	(std::bind(&TraceThread<void (*)()>, "upnp", &ThreadMapPort)));
	}
	}

	void InterruptMapPort() {
	if (g_upnp_thread.joinable()) {
	g_upnp_interrupt();
	}
	}

	void StopMapPort() {
	if (g_upnp_thread.joinable()) {
	g_upnp_thread.join();
	g_upnp_interrupt.reset();
	}
	}

	#else
	void StartMapPort() {
	// Intentionally left blank.
	}
	void InterruptMapPort() {
	// Intentionally left blank.
	}
	void StopMapPort() {
	// Intentionally left blank.
	}
	#endif

	void CConnman::ThreadDNSAddressSeed() {
	// goal: only query DNS seeds if address need is acute.
	// Avoiding DNS seeds when we don't need them 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.
	if ((addrman.size() > 0) &&
	(!gArgs.GetBoolArg("-forcednsseed", DEFAULT_FORCEDNSSEED))) {
	if (!interruptNet.sleep_for(std::chrono::seconds(11))) {
	return;
	}

	LOCK(cs_vNodes);
	int nRelevant = 0;
	for (const CNode *pnode : vNodes) {
	nRelevant += pnode->fSuccessfullyConnected && !pnode->fFeeler &&
	!pnode->fOneShot && !pnode->m_manual_connection &&
	!pnode->fInbound;
	}
	if (nRelevant >= 2) {
	LogPrintf("P2P peers available. Skipped DNS seeding.\n");
	return;
	}
	}

	const std::vector<std::string> &vSeeds =
	config->GetChainParams().DNSSeeds();
	int found = 0;

	LogPrintf("Loading addresses from DNS seeds (could take a while)\n");

	for (const std::string &seed : vSeeds) {
	if (interruptNet) {
	return;
	}
	if (HaveNameProxy()) {
	AddOneShot(seed);
	} else {
	std::vector<CNetAddr> vIPs;
	std::vector<CAddress> vAdd;
	ServiceFlags requiredServiceBits =
	GetDesirableServiceFlags(NODE_NONE);
	std::string host = strprintf("x%x.%s", requiredServiceBits, seed);
	CNetAddr resolveSource;
	if (!resolveSource.SetInternal(host)) {
	continue;
	}

	// Limits number of IPs learned from a DNS seed
	unsigned int nMaxIPs = 256;
	if (LookupHost(host.c_str(), vIPs, nMaxIPs, true)) {
	for (const CNetAddr &ip : vIPs) {
	int nOneDay = 24 * 3600;
	CAddress addr = CAddress(
	CService(ip, config->GetChainParams().GetDefaultPort()),
	requiredServiceBits);
	// Use a random age between 3 and 7 days old.
	addr.nTime = GetTime() - 3 * nOneDay - GetRand(4 * nOneDay);
	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
	// oneshot to get nodes with our desired service bits.
	AddOneShot(seed);
	}
	}
	}

	LogPrintf("%d addresses found from DNS seeds\n", found);
	}

	void CConnman::DumpAddresses() {
	int64_t nStart = GetTimeMillis();

	CAddrDB adb(config->GetChainParams());
	adb.Write(addrman);

	LogPrint(BCLog::NET, "Flushed %d addresses to peers.dat %dms\n",
	addrman.size(), GetTimeMillis() - nStart);
	}

	void CConnman::ProcessOneShot() {
	std::string strDest;
	{
	LOCK(cs_vOneShots);
	if (vOneShots.empty()) {
	return;
	}
	strDest = vOneShots.front();
	vOneShots.pop_front();
	}
	CAddress addr;
	CSemaphoreGrant grant(*semOutbound, true);
	if (grant) {
	OpenNetworkConnection(addr, false, &grant, strDest.c_str(), true);
	}
	}

	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 one-shots and feelers).
	// 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) {
	if (!pnode->fInbound && !pnode->m_manual_connection &&
	!pnode->fFeeler && !pnode->fDisconnect && !pnode->fOneShot &&
	pnode->fSuccessfullyConnected) {
	++nOutbound;
	}
	}
	}
	return std::max(
	nOutbound - m_max_outbound_full_relay - m_max_outbound_block_relay, 0);
	}

	void CConnman::ThreadOpenConnections(const std::vector<std::string> connect) {
	// Connect to specific addresses
	if (!connect.empty()) {
	for (int64_t nLoop = 0;; nLoop++) {
	ProcessOneShot();
	for (const std::string &strAddr : connect) {
	CAddress addr(CService(), NODE_NONE);
	OpenNetworkConnection(addr, false, nullptr, strAddr.c_str(),
	false, false, true);
	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) {
	ProcessOneShot();

	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?).
	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(convertSeed6(config->GetChainParams().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).
	int nOutboundFullRelay = 0;
	int nOutboundBlockRelay = 0;
	std::set<std::vector<uint8_t>> setConnected;
	{
	LOCK(cs_vNodes);
	for (const CNode *pnode : vNodes) {
	if (!pnode->fInbound && !pnode->m_manual_connection) {
	// Netgroups for inbound and addnode 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 addnode peers do not use our outbound slots. Inbound
	// peers also have the added issue that they're attacker
	// controlled and could be used to prevent us from
	// connecting to particular hosts if we used them here.
	setConnected.insert(pnode->addr.GetGroup());
	if (pnode->m_tx_relay == nullptr) {
	nOutboundBlockRelay++;
	} else if (!pnode->fFeeler) {
	nOutboundFullRelay++;
	}
	}
	}
	}

	// Feeler Connections
	//
	// Design goals:
	// * Increase the number of connectable addresses in the tried table.
	//
	// Method:
	// * Choose a random address from new and attempt to connect to it if
	// we can connect successfully it is added to tried.
	// * Start attempting feeler connections only after node finishes
	// making outbound connections.
	// * Only make a feeler connection once every few minutes.
	//
	bool fFeeler = false;

	if (nOutboundFullRelay >= m_max_outbound_full_relay &&
	nOutboundBlockRelay >= m_max_outbound_block_relay &&
	!GetTryNewOutboundPeer()) {
	// The current time right now (in microseconds).
	int64_t nTime = GetTimeMicros();
	if (nTime > nNextFeeler) {
	nNextFeeler = PoissonNextSend(nTime, FEELER_INTERVAL);
	fFeeler = true;
	} else {
	continue;
	}
	}

	addrman.ResolveCollisions();

	int64_t nANow = GetAdjustedTime();
	int nTries = 0;
	while (!interruptNet) {
	CAddrInfo addr = addrman.SelectTriedCollision();

	// SelectTriedCollision returns an invalid address if it is empty.
	if (!fFeeler \|\| !addr.IsValid()) {
	addr = addrman.Select(fFeeler);
	}

	// Require outbound connections, other than feelers, to be to
	// distinct network groups
	if (!fFeeler && setConnected.count(addr.GetGroup())) {
	break;
	}

	// if we selected an invalid or local address, restart
	if (!addr.IsValid() \|\| IsLocal(addr)) {
	break;
	}

	// 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;
	}

	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 (!fFeeler && !HasAllDesirableServiceFlags(addr.nServices)) {
	continue;
	}

	if (fFeeler && !MayHaveUsefulAddressDB(addr.nServices)) {
	continue;
	}

	// do not allow non-default ports, unless after 50 invalid addresses
	// selected already.
	if (addr.GetPort() != config->GetChainParams().GetDefaultPort() &&
	nTries < 50) {
	continue;
	}

	addrConnect = addr;
	break;
	}

	if (addrConnect.IsValid()) {
	if (fFeeler) {
	// Add small amount of random noise before connection to avoid
	// synchronization.
	int randsleep = GetRandInt(FEELER_SLEEP_WINDOW * 1000);
	if (!interruptNet.sleep_for(
	std::chrono::milliseconds(randsleep))) {
	return;
	}
	LogPrint(BCLog::NET, "Making feeler connection to %s\n",
	addrConnect.ToString());
	}

	// Open this connection as block-relay-only if we're already at our
	// full-relay capacity, but not yet at our block-relay peer limit.
	// (It should not be possible for fFeeler to be set if we're not
	// also at our block-relay peer limit, but check against that as
	// well for sanity.)
	bool block_relay_only =
	nOutboundBlockRelay < m_max_outbound_block_relay && !fFeeler &&
	nOutboundFullRelay >= m_max_outbound_full_relay;

	OpenNetworkConnection(
	addrConnect,
	int(setConnected.size()) >= std::min(nMaxConnections - 1, 2),
	&grant, nullptr, false, fFeeler, false, block_relay_only);
	}
	}
	}

	std::vector<AddedNodeInfo> CConnman::GetAddedNodeInfo() {
	std::vector<AddedNodeInfo> ret;

	std::list<std::string> 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<CService, bool> mapConnected;
	std::map<std::string, std::pair<bool, CService>> mapConnectedByName;
	{
	LOCK(cs_vNodes);
	for (const CNode *pnode : vNodes) {
	if (pnode->addr.IsValid()) {
	mapConnected[pnode->addr] = pnode->fInbound;
	}
	std::string addrName = pnode->GetAddrName();
	if (!addrName.empty()) {
	mapConnectedByName[std::move(addrName)] =
	std::make_pair(pnode->fInbound,
	static_cast<const CService &>(pnode->addr));
	}
	}
	}

	for (const std::string &strAddNode : lAddresses) {
	CService service(
	LookupNumeric(strAddNode.c_str(), Params().GetDefaultPort()));
	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<AddedNodeInfo> 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(), false, false,
	true);
	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;
	}
	}
	}

	// If successful, this moves the passed grant to the constructed node.
	void CConnman::OpenNetworkConnection(const CAddress &addrConnect,
	bool fCountFailure,
	CSemaphoreGrant *grantOutbound,
	const char *pszDest, bool fOneShot,
	bool fFeeler, bool manual_connection,
	bool block_relay_only) {
	//
	// Initiate outbound network connection
	//
	if (interruptNet) {
	return;
	}
	if (!fNetworkActive) {
	return;
	}
	if (!pszDest) {
	bool banned_or_discouraged =
	m_banman && (m_banman->IsDiscouraged(addrConnect) \|\|
	m_banman->IsBanned(addrConnect));
	if (IsLocal(addrConnect) \|\|
	FindNode(static_cast<CNetAddr>(addrConnect)) \|\|
	banned_or_discouraged \|\| FindNode(addrConnect.ToStringIPPort())) {
	return;
	}
	} else if (FindNode(std::string(pszDest))) {
	return;
	}

	CNode *pnode = ConnectNode(addrConnect, pszDest, fCountFailure,
	manual_connection, block_relay_only);

	if (!pnode) {
	return;
	}
	if (grantOutbound) {
	grantOutbound->MoveTo(pnode->grantOutbound);
	}
	if (fOneShot) {
	pnode->fOneShot = true;
	}
	if (fFeeler) {
	pnode->fFeeler = true;
	}
	if (manual_connection) {
	pnode->m_manual_connection = true;
	}

	m_msgproc->InitializeNode(*config, pnode);
	{
	LOCK(cs_vNodes);
	vNodes.push_back(pnode);
	}
	}

	void CConnman::ThreadMessageHandler() {
	while (!flagInterruptMsgProc) {
	std::vector<CNode *> vNodesCopy;
	{
	LOCK(cs_vNodes);
	vNodesCopy = vNodes;
	for (CNode *pnode : vNodesCopy) {
	pnode->AddRef();
	}
	}

	bool fMoreWork = false;

	for (CNode *pnode : vNodesCopy) {
	if (pnode->fDisconnect) {
	continue;
	}

	// Receive messages
	bool fMoreNodeWork = m_msgproc->ProcessMessages(
	*config, pnode, flagInterruptMsgProc);
	fMoreWork \|= (fMoreNodeWork && !pnode->fPauseSend);
	if (flagInterruptMsgProc) {
	return;
	}

	// Send messages
	{
	LOCK(pnode->cs_sendProcessing);
	m_msgproc->SendMessages(*config, pnode, flagInterruptMsgProc);
	}

	if (flagInterruptMsgProc) {
	return;
	}
	}

	{
	LOCK(cs_vNodes);
	for (CNode *pnode : vNodesCopy) {
	pnode->Release();
	}
	}

	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;
	}
	}

	bool CConnman::BindListenPort(const CService &addrBind, std::string &strError,
	NetPermissionFlags permissions) {
	strError = "";
	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("Error: Bind address family for %s not supported",
	addrBind.ToString());
	LogPrintf("%s\n", strError);
	return false;
	}

	SOCKET hListenSocket = CreateSocket(addrBind);
	if (hListenSocket == INVALID_SOCKET) {
	strError = strprintf("Error: Couldn't open socket for incoming "
	"connections (socket returned error %s)",
	NetworkErrorString(WSAGetLastError()));
	LogPrintf("%s\n", strError);
	return false;
	}

	// Allow binding if the port is still in TIME_WAIT state after
	// the program was closed and restarted.
	setsockopt(hListenSocket, 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(hListenSocket, IPPROTO_IPV6, IPV6_V6ONLY,
	(sockopt_arg_type)&nOne, sizeof(int));
	#endif
	#ifdef WIN32
	int nProtLevel = PROTECTION_LEVEL_UNRESTRICTED;
	setsockopt(hListenSocket, IPPROTO_IPV6, IPV6_PROTECTION_LEVEL,
	(sockopt_arg_type)&nProtLevel, sizeof(int));
	#endif
	}

	if (::bind(hListenSocket, (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.")
	.translated,
	addrBind.ToString(), PACKAGE_NAME);
	} else {
	strError = strprintf(_("Unable to bind to %s on this computer "
	"(bind returned error %s)")
	.translated,
	addrBind.ToString(), NetworkErrorString(nErr));
	}
	LogPrintf("%s\n", strError);
	CloseSocket(hListenSocket);
	return false;
	}
	LogPrintf("Bound to %s\n", addrBind.ToString());

	// Listen for incoming connections
	if (listen(hListenSocket, SOMAXCONN) == SOCKET_ERROR) {
	strError = strprintf(_("Error: Listening for incoming connections "
	"failed (listen returned error %s)")
	.translated,
	NetworkErrorString(WSAGetLastError()));
	LogPrintf("%s\n", strError);
	CloseSocket(hListenSocket);
	return false;
	}

	vhListenSocket.push_back(ListenSocket(hListenSocket, permissions));

	if (addrBind.IsRoutable() && fDiscover && (permissions & PF_NOBAN) == 0) {
	AddLocal(addrBind, LOCAL_BIND);
	}

	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<CNetAddr> 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 \|\| (ifa->ifa_flags & IFF_UP) == 0 \|\|
	strcmp(ifa->ifa_name, "lo") == 0 \|\|
	strcmp(ifa->ifa_name, "lo0") == 0) {
	continue;
	}
	if (ifa->ifa_addr->sa_family == AF_INET) {
	struct sockaddr_in *s4 =
	reinterpret_cast<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 =
	reinterpret_cast<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;
	uiInterface.NotifyNetworkActiveChanged(fNetworkActive);
	}

	CConnman::CConnman(const Config &configIn, uint64_t nSeed0In, uint64_t nSeed1In)
	: config(&configIn), nSeed0(nSeed0In), nSeed1(nSeed1In) {
	SetTryNewOutboundPeer(false);

	Options connOptions;
	Init(connOptions);
	}

	NodeId CConnman::GetNewNodeId() {
	return nLastNodeId.fetch_add(1);
	}

	bool CConnman::Bind(const CService &addr, unsigned int flags,
	NetPermissionFlags permissions) {
	if (!(flags & BF_EXPLICIT) && !IsReachable(addr)) {
	return false;
	}
	std::string strError;
	if (!BindListenPort(addr, strError, permissions)) {
	if ((flags & BF_REPORT_ERROR) && clientInterface) {
	clientInterface->ThreadSafeMessageBox(
	strError, "", CClientUIInterface::MSG_ERROR);
	}
	return false;
	}
	return true;
	}

	bool CConnman::InitBinds(
	const std::vector<CService> &binds,
	const std::vector<NetWhitebindPermissions> &whiteBinds) {
	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 = 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);
	}
	return fBound;
	}

	bool CConnman::Start(CScheduler &scheduler, const Options &connOptions) {
	Init(connOptions);

	{
	LOCK(cs_totalBytesRecv);
	nTotalBytesRecv = 0;
	}
	{
	LOCK(cs_totalBytesSent);
	nTotalBytesSent = 0;
	nMaxOutboundTotalBytesSentInCycle = 0;
	nMaxOutboundCycleStartTime = 0;
	}

	if (fListen && !InitBinds(connOptions.vBinds, connOptions.vWhiteBinds)) {
	if (clientInterface) {
	clientInterface->ThreadSafeMessageBox(
	_("Failed to listen on any port. Use -listen=0 if you want "
	"this.")
	.translated,
	"", CClientUIInterface::MSG_ERROR);
	}
	return false;
	}

	for (const auto &strDest : connOptions.vSeedNodes) {
	AddOneShot(strDest);
	}

	if (clientInterface) {
	clientInterface->InitMessage(_("Loading P2P addresses...").translated);
	}
	// Load addresses from peers.dat
	int64_t nStart = GetTimeMillis();
	{
	CAddrDB adb(config->GetChainParams());
	if (adb.Read(addrman)) {
	LogPrintf("Loaded %i addresses from peers.dat %dms\n",
	addrman.size(), GetTimeMillis() - nStart);
	} else {
	// Addrman can be in an inconsistent state after failure, reset it
	addrman.Clear();
	LogPrintf("Invalid or missing peers.dat; recreating\n");
	DumpAddresses();
	}
	}

	uiInterface.InitMessage(_("Starting network threads...").translated);

	fAddressesInitialized = true;

	if (semOutbound == nullptr) {
	// initialize semaphore
	semOutbound = std::make_unique<CSemaphore>(
	std::min(m_max_outbound, nMaxConnections));
	}
	if (semAddnode == nullptr) {
	// initialize semaphore
	semAddnode = std::make_unique<CSemaphore>(nMaxAddnode);
	}

	//
	// Start threads
	//
	assert(m_msgproc);
	InterruptSocks5(false);
	interruptNet.reset();
	flagInterruptMsgProc = false;

	{
	LOCK(mutexMsgProc);
	fMsgProcWake = false;
	}

	// Send and receive from sockets, accept connections
	threadSocketHandler = std::thread(
	&TraceThread<std::function<void()>>, "net",
	std::function<void()>(std::bind(&CConnman::ThreadSocketHandler, this)));

	if (!gArgs.GetBoolArg("-dnsseed", true)) {
	LogPrintf("DNS seeding disabled\n");
	} else {
	threadDNSAddressSeed =
	std::thread(&TraceThread<std::function<void()>>, "dnsseed",
	std::function<void()>(
	std::bind(&CConnman::ThreadDNSAddressSeed, this)));
	}

	// Initiate outbound connections from -addnode
	threadOpenAddedConnections =
	std::thread(&TraceThread<std::function<void()>>, "addcon",
	std::function<void()>(std::bind(
	&CConnman::ThreadOpenAddedConnections, this)));

	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.")
	.translated,
	"", CClientUIInterface::MSG_ERROR);
	}
	return false;
	}
	if (connOptions.m_use_addrman_outgoing \|\|
	!connOptions.m_specified_outgoing.empty()) {
	threadOpenConnections =
	std::thread(&TraceThread<std::function<void()>>, "opencon",
	std::function<void()>(
	std::bind(&CConnman::ThreadOpenConnections, this,
	connOptions.m_specified_outgoing)));
	}

	// Process messages
	threadMessageHandler =
	std::thread(&TraceThread<std::function<void()>>, "msghand",
	std::function<void()>(
	std::bind(&CConnman::ThreadMessageHandler, this)));

	// Dump network addresses
	scheduler.scheduleEvery(
	[this]() {
	this->DumpAddresses();
	return true;
	},
	DUMP_PEERS_INTERVAL);

	return true;
	}

	class CNetCleanup {
	public:
	CNetCleanup() {}

	~CNetCleanup() {
	#ifdef WIN32
	// Shutdown Windows Sockets
	WSACleanup();
	#endif
	}
	};
	static CNetCleanup instance_of_cnetcleanup;

	void CConnman::Interrupt() {
	{
	LOCK(mutexMsgProc);
	flagInterruptMsgProc = true;
	}
	condMsgProc.notify_all();

	interruptNet();
	InterruptSocks5(true);

	if (semOutbound) {
	for (int i = 0; i < m_max_outbound; i++) {
	semOutbound->post();
	}
	}

	if (semAddnode) {
	for (int i = 0; i < nMaxAddnode; i++) {
	semAddnode->post();
	}
	}
	}

	void CConnman::Stop() {
	if (threadMessageHandler.joinable()) {
	threadMessageHandler.join();
	}
	if (threadOpenConnections.joinable()) {
	threadOpenConnections.join();
	}
	if (threadOpenAddedConnections.joinable()) {
	threadOpenAddedConnections.join();
	}
	if (threadDNSAddressSeed.joinable()) {
	threadDNSAddressSeed.join();
	}
	if (threadSocketHandler.joinable()) {
	threadSocketHandler.join();
	}

	if (fAddressesInitialized) {
	DumpAddresses();
	fAddressesInitialized = false;
	}

	// Close sockets
	for (CNode *pnode : vNodes) {
	pnode->CloseSocketDisconnect();
	}
	for (ListenSocket &hListenSocket : vhListenSocket) {
	if (hListenSocket.socket != INVALID_SOCKET) {
	if (!CloseSocket(hListenSocket.socket)) {
	LogPrintf("CloseSocket(hListenSocket) failed with error %s\n",
	NetworkErrorString(WSAGetLastError()));
	}
	}
	}

	// clean up some globals (to help leak detection)
	for (CNode *pnode : vNodes) {
	DeleteNode(pnode);
	}
	for (CNode *pnode : vNodesDisconnected) {
	DeleteNode(pnode);
	}
	vNodes.clear();
	vNodesDisconnected.clear();
	vhListenSocket.clear();
	semOutbound.reset();
	semAddnode.reset();
	}

	void CConnman::DeleteNode(CNode *pnode) {
	assert(pnode);
	bool fUpdateConnectionTime = false;
	m_msgproc->FinalizeNode(*config, pnode->GetId(), fUpdateConnectionTime);
	if (fUpdateConnectionTime) {
	addrman.Connected(pnode->addr);
	}
	delete pnode;
	}

	CConnman::~CConnman() {
	Interrupt();
	Stop();
	}

	size_t CConnman::GetAddressCount() const {
	return addrman.size();
	}

	void CConnman::SetServices(const CService &addr, ServiceFlags nServices) {
	addrman.SetServices(addr, nServices);
	}

	void CConnman::MarkAddressGood(const CAddress &addr) {
	addrman.Good(addr);
	}

	void CConnman::AddNewAddresses(const std::vector<CAddress> &vAddr,
	const CAddress &addrFrom, int64_t nTimePenalty) {
	addrman.Add(vAddr, addrFrom, nTimePenalty);
	}

	std::vector<CAddress> CConnman::GetAddresses() {
	return addrman.GetAddr();
	}

	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<std::string>::iterator it = vAddedNodes.begin();
	it != vAddedNodes.end(); ++it) {
	if (strNode == *it) {
	vAddedNodes.erase(it);
	return true;
	}
	}
	return false;
	}

	size_t CConnman::GetNodeCount(NumConnections flags) {
	LOCK(cs_vNodes);
	// Shortcut if we want total
	if (flags == CConnman::CONNECTIONS_ALL) {
	return vNodes.size();
	}

	int nNum = 0;
	for (const auto &pnode : vNodes) {
	if (flags & (pnode->fInbound ? CONNECTIONS_IN : CONNECTIONS_OUT)) {
	nNum++;
	}
	}

	return nNum;
	}

	void CConnman::GetNodeStats(std::vector<CNodeStats> &vstats) {
	vstats.clear();
	LOCK(cs_vNodes);
	vstats.reserve(vNodes.size());
	for (CNode *pnode : vNodes) {
	vstats.emplace_back();
	pnode->copyStats(vstats.back());
	}
	}

	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::RecordBytesRecv(uint64_t bytes) {
	LOCK(cs_totalBytesRecv);
	nTotalBytesRecv += bytes;
	}

	void CConnman::RecordBytesSent(uint64_t bytes) {
	LOCK(cs_totalBytesSent);
	nTotalBytesSent += bytes;

	uint64_t now = GetTime();
	if (nMaxOutboundCycleStartTime + nMaxOutboundTimeframe < now) {
	// timeframe expired, reset cycle
	nMaxOutboundCycleStartTime = now;
	nMaxOutboundTotalBytesSentInCycle = 0;
	}

	// TODO, exclude whitebind peers
	nMaxOutboundTotalBytesSentInCycle += bytes;
	}

	void CConnman::SetMaxOutboundTarget(uint64_t limit) {
	LOCK(cs_totalBytesSent);
	nMaxOutboundLimit = limit;
	}

	uint64_t CConnman::GetMaxOutboundTarget() {
	LOCK(cs_totalBytesSent);
	return nMaxOutboundLimit;
	}

	uint64_t CConnman::GetMaxOutboundTimeframe() {
	LOCK(cs_totalBytesSent);
	return nMaxOutboundTimeframe;
	}

	uint64_t CConnman::GetMaxOutboundTimeLeftInCycle() {
	LOCK(cs_totalBytesSent);
	if (nMaxOutboundLimit == 0) {
	return 0;
	}

	if (nMaxOutboundCycleStartTime == 0) {
	return nMaxOutboundTimeframe;
	}

	uint64_t cycleEndTime = nMaxOutboundCycleStartTime + nMaxOutboundTimeframe;
	uint64_t now = GetTime();
	return (cycleEndTime < now) ? 0 : cycleEndTime - GetTime();
	}

	void CConnman::SetMaxOutboundTimeframe(uint64_t timeframe) {
	LOCK(cs_totalBytesSent);
	if (nMaxOutboundTimeframe != timeframe) {
	// reset measure-cycle in case of changing the timeframe.
	nMaxOutboundCycleStartTime = GetTime();
	}
	nMaxOutboundTimeframe = timeframe;
	}

	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.
	uint64_t timeLeftInCycle = GetMaxOutboundTimeLeftInCycle();
	uint64_t buffer = timeLeftInCycle / 600 * ONE_MEGABYTE;
	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;
	}

	void CConnman::SetBestHeight(int height) {
	nBestHeight.store(height, std::memory_order_release);
	}

	int CConnman::GetBestHeight() const {
	return nBestHeight.load(std::memory_order_acquire);
	}

	unsigned int CConnman::GetReceiveFloodSize() const {
	return nReceiveFloodSize;
	}

	CNode::CNode(NodeId idIn, ServiceFlags nLocalServicesIn,
	int nMyStartingHeightIn, SOCKET hSocketIn, const CAddress &addrIn,
	uint64_t nKeyedNetGroupIn, uint64_t nLocalHostNonceIn,
	const CAddress &addrBindIn, const std::string &addrNameIn,
	bool fInboundIn, bool block_relay_only)
	: nTimeConnected(GetSystemTimeInSeconds()), addr(addrIn),
	addrBind(addrBindIn), fInbound(fInboundIn),
	nKeyedNetGroup(nKeyedNetGroupIn), addrKnown(5000, 0.001),
	// Don't relay addr messages to peers that we connect to as
	// block-relay-only peers (to prevent adversaries from inferring these
	// links from addr traffic).
	m_addr_relay_peer(!block_relay_only), id(idIn),
	nLocalHostNonce(nLocalHostNonceIn), nLocalServices(nLocalServicesIn),
	nMyStartingHeight(nMyStartingHeightIn) {
	hSocket = hSocketIn;
	addrName = addrNameIn == "" ? addr.ToStringIPPort() : addrNameIn;
	hashContinue = BlockHash();
	if (!block_relay_only) {
	m_tx_relay = std::make_unique<TxRelay>();
	}

	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);
	}
	}

	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();
	size_t nTotalSize = nMessageSize + CMessageHeader::HEADER_SIZE;
	LogPrint(BCLog::NET, "sending %s (%d bytes) peer=%d\n",
	SanitizeString(msg.command), nMessageSize, pnode->GetId());

	std::vector<uint8_t> serializedHeader;
	serializedHeader.reserve(CMessageHeader::HEADER_SIZE);
	uint256 hash = Hash(msg.data.data(), msg.data.data() + nMessageSize);
	CMessageHeader hdr(config->GetChainParams().NetMagic(), msg.command.c_str(),
	nMessageSize);
	memcpy(hdr.pchChecksum, hash.begin(), CMessageHeader::CHECKSUM_SIZE);

	CVectorWriter{SER_NETWORK, INIT_PROTO_VERSION, serializedHeader, 0, hdr};

	size_t nBytesSent = 0;
	{
	LOCK(pnode->cs_vSend);
	bool optimisticSend(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));
	}

	// If write queue empty, attempt "optimistic write"
	if (optimisticSend == true) {
	nBytesSent = SocketSendData(pnode);
	}
	}
	if (nBytesSent) {
	RecordBytesSent(nBytesSent);
	}
	}

	bool CConnman::ForNode(NodeId id, std::function<bool(CNode *pnode)> func) {
	CNode *found = nullptr;
	LOCK(cs_vNodes);
	for (auto &&pnode : vNodes) {
	if (pnode->GetId() == id) {
	found = pnode;
	break;
	}
	}
	return found != nullptr && NodeFullyConnected(found) && func(found);
	}

	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 be 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);
	}

	CSipHasher CConnman::GetDeterministicRandomizer(uint64_t id) const {
	return CSipHasher(nSeed0, nSeed1).Write(id);
	}

	uint64_t CConnman::CalculateKeyedNetGroup(const CAddress &ad) const {
	std::vector<uint8_t> vchNetGroup(ad.GetGroup());

	return GetDeterministicRandomizer(RANDOMIZER_ID_NETGROUP)
	.Write(vchNetGroup.data(), vchNetGroup.size())
	.Finalize();
	}

	/**
	* This function convert MaxBlockSize from byte to
	* MB with a decimal precision one digit rounded down
	* E.g.
	* 1660000 -> 1.6
	* 2010000 -> 2.0
	* 1000000 -> 1.0
	* 230000 -> 0.2
	* 50000 -> 0.0
	*
	* NB behavior for EB<1MB not standardized yet still
	* the function applies the same algo used for
	* EB greater or equal to 1MB
	*/
	std::string getSubVersionEB(uint64_t MaxBlockSize) {
	// Prepare EB string we are going to add to SubVer:
	// 1) translate from byte to MB and convert to string
	// 2) limit the EB string to the first decimal digit (floored)
	std::stringstream ebMBs;
	ebMBs << (MaxBlockSize / (ONE_MEGABYTE / 10));
	std::string eb = ebMBs.str();
	eb.insert(eb.size() - 1, ".", 1);
	if (eb.substr(0, 1) == ".") {
	eb = "0" + eb;
	}
	return eb;
	}

	std::string userAgent(const Config &config) {
	// format excessive blocksize value
	std::string eb = getSubVersionEB(config.GetMaxBlockSize());
	std::vector<std::string> uacomments;
	uacomments.push_back("EB" + eb);

	// Comments are checked for char compliance at startup, it is safe to add
	// them to the user agent string
	for (const std::string &cmt : gArgs.GetArgs("-uacomment")) {
	uacomments.push_back(cmt);
	}

	// Size compliance is checked at startup, it is safe to not check it again
	std::string subversion =
	FormatSubVersion(CLIENT_NAME, CLIENT_VERSION, uacomments);

	return subversion;
	}

File Metadata

Mime Type: text/x-diff
Expires: Tue, May 13, 01:44 (1 d, 20 h)
Storage Engine: blob
Storage Format: Raw Data
Storage Handle: 5777060
Default Alt Text: (100 KB)

No OneTemporaryActions

View Options

File Metadata

Event Timeline

No OneTemporary
Actions