/*
* Copyright (c) 2022-2025, The PurpleI2P Project
*
* This file is part of Purple i2pd project and licensed under BSD3
*
* See full license text in LICENSE file at top of project tree
*/

#include <string.h>
#include <openssl/rand.h>
#include "Log.h"
#include "Transports.h"
#include "Gzip.h"
#include "NetDb.hpp"
#include "SSU2.h"
#include "SSU2Session.h"

namespace i2p
{
namespace transport
{
	void SSU2IncompleteMessage::AttachNextFragment (const uint8_t * fragment, size_t fragmentSize)
	{
		if (msg->len + fragmentSize > msg->maxLen)
		{
			LogPrint (eLogInfo, "SSU2: I2NP message size ", msg->maxLen, " is not enough");
			auto newMsg = NewI2NPMessage (msg->len + fragmentSize);
			*newMsg = *msg;
			msg = newMsg;
		}
		if (msg->Concat (fragment, fragmentSize) < fragmentSize)
			LogPrint (eLogError, "SSU2: I2NP buffer overflow ", msg->maxLen);
		nextFragmentNum++;
	}

	bool SSU2IncompleteMessage::ConcatOutOfSequenceFragments ()
	{
		bool isLast = false;
		while (outOfSequenceFragments)
		{
			if (outOfSequenceFragments->fragmentNum == nextFragmentNum)
			{
				AttachNextFragment (outOfSequenceFragments->buf, outOfSequenceFragments->len);
				isLast = outOfSequenceFragments->isLast;
				if (isLast)
					outOfSequenceFragments = nullptr;
				else
					outOfSequenceFragments = outOfSequenceFragments->next;
			}
			else
				break;
		}
		return isLast;
	}

	void SSU2IncompleteMessage::AddOutOfSequenceFragment (std::shared_ptr<SSU2IncompleteMessage::Fragment> fragment)
	{
		if (!fragment || !fragment->fragmentNum) return; // fragment 0 not allowed
		if (fragment->fragmentNum < nextFragmentNum) return; // already processed
		if (!outOfSequenceFragments)
			outOfSequenceFragments = fragment;
		else
		{
			auto frag = outOfSequenceFragments;
			std::shared_ptr<Fragment> prev;
			do
			{
				if (fragment->fragmentNum < frag->fragmentNum) break; // found
				if (fragment->fragmentNum == frag->fragmentNum) return; // duplicate
				prev = frag; frag = frag->next;
			}
			while (frag);
			fragment->next = frag;
			if (prev)
				prev->next = fragment;
			else
				outOfSequenceFragments = fragment;
		}
		lastFragmentInsertTime = i2p::util::GetSecondsSinceEpoch ();
	}

	SSU2Session::SSU2Session (SSU2Server& server, std::shared_ptr<const i2p::data::RouterInfo> in_RemoteRouter,
		std::shared_ptr<const i2p::data::RouterInfo::Address> addr, bool noise):
		TransportSession (in_RemoteRouter, SSU2_CONNECT_TIMEOUT),
		m_Server (server), m_Address (addr), m_RemoteTransports (0), m_RemotePeerTestTransports (0),
		m_RemoteVersion (0), m_DestConnID (0), m_SourceConnID (0), m_State (eSSU2SessionStateUnknown),
		m_SendPacketNum (0), m_ReceivePacketNum (0), m_LastDatetimeSentPacketNum (0),
		m_IsDataReceived (false), m_RTT (SSU2_UNKNOWN_RTT),
		m_MsgLocalExpirationTimeout (I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_MAX),
		m_MsgLocalSemiExpirationTimeout (I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_MAX / 2),
		m_WindowSize (SSU2_MIN_WINDOW_SIZE),
		m_RTO (SSU2_INITIAL_RTO), m_RelayTag (0),m_ConnectTimer (server.GetService ()), 
		m_TerminationReason (eSSU2TerminationReasonNormalClose),
		m_MaxPayloadSize (SSU2_MIN_PACKET_SIZE - IPV6_HEADER_SIZE - UDP_HEADER_SIZE - 32), // min size
		m_LastResendTime (0), m_LastResendAttemptTime (0), m_NumRanges (0)
	{
		if (noise)	
			m_NoiseState.reset (new i2p::crypto::NoiseSymmetricState);
		if (in_RemoteRouter && m_Address)
		{
			// outgoing
			if (noise)
				InitNoiseXKState1 (*m_NoiseState, m_Address->s);
			m_RemoteEndpoint = boost::asio::ip::udp::endpoint (m_Address->host, m_Address->port);
			m_RemoteTransports = in_RemoteRouter->GetCompatibleTransports (false);
			m_RemoteVersion = in_RemoteRouter->GetVersion ();
			if (in_RemoteRouter->IsSSU2PeerTesting (true)) m_RemotePeerTestTransports |= i2p::data::RouterInfo::eSSU2V4;
			if (in_RemoteRouter->IsSSU2PeerTesting (false)) m_RemotePeerTestTransports |= i2p::data::RouterInfo::eSSU2V6;
			RAND_bytes ((uint8_t *)&m_DestConnID, 8);
			RAND_bytes ((uint8_t *)&m_SourceConnID, 8);
		}
		else
		{
			// incoming
			if (noise)
				InitNoiseXKState1 (*m_NoiseState, i2p::context.GetSSU2StaticPublicKey ());
		}
	}

	SSU2Session::~SSU2Session ()
	{
	}

	void SSU2Session::Connect ()
	{
		if (m_State == eSSU2SessionStateUnknown || m_State == eSSU2SessionStateTokenReceived)
		{
			LogPrint(eLogDebug, "SSU2: Connecting to ", GetRemoteEndpoint (),
				" (", i2p::data::GetIdentHashAbbreviation (GetRemoteIdentity ()->GetIdentHash ()), ")");
			ScheduleConnectTimer ();
			auto token = m_Server.FindOutgoingToken (m_RemoteEndpoint);
			if (token)
				SendSessionRequest (token);
			else
			{
				m_State = eSSU2SessionStateUnknown;
				SendTokenRequest ();
			}
		}
	}

	void SSU2Session::ScheduleConnectTimer ()
	{
		m_ConnectTimer.cancel ();
		m_ConnectTimer.expires_from_now (boost::posix_time::seconds(SSU2_CONNECT_TIMEOUT));
		m_ConnectTimer.async_wait (std::bind (&SSU2Session::HandleConnectTimer,
			shared_from_this (), std::placeholders::_1));
	}

	void SSU2Session::HandleConnectTimer (const boost::system::error_code& ecode)
	{
		if (!ecode && m_State != eSSU2SessionStateTerminated)
		{
			// timeout expired
			if (m_State == eSSU2SessionStateIntroduced) // WaitForIntroducer
				LogPrint (eLogWarning, "SSU2: Session was not introduced after ", SSU2_CONNECT_TIMEOUT, " seconds");
			else
				LogPrint (eLogWarning, "SSU2: Session with ", m_RemoteEndpoint, " was not established after ", SSU2_CONNECT_TIMEOUT, " seconds");
			Terminate ();
		}
	}

	bool SSU2Session::Introduce (std::shared_ptr<SSU2Session> session, uint32_t relayTag)
	{
		// we are Alice
		if (!session || !relayTag) return false;
		// find local address to introduce
		auto localAddress = session->FindLocalAddress ();
		if (!localAddress || localAddress->host.is_unspecified () || !localAddress->port) 
		{	
			// can't introduce invalid endpoint
			LogPrint (eLogWarning, "SSU2: Can't find local address to introduce");
			return false; 
		}	
		// create nonce
		uint32_t nonce;
		RAND_bytes ((uint8_t *)&nonce, 4);
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		// payload
		auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
		uint8_t * payload = packet->payload;
		payload[0] = eSSU2BlkRelayRequest;
		payload[3] = 0; // flag
		htobe32buf (payload + 4, nonce);
		htobe32buf (payload + 8, relayTag);
		htobe32buf (payload + 12, ts/1000);
		payload[16] = 2; // ver
		size_t asz = CreateEndpoint (payload + 18, m_MaxPayloadSize - 18, boost::asio::ip::udp::endpoint (localAddress->host, localAddress->port));
		if (!asz) return false;
		payload[17] = asz;
		packet->payloadSize = asz + 18;
		SignedData<128> s;
		s.Insert ((const uint8_t *)"RelayRequestData", 16); // prologue
		s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
		s.Insert (session->GetRemoteIdentity ()->GetIdentHash (), 32); // chash
		s.Insert (payload + 4, 14 + asz); // nonce, relay tag, timestamp, ver, asz and Alice's endpoint
		s.Sign (i2p::context.GetPrivateKeys (), payload + packet->payloadSize);
		packet->payloadSize += i2p::context.GetIdentity ()->GetSignatureLen ();
		htobe16buf (payload + 1, packet->payloadSize - 3); // size
		packet->payloadSize += CreatePaddingBlock (payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
		// send
		m_RelaySessions.emplace (nonce, std::make_pair (session, ts/1000));
		session->m_SourceConnID = htobe64 (((uint64_t)nonce << 32) | nonce);
		session->m_DestConnID = ~session->m_SourceConnID;
		m_Server.AddSession (session);
		int32_t packetNum = SendData (packet->payload, packet->payloadSize);
		packet->sendTime = ts;
		m_SentPackets.emplace (packetNum, packet);
		
		return true;
	}

	void SSU2Session::WaitForIntroduction ()
	{
		m_State = eSSU2SessionStateIntroduced;
		ScheduleConnectTimer ();
	}

	void SSU2Session::ConnectAfterIntroduction ()
	{
		if (m_State == eSSU2SessionStateIntroduced)
		{
			// we are Alice
			//  keep ConnIDs used for introduction, because Charlie waits for SessionRequest from us
			m_State = eSSU2SessionStateTokenReceived;
			// move session to pending outgoing
			if (m_Server.AddPendingOutgoingSession (shared_from_this ()))
			{                                                             
				m_Server.RemoveSession (GetConnID ());
				// update endpoint in profile because we know it now 
				auto identity = GetRemoteIdentity ();
				if (identity)
				{	
					auto profile = i2p::data::GetRouterProfile (identity->GetIdentHash ());
					if (profile) profile->SetLastEndpoint (m_RemoteEndpoint);
				}	
				// connect
				LogPrint (eLogDebug, "SSU2: Connecting after introduction to ", GetIdentHashBase64());
				Connect ();
			}
			else 
			{
				LogPrint (eLogError, "SSU2: Session ", GetConnID (), " is already pending");
				m_Server.RequestRemoveSession (GetConnID ());
			}	
		}
	}

	void SSU2Session::SendPeerTest ()
	{
		// we are Alice
		uint32_t nonce;
		RAND_bytes ((uint8_t *)&nonce, 4);
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		// session for message 5
		auto session = std::make_shared<SSU2PeerTestSession> (m_Server, 
			htobe64 (((uint64_t)nonce << 32) | nonce), 0);
		m_Server.AddRequestedPeerTest (nonce, session, ts/1000);
		m_Server.AddSession (session);
		// peer test block
		auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
		packet->payloadSize = CreatePeerTestBlock (packet->payload, m_MaxPayloadSize, nonce);
		if (packet->payloadSize > 0)
		{
			packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
			uint32_t packetNum = SendData (packet->payload, packet->payloadSize, SSU2_FLAG_IMMEDIATE_ACK_REQUESTED);
			packet->sendTime = ts;
			m_SentPackets.emplace (packetNum, packet);
			LogPrint (eLogDebug, "SSU2: PeerTest msg=1 sent to ", i2p::data::GetIdentHashAbbreviation (GetRemoteIdentity ()->GetIdentHash ()));
		}
	}

	void SSU2Session::SendKeepAlive ()
	{
		if (IsEstablished ())
		{
			uint8_t payload[20];
			size_t payloadSize = CreatePaddingBlock (payload, 20, 8);
			SendData (payload, payloadSize, SSU2_FLAG_IMMEDIATE_ACK_REQUESTED);
		}
	}

	void SSU2Session::Terminate ()
	{
		if (m_State != eSSU2SessionStateTerminated)
		{
			m_State = eSSU2SessionStateTerminated;
			m_ConnectTimer.cancel ();
			m_OnEstablished = nullptr;
			if (m_RelayTag)
				m_Server.RemoveRelay (m_RelayTag);
			m_Server.AddConnectedRecently (m_RemoteEndpoint, GetLastActivityTimestamp ());
			m_SentHandshakePacket.reset (nullptr);
			m_SessionConfirmedFragment.reset (nullptr);
			m_PathChallenge.reset (nullptr);
			if (!m_IntermediateQueue.empty ())
				m_SendQueue.splice (m_SendQueue.end (), m_IntermediateQueue);
			for (auto& it: m_SendQueue)
				it->Drop ();
			m_SendQueue.clear ();
			SetSendQueueSize (0);
			m_SentPackets.clear ();
			m_IncompleteMessages.clear ();
			m_RelaySessions.clear ();
			m_ReceivedI2NPMsgIDs.clear ();
			m_Server.RemoveSession (m_SourceConnID);
			transports.PeerDisconnected (shared_from_this ());
			auto remoteIdentity = GetRemoteIdentity ();
			if (remoteIdentity)
				LogPrint (eLogDebug, "SSU2: Session with ", GetRemoteEndpoint (),
					" (", i2p::data::GetIdentHashAbbreviation (remoteIdentity->GetIdentHash ()), ") terminated");
			else
				LogPrint (eLogDebug, "SSU2: Session with ", GetRemoteEndpoint (), " terminated");
		}
	}

	void SSU2Session::RequestTermination (SSU2TerminationReason reason)
	{
		if (m_State == eSSU2SessionStateEstablished || m_State == eSSU2SessionStateClosing)
		{
			m_TerminationReason = reason;
			SendTermination ();
			m_State = eSSU2SessionStateClosing;
		}
		else
			Done ();
	}

	void SSU2Session::Established ()
	{
		m_State = eSSU2SessionStateEstablished;
		m_EphemeralKeys = nullptr;
		m_NoiseState.reset (nullptr);
		m_SessionConfirmedFragment.reset (nullptr);
		m_SentHandshakePacket.reset (nullptr);
		m_ConnectTimer.cancel ();
		SetTerminationTimeout (SSU2_TERMINATION_TIMEOUT);
		SendQueue ();
		transports.PeerConnected (shared_from_this ());
		
		LogPrint(eLogDebug, "SSU2: Session with ", GetRemoteEndpoint (),
			" (", i2p::data::GetIdentHashAbbreviation (GetRemoteIdentity ()->GetIdentHash ()), ") established");
		if (m_OnEstablished)
		{
			m_OnEstablished ();
			m_OnEstablished = nullptr;
		}
	}

	void SSU2Session::Done ()
	{
		boost::asio::post (m_Server.GetService (), std::bind (&SSU2Session::Terminate, shared_from_this ()));
	}

	void SSU2Session::SendLocalRouterInfo (bool update)
	{
		if (update || !IsOutgoing ())
		{
			auto s = shared_from_this ();
			boost::asio::post (m_Server.GetService (), [s]()
				{
					if (!s->IsEstablished ()) return;
					uint8_t payload[SSU2_MAX_PACKET_SIZE];
					size_t payloadSize = s->CreateRouterInfoBlock (payload, s->m_MaxPayloadSize - 32, i2p::context.CopyRouterInfoBuffer ());
					if (payloadSize)
					{
						if (payloadSize < s->m_MaxPayloadSize)
							payloadSize += s->CreatePaddingBlock (payload + payloadSize, s->m_MaxPayloadSize - payloadSize);
						s->SendData (payload, payloadSize);
					}
					else
						s->SendFragmentedMessage (CreateDatabaseStoreMsg ());
				});
		}

	}

	void SSU2Session::SendI2NPMessages (std::list<std::shared_ptr<I2NPMessage> >& msgs)
	{
		if (m_State == eSSU2SessionStateTerminated || msgs.empty ()) 
		{
			msgs.clear ();
			return;
		}	
		bool empty = false;
		{
			std::lock_guard<std::mutex> l(m_IntermediateQueueMutex);
			empty = m_IntermediateQueue.empty ();
			m_IntermediateQueue.splice (m_IntermediateQueue.end (), msgs);
		}
		if (empty)
			boost::asio::post (m_Server.GetService (), std::bind (&SSU2Session::PostI2NPMessages, shared_from_this ()));
	}

	void SSU2Session::PostI2NPMessages ()
	{
		if (m_State == eSSU2SessionStateTerminated) return;
		std::list<std::shared_ptr<I2NPMessage> > msgs;
		{
			std::lock_guard<std::mutex> l(m_IntermediateQueueMutex);
			m_IntermediateQueue.swap (msgs);		
		}	
		uint64_t mts = i2p::util::GetMonotonicMicroseconds ();
		bool isSemiFull = false;
		if (m_SendQueue.size ())
		{
			int64_t queueLag = (int64_t)mts - (int64_t)m_SendQueue.front ()->GetEnqueueTime ();
			isSemiFull = queueLag > m_MsgLocalSemiExpirationTimeout;
			if (isSemiFull)
			{
				LogPrint (eLogWarning, "SSU2: Outgoing messages queue to ",
					i2p::data::GetIdentHashAbbreviation (GetRemoteIdentity ()->GetIdentHash ()),
					" is semi-full (size = ", m_SendQueue.size (), ", lag = ", queueLag / 1000, ", rtt = ", (int)m_RTT, ")");
			}
		}
		if (isSemiFull)
		{	
			for (auto it: msgs)
			{
				if (it->onDrop)
					it->Drop (); // drop earlier because we can handle it
				else
				{
					it->SetEnqueueTime (mts);
					m_SendQueue.push_back (std::move (it));
				}
			}
		}	
		else
		{
			for (auto& it: msgs) it->SetEnqueueTime (mts);
			m_SendQueue.splice (m_SendQueue.end (), msgs);
		}	
		if (IsEstablished ())
		{	
			SendQueue ();
			if (m_SendQueue.size () > 0) // windows is full
				Resend (i2p::util::GetMillisecondsSinceEpoch ());
		}	
		SetSendQueueSize (m_SendQueue.size ());
	}

	void SSU2Session::MoveSendQueue (std::shared_ptr<SSU2Session> other)
	{
		if (!other || m_SendQueue.empty ()) return;
		std::list<std::shared_ptr<I2NPMessage> > msgs;
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		for (auto it: m_SendQueue)
			if (!it->IsExpired (ts))
				msgs.push_back (it);
			else
				it->Drop ();
		m_SendQueue.clear ();
		if (!msgs.empty ())
			other->SendI2NPMessages (msgs);
	}	
		
	bool SSU2Session::SendQueue ()
	{
		if (!m_SendQueue.empty () && m_SentPackets.size () <= m_WindowSize && IsEstablished ())
		{
			auto ts = i2p::util::GetMillisecondsSinceEpoch ();
			uint64_t mts = i2p::util::GetMonotonicMicroseconds ();
			auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
			size_t ackBlockSize = CreateAckBlock (packet->payload, m_MaxPayloadSize);
			bool ackBlockSent = false;
			packet->payloadSize += ackBlockSize;
			while (!m_SendQueue.empty () && m_SentPackets.size () <= m_WindowSize)
			{
				auto msg = m_SendQueue.front ();
				if (!msg || msg->IsExpired (ts) || msg->GetEnqueueTime() + I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_TRANSIT < mts)
				{
					// drop null or expired message
					if (msg) msg->Drop ();
					m_SendQueue.pop_front ();
					continue;
				}
				size_t len = msg->GetNTCP2Length () + 3;
				if (len > m_MaxPayloadSize) // message too long
				{
					m_SendQueue.pop_front ();
					if (SendFragmentedMessage (msg))
						ackBlockSent = true;
				}
				else if (packet->payloadSize + len <= m_MaxPayloadSize)
				{
					m_SendQueue.pop_front ();
					packet->payloadSize += CreateI2NPBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize, std::move (msg));
				}
				else
				{
					// create new packet and copy ack block
					auto newPacket = m_Server.GetSentPacketsPool ().AcquireShared ();
					memcpy (newPacket->payload, packet->payload, ackBlockSize);
					newPacket->payloadSize = ackBlockSize;
					// complete current packet
					if (packet->payloadSize > ackBlockSize) // more than just ack block
					{
						ackBlockSent = true;
						// try to add padding
						if (packet->payloadSize + 16 < m_MaxPayloadSize)
							packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
					}
					else
					{
						// reduce ack block
						if (len + 8 < m_MaxPayloadSize)
						{
							// keep Ack block and drop some ranges
							ackBlockSent = true;
							packet->payloadSize = m_MaxPayloadSize - len;
							if (packet->payloadSize & 0x01) packet->payloadSize--; // make it even
							htobe16buf (packet->payload + 1, packet->payloadSize - 3); // new block size
						}
						else // drop Ack block completely
							packet->payloadSize = 0;
						// msg fits single packet
						m_SendQueue.pop_front ();
						packet->payloadSize += CreateI2NPBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize, std::move (msg));
					}
					// send right a way
					uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
					packet->sendTime = ts;
					m_SentPackets.emplace (packetNum, packet);
					packet = newPacket; // just ack block
				}
			};
			if (packet->payloadSize > ackBlockSize)
			{
				// last
				ackBlockSent = true;
				if (packet->payloadSize + 16 < m_MaxPayloadSize)
					packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
				uint32_t packetNum = SendData (packet->payload, packet->payloadSize, SSU2_FLAG_IMMEDIATE_ACK_REQUESTED);
				packet->sendTime = ts;
				m_SentPackets.emplace (packetNum, packet);
			}
			return ackBlockSent;
		}
		return false;
	}

	bool SSU2Session::SendFragmentedMessage (std::shared_ptr<I2NPMessage> msg)
	{
		if (!msg) return false;
		size_t lastFragmentSize = (msg->GetNTCP2Length () + 3 - m_MaxPayloadSize) % (m_MaxPayloadSize - 8);
		size_t extraSize = m_MaxPayloadSize - lastFragmentSize;
		bool ackBlockSent = false;
		uint32_t msgID;
		memcpy (&msgID, msg->GetHeader () + I2NP_HEADER_MSGID_OFFSET, 4);
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
		if (extraSize >= 8)
		{
			packet->payloadSize = CreateAckBlock (packet->payload, extraSize);
			ackBlockSent = true;
			if (packet->payloadSize + 12 < m_MaxPayloadSize)
			{
				uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
				packet->sendTime = ts;
				m_SentPackets.emplace (packetNum, packet);
				packet = m_Server.GetSentPacketsPool ().AcquireShared ();
			}
			else
				extraSize -= packet->payloadSize;
		}
		size_t offset = extraSize > 0 ? (m_Server.GetRng ()() % extraSize) : 0;
		if (offset + packet->payloadSize >= m_MaxPayloadSize) offset = 0;
		auto size = CreateFirstFragmentBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - offset - packet->payloadSize, msg);
		if (!size) return false;
		extraSize -= offset;
		packet->payloadSize += size;
		uint32_t firstPacketNum = SendData (packet->payload, packet->payloadSize);
		packet->sendTime = ts;
		m_SentPackets.emplace (firstPacketNum, packet);
		uint8_t fragmentNum = 0;
		while (msg->offset < msg->len)
		{
			offset = extraSize > 0 ? (m_Server.GetRng ()() % extraSize) : 0;
			packet = m_Server.GetSentPacketsPool ().AcquireShared ();
			packet->payloadSize = CreateFollowOnFragmentBlock (packet->payload, m_MaxPayloadSize - offset, msg, fragmentNum, msgID);
			extraSize -= offset;
			uint8_t flags = 0;
			if (msg->offset >= msg->len && packet->payloadSize + 16 < m_MaxPayloadSize) // last fragment
			{
				packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
				if (fragmentNum > 2) // 3 or more fragments
					flags |= SSU2_FLAG_IMMEDIATE_ACK_REQUESTED;
			}
			uint32_t followonPacketNum = SendData (packet->payload, packet->payloadSize, flags);
			packet->sendTime = ts;
			m_SentPackets.emplace (followonPacketNum, packet);
		}
		return ackBlockSent;
	}

	size_t SSU2Session::Resend (uint64_t ts)
	{
		if (ts + SSU2_RESEND_ATTEMPT_MIN_INTERVAL < m_LastResendAttemptTime) return 0;
		m_LastResendAttemptTime = ts;
		// resend handshake packet
		if (m_SentHandshakePacket && ts >= m_SentHandshakePacket->sendTime + SSU2_HANDSHAKE_RESEND_INTERVAL)
		{
			LogPrint (eLogDebug, "SSU2: Resending ", (int)m_State);
			ResendHandshakePacket ();
			m_SentHandshakePacket->sendTime = ts;
			return 0;
		}
		// resend data packets
		if (m_SentPackets.empty ()) return 0;
		std::map<uint32_t, std::shared_ptr<SSU2SentPacket> > resentPackets;
		for (auto it = m_SentPackets.begin (); it != m_SentPackets.end (); )
			if (ts >= it->second->sendTime + (it->second->numResends + 1) * m_RTO)
			{
				if (it->second->numResends > SSU2_MAX_NUM_RESENDS)
				{
					LogPrint (eLogInfo, "SSU2: Packet was not Acked after ", it->second->numResends, " attempts. Terminate session");
					m_SentPackets.clear ();
					m_SendQueue.clear ();
					SetSendQueueSize (0);
					RequestTermination (eSSU2TerminationReasonTimeout);
					return resentPackets.size ();
				}
				else
				{
					uint32_t packetNum = SendData (it->second->payload, it->second->payloadSize, 
						it->second->numResends > 1 ? SSU2_FLAG_IMMEDIATE_ACK_REQUESTED : 0);
					it->second->numResends++;
					it->second->sendTime = ts;
					resentPackets.emplace (packetNum, it->second);
					it = m_SentPackets.erase (it);
				}
			}
			else
				it++;
		if (!resentPackets.empty ())
		{
			m_LastResendTime = ts;
			m_SentPackets.merge (resentPackets);
			m_WindowSize >>= 1; // /2
			if (m_WindowSize < SSU2_MIN_WINDOW_SIZE) m_WindowSize = SSU2_MIN_WINDOW_SIZE;
			return resentPackets.size ();
		}
		return 0;
	}

	void SSU2Session::ResendHandshakePacket ()
	{
		if (m_SentHandshakePacket)
		{
			m_Server.Send (m_SentHandshakePacket->header.buf, 16, m_SentHandshakePacket->headerX, 48,
				m_SentHandshakePacket->payload, m_SentHandshakePacket->payloadSize, m_RemoteEndpoint);
			if (m_SessionConfirmedFragment && m_State == eSSU2SessionStateSessionConfirmedSent)
				// resend second fragment of SessionConfirmed
				m_Server.Send (m_SessionConfirmedFragment->header.buf, 16,
					m_SessionConfirmedFragment->payload, m_SessionConfirmedFragment->payloadSize, m_RemoteEndpoint);
		}
	}

	bool SSU2Session::ProcessFirstIncomingMessage (uint64_t connID, uint8_t * buf, size_t len)
	{
		// we are Bob
		m_SourceConnID = connID;
		Header header;
		header.h.connID = connID;
		memcpy (header.buf + 8, buf + 8, 8);
		header.ll[1] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), buf + (len - 12));
		switch (header.h.type)
		{
			case eSSU2SessionRequest:
				ProcessSessionRequest (header, buf, len);
			break;
			case eSSU2TokenRequest:
				ProcessTokenRequest (header, buf, len);
			break;
			case eSSU2PeerTest:
			{
				// TODO: remove later
				if (len < 32)
				{
					LogPrint (eLogWarning, "SSU2: PeerTest message too short ", len);
					break;
				}
				const uint8_t nonce[12] = {0};
				uint64_t headerX[2];
				m_Server.ChaCha20 (buf + 16, 16, i2p::context.GetSSU2IntroKey (), nonce, (uint8_t *)headerX);
				LogPrint (eLogWarning, "SSU2: Unexpected PeerTest message SourceConnID=", connID, " DestConnID=", headerX[0]);
				break;
			}
			case eSSU2HolePunch:
				LogPrint (eLogDebug, "SSU2: Late HolePunch for ", connID);
			break;
			default:
			{
				LogPrint (eLogWarning, "SSU2: Unexpected message type ", (int)header.h.type, " from ", m_RemoteEndpoint, " of ", len, " bytes");
				return false;
			}
		}
		return true;
	}

	void SSU2Session::SendSessionRequest (uint64_t token)
	{
		// we are Alice
		m_EphemeralKeys = i2p::transport::transports.GetNextX25519KeysPair ();
		m_SentHandshakePacket.reset (new HandshakePacket);
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		m_SentHandshakePacket->sendTime = ts;

		Header& header = m_SentHandshakePacket->header;
		uint8_t * headerX = m_SentHandshakePacket->headerX,
				* payload = m_SentHandshakePacket->payload;
		// fill packet
		header.h.connID = m_DestConnID; // dest id
		RAND_bytes (header.buf + 8, 4); // random packet num
		header.h.type = eSSU2SessionRequest;
		header.h.flags[0] = 2; // ver
		header.h.flags[1] = (uint8_t)i2p::context.GetNetID (); // netID
		header.h.flags[2] = 0; // flag
		memcpy (headerX, &m_SourceConnID, 8); // source id
		memcpy (headerX + 8, &token, 8); // token
		memcpy (headerX + 16, m_EphemeralKeys->GetPublicKey (), 32); // X
		// payload
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (ts + 500)/1000);
		size_t payloadSize = 7;
		if (GetRouterStatus () == eRouterStatusFirewalled && m_Address->IsIntroducer ())
		{
			if (!m_Server.IsMaxNumIntroducers (m_RemoteEndpoint.address ().is_v4 ()) ||
			    m_Server.GetRng ()() & 0x01) // request tag with probability 1/2 if we have enough introducers
			{	
				// relay tag request
				payload[payloadSize] = eSSU2BlkRelayTagRequest;
				memset (payload + payloadSize + 1, 0, 2); // size = 0
				payloadSize += 3;
			}	
		}
		payloadSize += CreatePaddingBlock (payload + payloadSize, 40 - payloadSize, 1);
		// KDF for session request
		m_NoiseState->MixHash ({ {header.buf, 16}, {headerX, 16} }); // h = SHA256(h || header)
		m_NoiseState->MixHash (m_EphemeralKeys->GetPublicKey (), 32); // h = SHA256(h || aepk);
		uint8_t sharedSecret[32];
		m_EphemeralKeys->Agree (m_Address->s, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		// encrypt
		const uint8_t nonce[12] = {0}; // always 0
		i2p::crypto::AEADChaCha20Poly1305 (payload, payloadSize, m_NoiseState->m_H, 32, m_NoiseState->m_CK + 32, nonce, payload, payloadSize + 16, true);
		payloadSize += 16;
		header.ll[0] ^= CreateHeaderMask (m_Address->i, payload + (payloadSize - 24));
		header.ll[1] ^= CreateHeaderMask (m_Address->i, payload + (payloadSize - 12));
		m_Server.ChaCha20 (headerX, 48, m_Address->i, nonce, headerX);
		m_NoiseState->MixHash (payload, payloadSize); // h = SHA256(h || encrypted payload from Session Request) for SessionCreated
		m_SentHandshakePacket->payloadSize = payloadSize;
		// send
		if (m_State == eSSU2SessionStateTokenReceived || m_Server.AddPendingOutgoingSession (shared_from_this ()))
		{
			m_State = eSSU2SessionStateSessionRequestSent;
			m_HandshakeInterval = ts;
			m_Server.Send (header.buf, 16, headerX, 48, payload, payloadSize, m_RemoteEndpoint);
		}
		else
		{
			LogPrint (eLogWarning, "SSU2: SessionRequest request to ", m_RemoteEndpoint, " already pending");
			Terminate ();
		}
	}

	void SSU2Session::ProcessSessionRequest (Header& header, uint8_t * buf, size_t len)
	{
		// we are Bob
		if (len < 88)
		{
			LogPrint (eLogWarning, "SSU2: SessionRequest message too short ", len);
			return;
		}
		const uint8_t nonce[12] = {0};
		uint8_t headerX[48];
		m_Server.ChaCha20 (buf + 16, 48, i2p::context.GetSSU2IntroKey (), nonce, headerX);
		memcpy (&m_DestConnID, headerX, 8);
		uint64_t token;
		memcpy (&token, headerX + 8, 8);
		if (!token || token != m_Server.GetIncomingToken (m_RemoteEndpoint))
		{
			LogPrint (eLogDebug, "SSU2: SessionRequest token mismatch. Retry");
			SendRetry ();
			return;
		}
		// KDF for session request
		m_NoiseState->MixHash ( { {header.buf, 16}, {headerX, 16} } ); // h = SHA256(h || header)
		m_NoiseState->MixHash (headerX + 16, 32); // h = SHA256(h || aepk);
		uint8_t sharedSecret[32];
		i2p::context.GetSSU2StaticKeys ().Agree (headerX + 16, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		// decrypt
		uint8_t * payload = buf + 64;
		std::vector<uint8_t> decryptedPayload(len - 80);
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 80, m_NoiseState->m_H, 32,
			m_NoiseState->m_CK + 32, nonce, decryptedPayload.data (), decryptedPayload.size (), false))
		{
			LogPrint (eLogWarning, "SSU2: SessionRequest AEAD verification failed ");
			return;
		}
		m_NoiseState->MixHash (payload, len - 64); // h = SHA256(h || encrypted payload from Session Request) for SessionCreated
		// payload
		m_State = eSSU2SessionStateSessionRequestReceived;
		HandlePayload (decryptedPayload.data (), decryptedPayload.size ());

		if (m_TerminationReason == eSSU2TerminationReasonNormalClose)
		{
			m_Server.AddSession (shared_from_this ());
			SendSessionCreated (headerX + 16);
		}
		else
			SendRetry ();
	}

	void SSU2Session::SendSessionCreated (const uint8_t * X)
	{
		// we are Bob
		m_EphemeralKeys = i2p::transport::transports.GetNextX25519KeysPair ();
		m_SentHandshakePacket.reset (new HandshakePacket);
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		m_SentHandshakePacket->sendTime = ts;

		uint8_t kh2[32];
		i2p::crypto::HKDF (m_NoiseState->m_CK, nullptr, 0, "SessCreateHeader", kh2, 32); // k_header_2 = HKDF(chainKey, ZEROLEN, "SessCreateHeader", 32)
		// fill packet
		Header& header = m_SentHandshakePacket->header;
		uint8_t * headerX = m_SentHandshakePacket->headerX,
				* payload = m_SentHandshakePacket->payload;
		header.h.connID = m_DestConnID; // dest id
		RAND_bytes (header.buf + 8, 4); // random packet num
		header.h.type = eSSU2SessionCreated;
		header.h.flags[0] = 2; // ver
		header.h.flags[1] = (uint8_t)i2p::context.GetNetID (); // netID
		header.h.flags[2] = 0; // flag
		memcpy (headerX, &m_SourceConnID, 8); // source id
		memset (headerX + 8, 0, 8); // token = 0
		memcpy (headerX + 16, m_EphemeralKeys->GetPublicKey (), 32); // Y
		// payload
		size_t maxPayloadSize = m_MaxPayloadSize - 48;
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (ts + 500)/1000);
		size_t payloadSize = 7;
		payloadSize += CreateAddressBlock (payload + payloadSize, maxPayloadSize - payloadSize, m_RemoteEndpoint);
		if (m_RelayTag)
		{
			payload[payloadSize] = eSSU2BlkRelayTag;
			htobe16buf (payload + payloadSize + 1, 4);
			htobe32buf (payload + payloadSize + 3, m_RelayTag);
			payloadSize += 7;
		}
		auto token = m_Server.NewIncomingToken (m_RemoteEndpoint);
		if (ts + SSU2_TOKEN_EXPIRATION_THRESHOLD > token.second) // not expired?
		{
			payload[payloadSize] = eSSU2BlkNewToken;
			htobe16buf (payload + payloadSize + 1, 12);
			htobe32buf (payload + payloadSize + 3, token.second - SSU2_TOKEN_EXPIRATION_THRESHOLD); // expires
			memcpy (payload + payloadSize + 7, &token.first, 8); // token
			payloadSize += 15;
		}
		payloadSize += CreatePaddingBlock (payload + payloadSize, maxPayloadSize - payloadSize);
		// KDF for SessionCreated
		m_NoiseState->MixHash ( { {header.buf, 16}, {headerX, 16} } ); // h = SHA256(h || header)
		m_NoiseState->MixHash (headerX + 16, 32); // h = SHA256(h || bepk);
		uint8_t sharedSecret[32];
		m_EphemeralKeys->Agree (X, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		// encrypt
		const uint8_t nonce[12] = {0}; // always zero
		i2p::crypto::AEADChaCha20Poly1305 (payload, payloadSize, m_NoiseState->m_H, 32, m_NoiseState->m_CK + 32, nonce, payload, payloadSize + 16, true);
		payloadSize += 16;
		m_NoiseState->MixHash (payload, payloadSize); // h = SHA256(h || encrypted Noise payload from Session Created)
		header.ll[0] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), payload + (payloadSize - 24));
		header.ll[1] ^= CreateHeaderMask (kh2, payload + (payloadSize - 12));
		m_Server.ChaCha20 (headerX, 48, kh2, nonce, headerX);
		m_State = eSSU2SessionStateSessionCreatedSent;
		m_SentHandshakePacket->payloadSize = payloadSize;
		// send
		m_HandshakeInterval = ts;
		m_Server.Send (header.buf, 16, headerX, 48, payload, payloadSize, m_RemoteEndpoint);
	}

	bool SSU2Session::ProcessSessionCreated (uint8_t * buf, size_t len)
	{
		// we are Alice
		Header header;
		memcpy (header.buf, buf, 16);
		header.ll[0] ^= CreateHeaderMask (m_Address->i, buf + (len - 24));
		uint8_t kh2[32];
		i2p::crypto::HKDF (m_NoiseState->m_CK, nullptr, 0, "SessCreateHeader", kh2, 32); // k_header_2 = HKDF(chainKey, ZEROLEN, "SessCreateHeader", 32)
		header.ll[1] ^= CreateHeaderMask (kh2, buf + (len - 12));
		if (header.h.type != eSSU2SessionCreated)
		// this situation is valid, because it might be Retry with different encryption
			return false;
		if (len < 80)
		{
			LogPrint (eLogWarning, "SSU2: SessionCreated message too short ", len);
			return false;
		}
		m_HandshakeInterval = i2p::util::GetMillisecondsSinceEpoch () - m_HandshakeInterval;
		const uint8_t nonce[12] = {0};
		uint8_t headerX[48];
		m_Server.ChaCha20 (buf + 16, 48, kh2, nonce, headerX);
		// KDF for SessionCreated
		m_NoiseState->MixHash ( { {header.buf, 16}, {headerX, 16} } ); // h = SHA256(h || header)
		m_NoiseState->MixHash (headerX + 16, 32); // h = SHA256(h || bepk);
		uint8_t sharedSecret[32];
		m_EphemeralKeys->Agree (headerX + 16, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		// decrypt
		uint8_t * payload = buf + 64;
		std::vector<uint8_t> decryptedPayload(len - 80);
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 80, m_NoiseState->m_H, 32,
			m_NoiseState->m_CK + 32, nonce, decryptedPayload.data (), decryptedPayload.size (), false))
		{
			LogPrint (eLogWarning, "SSU2: SessionCreated AEAD verification failed ");
			if (GetRemoteIdentity ())
				i2p::data::netdb.SetUnreachable (GetRemoteIdentity ()->GetIdentHash (), true);  // assume wrong s key
			return false;
		}
		m_NoiseState->MixHash (payload, len - 64); // h = SHA256(h || encrypted payload from SessionCreated) for SessionConfirmed
		// payload
		m_State = eSSU2SessionStateSessionCreatedReceived;
		HandlePayload (decryptedPayload.data (), decryptedPayload.size ());

		m_Server.AddSession (shared_from_this ());
		AdjustMaxPayloadSize ();
		SendSessionConfirmed (headerX + 16);
		KDFDataPhase (m_KeyDataSend, m_KeyDataReceive);

		return true;
	}

	void SSU2Session::SendSessionConfirmed (const uint8_t * Y)
	{
		// we are Alice
		m_SentHandshakePacket.reset (new HandshakePacket);
		m_SentHandshakePacket->sendTime = i2p::util::GetMillisecondsSinceEpoch ();

		uint8_t kh2[32];
		i2p::crypto::HKDF (m_NoiseState->m_CK, nullptr, 0, "SessionConfirmed", kh2, 32); // k_header_2 = HKDF(chainKey, ZEROLEN, "SessionConfirmed", 32)
		// fill packet
		Header& header = m_SentHandshakePacket->header;
		header.h.connID = m_DestConnID; // dest id
		header.h.packetNum = 0; // always zero
		header.h.type = eSSU2SessionConfirmed;
		memset (header.h.flags, 0, 3);
		header.h.flags[0] = 1; // frag, total fragments always 1
		// payload
		size_t maxPayloadSize = m_MaxPayloadSize - 48; // for part 2, 48 is part1
		uint8_t * payload = m_SentHandshakePacket->payload;
		size_t payloadSize = CreateRouterInfoBlock (payload, maxPayloadSize, i2p::context.CopyRouterInfoBuffer ());
		if (!payloadSize)
		{
			// split by two fragments
			maxPayloadSize += m_MaxPayloadSize;
			payloadSize = CreateRouterInfoBlock (payload, maxPayloadSize, i2p::context.CopyRouterInfoBuffer ());
			header.h.flags[0] = 0x02; // frag 0, total fragments 2
			// TODO: check if we need more fragments
		}
		if (payloadSize < maxPayloadSize)
			payloadSize += CreatePaddingBlock (payload + payloadSize, maxPayloadSize - payloadSize);
		// KDF for Session Confirmed part 1
		m_NoiseState->MixHash (header.buf, 16); // h = SHA256(h || header)
		// Encrypt part 1
		uint8_t * part1 = m_SentHandshakePacket->headerX;
		uint8_t nonce[12];
		CreateNonce (1, nonce); // always one
		i2p::crypto::AEADChaCha20Poly1305 (i2p::context.GetSSU2StaticPublicKey (), 32, m_NoiseState->m_H, 32, m_NoiseState->m_CK + 32, nonce, part1, 48, true);
		m_NoiseState->MixHash (part1, 48); // h = SHA256(h || ciphertext);
		// KDF for Session Confirmed part 2
		uint8_t sharedSecret[32];
		i2p::context.GetSSU2StaticKeys ().Agree (Y, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		// Encrypt part2
		memset (nonce, 0, 12); // always zero
		i2p::crypto::AEADChaCha20Poly1305 (payload, payloadSize, m_NoiseState->m_H, 32, m_NoiseState->m_CK + 32, nonce, payload, payloadSize + 16, true);
		payloadSize += 16;
		m_NoiseState->MixHash (payload, payloadSize); // h = SHA256(h || ciphertext);
		m_SentHandshakePacket->payloadSize = payloadSize;
		if (header.h.flags[0] > 1)
		{
			if (payloadSize > m_MaxPayloadSize - 48)
			{
				payloadSize = m_MaxPayloadSize - 48 - (m_Server.GetRng ()() % 16);
				if (m_SentHandshakePacket->payloadSize - payloadSize < 24)
					payloadSize -= 24;
			}
			else
				header.h.flags[0] = 1;
		}
		// Encrypt header
		header.ll[0] ^= CreateHeaderMask (m_Address->i, payload + (payloadSize - 24));
		header.ll[1] ^= CreateHeaderMask (kh2, payload + (payloadSize - 12));
		m_State = eSSU2SessionStateSessionConfirmedSent;
		// send
		m_Server.Send (header.buf, 16, part1, 48, payload, payloadSize, m_RemoteEndpoint);
		m_SendPacketNum++;
		if (m_SentHandshakePacket->payloadSize > payloadSize)
		{
			// send second fragment
			m_SessionConfirmedFragment.reset (new HandshakePacket);
			Header& header = m_SessionConfirmedFragment->header;
			header.h.connID = m_DestConnID; // dest id
			header.h.packetNum = 0;
			header.h.type = eSSU2SessionConfirmed;
			memset (header.h.flags, 0, 3);
			header.h.flags[0] = 0x12; // frag 1, total fragments 2
			m_SessionConfirmedFragment->payloadSize = m_SentHandshakePacket->payloadSize - payloadSize;
			memcpy (m_SessionConfirmedFragment->payload, m_SentHandshakePacket->payload + payloadSize, m_SessionConfirmedFragment->payloadSize);
			m_SentHandshakePacket->payloadSize = payloadSize;
			header.ll[0] ^= CreateHeaderMask (m_Address->i, m_SessionConfirmedFragment->payload + (m_SessionConfirmedFragment->payloadSize - 24));
			header.ll[1] ^= CreateHeaderMask (kh2, m_SessionConfirmedFragment->payload + (m_SessionConfirmedFragment->payloadSize - 12));
			m_Server.Send (header.buf, 16, m_SessionConfirmedFragment->payload, m_SessionConfirmedFragment->payloadSize, m_RemoteEndpoint);
		}
	}

	bool SSU2Session::ProcessSessionConfirmed (uint8_t * buf, size_t len)
	{
		// we are Bob
		Header header;
		memcpy (header.buf, buf, 16);
		header.ll[0] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), buf + (len - 24));
		uint8_t kh2[32];
		i2p::crypto::HKDF (m_NoiseState->m_CK, nullptr, 0, "SessionConfirmed", kh2, 32); // k_header_2 = HKDF(chainKey, ZEROLEN, "SessionConfirmed", 32)
		header.ll[1] ^= CreateHeaderMask (kh2, buf + (len - 12));
		if (header.h.type != eSSU2SessionConfirmed)
		{
			LogPrint (eLogInfo, "SSU2: Unexpected message type ", (int)header.h.type, " instead ", (int)eSSU2SessionConfirmed);
			// TODO: queue up
			return true;
		}
		// packet num must be always zero
		if (header.h.packetNum)
		{
			LogPrint (eLogError, "SSU2: Non zero packet number in SessionConfirmed");
			return false;
		}
		// check if fragmented
		uint8_t numFragments = header.h.flags[0] & 0x0F;
		if (numFragments > 1)
		{
			// fragmented
			if (numFragments > 2)
			{
				LogPrint (eLogError, "SSU2: Too many fragments ", (int)numFragments, " in SessionConfirmed from ", m_RemoteEndpoint);
				return false;
			}
			if (len < 32)
			{
				LogPrint (eLogWarning, "SSU2: SessionConfirmed fragment too short ", len);
				if (m_SessionConfirmedFragment) m_SessionConfirmedFragment.reset (nullptr);
				return false;
			}
			if (!(header.h.flags[0] & 0xF0))
			{
				// first fragment
				if (!m_SessionConfirmedFragment)
				{
					m_SessionConfirmedFragment.reset (new HandshakePacket);
					m_SessionConfirmedFragment->header = header;
					memcpy (m_SessionConfirmedFragment->payload, buf + 16, len - 16);
					m_SessionConfirmedFragment->payloadSize = len - 16;
					return true; // wait for second fragment
				}
				else if (m_SessionConfirmedFragment->isSecondFragment)
				{
					// we have second fragment
					m_SessionConfirmedFragment->header = header;
					memmove (m_SessionConfirmedFragment->payload + (len - 16), m_SessionConfirmedFragment->payload, m_SessionConfirmedFragment->payloadSize);
					memcpy (m_SessionConfirmedFragment->payload, buf + 16, len - 16);
					m_SessionConfirmedFragment->payloadSize += (len - 16);
					m_SessionConfirmedFragment->isSecondFragment = false;
					buf = m_SessionConfirmedFragment->payload - 16;
					len = m_SessionConfirmedFragment->payloadSize + 16;
				}
				else
					return true;
			}
			else
			{
				// second fragment
				if (!m_SessionConfirmedFragment)
				{
					// out of sequence, save it
					m_SessionConfirmedFragment.reset (new HandshakePacket);
					memcpy (m_SessionConfirmedFragment->payload, buf + 16, len - 16);
					m_SessionConfirmedFragment->payloadSize = len - 16;
					m_SessionConfirmedFragment->isSecondFragment = true;
					return true;
				}
				header = m_SessionConfirmedFragment->header;
				if (m_SessionConfirmedFragment->payloadSize + (len - 16) <= SSU2_MAX_PACKET_SIZE*2)
				{
					memcpy (m_SessionConfirmedFragment->payload + m_SessionConfirmedFragment->payloadSize, buf + 16, len - 16);
					m_SessionConfirmedFragment->payloadSize += (len - 16);
				}
				buf = m_SessionConfirmedFragment->payload - 16;
				len = m_SessionConfirmedFragment->payloadSize + 16;
			}
		}
		if (len < 80)
		{
			LogPrint (eLogWarning, "SSU2: SessionConfirmed message too short ", len);
			if (m_SessionConfirmedFragment) m_SessionConfirmedFragment.reset (nullptr);
			return false;
		}
		m_HandshakeInterval = i2p::util::GetMillisecondsSinceEpoch () - m_HandshakeInterval;
		// KDF for Session Confirmed part 1
		m_NoiseState->MixHash (header.buf, 16); // h = SHA256(h || header)
		// decrypt part1
		uint8_t nonce[12];
		CreateNonce (1, nonce);
		uint8_t S[32];
		if (!i2p::crypto::AEADChaCha20Poly1305 (buf + 16, 32, m_NoiseState->m_H, 32,
			m_NoiseState->m_CK + 32, nonce, S, 32, false))
		{
			LogPrint (eLogWarning, "SSU2: SessionConfirmed part 1 AEAD verification failed ");
			if (m_SessionConfirmedFragment) m_SessionConfirmedFragment.reset (nullptr);
			return false;
		}
		m_NoiseState->MixHash (buf + 16, 48); // h = SHA256(h || ciphertext);
		// KDF for Session Confirmed part 2 and data phase
		uint8_t sharedSecret[32];
		m_EphemeralKeys->Agree (S, sharedSecret);
		m_NoiseState->MixKey (sharedSecret);
		KDFDataPhase (m_KeyDataReceive, m_KeyDataSend);
		// decrypt part2
		memset (nonce, 0, 12);
		uint8_t * payload = buf + 64;
		std::vector<uint8_t> decryptedPayload(len - 80);
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 80, m_NoiseState->m_H, 32,
			m_NoiseState->m_CK + 32, nonce, decryptedPayload.data (), decryptedPayload.size (), false))
		{
			LogPrint (eLogWarning, "SSU2: SessionConfirmed part 2 AEAD verification failed ");
			if (m_SessionConfirmedFragment) m_SessionConfirmedFragment.reset (nullptr);
			return false;
		}
		m_NoiseState->MixHash (payload, len - 64); // h = SHA256(h || ciphertext);
		if (m_SessionConfirmedFragment) m_SessionConfirmedFragment.reset (nullptr);
		// payload
		// handle RouterInfo block that must be first
		if (decryptedPayload[0] != eSSU2BlkRouterInfo)
		{
			LogPrint (eLogError, "SSU2: SessionConfirmed unexpected first block type ", (int)decryptedPayload[0]);
			return false;
		}
		size_t riSize = bufbe16toh (decryptedPayload.data () + 1);
		if (riSize + 3 > decryptedPayload.size ())
		{
			LogPrint (eLogError, "SSU2: SessionConfirmed RouterInfo block is too long ", riSize);
			return false;
		}
		LogPrint (eLogDebug, "SSU2: RouterInfo in SessionConfirmed");
		auto ri = ExtractRouterInfo (decryptedPayload.data () + 3, riSize);
		if (!ri)
		{
			LogPrint (eLogError, "SSU2: SessionConfirmed malformed RouterInfo block");
			return false;
		}
		auto ts = i2p::util::GetMillisecondsSinceEpoch();
		if (ts > ri->GetTimestamp () + i2p::data::NETDB_MIN_EXPIRATION_TIMEOUT*1000LL) // 90 minutes
		{
			LogPrint (eLogError, "SSU2: RouterInfo in SessionConfirmed is too old for ", (ts - ri->GetTimestamp ())/1000LL, " seconds");
			return false;
		}	
		if (ts + i2p::data::NETDB_EXPIRATION_TIMEOUT_THRESHOLD*1000LL < ri->GetTimestamp ()) // 2 minutes
		{
			LogPrint (eLogError, "SSU2: RouterInfo in SessionConfirmed is from future for ", (ri->GetTimestamp () - ts)/1000LL, " seconds");
			return false;
		}	
		// update RouterInfo in netdb
		auto ri1 = i2p::data::netdb.AddRouterInfo (ri->GetBuffer (), ri->GetBufferLen ()); // ri points to one from netdb now
		if (!ri1)
		{
			LogPrint (eLogError, "SSU2: Couldn't update RouterInfo from SessionConfirmed in netdb");
			return false;
		}
		
		bool isOlder = false;
		if (ri->GetTimestamp () + i2p::data::NETDB_EXPIRATION_TIMEOUT_THRESHOLD*1000LL < ri1->GetTimestamp ())
		{	
			// received RouterInfo is older than one in netdb
			isOlder = true;
			if (ri->HasProfile ())
			{	
				auto profile = i2p::data::GetRouterProfile (ri->GetIdentHash ()); // retrieve profile	
				if (profile && profile->IsDuplicated ())
					return false;
			}	
		}	
		ri = ri1;
		
		m_Address = m_RemoteEndpoint.address ().is_v6 () ? ri->GetSSU2V6Address () : ri->GetSSU2V4Address ();
		if (!m_Address || memcmp (S, m_Address->s, 32))
		{
			LogPrint (eLogError, "SSU2: Wrong static key in SessionConfirmed from ", i2p::data::GetIdentHashAbbreviation (ri->GetIdentHash ()));
			return false;
		}
		if (m_Address->published && m_RemoteEndpoint.address () != m_Address->host &&
		    (!m_RemoteEndpoint.address ().is_v6 () ||
			 memcmp (m_RemoteEndpoint.address ().to_v6 ().to_bytes ().data (), m_Address->host.to_v6 ().to_bytes ().data (), 8))) // temporary address
		{
			if (isOlder) // older router?
				i2p::data::UpdateRouterProfile (ri->GetIdentHash (),
					[](std::shared_ptr<i2p::data::RouterProfile> profile)
					{
						if (profile) profile->Duplicated (); // mark router as duplicated in profile
					});
			else	
				LogPrint (eLogInfo, "SSU2: Host mismatch between published address ", m_Address->host,
					" and actual endpoint ", m_RemoteEndpoint.address (), " from ", i2p::data::GetIdentHashAbbreviation (ri->GetIdentHash ()));
			return false;
		}
		if (!m_Address->published)
		{	
			if (ri->HasProfile ())	
				ri->GetProfile ()->SetLastEndpoint (m_RemoteEndpoint);
			else
				i2p::data::UpdateRouterProfile (ri->GetIdentHash (), 
					[ep = m_RemoteEndpoint](std::shared_ptr<i2p::data::RouterProfile> profile)
				    {
						if (profile) profile->SetLastEndpoint (ep);
					});	
		}	
		SetRemoteIdentity (ri->GetRouterIdentity ());
		AdjustMaxPayloadSize ();
		m_Server.AddSessionByRouterHash (shared_from_this ()); // we know remote router now
		m_RemoteTransports = ri->GetCompatibleTransports (false);
		m_RemotePeerTestTransports = 0;
		if (ri->IsSSU2PeerTesting (true)) m_RemotePeerTestTransports |= i2p::data::RouterInfo::eSSU2V4;
		if (ri->IsSSU2PeerTesting (false)) m_RemotePeerTestTransports |= i2p::data::RouterInfo::eSSU2V6;
		m_RemoteVersion = ri->GetVersion ();
		
		// handle other blocks
		HandlePayload (decryptedPayload.data () + riSize + 3, decryptedPayload.size () - riSize - 3);
		Established ();

		SendQuickAck ();

		return true;
	}

	void SSU2Session::KDFDataPhase (uint8_t * keydata_ab, uint8_t * keydata_ba)
	{
		uint8_t keydata[64];
		i2p::crypto::HKDF (m_NoiseState->m_CK, nullptr, 0, "", keydata); // keydata = HKDF(chainKey, ZEROLEN, "", 64)
		// ab
		i2p::crypto::HKDF (keydata, nullptr, 0, "HKDFSSU2DataKeys", keydata_ab); // keydata_ab = HKDF(keydata, ZEROLEN, "HKDFSSU2DataKeys", 64)
		// ba
		i2p::crypto::HKDF (keydata + 32, nullptr, 0, "HKDFSSU2DataKeys", keydata_ba); // keydata_ba = HKDF(keydata + 32, ZEROLEN, "HKDFSSU2DataKeys", 64)
	}

	void SSU2Session::SendTokenRequest ()
	{
		// we are Alice
		Header header;
		uint8_t h[32], payload[41];
		// fill packet
		header.h.connID = m_DestConnID; // dest id
		RAND_bytes (header.buf + 8, 4); // random packet num
		header.h.type = eSSU2TokenRequest;
		header.h.flags[0] = 2; // ver
		header.h.flags[1] = (uint8_t)i2p::context.GetNetID (); // netID
		header.h.flags[2] = 0; // flag
		memcpy (h, header.buf, 16);
		memcpy (h + 16, &m_SourceConnID, 8); // source id
		memset (h + 24, 0, 8); // zero token
		// payload
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (i2p::util::GetMillisecondsSinceEpoch () + 500)/1000);
		size_t payloadSize = 7;
		payloadSize += CreatePaddingBlock (payload + payloadSize, 25 - payloadSize, 1);
		// encrypt
		uint8_t nonce[12];
		CreateNonce (be32toh (header.h.packetNum), nonce);
		i2p::crypto::AEADChaCha20Poly1305 (payload, payloadSize, h, 32, m_Address->i, nonce, payload, payloadSize + 16, true);
		payloadSize += 16;
		header.ll[0] ^= CreateHeaderMask (m_Address->i, payload + (payloadSize - 24));
		header.ll[1] ^= CreateHeaderMask (m_Address->i, payload + (payloadSize - 12));
		memset (nonce, 0, 12);
		m_Server.ChaCha20 (h + 16, 16, m_Address->i, nonce, h + 16);
		// send
		if (m_Server.AddPendingOutgoingSession (shared_from_this ()))
			m_Server.Send (header.buf, 16, h + 16, 16, payload, payloadSize, m_RemoteEndpoint);
		else
		{
			LogPrint (eLogWarning, "SSU2: TokenRequest request to ", m_RemoteEndpoint, " already pending");
			Terminate ();
		}
	}

	void SSU2Session::ProcessTokenRequest (Header& header, uint8_t * buf, size_t len)
	{
		// we are Bob
		if (len < 48)
		{
			LogPrint (eLogWarning, "SSU2: Incorrect TokenRequest len ", len);
			return;
		}
		uint8_t nonce[12] = {0};
		uint8_t h[32];
		memcpy (h, header.buf, 16);
		m_Server.ChaCha20 (buf + 16, 16, i2p::context.GetSSU2IntroKey (), nonce, h + 16);
		memcpy (&m_DestConnID, h + 16, 8);
		// decrypt
		CreateNonce (be32toh (header.h.packetNum), nonce);
		uint8_t * payload = buf + 32;
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 48, h, 32,
			i2p::context.GetSSU2IntroKey (), nonce, payload, len - 48, false))
		{
			LogPrint (eLogWarning, "SSU2: TokenRequest AEAD verification failed ");
			return;
		}
		// payload
		m_State = eSSU2SessionStateTokenRequestReceived;
		HandlePayload (payload, len - 48);
		SendRetry ();
	}

	void SSU2Session::SendRetry ()
	{
		// we are Bob
		Header header;
		uint8_t h[32], payload[72];
		// fill packet
		header.h.connID = m_DestConnID; // dest id
		RAND_bytes (header.buf + 8, 4); // random packet num
		header.h.type = eSSU2Retry;
		header.h.flags[0] = 2; // ver
		header.h.flags[1] = (uint8_t)i2p::context.GetNetID (); // netID
		header.h.flags[2] = 0; // flag
		memcpy (h, header.buf, 16);
		memcpy (h + 16, &m_SourceConnID, 8); // source id
		uint64_t token = 0;
		if (m_TerminationReason == eSSU2TerminationReasonNormalClose)
			token = m_Server.GetIncomingToken (m_RemoteEndpoint);
		memcpy (h + 24, &token, 8); // token
		// payload
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (i2p::util::GetMillisecondsSinceEpoch () + 500)/1000);
		size_t payloadSize = 7;
		payloadSize += CreateAddressBlock (payload + payloadSize, 56 - payloadSize, m_RemoteEndpoint);
		if (m_TerminationReason != eSSU2TerminationReasonNormalClose)
			payloadSize += CreateTerminationBlock (payload + payloadSize, 56 - payloadSize);
		payloadSize += CreatePaddingBlock (payload + payloadSize, 56 - payloadSize);
		// encrypt
		uint8_t nonce[12];
		CreateNonce (be32toh (header.h.packetNum), nonce);
		i2p::crypto::AEADChaCha20Poly1305 (payload, payloadSize, h, 32, i2p::context.GetSSU2IntroKey (), nonce, payload, payloadSize + 16, true);
		payloadSize += 16;
		header.ll[0] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), payload + (payloadSize - 24));
		header.ll[1] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), payload + (payloadSize - 12));
		memset (nonce, 0, 12);
		m_Server.ChaCha20 (h + 16, 16, i2p::context.GetSSU2IntroKey (), nonce, h + 16);
		// send
		m_Server.Send (header.buf, 16, h + 16, 16, payload, payloadSize, m_RemoteEndpoint);
	}

	bool SSU2Session::ProcessRetry (uint8_t * buf, size_t len)
	{
		// we are Alice
		Header header;
		memcpy (header.buf, buf, 16);
		header.ll[0] ^= CreateHeaderMask (m_Address->i, buf + (len - 24));
		header.ll[1] ^= CreateHeaderMask (m_Address->i, buf + (len - 12));
		if (header.h.type != eSSU2Retry)
		{
			LogPrint (eLogWarning, "SSU2: Unexpected message type ", (int)header.h.type, " instead ", (int)eSSU2Retry);
			return false;
		}
		if (len < 48)
		{
			LogPrint (eLogWarning, "SSU2: Retry message too short ", len);
			return false;
		}
		uint8_t nonce[12] = {0};
		uint64_t headerX[2]; // sourceConnID, token
		m_Server.ChaCha20 (buf + 16, 16, m_Address->i, nonce, (uint8_t *)headerX);
		uint64_t token = headerX[1];
		if (token)
			m_Server.UpdateOutgoingToken (m_RemoteEndpoint, token, i2p::util::GetSecondsSinceEpoch () + SSU2_TOKEN_EXPIRATION_TIMEOUT);
		// decrypt and handle payload
		uint8_t * payload = buf + 32;
		CreateNonce (be32toh (header.h.packetNum), nonce);
		uint8_t h[32];
		memcpy (h, header.buf, 16);
		memcpy (h + 16, &headerX, 16);
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 48, h, 32,
			m_Address->i, nonce, payload, len - 48, false))
		{
			LogPrint (eLogWarning, "SSU2: Retry AEAD verification failed");
			return false;
		}
		m_State = eSSU2SessionStateTokenReceived;
		HandlePayload (payload, len - 48);
		if (!token)
		{
			// we should handle payload even for zero token to handle Datetime block and adjust clock in case of clock skew
			LogPrint (eLogWarning, "SSU2: Retry token is zero");
			return false;
		}
		InitNoiseXKState1 (*m_NoiseState, m_Address->s); // reset Noise TODO: check state
		SendSessionRequest (token);
		return true;
	}
		
	bool SSU2Session::ProcessHolePunch (uint8_t * buf, size_t len)
	{
		// we are Alice
		LogPrint (eLogDebug, "SSU2: HolePunch");
		Header header;
		memcpy (header.buf, buf, 16);
		header.ll[0] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), buf + (len - 24));
		header.ll[1] ^= CreateHeaderMask (i2p::context.GetSSU2IntroKey (), buf + (len - 12));
		if (header.h.type != eSSU2HolePunch)
		{
			LogPrint (eLogWarning, "SSU2: Unexpected message type ", (int)header.h.type, " instead ", (int)eSSU2HolePunch);
			return false;
		}
		if (len < 48)
		{
			LogPrint (eLogWarning, "SSU2: HolePunch message too short ", len);
			return false;
		}
		uint8_t nonce[12] = {0};
		uint64_t headerX[2]; // sourceConnID, token
		m_Server.ChaCha20 (buf + 16, 16, i2p::context.GetSSU2IntroKey (), nonce, (uint8_t *)headerX);
		m_DestConnID = headerX[0];
		// decrypt and handle payload
		uint8_t * payload = buf + 32;
		CreateNonce (be32toh (header.h.packetNum), nonce);
		uint8_t h[32];
		memcpy (h, header.buf, 16);
		memcpy (h + 16, &headerX, 16);
		if (!i2p::crypto::AEADChaCha20Poly1305 (payload, len - 48, h, 32,
			i2p::context.GetSSU2IntroKey (), nonce, payload, len - 48, false))
		{
			LogPrint (eLogWarning, "SSU2: HolePunch AEAD verification failed ");
			return false;
		}
		HandlePayload (payload, len - 48);
		m_IsDataReceived = false;
		// connect to Charlie
		ConnectAfterIntroduction ();

		return true;
	}

	bool SSU2Session::ProcessPeerTest (uint8_t * buf, size_t len)
	{
		LogPrint (eLogWarning, "SSU2:  Unexpected peer test message for this session type");
		return false;
	}

	uint32_t SSU2Session::SendData (const uint8_t * buf, size_t len, uint8_t flags)
	{
		if (len < 8)
		{
			LogPrint (eLogWarning, "SSU2: Data message payload is too short ", (int)len);
			return 0;
		}
		Header header;
		header.h.connID = m_DestConnID;
		header.h.packetNum = htobe32 (m_SendPacketNum);
		header.h.type = eSSU2Data;
		memset (header.h.flags, 0, 3);
		if (flags) header.h.flags[0] = flags;
		uint8_t nonce[12];
		CreateNonce (m_SendPacketNum, nonce);
		uint8_t payload[SSU2_MAX_PACKET_SIZE];
		m_Server.AEADChaCha20Poly1305Encrypt (buf, len, header.buf, 16, m_KeyDataSend, nonce, payload, SSU2_MAX_PACKET_SIZE);
		header.ll[0] ^= CreateHeaderMask (m_Address->i, payload + (len - 8));
		header.ll[1] ^= CreateHeaderMask (m_KeyDataSend + 32, payload + (len + 4));
		m_Server.Send (header.buf, 16, payload, len + 16, m_RemoteEndpoint);
		m_SendPacketNum++;
		UpdateNumSentBytes (len + 32);
		return m_SendPacketNum - 1;
	}

	void SSU2Session::ProcessData (uint8_t * buf, size_t len, const boost::asio::ip::udp::endpoint& from)
	{
		Header header;
		header.ll[0] = m_SourceConnID;
		memcpy (header.buf + 8, buf + 8, 8);
		header.ll[1] ^= CreateHeaderMask (m_KeyDataReceive + 32, buf + (len - 12));
		if (header.h.type != eSSU2Data)
		{
			LogPrint (eLogWarning, "SSU2: Unexpected message type ", (int)header.h.type, " instead ", (int)eSSU2Data);
			if (IsEstablished ())
				SendQuickAck (); // in case it was SessionConfirmed
			else
				ResendHandshakePacket (); // assume we receive
			return;
		}
		if (from != m_RemoteEndpoint && !i2p::transport::transports.IsInReservedRange (from.address ()) &&
		    (!m_PathChallenge || from != m_PathChallenge->second)) // path challenge was not sent to this endpoint yet 
		{
			LogPrint (eLogInfo, "SSU2: Remote endpoint update ", m_RemoteEndpoint, "->", from);
			SendPathChallenge (from);
		}
		if (len < 32)
		{
			LogPrint (eLogWarning, "SSU2: Data message too short ", len);
			return;
		}
		uint8_t payload[SSU2_MAX_PACKET_SIZE];
		size_t payloadSize = len - 32;
		uint32_t packetNum = be32toh (header.h.packetNum);
		uint8_t nonce[12];
		CreateNonce (packetNum, nonce);
		if (!m_Server.AEADChaCha20Poly1305Decrypt (buf + 16, payloadSize, header.buf, 16,
			m_KeyDataReceive, nonce, payload, payloadSize))
		{
			LogPrint (eLogWarning, "SSU2: Data AEAD verification failed ");
			return;
		}
		UpdateNumReceivedBytes (len);
		if (header.h.flags[0] & SSU2_FLAG_IMMEDIATE_ACK_REQUESTED) m_IsDataReceived = true;
		if (!packetNum || UpdateReceivePacketNum (packetNum))
			HandlePayload (payload, payloadSize);
	}

	void SSU2Session::HandlePayload (const uint8_t * buf, size_t len)
	{
		size_t offset = 0;
		while (offset < len)
		{
			uint8_t blk = buf[offset];
			offset++;
			auto size = bufbe16toh (buf + offset);
			offset += 2;
			LogPrint (eLogDebug, "SSU2: Block type ", (int)blk, " of size ", size);
			if (offset + size > len)
			{
				LogPrint (eLogError, "SSU2: Unexpected block length ", size);
				break;
			}
			switch (blk)
			{
				case eSSU2BlkDateTime:
					LogPrint (eLogDebug, "SSU2: Datetime");
					HandleDateTime (buf + offset, size);
				break;
				case eSSU2BlkOptions:
					LogPrint (eLogDebug, "SSU2: Options");
				break;
				case eSSU2BlkRouterInfo:
					LogPrint (eLogDebug, "SSU2: RouterInfo");
					HandleRouterInfo (buf + offset, size);
				break;
				case eSSU2BlkI2NPMessage:
				{
					LogPrint (eLogDebug, "SSU2: I2NP message");
					auto nextMsg = (buf[offset] == eI2NPTunnelData) ? NewI2NPTunnelMessage (true) : NewI2NPShortMessage ();
					nextMsg->len = nextMsg->offset + size + 7; // 7 more bytes for full I2NP header
					memcpy (nextMsg->GetNTCP2Header (), buf + offset, size);
					nextMsg->FromNTCP2 (); // SSU2 has the same format as NTCP2
					HandleI2NPMsg (std::move (nextMsg));
					m_IsDataReceived = true;
					break;
				}
				case eSSU2BlkFirstFragment:
					LogPrint (eLogDebug, "SSU2: First fragment");
					HandleFirstFragment (buf + offset, size);
					m_IsDataReceived = true;
				break;
				case eSSU2BlkFollowOnFragment:
					LogPrint (eLogDebug, "SSU2: Follow-on fragment");
					HandleFollowOnFragment (buf + offset, size);
					m_IsDataReceived = true;
				break;
				case eSSU2BlkTermination:
				{
					if (size >= 9)
					{
						uint8_t rsn = buf[offset + 8]; // reason
						LogPrint (eLogDebug, "SSU2: Termination reason=", (int)rsn);
						if (IsEstablished () && rsn != eSSU2TerminationReasonTerminationReceived)
							RequestTermination (eSSU2TerminationReasonTerminationReceived);
						else if (m_State != eSSU2SessionStateTerminated)
						{
							if (m_State == eSSU2SessionStateClosing && rsn == eSSU2TerminationReasonTerminationReceived)
								m_State = eSSU2SessionStateClosingConfirmed;
							Done ();
						}
					}
					else
						LogPrint(eLogWarning, "SSU2: Unexpected termination block size ", size);
					break;
				}
				case eSSU2BlkRelayRequest:
					LogPrint (eLogDebug, "SSU2: RelayRequest");
					HandleRelayRequest (buf + offset, size);
					m_IsDataReceived = true;
				break;
				case eSSU2BlkRelayResponse:
					LogPrint (eLogDebug, "SSU2: RelayResponse");
					HandleRelayResponse (buf + offset, size);
					m_IsDataReceived = true;
				break;
				case eSSU2BlkRelayIntro:
					LogPrint (eLogDebug, "SSU2: RelayIntro");
					HandleRelayIntro (buf + offset, size);
					m_IsDataReceived = true;
				break;
				case eSSU2BlkPeerTest:
					LogPrint (eLogDebug, "SSU2: PeerTest msg=", (int)buf[offset], " code=", (int)buf[offset+1]);
					HandlePeerTest (buf + offset, size);
					if (buf[offset] < 5)
						m_IsDataReceived = true;
				break;
				case eSSU2BlkNextNonce:
				break;
				case eSSU2BlkAck:
					LogPrint (eLogDebug, "SSU2: Ack");
					HandleAck (buf + offset, size);
				break;
				case eSSU2BlkAddress:
					LogPrint (eLogDebug, "SSU2: Address");
					HandleAddress (buf + offset, size);
				break;
				case eSSU2BlkIntroKey:
				break;
				case eSSU2BlkRelayTagRequest:
					LogPrint (eLogDebug, "SSU2: RelayTagRequest");
					if (!m_RelayTag)
					{
						auto addr = FindLocalAddress ();
						if (addr && addr->IsIntroducer ())
						{	
							RAND_bytes ((uint8_t *)&m_RelayTag, 4);
							m_Server.AddRelay (m_RelayTag, shared_from_this ());
						}	
					}
				break;
				case eSSU2BlkRelayTag:
					LogPrint (eLogDebug, "SSU2: RelayTag");
					m_RelayTag = bufbe32toh (buf + offset);
				break;
				case eSSU2BlkNewToken:
				{
					LogPrint (eLogDebug, "SSU2: New token");
					uint64_t token;
					memcpy (&token, buf + offset + 4, 8);
					m_Server.UpdateOutgoingToken (m_RemoteEndpoint, token, bufbe32toh (buf + offset));
					break;
				}
				case eSSU2BlkPathChallenge:
					LogPrint (eLogDebug, "SSU2: Path challenge");
					SendPathResponse (buf + offset, size);
				break;
				case eSSU2BlkPathResponse:
				{
					LogPrint (eLogDebug, "SSU2: Path response");
					if (m_PathChallenge)
					{
						if (buf64toh (buf + offset) == m_PathChallenge->first)
						{
							m_RemoteEndpoint = m_PathChallenge->second;
							m_PathChallenge.reset (nullptr);
						}	
					}
					break;
				}
				case eSSU2BlkFirstPacketNumber:
				break;
				case eSSU2BlkPadding:
					LogPrint (eLogDebug, "SSU2: Padding");
				break;
				default:
					LogPrint (eLogWarning, "SSU2: Unknown block type ", (int)blk);
			}
			offset += size;
		}
	}

	void SSU2Session::HandleDateTime (const uint8_t * buf, size_t len)
	{
		int64_t offset = (int64_t)i2p::util::GetSecondsSinceEpoch () - (int64_t)bufbe32toh (buf);
		switch (m_State)
		{
			case eSSU2SessionStateSessionRequestReceived:
			case eSSU2SessionStateTokenRequestReceived:
			case eSSU2SessionStateEstablished:
				if (std::abs (offset) > SSU2_CLOCK_SKEW)
					m_TerminationReason = eSSU2TerminationReasonClockSkew;
			break;
			case eSSU2SessionStateSessionCreatedReceived:
			case eSSU2SessionStateTokenReceived:
				if ((m_RemoteEndpoint.address ().is_v4 () && i2p::context.GetTesting ()) ||
				    (m_RemoteEndpoint.address ().is_v6 () && i2p::context.GetTestingV6 ()))
				{
					if (m_Server.IsSyncClockFromPeers ())
					{
						if (std::abs (offset) > SSU2_CLOCK_THRESHOLD)
						{	
							LogPrint (eLogWarning, "SSU2: Time offset ", offset, " from ", m_RemoteEndpoint);
							m_Server.AdjustTimeOffset (-offset, GetRemoteIdentity ());
						}	
						else
							m_Server.AdjustTimeOffset (0, nullptr);
					}
					else if (std::abs (offset) > SSU2_CLOCK_SKEW)
					{
						LogPrint (eLogError, "SSU2: Clock skew detected ", offset, ". Check your clock");
						i2p::context.SetError (eRouterErrorClockSkew);
					}
				}
			break;
			default: ;
		};
	}

	void SSU2Session::HandleRouterInfo (const uint8_t * buf, size_t len)
	{
		if (len < 2) return;
		// not from SessionConfirmed, we must add it instantly to use in next block
		std::shared_ptr<const i2p::data::RouterInfo> newRi;
		if (buf[0] & SSU2_ROUTER_INFO_FLAG_GZIP) // compressed?
		{	
			auto ri = ExtractRouterInfo (buf, len);
			if (ri)
				newRi = i2p::data::netdb.AddRouterInfo (ri->GetBuffer (), ri->GetBufferLen ());
		}	
		else // use buffer directly. TODO: handle frag
			newRi = i2p::data::netdb.AddRouterInfo (buf + 2, len - 2);

		if (newRi)
		{
			auto remoteIdentity = GetRemoteIdentity ();
			if (remoteIdentity && remoteIdentity->GetIdentHash () == newRi->GetIdentHash ())
			{
				// peer's RouterInfo update
				SetRemoteIdentity (newRi->GetIdentity ());
				auto address = m_RemoteEndpoint.address ().is_v6 () ? newRi->GetSSU2V6Address () : newRi->GetSSU2V4Address ();
				if (address)
				{
					m_Address = address;
					if (IsOutgoing () && m_RelayTag && !address->IsIntroducer ())
						m_RelayTag = 0; // not longer introducer
				}	
			}	
		}		
	}	
		
	void SSU2Session::HandleAck (const uint8_t * buf, size_t len)
	{
		if (m_State == eSSU2SessionStateSessionConfirmedSent)
		{
			Established ();
			return;
		}
		if (m_SentPackets.empty ()) return;
		if (len < 5) return;
		// acnt
		uint32_t ackThrough = bufbe32toh (buf);
		uint32_t firstPacketNum = ackThrough > buf[4] ? ackThrough - buf[4] : 0;
		HandleAckRange (firstPacketNum, ackThrough, i2p::util::GetMillisecondsSinceEpoch ()); // acnt
		// ranges
		len -= 5;
		if (!len || m_SentPackets.empty ()) return; // don't handle ranges if nothing to acknowledge
		const uint8_t * ranges = buf + 5;
		while (len > 0 && firstPacketNum && ackThrough - firstPacketNum < SSU2_MAX_NUM_ACK_PACKETS)
		{
			uint32_t lastPacketNum = firstPacketNum - 1;
			if (*ranges > lastPacketNum) break;
			lastPacketNum -= *ranges; ranges++; // nacks
			if (*ranges > lastPacketNum + 1) break;
			firstPacketNum = lastPacketNum - *ranges + 1; ranges++; // acks
			len -= 2;
			HandleAckRange (firstPacketNum, lastPacketNum, 0);
		}
	}

	void SSU2Session::HandleAckRange (uint32_t firstPacketNum, uint32_t lastPacketNum, uint64_t ts)
	{
		if (firstPacketNum > lastPacketNum) return;
		auto it = m_SentPackets.begin ();
		while (it != m_SentPackets.end () && it->first < firstPacketNum) it++; // find first acked packet
		if (it == m_SentPackets.end () || it->first > lastPacketNum) return; // not found
		auto it1 = it;
		int numPackets = 0;
		while (it1 != m_SentPackets.end () && it1->first <= lastPacketNum)
		{
			if (ts && !it1->second->numResends)
			{
				if (ts > it1->second->sendTime)
				{
					auto rtt = ts - it1->second->sendTime;
					if (m_RTT != SSU2_UNKNOWN_RTT)
						m_RTT = SSU2_RTT_EWMA_ALPHA * rtt + (1.0 - SSU2_RTT_EWMA_ALPHA) * m_RTT;
					else
						m_RTT = rtt;
					m_RTO = m_RTT*SSU2_kAPPA;
					m_MsgLocalExpirationTimeout = std::max (I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_MIN,
						std::min (I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_MAX,
						(unsigned int)(m_RTT * 1000 * I2NP_MESSAGE_LOCAL_EXPIRATION_TIMEOUT_FACTOR)));
					m_MsgLocalSemiExpirationTimeout = m_MsgLocalExpirationTimeout / 2;
					if (m_RTO < SSU2_MIN_RTO) m_RTO = SSU2_MIN_RTO;
					if (m_RTO > SSU2_MAX_RTO) m_RTO = SSU2_MAX_RTO;
				}
				ts = 0; // update RTT one time per range
			}
			it1++;
			numPackets++;
		}
		m_SentPackets.erase (it, it1);
		if (numPackets > 0)
		{
			m_WindowSize += numPackets;
			if (m_WindowSize > SSU2_MAX_WINDOW_SIZE) m_WindowSize = SSU2_MAX_WINDOW_SIZE;
		}
	}

	void SSU2Session::HandleAddress (const uint8_t * buf, size_t len)
	{
		boost::asio::ip::udp::endpoint ep;
		if (ExtractEndpoint (buf, len, ep))
		{
			LogPrint (eLogInfo, "SSU2: Our external address is ", ep);
			if (!i2p::transport::transports.IsInReservedRange (ep.address ()))
			{
				i2p::context.UpdateAddress (ep.address ());
				// check our port
				bool isV4 = ep.address ().is_v4 ();
				if (ep.port () != m_Server.GetPort (isV4))
				{
					LogPrint (eLogInfo, "SSU2: Our port ", ep.port (), " received from ", m_RemoteEndpoint, " is different from ", m_Server.GetPort (isV4));
					if (isV4)
					{
						if (i2p::context.GetTesting ())
							i2p::context.SetError (eRouterErrorSymmetricNAT);
						else if (m_State == eSSU2SessionStatePeerTest)
							i2p::context.SetError (eRouterErrorFullConeNAT);
					}
					else
					{
						if (i2p::context.GetTestingV6 ())
							i2p::context.SetErrorV6 (eRouterErrorSymmetricNAT);
						else if (m_State == eSSU2SessionStatePeerTest)
							i2p::context.SetErrorV6 (eRouterErrorFullConeNAT);
					}
				}
				else
				{
					if (isV4)
					{
						if (i2p::context.GetError () == eRouterErrorSymmetricNAT)
						{
							if (m_State == eSSU2SessionStatePeerTest)
								i2p::context.SetStatus (eRouterStatusOK);
							i2p::context.SetError (eRouterErrorNone);
						}
						else if (i2p::context.GetError () == eRouterErrorFullConeNAT)
							i2p::context.SetError (eRouterErrorNone);
					}
					else
					{
						if (i2p::context.GetErrorV6 () == eRouterErrorSymmetricNAT)
						{
							if (m_State == eSSU2SessionStatePeerTest)
								i2p::context.SetStatusV6 (eRouterStatusOK);
							i2p::context.SetErrorV6 (eRouterErrorNone);
						}
						else if (i2p::context.GetErrorV6 () == eRouterErrorFullConeNAT)
							i2p::context.SetErrorV6 (eRouterErrorNone);
					}
				}
			}
		}
	}

	void SSU2Session::HandleFirstFragment (const uint8_t * buf, size_t len)
	{
		auto msg = (buf[0] == eI2NPTunnelData) ? NewI2NPTunnelMessage (true) : NewI2NPShortMessage ();
		uint32_t msgID; memcpy (&msgID, buf + 1, 4);
		// same format as I2NP message block
		msg->len = msg->offset + len + 7;
		memcpy (msg->GetNTCP2Header (), buf, len);
		std::shared_ptr<SSU2IncompleteMessage> m;
		bool found = false;
		auto it = m_IncompleteMessages.find (msgID);
		if (it != m_IncompleteMessages.end ())
		{
			found = true;
			m = it->second;
		}
		else
		{
			m = m_Server.GetIncompleteMessagesPool ().AcquireShared ();
			m_IncompleteMessages.emplace (msgID, m);
		}
		m->msg = msg;
		m->nextFragmentNum = 1;
		m->lastFragmentInsertTime = i2p::util::GetSecondsSinceEpoch ();
		if (found && m->ConcatOutOfSequenceFragments ())
		{
			// we have all follow-on fragments already
			m->msg->FromNTCP2 ();
			HandleI2NPMsg (std::move (m->msg));
			m_IncompleteMessages.erase (it);
		}
	}

	void SSU2Session::HandleFollowOnFragment (const uint8_t * buf, size_t len)
	{
		if (len < 5) return;
		uint8_t fragmentNum = buf[0] >> 1;
		if (!fragmentNum || fragmentNum >= SSU2_MAX_NUM_FRAGMENTS)
		{
			LogPrint (eLogWarning, "SSU2: Invalid follow-on fragment num ", fragmentNum);
			return;
		}
		bool isLast = buf[0] & 0x01;
		uint32_t msgID; memcpy (&msgID, buf + 1, 4);
		auto it = m_IncompleteMessages.find (msgID);
		if (it != m_IncompleteMessages.end ())
		{
			if (fragmentNum < it->second->nextFragmentNum) return; // duplicate
			if (it->second->nextFragmentNum == fragmentNum && fragmentNum < SSU2_MAX_NUM_FRAGMENTS &&
			    it->second->msg)
			{
				// in sequence
				it->second->AttachNextFragment (buf + 5, len - 5);
				if (isLast)
				{
					it->second->msg->FromNTCP2 ();
					HandleI2NPMsg (std::move (it->second->msg));
					m_IncompleteMessages.erase (it);
				}
				else
				{
					if (it->second->ConcatOutOfSequenceFragments ())
					{
						HandleI2NPMsg (std::move (it->second->msg));
						m_IncompleteMessages.erase (it);
					}
					else
						it->second->lastFragmentInsertTime = i2p::util::GetSecondsSinceEpoch ();
				}
				return;
			}
		}
		else
		{
			// follow-on fragment before first fragment
			auto msg = m_Server.GetIncompleteMessagesPool ().AcquireShared ();
			msg->nextFragmentNum = 0;
			it = m_IncompleteMessages.emplace (msgID, msg).first;
		}
		// insert out of sequence fragment
		auto fragment = m_Server.GetFragmentsPool ().AcquireShared ();
		memcpy (fragment->buf, buf + 5, len -5);
		fragment->len = len - 5;
		fragment->fragmentNum = fragmentNum;
		fragment->isLast = isLast;
		it->second->AddOutOfSequenceFragment (fragment);
	}

	void SSU2Session::HandleRelayRequest (const uint8_t * buf, size_t len)
	{
		// we are Bob
		if (len < 9) return;
		auto mts = i2p::util::GetMillisecondsSinceEpoch ();
		uint32_t nonce = bufbe32toh (buf + 1); // nonce
		uint32_t relayTag = bufbe32toh (buf + 5); // relay tag
		auto session = m_Server.FindRelaySession (relayTag);
		if (!session)
		{
			LogPrint (eLogWarning, "SSU2: RelayRequest session with relay tag ", relayTag, " not found");
			// send relay response back to Alice
			auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
			packet->payloadSize = CreateAckBlock (packet->payload, m_MaxPayloadSize);
			packet->payloadSize += CreateRelayResponseBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize,
				eSSU2RelayResponseCodeBobRelayTagNotFound, nonce, 0, false);
			packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
			uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
			if (m_RemoteVersion >= SSU2_MIN_RELAY_RESPONSE_RESEND_VERSION)
			{	
				// sometimes Alice doesn't ack this RelayResponse in older versions
				packet->sendTime = mts;
				m_SentPackets.emplace (packetNum, packet);
			}	
			return;
		}
		if (session->m_RelaySessions.emplace (nonce, std::make_pair (shared_from_this (), mts/1000)).second)
		{
			// send relay intro to Charlie
			auto r = i2p::data::netdb.FindRouter (GetRemoteIdentity ()->GetIdentHash ()); // Alice's RI
			if (r && (r->IsUnreachable () || !i2p::data::netdb.PopulateRouterInfoBuffer (r))) r = nullptr;
			if (!r) LogPrint (eLogWarning, "SSU2: RelayRequest Alice's router info not found");

			auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
			packet->payloadSize = r ? CreateRouterInfoBlock (packet->payload, m_MaxPayloadSize - len - 32, r) : 0;
			if (!packet->payloadSize && r)
				session->SendFragmentedMessage (CreateDatabaseStoreMsg (r));
			packet->payloadSize += CreateRelayIntroBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize, buf + 1, len - 1);
			if (packet->payloadSize < m_MaxPayloadSize)
				packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
			uint32_t packetNum = session->SendData (packet->payload, packet->payloadSize);
			packet->sendTime = mts;
			// Charlie always responds with RelayResponse
			session->m_SentPackets.emplace (packetNum, packet);
		}
		else
			LogPrint (eLogInfo, "SSU2: Relay request nonce ", nonce, " already exists. Ignore");
	}

	void SSU2Session::HandleRelayIntro (const uint8_t * buf, size_t len, int attempts)
	{
		// we are Charlie
		if (len < 47) return;
		SSU2RelayResponseCode code = eSSU2RelayResponseCodeAccept;
		boost::asio::ip::udp::endpoint ep;
		std::shared_ptr<const i2p::data::RouterInfo::Address> addr;
		auto r = i2p::data::netdb.FindRouter (buf + 1); // Alice
		if (r)
		{
			SignedData<128> s;
			s.Insert ((const uint8_t *)"RelayRequestData", 16); // prologue
			s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
			s.Insert (i2p::context.GetIdentHash (), 32); // chash
			s.Insert (buf + 33, 14); // nonce, relay tag, timestamp, ver, asz
			uint8_t asz = buf[46];
			if (asz + 47 + r->GetIdentity ()->GetSignatureLen () > len) 
			{	
				LogPrint (eLogWarning, "SSU2: Malformed RelayIntro len=", len);
				return; 
			}	
			s.Insert (buf + 47, asz); // Alice Port, Alice IP
			if (s.Verify (r->GetIdentity (), buf + 47 + asz))
			{
				// obtain and check endpoint and address for HolePunch
				if (ExtractEndpoint (buf + 47, asz, ep))
				{
					if (!ep.address ().is_unspecified () && ep.port ())
					{
						if (m_Server.IsSupported (ep.address ()))
						{
							addr = ep.address ().is_v6 () ? r->GetSSU2V6Address () : r->GetSSU2V4Address ();
							if (!addr)
							{
								LogPrint (eLogWarning, "SSU2: RelayIntro address for endpoint not found");
								code = eSSU2RelayResponseCodeCharlieAliceIsUnknown;
							}	
						}
						else
						{
							LogPrint (eLogWarning, "SSU2: RelayIntro unsupported address");
							code = eSSU2RelayResponseCodeCharlieUnsupportedAddress;
						}	
					}
					else
					{
						LogPrint (eLogWarning, "SSU2: RelayIntro invalid endpoint");
						code = eSSU2RelayResponseCodeCharlieAliceIsUnknown;
					}
				}
				else
				{
					LogPrint (eLogWarning, "SSU2: RelayIntro can't extract endpoint");
					code = eSSU2RelayResponseCodeCharlieAliceIsUnknown;
				}
			}
			else
			{
				LogPrint (eLogWarning, "SSU2: RelayIntro signature verification failed");
				code = eSSU2RelayResponseCodeCharlieSignatureFailure;
			}
		}
		else if (!attempts)
		{
			// RouterInfo might come in the next packet, try again
			auto vec = std::make_shared<std::vector<uint8_t> >(len);
			memcpy (vec->data (), buf, len);
			auto s = shared_from_this ();
			boost::asio::post (m_Server.GetService (), [s, vec, attempts]()
				{
					LogPrint (eLogDebug, "SSU2: RelayIntro attempt ", attempts + 1);
					s->HandleRelayIntro (vec->data (), vec->size (), attempts + 1);
				});
			return;
		}
		else
		{
			LogPrint (eLogWarning, "SSU2: RelayIntro unknown router to introduce");
			code = eSSU2RelayResponseCodeCharlieAliceIsUnknown;
		}
		// send relay response to Bob
		auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
		uint32_t nonce = bufbe32toh (buf + 33);
		packet->payloadSize = CreateRelayResponseBlock (packet->payload, m_MaxPayloadSize,
			code, nonce, m_Server.GetIncomingToken (ep), ep.address ().is_v4 ());
		if (code == eSSU2RelayResponseCodeAccept && addr)
		{
			// send HolePunch 
			auto holePunchSession = std::make_shared<SSU2HolePunchSession>(m_Server, nonce, ep, addr); 
			if (m_Server.AddSession (holePunchSession))
				holePunchSession->SendHolePunch (packet->payload, packet->payloadSize); // relay response block
			else
			{
				LogPrint (eLogInfo, "SSU2: Relay intro nonce ", nonce, " already exists. Ignore");
				return;
			}		
		}	
		packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
		uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
		if (m_RemoteVersion >= SSU2_MIN_RELAY_RESPONSE_RESEND_VERSION)
		{	
			// sometimes Bob doesn't ack this RelayResponse in older versions
			packet->sendTime = i2p::util::GetMillisecondsSinceEpoch ();
			m_SentPackets.emplace (packetNum, packet);
		}	
	}

	void SSU2Session::HandleRelayResponse (const uint8_t * buf, size_t len)
	{
		if (len < 6) return;
		uint32_t nonce = bufbe32toh (buf + 2);
		if (m_State == eSSU2SessionStateIntroduced)
		{
			// HolePunch from Charlie
			// TODO: verify address and signature
			// verify nonce
			if (~htobe64 (((uint64_t)nonce << 32) | nonce) != m_DestConnID)
				LogPrint (eLogWarning, "SSU2: Relay response nonce mismatch ", nonce, " connID=", m_DestConnID);
			if (len >= 8)
			{
				// new token
				uint64_t token;
				memcpy (&token, buf + len - 8, 8);
				m_Server.UpdateOutgoingToken (m_RemoteEndpoint, token, i2p::util::GetSecondsSinceEpoch () + SSU2_TOKEN_EXPIRATION_TIMEOUT);
			}
			return;
		}
		auto it = m_RelaySessions.find (nonce);
		if (it != m_RelaySessions.end ())
		{
			auto relaySession = it->second.first;
			m_RelaySessions.erase (it);
			if (relaySession && relaySession->IsEstablished ())
			{
				// we are Bob, message from Charlie
				auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
				uint8_t * payload = packet->payload;
				payload[0] = eSSU2BlkRelayResponse;
				htobe16buf (payload + 1, len);
				memcpy (payload + 3, buf, len); // forward to Alice as is
				packet->payloadSize = len + 3;
				packet->payloadSize += CreatePaddingBlock (payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
				uint32_t packetNum = relaySession->SendData (packet->payload, packet->payloadSize);
				if (m_RemoteVersion >= SSU2_MIN_RELAY_RESPONSE_RESEND_VERSION)
				{	
					// sometimes Alice doesn't ack this RelayResponse in older versions
					packet->sendTime = i2p::util::GetMillisecondsSinceEpoch ();
					relaySession->m_SentPackets.emplace (packetNum, packet);
				}	
			}
			else
			{
				// we are Alice, message from Bob
				if (!buf[1]) // status code accepted?
				{
					// verify signature
					uint8_t csz = (len >= 12) ? buf[11] : 0;
					if (csz + 12 + relaySession->GetRemoteIdentity ()->GetSignatureLen () > len)
					{
						LogPrint (eLogWarning, "SSU2: Malformed RelayResponse len=", len);
						relaySession->Done ();
						return;
					}	
					SignedData<128> s;
					s.Insert ((const uint8_t *)"RelayAgreementOK", 16); // prologue
					s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
					s.Insert (buf + 2, 10 + csz); // nonce, timestamp, ver, csz and Charlie's endpoint
					if (s.Verify (relaySession->GetRemoteIdentity (), buf + 12 + csz))
					{
						if (relaySession->m_State == eSSU2SessionStateIntroduced) // HolePunch not received yet
						{
							// update Charlie's endpoint
							if (ExtractEndpoint (buf + 12, csz, relaySession->m_RemoteEndpoint))
							{
								// update token
								uint64_t token;
								memcpy (&token, buf + len - 8, 8);
								m_Server.UpdateOutgoingToken (relaySession->m_RemoteEndpoint,
									token, i2p::util::GetSecondsSinceEpoch () + SSU2_TOKEN_EXPIRATION_TIMEOUT);
								// connect to Charlie, HolePunch will be ignored
								relaySession->ConnectAfterIntroduction ();
							}
							else
								LogPrint (eLogWarning, "SSU2: RelayResponse can't extract endpoint");
						}
					}
					else
					{
						LogPrint (eLogWarning, "SSU2: RelayResponse signature verification failed");
						relaySession->Done ();
					}
				}
				else
				{
					LogPrint (eLogInfo, "SSU2: RelayResponse status code=", (int)buf[1], " nonce=", bufbe32toh (buf + 2));
					relaySession->Done ();
				}
			}
		}
		else
			LogPrint (eLogDebug, "SSU2: RelayResponse unknown nonce ", bufbe32toh (buf + 2));
	}

	void SSU2Session::HandlePeerTest (const uint8_t * buf, size_t len)
	{
		// msgs 1-4	
		if (len < 3) return;
		uint8_t msg = buf[0];
		size_t offset = 3; // points to signed data
		if (msg == 2 || msg == 4) offset += 32; // hash is presented for msg 2 and 4 only
		if (len < offset + 5) return;
		auto ts = i2p::util::GetMillisecondsSinceEpoch ();
		uint32_t nonce = bufbe32toh (buf + offset + 1);
		switch (msg) // msg
		{
			case 1: // Bob from Alice
			{
				auto session = m_Server.GetRandomPeerTestSession ((buf[12] == 6) ? i2p::data::RouterInfo::eSSU2V4 : i2p::data::RouterInfo::eSSU2V6,
					GetRemoteIdentity ()->GetIdentHash ());
				if (session) // session with Charlie
				{
					if (m_Server.AddPeerTest (nonce, shared_from_this (), ts/1000))
					{	
						auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
						// Alice's RouterInfo
						auto r = i2p::data::netdb.FindRouter (GetRemoteIdentity ()->GetIdentHash ());
						if (r && (r->IsUnreachable () || !i2p::data::netdb.PopulateRouterInfoBuffer (r))) r = nullptr;
						packet->payloadSize = r ? CreateRouterInfoBlock (packet->payload, m_MaxPayloadSize - len - 32, r) : 0;
						if (!packet->payloadSize && r)
							session->SendFragmentedMessage (CreateDatabaseStoreMsg (r));
						if (packet->payloadSize + len + 48 > m_MaxPayloadSize)
						{
							// doesn't fit one message, send RouterInfo in separate message
							uint32_t packetNum = session->SendData (packet->payload, packet->payloadSize, SSU2_FLAG_IMMEDIATE_ACK_REQUESTED);
							packet->sendTime = ts;
							session->m_SentPackets.emplace (packetNum, packet);
							packet = m_Server.GetSentPacketsPool ().AcquireShared (); // new packet
						}
						// PeerTest to Charlie
						packet->payloadSize += CreatePeerTestBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize, 2,
							eSSU2PeerTestCodeAccept, GetRemoteIdentity ()->GetIdentHash (), buf + offset, len - offset);
						packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
						uint32_t packetNum = session->SendData (packet->payload, packet->payloadSize, SSU2_FLAG_IMMEDIATE_ACK_REQUESTED);
						packet->sendTime = ts;
						session->m_SentPackets.emplace (packetNum, packet);
					}
					else
						LogPrint (eLogInfo, "SSU2: Peer test 1 nonce ", nonce, " already exists. Ignored");
				}
				else
				{
					// Charlie not found, send error back to Alice
					auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
					uint8_t zeroHash[32] = {0};
					packet->payloadSize = CreatePeerTestBlock (packet->payload, m_MaxPayloadSize, 4,
						eSSU2PeerTestCodeBobNoCharlieAvailable, zeroHash, buf + offset, len - offset);
					packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
					uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
					packet->sendTime = ts;
					m_SentPackets.emplace (packetNum, packet);
				}
				break;
			}
			case 2: // Charlie from Bob
			{
				// sign with Charlie's key
				if (len < offset + 9) return;
				uint8_t asz = buf[offset + 9];
				size_t l = asz + 10 + i2p::context.GetIdentity ()->GetSignatureLen ();
				if (len < offset + l) return;
				std::vector<uint8_t> newSignedData (l);
				memcpy (newSignedData.data (), buf + offset, asz + 10);
				SignedData<128> s;
				s.Insert ((const uint8_t *)"PeerTestValidate", 16); // prologue
				s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
				s.Insert (buf + 3, 32); // ahash
				s.Insert (newSignedData.data (), asz + 10); // ver, nonce, ts, asz, Alice's endpoint
				s.Sign (i2p::context.GetPrivateKeys (), newSignedData.data () + 10 + asz);
				// send response (msg 3) back and msg 5 if accepted
				SSU2PeerTestCode code = eSSU2PeerTestCodeAccept;
				auto r = i2p::data::netdb.FindRouter (buf + 3); // find Alice
				if (r)
				{
					size_t signatureLen = r->GetIdentity ()->GetSignatureLen ();
					if (len >= offset + asz + 10 + signatureLen)
					{
						s.Reset ();
						s.Insert ((const uint8_t *)"PeerTestValidate", 16); // prologue
						s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
						s.Insert (buf + offset, asz + 10); // signed data
						if (s.Verify (r->GetIdentity (), buf + offset + asz + 10))
						{
							if (!m_Server.FindSession (r->GetIdentity ()->GetIdentHash ()))
							{
								boost::asio::ip::udp::endpoint ep;
								std::shared_ptr<const i2p::data::RouterInfo::Address> addr;
								if (ExtractEndpoint (buf + offset + 10, asz, ep) && !ep.address ().is_unspecified () && ep.port ())
									addr = r->GetSSU2Address (ep.address ().is_v4 ());
								if (addr && m_Server.IsSupported (ep.address ()) && 
								    i2p::context.GetRouterInfo ().IsSSU2PeerTesting (ep.address ().is_v4 ()))
								{
									if (!m_Server.IsConnectedRecently (ep)) // no alive hole punch
									{	
										// send msg 5 to Alice
										auto session = std::make_shared<SSU2PeerTestSession> (m_Server, 
											0, htobe64 (((uint64_t)nonce << 32) | nonce));
										session->m_RemoteEndpoint = ep; // might be different
										m_Server.AddSession (session);
										session->SendPeerTest (5, newSignedData.data (), newSignedData.size (), addr);
									}
									else
										code = eSSU2PeerTestCodeCharlieAliceIsAlreadyConnected;
								}
								else
									code = eSSU2PeerTestCodeCharlieUnsupportedAddress;
							}
							else
								code = eSSU2PeerTestCodeCharlieAliceIsAlreadyConnected;
						}
						else
							code = eSSU2PeerTestCodeCharlieSignatureFailure;
					}
					else // maformed message
						code = eSSU2PeerTestCodeCharlieReasonUnspecified;
				}
				else
					code = eSSU2PeerTestCodeCharlieAliceIsUnknown;
				// send msg 3 back to Bob
				auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
				packet->payloadSize = CreatePeerTestBlock (packet->payload, m_MaxPayloadSize, 3,
					code, nullptr, newSignedData.data (), newSignedData.size ());
				packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
				uint32_t packetNum = SendData (packet->payload, packet->payloadSize);
				packet->sendTime = ts;
				m_SentPackets.emplace (packetNum, packet);
				break;
			}
			case 3: // Bob from Charlie
			{
				auto aliceSession = m_Server.GetPeerTest (nonce);
				if (aliceSession && aliceSession->IsEstablished ())
				{	
					auto packet = m_Server.GetSentPacketsPool ().AcquireShared ();
					// Charlie's RouterInfo
					auto r = i2p::data::netdb.FindRouter (GetRemoteIdentity ()->GetIdentHash ());
					if (r && (r->IsUnreachable () || !i2p::data::netdb.PopulateRouterInfoBuffer (r))) r = nullptr;
					packet->payloadSize = r ? CreateRouterInfoBlock (packet->payload, m_MaxPayloadSize - len - 32, r) : 0;
					if (!packet->payloadSize && r)
						aliceSession->SendFragmentedMessage (CreateDatabaseStoreMsg (r));
					if (packet->payloadSize + len + 16 > m_MaxPayloadSize)
					{
						// doesn't fit one message, send RouterInfo in separate message
						uint32_t packetNum = aliceSession->SendData (packet->payload, packet->payloadSize);
						packet->sendTime = ts;
						aliceSession->m_SentPackets.emplace (packetNum, packet);
						packet = m_Server.GetSentPacketsPool ().AcquireShared ();
					}
					// PeerTest to Alice
					packet->payloadSize += CreatePeerTestBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize, 4,
						(SSU2PeerTestCode)buf[1], GetRemoteIdentity ()->GetIdentHash (), buf + offset, len - offset);
					if (packet->payloadSize < m_MaxPayloadSize)
						packet->payloadSize += CreatePaddingBlock (packet->payload + packet->payloadSize, m_MaxPayloadSize - packet->payloadSize);
					uint32_t packetNum = aliceSession->SendData (packet->payload, packet->payloadSize);
					packet->sendTime = ts;
					aliceSession->m_SentPackets.emplace (packetNum, packet);
				}	
				else
					LogPrint (eLogDebug, "SSU2: Unknown peer test 3 nonce ", nonce);
				break;
			}
			case 4: // Alice from Bob
			{
				auto session = m_Server.GetRequestedPeerTest (nonce);
				if (session)
				{
					if (buf[1] == eSSU2PeerTestCodeAccept)
					{
						if (GetRouterStatus () == eRouterStatusUnknown)
							SetTestingState (true);
						auto r = i2p::data::netdb.FindRouter (buf + 3); // find Charlie
						if (r && len >= offset + 9)
						{
							uint8_t asz = buf[offset + 9];
							if (len < offset + asz + 10 + r->GetIdentity ()->GetSignatureLen ())
							{
								LogPrint (eLogWarning, "Malformed PeerTest 4 len=", len);
								session->Done ();
								return;
							}	
							SignedData<128> s;
							s.Insert ((const uint8_t *)"PeerTestValidate", 16); // prologue
							s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
							s.Insert (i2p::context.GetIdentity ()->GetIdentHash (), 32); // ahash
							s.Insert (buf + offset, asz + 10); // ver, nonce, ts, asz, Alice's endpoint
							if (s.Verify (r->GetIdentity (), buf + offset + asz + 10))
							{
								session->SetRemoteIdentity (r->GetIdentity ());
								auto addr = r->GetSSU2Address (m_Address->IsV4 ());
								if (addr && addr->IsPeerTesting ())
								{
									if (session->GetMsgNumReceived () >= 5)
									{
										// msg 5 already received and we know remote endpoint
										if (session->GetMsgNumReceived () == 5)
										{	
											if (!session->IsConnectedRecently ())
												SetRouterStatus (eRouterStatusOK);
										 	// send msg 6 immeditely
											session->SendPeerTest (6, buf + offset, len - offset, addr);
										}
										else
											LogPrint (eLogWarning, "SSU2: PeerTest 4 received, but msg ", session->GetMsgNumReceived (), " already received");
									}
									else
									{
										session->m_Address = addr;
										if (GetTestingState ())
										{
											// schedule msg 6 with delay
											if (!addr->host.is_unspecified () && addr->port)
											{	
												session->SetRemoteEndpoint (boost::asio::ip::udp::endpoint (addr->host, addr->port));
												session->SendPeerTest (6, buf + offset, len - offset, addr, true);
											}	
											SetTestingState (false);
											if (GetRouterStatus () != eRouterStatusFirewalled && addr->IsPeerTesting ())
											{
												SetRouterStatus (eRouterStatusFirewalled);
												session->SetStatusChanged ();
												if (m_Address->IsV4 ())
													m_Server.RescheduleIntroducersUpdateTimer ();
												else
													m_Server.RescheduleIntroducersUpdateTimerV6 ();
											}
										}
									}
									LogPrint (eLogDebug, "SSU2: Peer test 4 received from ", i2p::data::GetIdentHashAbbreviation (GetRemoteIdentity ()->GetIdentHash ()),
										" with information about ", i2p::data::GetIdentHashAbbreviation (i2p::data::IdentHash (buf + 3)));
								}
								else
								{
									LogPrint (eLogWarning, "SSU2: Peer test 4 address not found or not supported");
									session->Done ();
								}
							}
							else
							{
								LogPrint (eLogWarning, "SSU2: Peer test 4 signature verification failed");
								session->Done ();
							}
						}
						else
						{
							LogPrint (eLogWarning, "SSU2: Peer test 4 router not found");
							session->Done ();
						}
					}
					else
					{
						LogPrint (eLogInfo, "SSU2: Peer test 4 error code ", (int)buf[1], " from ",
							i2p::data::GetIdentHashAbbreviation (buf[1] < 64 ? GetRemoteIdentity ()->GetIdentHash () : i2p::data::IdentHash (buf + 3)));
						if (GetTestingState () && GetRouterStatus () != eRouterStatusFirewalled)
							SetRouterStatus (eRouterStatusUnknown);
						session->Done ();
					}
				}
				else
					LogPrint (eLogDebug, "SSU2: Unknown peer test 4 nonce ", nonce);
				break;
			}
			default:
				LogPrint (eLogWarning, "SSU2: PeerTest unexpected msg num ", buf[0]);
		}
	}

	void SSU2Session::HandleI2NPMsg (std::shared_ptr<I2NPMessage>&& msg)
	{
		if (!msg) return;
		uint32_t msgID = msg->GetMsgID ();
		if (!msg->IsExpired ())
		{
			// m_LastActivityTimestamp is updated in ProcessData before
			if (m_ReceivedI2NPMsgIDs.emplace (msgID, (uint32_t)GetLastActivityTimestamp ()).second)
				m_Handler.PutNextMessage (std::move (msg));
			else
				LogPrint (eLogDebug, "SSU2: Message ", msgID, " already received");
		}
		else
			LogPrint (eLogDebug, "SSU2: Message ", msgID, " expired");
	}

	bool SSU2Session::ExtractEndpoint (const uint8_t * buf, size_t size, boost::asio::ip::udp::endpoint& ep)
	{
		if (size < 2) return false;
		int port = bufbe16toh (buf);
		if (size == 6)
		{
			boost::asio::ip::address_v4::bytes_type bytes;
			memcpy (bytes.data (), buf + 2, 4);
			ep = boost::asio::ip::udp::endpoint (boost::asio::ip::address_v4 (bytes), port);
		}
		else if (size == 18)
		{
			boost::asio::ip::address_v6::bytes_type bytes;
			memcpy (bytes.data (), buf + 2, 16);
			ep = boost::asio::ip::udp::endpoint (boost::asio::ip::address_v6 (bytes), port);
		}
		else
		{
			LogPrint (eLogWarning, "SSU2: Address size ", int(size), " is not supported");
			return false;
		}
		return true;
	}

	size_t SSU2Session::CreateEndpoint (uint8_t * buf, size_t len, const boost::asio::ip::udp::endpoint& ep)
	{
		if (len < 6) return 0;
		htobe16buf (buf, ep.port ());
		size_t size = 0;
		if (ep.address ().is_v4 ())
		{
			memcpy (buf + 2, ep.address ().to_v4 ().to_bytes ().data (), 4);
			size = 6;
		}
		else if (ep.address ().is_v6 ())
		{
			if (len < 18) return 0;
			memcpy (buf + 2, ep.address ().to_v6 ().to_bytes ().data (), 16);
			size = 18;
		}
		else
		{
			LogPrint (eLogWarning, "SSU2: Wrong address type ", ep.address ().to_string ());
			return 0;
		}
		return size;
	}

	std::shared_ptr<const i2p::data::RouterInfo::Address> SSU2Session::FindLocalAddress () const
	{
		if (m_Address)
			return i2p::context.GetRouterInfo ().GetSSU2Address (m_Address->IsV4 ());
		else if (!m_RemoteEndpoint.address ().is_unspecified ())
			return i2p::context.GetRouterInfo ().GetSSU2Address (m_RemoteEndpoint.address ().is_v4 ());
		return nullptr;
	}

	void SSU2Session::AdjustMaxPayloadSize (size_t maxMtu)
	{
		auto addr = FindLocalAddress ();
		if (addr && addr->ssu)
		{
			int mtu = addr->ssu->mtu;
			if (!mtu && addr->IsV4 ()) mtu = SSU2_MAX_PACKET_SIZE;
			if (mtu > (int)maxMtu) mtu = maxMtu;
			if (m_Address && m_Address->ssu && (!mtu || m_Address->ssu->mtu < mtu))
				mtu = m_Address->ssu->mtu;
			if (mtu)
			{
				if (mtu > (int)SSU2_MAX_PACKET_SIZE) mtu = SSU2_MAX_PACKET_SIZE;
				if (mtu < (int)SSU2_MIN_PACKET_SIZE) mtu = SSU2_MIN_PACKET_SIZE;
				m_MaxPayloadSize = mtu - (addr->IsV6 () ? IPV6_HEADER_SIZE: IPV4_HEADER_SIZE) - UDP_HEADER_SIZE - 32;
				LogPrint (eLogDebug, "SSU2: Session MTU=", mtu, ", max payload size=", m_MaxPayloadSize);
			}
		}
	}

	RouterStatus SSU2Session::GetRouterStatus () const
	{
		if (m_Address)
		{
			if (m_Address->IsV4 ())
				return i2p::context.GetStatus ();
			if (m_Address->IsV6 ())
				return i2p::context.GetStatusV6 ();
		}
		return eRouterStatusUnknown;
	}

	void SSU2Session::SetRouterStatus (RouterStatus status) const
	{
		if (m_Address)
		{
			if (m_Address->IsV4 ())
				i2p::context.SetStatus (status);
			else if (m_Address->IsV6 ())
				i2p::context.SetStatusV6 (status);
		}
	}

	bool SSU2Session::GetTestingState () const
	{
		if (m_Address)
		{
			if (m_Address->IsV4 ())
				return i2p::context.GetTesting ();
			if (m_Address->IsV6 ())
				return i2p::context.GetTestingV6 ();
		}
		return false;
	}

	void SSU2Session::SetTestingState (bool testing) const
	{
		if (m_Address)
		{
			if (m_Address->IsV4 ())
				i2p::context.SetTesting (testing);
			else if (m_Address->IsV6 ())
				i2p::context.SetTestingV6 (testing);
		}
		if (!testing)
			m_Server.AdjustTimeOffset (0, nullptr); // reset time offset when testing is over
	}

	size_t SSU2Session::CreateAddressBlock (uint8_t * buf, size_t len, const boost::asio::ip::udp::endpoint& ep)
	{
		if (len < 9) return 0;
		buf[0] = eSSU2BlkAddress;
		size_t size = CreateEndpoint (buf + 3, len - 3, ep);
		if (!size) return 0;
		htobe16buf (buf + 1, size);
		return size + 3;
	}

	size_t SSU2Session::CreateRouterInfoBlock (uint8_t * buf, size_t len, std::shared_ptr<const i2p::data::RouterInfo> r)
	{
		if (!r || len < 5) return 0;
		return CreateRouterInfoBlock (buf, len, r->GetSharedBuffer ());
	}

	size_t SSU2Session::CreateRouterInfoBlock (uint8_t * buf, size_t len, std::shared_ptr<const i2p::data::RouterInfo::Buffer> riBuffer)
	{
		if (!riBuffer || len < 5) return 0;
		buf[0] = eSSU2BlkRouterInfo;
		size_t size = riBuffer->GetBufferLen ();
		if (size + 5 < len)
		{
			memcpy (buf + 5, riBuffer->data (), size);
			buf[3] = 0; // flag
		}
		else
		{
			i2p::data::GzipDeflator deflator;
			deflator.SetCompressionLevel (9);
			size = deflator.Deflate (riBuffer->data (), riBuffer->GetBufferLen (), buf + 5, len - 5);
			if (!size) return 0; // doesn't fit
			buf[3] = SSU2_ROUTER_INFO_FLAG_GZIP; // flag
		}
		htobe16buf (buf + 1, size + 2); // size
		buf[4] = 1; // frag
		return size + 5;
	}	
	
		
	size_t SSU2Session::CreateAckBlock (uint8_t * buf, size_t len)
	{
		if (len < 8) return 0;
		buf[0] = eSSU2BlkAck;
		uint32_t ackThrough = m_OutOfSequencePackets.empty () ? m_ReceivePacketNum : *m_OutOfSequencePackets.rbegin ();
		htobe32buf (buf + 3, ackThrough); // Ack Through
		uint16_t acnt = 0;
		if (ackThrough)
		{
			if (m_OutOfSequencePackets.empty ())
			{	
				acnt = std::min ((int)ackThrough, SSU2_MAX_NUM_ACNT); // no gaps
				m_NumRanges = 0;
			}	
			else
			{
				auto it = m_OutOfSequencePackets.rbegin (); it++; // prev packet num
				while (it != m_OutOfSequencePackets.rend () && *it == ackThrough - acnt	- 1)
				{
					acnt++;
					if (acnt >= SSU2_MAX_NUM_ACK_PACKETS)
						break;
					else
						it++;
				}
				// ranges
				if (!m_NumRanges)
				{	
					int maxNumRanges = (len - 8) >> 1;
					if (maxNumRanges > SSU2_MAX_NUM_ACK_RANGES) maxNumRanges = SSU2_MAX_NUM_ACK_RANGES;
					int numRanges = 0;
					uint32_t lastNum = ackThrough - acnt;
					if (acnt > SSU2_MAX_NUM_ACNT)
					{
						auto d = std::div (acnt - SSU2_MAX_NUM_ACNT, SSU2_MAX_NUM_ACNT);
						acnt = SSU2_MAX_NUM_ACNT;
						if (d.quot > maxNumRanges)
						{
							d.quot = maxNumRanges;
							d.rem = 0;
						}
						// Acks only ranges for acnt
						for (int i = 0; i < d.quot; i++)
						{
							m_Ranges[numRanges*2] = 0; m_Ranges[numRanges*2 + 1] = SSU2_MAX_NUM_ACNT; // NACKs 0, Acks 255
							numRanges++;
						}
						if (d.rem > 0)
						{
							m_Ranges[numRanges*2] = 0; m_Ranges[numRanges*2 + 1] = d.rem;
							numRanges++;
						}
					}
					int numPackets = acnt + numRanges*SSU2_MAX_NUM_ACNT;
					while (it != m_OutOfSequencePackets.rend () &&
						numRanges < maxNumRanges && numPackets < SSU2_MAX_NUM_ACK_PACKETS)
					{
						if (lastNum - (*it) > SSU2_MAX_NUM_ACNT)
						{
							// NACKs only ranges
							if (lastNum > (*it) + SSU2_MAX_NUM_ACNT*(maxNumRanges - numRanges)) break; // too many NACKs
							while (lastNum - (*it) > SSU2_MAX_NUM_ACNT)
							{
								m_Ranges[numRanges*2] = SSU2_MAX_NUM_ACNT; m_Ranges[numRanges*2 + 1] = 0; // NACKs 255, Acks 0
								lastNum -= SSU2_MAX_NUM_ACNT;
								numRanges++;
								numPackets += SSU2_MAX_NUM_ACNT;
							}
						}
						// NACKs and Acks ranges
						m_Ranges[numRanges*2] = lastNum - (*it) - 1; // NACKs
						numPackets += m_Ranges[numRanges*2];
						lastNum = *it; it++;
						int numAcks = 1;
						while (it != m_OutOfSequencePackets.rend () && lastNum > 0 && *it == lastNum - 1)
						{
							numAcks++; lastNum--;
							it++;
						}
						while (numAcks > SSU2_MAX_NUM_ACNT)
						{
							// Acks only ranges
							m_Ranges[numRanges*2 + 1] = SSU2_MAX_NUM_ACNT; // Acks 255
							numAcks -= SSU2_MAX_NUM_ACNT;
							numRanges++;
							numPackets += SSU2_MAX_NUM_ACNT;
							m_Ranges[numRanges*2] = 0; // NACKs 0
							if (numRanges >= maxNumRanges || numPackets >= SSU2_MAX_NUM_ACK_PACKETS) break;
						}
						if (numAcks > SSU2_MAX_NUM_ACNT) numAcks = SSU2_MAX_NUM_ACNT;
						m_Ranges[numRanges*2 + 1] = (uint8_t)numAcks; // Acks
						numPackets += numAcks;
						numRanges++;
					}
					if (it == m_OutOfSequencePackets.rend () &&
						numRanges < maxNumRanges && numPackets < SSU2_MAX_NUM_ACK_PACKETS)
					{
						// add range between out-of-sequence and received
						int nacks = *m_OutOfSequencePackets.begin () - m_ReceivePacketNum - 1;
						if (nacks > 0)
						{
							if (nacks > SSU2_MAX_NUM_ACNT) nacks = SSU2_MAX_NUM_ACNT;
							m_Ranges[numRanges*2] = nacks;
							m_Ranges[numRanges*2 + 1] = std::min ((int)m_ReceivePacketNum + 1, SSU2_MAX_NUM_ACNT);
							numRanges++;
						}
					}
					m_NumRanges = numRanges;
				}	
				if (m_NumRanges)
					memcpy (buf + 8, m_Ranges, m_NumRanges*2);
			}
		}
		buf[7] = (uint8_t)acnt; // acnt
		htobe16buf (buf + 1, 5 + m_NumRanges*2);
		return 8 + m_NumRanges*2;
	}

	size_t SSU2Session::CreatePaddingBlock (uint8_t * buf, size_t len, size_t minSize)
	{
		if (len < 3 || len < minSize) return 0;
		size_t paddingSize = m_Server.GetRng ()() & 0x1F; // 0 - 31
		if (paddingSize + 3 > len) paddingSize = len - 3;
		else if (paddingSize + 3 < minSize) paddingSize = minSize - 3;
		buf[0] = eSSU2BlkPadding;
		htobe16buf (buf + 1, paddingSize);
		memset (buf + 3, 0, paddingSize);
		return paddingSize + 3;
	}

	size_t SSU2Session::CreateI2NPBlock (uint8_t * buf, size_t len, std::shared_ptr<I2NPMessage>&& msg)
	{
		msg->ToNTCP2 ();
		auto msgBuf = msg->GetNTCP2Header ();
		auto msgLen = msg->GetNTCP2Length ();
		if (msgLen + 3 > len) msgLen = len - 3;
		buf[0] = eSSU2BlkI2NPMessage;
		htobe16buf (buf + 1, msgLen); // size
		memcpy (buf + 3, msgBuf, msgLen);
		return msgLen + 3;
	}

	size_t SSU2Session::CreateFirstFragmentBlock (uint8_t * buf, size_t len, std::shared_ptr<I2NPMessage> msg)
	{
		if (len < 12) return 0;
		msg->ToNTCP2 ();
		auto msgBuf = msg->GetNTCP2Header ();
		auto msgLen = msg->GetNTCP2Length ();
		if (msgLen + 3 <= len) return 0;
		msgLen = len - 3;
		buf[0] = eSSU2BlkFirstFragment;
		htobe16buf (buf + 1, msgLen); // size
		memcpy (buf + 3, msgBuf, msgLen);
		msg->offset = (msgBuf - msg->buf) + msgLen;
		return msgLen + 3;
	}

	size_t SSU2Session::CreateFollowOnFragmentBlock (uint8_t * buf, size_t len, std::shared_ptr<I2NPMessage> msg, uint8_t& fragmentNum, uint32_t msgID)
	{
		if (len < 8) return 0;
		bool isLast = true;
		auto msgLen = msg->len - msg->offset;
		if (msgLen + 8 > len)
		{
			msgLen = len - 8;
			isLast = false;
		}
		buf[0] = eSSU2BlkFollowOnFragment;
		htobe16buf (buf + 1, msgLen + 5); // size
		fragmentNum++;
		buf[3] = fragmentNum << 1;
		if (isLast) buf[3] |= 0x01;
		memcpy (buf + 4, &msgID, 4);
		memcpy (buf + 8, msg->buf + msg->offset, msgLen);
		msg->offset += msgLen;
		return msgLen + 8;
	}

	size_t SSU2Session::CreateRelayIntroBlock (uint8_t * buf, size_t len, const uint8_t * introData, size_t introDataLen)
	{
		buf[0] = eSSU2BlkRelayIntro;
		size_t payloadSize = 1/* flag */ + 32/* Alice router hash */ + introDataLen;
		if (payloadSize + 3 > len) return 0;
		htobe16buf (buf + 1, payloadSize); // size
		buf[3] = 0; // flag
		memcpy (buf + 4, GetRemoteIdentity ()->GetIdentHash (), 32); // Alice router hash
		memcpy (buf + 36, introData, introDataLen);
		return payloadSize + 3;
	}

	size_t SSU2Session::CreateRelayResponseBlock (uint8_t * buf, size_t len,
		SSU2RelayResponseCode code, uint32_t nonce, uint64_t token, bool v4)
	{
		buf[0] = eSSU2BlkRelayResponse;
		buf[3] = 0; // flag
		buf[4] = code; // code
		htobe32buf (buf + 5, nonce); // nonce
		htobe32buf (buf + 9, i2p::util::GetSecondsSinceEpoch ()); // timestamp
		buf[13] = 2; // ver
		size_t csz = 0;
		if (code == eSSU2RelayResponseCodeAccept)
		{
			auto addr = i2p::context.GetRouterInfo ().GetSSU2Address (v4);
			if (!addr)
			{
				LogPrint (eLogError, "SSU2: Can't find local address for RelayResponse");
				return 0;
			}
			csz = CreateEndpoint (buf + 15, len - 15, boost::asio::ip::udp::endpoint (addr->host, addr->port));
			if (!csz)
			{
				LogPrint (eLogError, "SSU2: Can't create local endpoint for RelayResponse");
				return 0;
			}
		}
		buf[14] = csz; // csz
		// signature
		size_t signatureLen = i2p::context.GetIdentity ()->GetSignatureLen ();
		if (15 + csz + signatureLen > len)
		{
			LogPrint (eLogError, "SSU2: Buffer for RelayResponse signature is too small ", len);
			return 0;
		}
		SignedData<128> s;
		s.Insert ((const uint8_t *)"RelayAgreementOK", 16); // prologue
		if (code == eSSU2RelayResponseCodeAccept || code >= 64) // Charlie
			s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
		else // Bob's reject
			s.Insert (i2p::context.GetIdentity ()->GetIdentHash (), 32); // bhash
		s.Insert (buf + 5, 10 + csz); // nonce, timestamp, ver, csz and Charlie's endpoint
		s.Sign (i2p::context.GetPrivateKeys (), buf + 15 + csz);
		size_t payloadSize = 12 + csz + signatureLen;
		if (!code)
		{
			if (payloadSize + 11 > len)
			{
				LogPrint (eLogError, "SSU2: Buffer for RelayResponse token is too small ", len);
				return 0;
			}
			memcpy (buf + 3 + payloadSize, &token, 8);
			payloadSize += 8;
		}
		htobe16buf (buf + 1, payloadSize); // size
		return payloadSize + 3;
	}

	size_t SSU2Session::CreatePeerTestBlock (uint8_t * buf, size_t len, uint8_t msg, SSU2PeerTestCode code,
		const uint8_t * routerHash, const uint8_t * signedData, size_t signedDataLen)
	{
		buf[0] = eSSU2BlkPeerTest;
		size_t payloadSize = 3/* msg, code, flag */ + signedDataLen;
		if (routerHash) payloadSize += 32; // router hash
		if (payloadSize + 3 > len) return 0;
		htobe16buf (buf + 1, payloadSize); // size
		buf[3] = msg; // msg
		buf[4] = (uint8_t)code; // code
		buf[5] = 0; //flag
		size_t offset = 6;
		if (routerHash)
		{
			memcpy (buf + offset, routerHash, 32); // router hash
			offset += 32;
		}
		memcpy (buf + offset, signedData, signedDataLen);
		return payloadSize + 3;
	}

	size_t SSU2Session::CreatePeerTestBlock (uint8_t * buf, size_t len, uint32_t nonce)
	{
		auto localAddress = FindLocalAddress ();
		if (!localAddress || !localAddress->port || localAddress->host.is_unspecified () ||
		    localAddress->host.is_v4 () != m_RemoteEndpoint.address ().is_v4 ())
		{
			LogPrint (eLogWarning, "SSU2: Can't find local address for peer test");
			return 0;
		}
		// signed data
		auto ts = i2p::util::GetSecondsSinceEpoch ();
		uint8_t signedData[96];
		signedData[0] = 2; // ver
		htobe32buf (signedData + 1, nonce);
		htobe32buf (signedData + 5, ts);
		size_t asz = CreateEndpoint (signedData + 10, 86, boost::asio::ip::udp::endpoint (localAddress->host, localAddress->port));
		signedData[9] = asz;
		// signature
		SignedData<128> s;
		s.Insert ((const uint8_t *)"PeerTestValidate", 16); // prologue
		s.Insert (GetRemoteIdentity ()->GetIdentHash (), 32); // bhash
		s.Insert (signedData, 10 + asz); // ver, nonce, ts, asz, Alice's endpoint
		s.Sign (i2p::context.GetPrivateKeys (), signedData + 10 + asz);
		return CreatePeerTestBlock (buf, len, 1, eSSU2PeerTestCodeAccept, nullptr,
			signedData, 10 + asz + i2p::context.GetIdentity ()->GetSignatureLen ());
	}

	size_t SSU2Session::CreateTerminationBlock (uint8_t * buf, size_t len)
	{
		buf[0] = eSSU2BlkTermination;
		htobe16buf (buf + 1, 9);
		htobe64buf (buf + 3, m_ReceivePacketNum);
		buf[11] = (uint8_t)m_TerminationReason;
		return 12;
	}

	std::shared_ptr<const i2p::data::RouterInfo> SSU2Session::ExtractRouterInfo (const uint8_t * buf, size_t size)
	{
		if (size < 2) return nullptr;
		// TODO: handle frag
		std::shared_ptr<const i2p::data::RouterInfo> ri;
		if (buf[0] & SSU2_ROUTER_INFO_FLAG_GZIP)
		{
			i2p::data::GzipInflator inflator;
			uint8_t uncompressed[i2p::data::MAX_RI_BUFFER_SIZE];
			size_t uncompressedSize = inflator.Inflate (buf + 2, size - 2, uncompressed, i2p::data::MAX_RI_BUFFER_SIZE);
			if (uncompressedSize && uncompressedSize <= i2p::data::MAX_RI_BUFFER_SIZE)
				ri = std::make_shared<i2p::data::RouterInfo>(uncompressed, uncompressedSize);
			else
				LogPrint (eLogInfo, "SSU2: RouterInfo decompression failed ", uncompressedSize);
		}
		else if (size <= i2p::data::MAX_RI_BUFFER_SIZE + 2)
			ri = std::make_shared<i2p::data::RouterInfo>(buf + 2, size - 2);
		else
			LogPrint (eLogInfo, "SSU2: RouterInfo is too long ", size);
		return ri;
	}

	bool SSU2Session::UpdateReceivePacketNum (uint32_t packetNum)
	{
		if (packetNum <= m_ReceivePacketNum) return false; // duplicate
		if (packetNum == m_ReceivePacketNum + 1)
		{
			if (!m_OutOfSequencePackets.empty ())
			{
				auto it = m_OutOfSequencePackets.begin ();
				if (*it == packetNum + 1)
				{
					// first out of sequence packet is in sequence now
					packetNum++; it++;
					while (it != m_OutOfSequencePackets.end ())
					{
						if (*it == packetNum + 1)
						{
							packetNum++;
							it++;
						}
						else // next out of sequence
							break;
					}
					m_OutOfSequencePackets.erase (m_OutOfSequencePackets.begin (), it);
				}
				m_NumRanges = 0; // recalculate ranges when create next Ack
			}
			m_ReceivePacketNum = packetNum;
		}
		else
		{
			if (m_NumRanges && (m_OutOfSequencePackets.empty () ||
				packetNum != (*m_OutOfSequencePackets.rbegin ()) + 1))
				m_NumRanges = 0; // reset ranges if received packet is not next
			m_OutOfSequencePackets.insert (packetNum);
		}	
		return true;
	}

	void SSU2Session::SendQuickAck ()
	{
		uint8_t payload[SSU2_MAX_PACKET_SIZE];
		size_t payloadSize = 0;
		if (m_SendPacketNum > m_LastDatetimeSentPacketNum + SSU2_SEND_DATETIME_NUM_PACKETS)
		{
			payload[0] = eSSU2BlkDateTime;
			htobe16buf (payload + 1, 4);
			htobe32buf (payload + 3, (i2p::util::GetMillisecondsSinceEpoch () + 500)/1000);
			payloadSize += 7;
			m_LastDatetimeSentPacketNum = m_SendPacketNum;
		}
		payloadSize += CreateAckBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		payloadSize += CreatePaddingBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		SendData (payload, payloadSize);
	}

	void SSU2Session::SendTermination ()
	{
		uint8_t payload[32];
		size_t payloadSize = CreateTerminationBlock (payload, 32);
		payloadSize += CreatePaddingBlock (payload + payloadSize, 32 - payloadSize);
		SendData (payload, payloadSize);
	}

	void SSU2Session::SendPathResponse (const uint8_t * data, size_t len)
	{
		uint8_t payload[SSU2_MAX_PACKET_SIZE];
		size_t payloadSize = 0;
		// datetime block
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (i2p::util::GetMillisecondsSinceEpoch () + 500)/1000);
		payloadSize += 7;
		// address block 
		payloadSize += CreateAddressBlock (payload + payloadSize, m_MaxPayloadSize  - payloadSize, m_RemoteEndpoint);
		// path response
		if (payloadSize + len > m_MaxPayloadSize)
		{
			LogPrint (eLogWarning, "SSU2: Incorrect data size for path response ", len);
			return;
		}	
		payload[payloadSize] = eSSU2BlkPathResponse;
		htobe16buf (payload + payloadSize + 1, len);
		memcpy (payload + payloadSize + 3, data, len);
		payloadSize += len + 3;	
		// ack block
		if (payloadSize < m_MaxPayloadSize)
			payloadSize += CreateAckBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		// padding
		if (payloadSize < m_MaxPayloadSize)
			payloadSize += CreatePaddingBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		SendData (payload, payloadSize);
	}

	void SSU2Session::SendPathChallenge (const boost::asio::ip::udp::endpoint& to)
	{
		AdjustMaxPayloadSize (SSU2_MIN_PACKET_SIZE); // reduce to minimum 
		m_WindowSize = SSU2_MIN_WINDOW_SIZE; // reduce window to minimum
		
		uint8_t payload[SSU2_MAX_PACKET_SIZE];
		size_t payloadSize = 0;
		// datetime block
		payload[0] = eSSU2BlkDateTime;
		htobe16buf (payload + 1, 4);
		htobe32buf (payload + 3, (i2p::util::GetMillisecondsSinceEpoch () + 500)/1000);
		payloadSize += 7;
		// address block with new address
		payloadSize += CreateAddressBlock (payload + payloadSize, m_MaxPayloadSize  - payloadSize, to);
		// path challenge block
		payload[payloadSize] = eSSU2BlkPathChallenge;
		uint64_t challenge;
		RAND_bytes ((uint8_t *)&challenge, 8);		
		htobe16buf (payload + payloadSize + 1, 8); // always 8 bytes
		htobuf64 (payload + payloadSize + 3, challenge);
		payloadSize += 11;
		m_PathChallenge = std::make_unique<std::pair<uint64_t, boost::asio::ip::udp::endpoint> >(challenge, to);	
		// ack block
		if (payloadSize < m_MaxPayloadSize)
			payloadSize += CreateAckBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		// padding block
		if (payloadSize < m_MaxPayloadSize)
			payloadSize += CreatePaddingBlock (payload + payloadSize, m_MaxPayloadSize - payloadSize);
		// send to new endpoint
		auto existing = m_RemoteEndpoint;
		m_RemoteEndpoint = to; // send path challenge to new endpoint
		SendData (payload, payloadSize);
		m_RemoteEndpoint = existing; // restore endpoint back until path response received
	}

	void SSU2Session::CleanUp (uint64_t ts)
	{
		for (auto it = m_IncompleteMessages.begin (); it != m_IncompleteMessages.end ();)
		{
			if (ts > it->second->lastFragmentInsertTime + SSU2_INCOMPLETE_MESSAGES_CLEANUP_TIMEOUT)
			{
				LogPrint (eLogWarning, "SSU2: message ", it->first, " was not completed in ", SSU2_INCOMPLETE_MESSAGES_CLEANUP_TIMEOUT, " seconds, deleted");
				it = m_IncompleteMessages.erase (it);
			}
			else
				++it;
		}
		if (m_ReceivedI2NPMsgIDs.size () > SSU2_MAX_NUM_RECEIVED_I2NP_MSGIDS || ts > GetLastActivityTimestamp () + SSU2_DECAY_INTERVAL)
			// decay
			m_ReceivedI2NPMsgIDs.clear ();
		else
		{
			// delete old received msgIDs
			for (auto it = m_ReceivedI2NPMsgIDs.begin (); it != m_ReceivedI2NPMsgIDs.end ();)
			{
				if (ts > it->second + SSU2_RECEIVED_I2NP_MSGIDS_CLEANUP_TIMEOUT)
					it = m_ReceivedI2NPMsgIDs.erase (it);
				else
					++it;
			}
		}
		if (!m_OutOfSequencePackets.empty ())
		{
			int ranges = 0;
			while (ranges < 8 && !m_OutOfSequencePackets.empty () &&
				(m_OutOfSequencePackets.size () > 2*SSU2_MAX_NUM_ACK_RANGES ||
			    *m_OutOfSequencePackets.rbegin () > m_ReceivePacketNum + SSU2_MAX_NUM_ACK_PACKETS))
			{
				uint32_t packet = *m_OutOfSequencePackets.begin ();
				if (packet > m_ReceivePacketNum + 1)
				{
					// like we've just received all packets before first
					packet--;
					m_ReceivePacketNum = packet - 1;
					UpdateReceivePacketNum (packet);
					ranges++;
				}
				else
				{
					LogPrint (eLogError, "SSU2: Out of sequence packet ", packet, " is less than last received ", m_ReceivePacketNum);
					break;
				}
			}
			if (m_OutOfSequencePackets.size () > 255*4)
			{
				// seems we have a serious network issue
				m_ReceivePacketNum = *m_OutOfSequencePackets.rbegin ();
				m_OutOfSequencePackets.clear ();
			}
		}

		for (auto it = m_RelaySessions.begin (); it != m_RelaySessions.end ();)
		{
			if (ts > it->second.second + SSU2_RELAY_NONCE_EXPIRATION_TIMEOUT)
			{
				LogPrint (eLogInfo, "SSU2: Relay nonce ", it->first, " was not responded in ", SSU2_RELAY_NONCE_EXPIRATION_TIMEOUT, " seconds, deleted");
				it = m_RelaySessions.erase (it);
			}
			else
				++it;
		}
		if (m_PathChallenge)
			RequestTermination (eSSU2TerminationReasonNormalClose);
	}

	void SSU2Session::FlushData ()
	{
		bool sent = SendQueue (); // if we have something to send
		if (sent)
			SetSendQueueSize (m_SendQueue.size ());
		if (m_IsDataReceived)
		{
			if (!sent) SendQuickAck ();
			m_Handler.Flush ();
			m_IsDataReceived = false;
		}
		else if (!sent && !m_SentPackets.empty ()) // if only acks received, nothing sent and we still have something to resend
			Resend (i2p::util::GetMillisecondsSinceEpoch ()); // than right time to resend
	}

	i2p::data::RouterInfo::SupportedTransports SSU2Session::GetTransportType () const
	{
		return m_RemoteEndpoint.address ().is_v4 () ? i2p::data::RouterInfo::eSSU2V4 : i2p::data::RouterInfo::eSSU2V6;
	}	
}
}