#include "protocol.h"

#include <sys/socket.h>
#include <unistd.h>

#include <algorithm>
#include <cstring>
#include <iostream>
#include <mutex>
#include <system_error>

using std::get_if;
using std::holds_alternative;
using std::move;
using std::nullopt;
using std::runtime_error;
using std::scoped_lock;
using std::to_string;
using std::visit;

namespace erebos {

struct NetworkProtocol::ConnectionPriv
{
	Connection::Id id() const;

	bool send(const PartialStorage &, Header,
			const vector<Object> &, bool secure);
	bool send( const StreamData & chunk );

	NetworkProtocol * protocol;
	const sockaddr_in6 peerAddress;

	mutex cmutex {};
	vector<uint8_t> buffer {};

	optional<Cookie> receivedCookie = nullopt;
	bool confirmedCookie = false;
	ChannelState channel = monostate();
	vector<vector<uint8_t>> secureOutQueue {};

	size_t mtu = 500; // TODO: MTU

	vector<uint64_t> toAcknowledge {};

	vector< shared_ptr< InStream >> inStreams {};
	vector< shared_ptr< OutStream >> outStreams {};
};


NetworkProtocol::NetworkProtocol():
	sock(-1)
{}

NetworkProtocol::NetworkProtocol(int s, Identity id):
	sock(s),
	self(move(id))
{}

NetworkProtocol::NetworkProtocol(NetworkProtocol && other):
	sock(other.sock),
	self(move(other.self))
{
	other.sock = -1;
}

NetworkProtocol & NetworkProtocol::operator=(NetworkProtocol && other)
{
	sock = other.sock;
	other.sock = -1;
	self = move(other.self);
	return *this;
}

NetworkProtocol::~NetworkProtocol()
{
	if (sock >= 0)
		close(sock);

	for (auto & c : connections)
		c->protocol = nullptr;
}

NetworkProtocol::PollResult NetworkProtocol::poll()
{
	{
		scoped_lock lock(protocolMutex);

		for (const auto & c : connections) {
			vector< StreamData > streamChunks;
			bool sendAck = false;
			{
				scoped_lock clock(c->cmutex);
				sendAck = not c->toAcknowledge.empty() &&
					holds_alternative< unique_ptr< Channel >>( c->channel );

				for (const auto & s : c->outStreams) {
					scoped_lock slock(s->streamMutex);
					while (s->hasDataLocked())
						streamChunks.push_back( s->getNextChunkLocked( c->mtu ) );
				}
			}
			if (sendAck) {
				auto pst = self->ref()->storage().deriveEphemeralStorage();
				c->send(pst, Header {{}}, {}, true);
			}
			for (const auto & chunk : streamChunks) {
				c->send( chunk );
			}
		}
	}

	sockaddr_in6 addr;
	if (!recvfrom(buffer, addr))
		return ProtocolClosed {};

	{
		scoped_lock lock(protocolMutex);

		for (const auto & c : connections) {
			if (memcmp(&c->peerAddress, &addr, sizeof addr) == 0) {
				scoped_lock clock(c->cmutex);
				buffer.swap(c->buffer);
				return ConnectionReadReady { c->id() };
			}
		}

		auto pst = self->ref()->storage().deriveEphemeralStorage();
		optional<uint64_t> secure = false;
		auto parsed = Connection::parsePacket(buffer, nullptr, pst, secure);
		if (const auto * header = get_if< Header >( &parsed )) {
			if (auto conn = verifyNewConnection(*header, addr))
				return NewConnection { move(*conn) };

			if (auto ann = header->lookupFirst<Header::AnnounceSelf>())
				return ReceivedAnnounce { addr, ann->value };
		}
	}

	return poll();
}

NetworkProtocol::Connection NetworkProtocol::connect(sockaddr_in6 addr)
{
	auto conn = unique_ptr<ConnectionPriv>(new ConnectionPriv {
		.protocol = this,
		.peerAddress = addr,
	});

	{
		scoped_lock lock(protocolMutex);
		connections.push_back(conn.get());

		vector<Header::Item> header {
			Header::Initiation { Digest::of(Object(Record())) },
			Header::AnnounceSelf { self->ref()->digest() },
			Header::Version { defaultVersion },
		};
		conn->send(self->ref()->storage(), move(header), {}, false);
	}

	return Connection(move(conn));
}

void NetworkProtocol::updateIdentity(Identity id)
{
	scoped_lock lock(protocolMutex);
	self = move(id);

	vector<Header::Item> hitems;
	for (const auto & r : self->extRefs())
		hitems.push_back(Header::AnnounceUpdate { r.digest() });
	for (const auto & r : self->updates())
		hitems.push_back(Header::AnnounceUpdate { r.digest() });

	Header header(hitems);

	for (const auto & conn : connections)
		conn->send(self->ref()->storage(), header, { **self->ref() }, false);
}

void NetworkProtocol::announceTo(variant<sockaddr_in, sockaddr_in6> addr)
{
	vector<uint8_t> bytes;
	{
		scoped_lock lock(protocolMutex);

		if (!self)
			throw runtime_error("NetworkProtocol::announceTo without self identity");

		bytes = Header({
			Header::AnnounceSelf { self->ref()->digest() },
			Header::Version { defaultVersion },
		}).toObject(self->ref()->storage()).encode();
	}

	sendto(bytes, addr);
}

void NetworkProtocol::shutdown()
{
	::shutdown(sock, SHUT_RDWR);
}

bool NetworkProtocol::recvfrom(vector<uint8_t> & buffer, sockaddr_in6 & addr)
{
	socklen_t addrlen = sizeof(addr);
	buffer.resize(4096);
	ssize_t ret = ::recvfrom(sock, buffer.data(), buffer.size(), 0,
			(sockaddr *) &addr, &addrlen);
	if (ret < 0)
		throw std::system_error(errno, std::generic_category());
	if (ret == 0)
		return false;

	buffer.resize(ret);
	return true;
}

void NetworkProtocol::sendto(const vector<uint8_t> & buffer, variant<sockaddr_in, sockaddr_in6> vaddr)
{
	visit([&](auto && addr) {
		::sendto(sock, buffer.data(), buffer.size(), 0,
				(sockaddr *) &addr, sizeof(addr));
	}, vaddr);
}

void NetworkProtocol::sendCookie(variant<sockaddr_in, sockaddr_in6> addr)
{
	auto bytes = Header({
		Header::CookieSet { generateCookie(addr) },
		Header::AnnounceSelf { self->ref()->digest() },
		Header::Version { defaultVersion },
	}).toObject(self->ref()->storage()).encode();

	sendto(bytes, addr);
}

optional<NetworkProtocol::Connection> NetworkProtocol::verifyNewConnection(const Header & header, sockaddr_in6 addr)
{
	optional<string> version;
	for (const auto & h : header.items) {
		if (const auto * ptr = get_if<Header::Version>(&h)) {
			if (ptr->value == defaultVersion) {
				version = ptr->value;
				break;
			}
		}
	}
	if (!version)
		return nullopt;

	if (header.lookupFirst<Header::Initiation>()) {
		sendCookie(addr);
	}

	else if (auto cookie = header.lookupFirst<Header::CookieEcho>()) {
		if (verifyCookie(addr, cookie->value)) {
			auto conn = unique_ptr<ConnectionPriv>(new ConnectionPriv {
				.protocol = this,
				.peerAddress = addr,
			});

			connections.push_back(conn.get());
			buffer.swap(conn->buffer);
			return Connection(move(conn));
		}
	}

	return nullopt;
}

NetworkProtocol::Cookie NetworkProtocol::generateCookie(variant<sockaddr_in, sockaddr_in6> vaddr) const
{
	vector<uint8_t> cookie;
	visit([&](auto && addr) {
		cookie.resize(sizeof addr);
		memcpy(cookie.data(), &addr, sizeof addr);
	}, vaddr);
	return Cookie { cookie };
}

bool NetworkProtocol::verifyCookie(variant<sockaddr_in, sockaddr_in6> vaddr, const NetworkProtocol::Cookie & cookie) const
{
	return visit([&](auto && addr) {
		if (cookie.value.size() != sizeof addr)
			return false;
		return memcmp(cookie.value.data(), &addr, sizeof addr) == 0;
	}, vaddr);
}

/******************************************************************************/
/* Connection                                                                 */
/******************************************************************************/

NetworkProtocol::Connection::Id NetworkProtocol::ConnectionPriv::id() const
{
	return reinterpret_cast<uintptr_t>(this);
}

NetworkProtocol::Connection::Connection(unique_ptr<ConnectionPriv> p_):
	p(move(p_))
{
}

NetworkProtocol::Connection::Connection(Connection && other):
	p(move(other.p))
{
}

NetworkProtocol::Connection & NetworkProtocol::Connection::operator=(Connection && other)
{
	close();
	p = move(other.p);
	return *this;
}

NetworkProtocol::Connection::~Connection()
{
	close();
}

NetworkProtocol::Connection::Id NetworkProtocol::Connection::id() const
{
	return p->id();
}

const sockaddr_in6 & NetworkProtocol::Connection::peerAddress() const
{
	return p->peerAddress;
}

optional<NetworkProtocol::Header> NetworkProtocol::Connection::receive(const PartialStorage & partStorage)
{
	vector<uint8_t> buf;

	Channel * channel = nullptr;
	unique_ptr<Channel> channelPtr;

	{
		scoped_lock lock(p->cmutex);

		if (p->buffer.empty())
			return nullopt;
		buf.swap(p->buffer);

		if (holds_alternative<unique_ptr<Channel>>(p->channel)) {
			channel = std::get<unique_ptr<Channel>>(p->channel).get();
		} else if (holds_alternative<Stored<ChannelAccept>>(p->channel)) {
			channelPtr = std::get<Stored<ChannelAccept>>(p->channel)->data->channel();
			channel = channelPtr.get();
		}
	}

	optional<uint64_t> secure = false;
	auto parsed = parsePacket(buf, channel, partStorage, secure);
	if (const auto * header = get_if< Header >( &parsed )) {
		scoped_lock lock(p->cmutex);

		if (secure) {
			if (header->isAcknowledged())
				p->toAcknowledge.push_back(*secure);
			return *header;
		}

		if (const auto * cookieEcho = header->lookupFirst<Header::CookieEcho>()) {
			if (!p->protocol->verifyCookie(p->peerAddress, cookieEcho->value))
				return nullopt;

			p->confirmedCookie = true;

			if (const auto * cookieSet = header->lookupFirst<Header::CookieSet>())
				p->receivedCookie = cookieSet->value;

			return *header;
		}

		if (holds_alternative<monostate>(p->channel)) {
			if (const auto * cookieSet = header->lookupFirst<Header::CookieSet>()) {
				p->receivedCookie = cookieSet->value;
				return *header;
			}
		}

		if (header->lookupFirst<Header::Initiation>()) {
			p->protocol->sendCookie(p->peerAddress);
			return nullopt;
		}
	}
	else if (const auto * sdata = get_if< StreamData >( &parsed )) {
		scoped_lock lock(p->cmutex);
		if (secure)
			p->toAcknowledge.push_back(*secure);

		InStream * stream = nullptr;
		for (const auto & s : p->inStreams) {
			if (s->id == sdata->id) {
				stream = s.get();
				break;
			}
		}
		if (not stream) {
			std::cerr << "unexpected stream number\n";
			return nullopt;
		}

		stream->writeChunk( move(*sdata) );
		if( stream->closed )
			p->inStreams.erase(
					std::remove_if( p->inStreams.begin(), p->inStreams.end(),
						[&]( auto & sptr ) { return sptr.get() == stream; } ),
					p->inStreams.end() );
		return nullopt;
	}
	return nullopt;
}

variant< monostate, NetworkProtocol::Header, NetworkProtocol::StreamData >
NetworkProtocol::Connection::parsePacket(vector<uint8_t> & buf,
		Channel * channel, const PartialStorage & partStorage,
		optional<uint64_t> & secure)
{
	vector<uint8_t> decrypted;
	auto plainBegin = buf.cbegin();
	auto plainEnd = buf.cbegin();

	secure = nullopt;

	if ((buf[0] & 0xE0) == 0x80) {
		if (not channel) {
			std::cerr << "unexpected encrypted packet\n";
			return monostate();
		}

		if ((secure = channel->decrypt(buf.begin() + 1, buf.end(), decrypted, 0))) {
			if (decrypted.empty()) {
				std::cerr << "empty decrypted content\n";
			}
			else if (decrypted[0] == 0x00) {
				plainBegin = decrypted.begin() + 1;
				plainEnd = decrypted.end();
			}
			else if (decrypted[0] < 0x40) {
				StreamData sdata;
				sdata.id = decrypted[0];
				sdata.sequence = decrypted[1];
				sdata.data.resize( decrypted.size() - 2 );
				std::copy(decrypted.begin() + 2, decrypted.end(), sdata.data.begin());
				return sdata;
			}
			else {
				std::cerr << "unexpected stream header\n";
				return monostate();
			}
		}
	}
	else if ((buf[0] & 0xE0) == 0x60) {
		plainBegin = buf.begin();
		plainEnd = buf.end();
	}

	if (auto dec = PartialObject::decodePrefix(partStorage, plainBegin, plainEnd)) {
		if (auto header = Header::load(std::get<PartialObject>(*dec))) {
			auto pos = std::get<1>(*dec);
			while (auto cdec = PartialObject::decodePrefix(partStorage, pos, plainEnd)) {
				partStorage.storeObject(std::get<PartialObject>(*cdec));
				pos = std::get<1>(*cdec);
			}

			return *header;
		}
	}

	std::cerr << "invalid packet\n";
	return monostate();
}

bool NetworkProtocol::Connection::send(const PartialStorage & partStorage,
		Header header,
		const vector<Object> & objs, bool secure)
{
	return p->send(partStorage, move(header), objs, secure);
}

bool NetworkProtocol::ConnectionPriv::send(const PartialStorage & partStorage,
		Header header,
		const vector<Object> & objs, bool secure)
{
	vector<uint8_t> data, part, out;

	{
		scoped_lock clock(cmutex);

		Channel * channel = nullptr;
		if (auto uptr = get_if<unique_ptr<Channel>>(&this->channel))
			channel = uptr->get();

		if (channel || secure) {
			data.push_back(0x00);
		} else {
			if (receivedCookie)
				header.items.push_back(Header::CookieEcho { receivedCookie->value });
			if (!confirmedCookie)
				header.items.push_back(Header::CookieSet { protocol->generateCookie(peerAddress) });
		}

		if (channel) {
			for (auto num : toAcknowledge)
				header.items.push_back(Header::AcknowledgedSingle { num });
			toAcknowledge.clear();
		}

		if (header.items.empty())
			return false;

		part = header.toObject(partStorage).encode();
		data.insert(data.end(), part.begin(), part.end());
		for (const auto & obj : objs) {
			part = obj.encode();
			data.insert(data.end(), part.begin(), part.end());
		}

		if (channel) {
			out.push_back(0x80);
			channel->encrypt(data.begin(), data.end(), out, 1);
		} else if (secure) {
			secureOutQueue.emplace_back(move(data));
		} else {
			out = std::move(data);
		}
	}

	if (not out.empty())
		protocol->sendto(out, peerAddress);

	return true;
}

bool NetworkProtocol::Connection::send( const StreamData & chunk )
{
	return p->send( chunk );
}

bool NetworkProtocol::ConnectionPriv::send( const StreamData & chunk )
{
	vector<uint8_t> data, out;

	{
		scoped_lock clock( cmutex );

		Channel * channel = nullptr;
		if (auto uptr = get_if< unique_ptr< Channel >>( &this->channel ))
			channel = uptr->get();
		if (not channel)
			return false;

		data.push_back( chunk.id );
		data.push_back( static_cast< uint8_t >( chunk.sequence ));
		data.insert( data.end(), chunk.data.begin(), chunk.data.end() );

		out.push_back( 0x80 );
		channel->encrypt( data.begin(), data.end(), out, 1 );
	}

	protocol->sendto( out, peerAddress );
	return true;
}


void NetworkProtocol::Connection::close()
{
	if (not p)
		return;

	if (p->protocol) {
		scoped_lock lock(p->protocol->protocolMutex);
		for (auto it = p->protocol->connections.begin();
				it != p->protocol->connections.end(); it++) {
			if ((*it) == p.get()) {
				p->protocol->connections.erase(it);
				break;
			}
		}
	}

	p = nullptr;
}

shared_ptr< NetworkProtocol::InStream > NetworkProtocol::Connection::openInStream( uint8_t sid )
{
	scoped_lock lock( p->cmutex );
	for (const auto & s : p->inStreams)
		if (s->id == sid)
			throw runtime_error("inbound stream " + to_string(sid) + " already open");

	p->inStreams.emplace_back( new InStream( sid ));
	return p->inStreams.back();
}

shared_ptr< NetworkProtocol::OutStream > NetworkProtocol::Connection::openOutStream( uint8_t sid )
{
	scoped_lock lock( p->cmutex );
	for (const auto & s : p->outStreams)
		if (s->id == sid)
			throw runtime_error("outbound stream " + to_string(sid) + " already open");

	p->outStreams.emplace_back( new OutStream( sid ));
	return p->outStreams.back();
}

NetworkProtocol::ChannelState & NetworkProtocol::Connection::channel()
{
	return p->channel;
}

void NetworkProtocol::Connection::trySendOutQueue()
{
	decltype(p->secureOutQueue) queue;
	{
		scoped_lock clock(p->cmutex);

		if (p->secureOutQueue.empty())
			return;

		if (not holds_alternative<unique_ptr<Channel>>(p->channel))
			return;

		queue.swap(p->secureOutQueue);
	}

	vector<uint8_t> out { 0x80 };
	for (const auto & data : queue) {
		std::get<unique_ptr<Channel>>(p->channel)->encrypt(data.begin(), data.end(), out, 1);
		p->protocol->sendto(out, p->peerAddress);
	}
}


bool NetworkProtocol::Stream::hasDataLocked() const
{
	return not writeBuffer.empty() || not readBuffer.empty();
}

size_t NetworkProtocol::Stream::writeLocked( const uint8_t * buf, size_t size )
{
	writeBuffer.insert( writeBuffer.end(), buf, buf + size );
	return size;
}

size_t NetworkProtocol::Stream::readLocked( uint8_t * buf, size_t size )
{
	size_t res = 0;
	if (readPtr < readBuffer.end()) {
		res = std::min( size, static_cast< size_t >( readBuffer.end() - readPtr ));
		std::copy_n( readPtr, res, buf );
		readPtr += res;
	}
	if (res < size && not writeBuffer.empty()) {
		std::swap( readBuffer, writeBuffer );
		readPtr = readBuffer.begin();
		writeBuffer.clear();
		return res + readLocked( buf + res, size - res );
	}
	return res;
}

bool NetworkProtocol::InStream::isComplete() const
{
	scoped_lock lock( streamMutex );
	return closed && outOfOrderChunks.empty();
}

vector< uint8_t > NetworkProtocol::InStream::readAll()
{
	scoped_lock lock( streamMutex );
	if (readBuffer.empty()) {
		vector< uint8_t > res;
		std::swap( res, writeBuffer );
		return res;
	}

	readBuffer.insert( readBuffer.end(), writeBuffer.begin(), writeBuffer.end() );
	writeBuffer.clear();

	vector< uint8_t > res;
	std::swap( res, readBuffer );
	readPtr = readBuffer.begin();
	return res;
}

size_t NetworkProtocol::InStream::read( uint8_t * buf, size_t size )
{
	scoped_lock lock( streamMutex );
	return readLocked( buf, size );
}

void NetworkProtocol::InStream::writeChunk( StreamData chunk )
{
	scoped_lock lock( streamMutex );
	if( tryUseChunkLocked( chunk )) {
		auto it = outOfOrderChunks.begin();
		while( it != outOfOrderChunks.end() && tryUseChunkLocked( *it ))
			it++;
		outOfOrderChunks.erase( outOfOrderChunks.begin(), it );
	} else {
		auto it = outOfOrderChunks.begin();
		while( it < outOfOrderChunks.end() &&
				it->sequence - static_cast< uint8_t >( nextSequence )
				< chunk.sequence - static_cast< uint8_t >( nextSequence ))
			it++;
		outOfOrderChunks.insert( it, move(chunk) );
	}
}

bool NetworkProtocol::InStream::tryUseChunkLocked( const StreamData & chunk )
{
	if( chunk.sequence != static_cast< uint8_t >( nextSequence ))
		return false;

	if( chunk.data.empty() )
		closed = true;
	else
		writeLocked( chunk.data.data(), chunk.data.size() );
	nextSequence++;
	return true;
}

NetworkProtocol::StreamData NetworkProtocol::OutStream::getNextChunkLocked( size_t size )
{
	StreamData res;
	res.id = id;
	res.sequence = nextSequence++,

	res.data.resize( size );
	size = readLocked( res.data.data(), size );
	res.data.resize( size );

	return res;
}


/******************************************************************************/
/* Header                                                                     */
/******************************************************************************/

bool operator==(const NetworkProtocol::Header::Item & left,
		const NetworkProtocol::Header::Item & right)
{
	if (left.index() != right.index())
		return false;

	return visit([&](auto && arg) {
            using T = std::decay_t<decltype(arg)>;
	    return arg.value == std::get<T>(right).value;
	}, left);
}

optional<NetworkProtocol::Header> NetworkProtocol::Header::load(const PartialRef & ref)
{
	return load(*ref);
}

optional<NetworkProtocol::Header> NetworkProtocol::Header::load(const PartialObject & obj)
{
	auto rec = obj.asRecord();
	if (!rec)
		return nullopt;

	vector<Item> items;
	for (const auto & item : rec->items()) {
		if (item.name == "ACK") {
			if (auto ref = item.asRef())
				items.emplace_back(Acknowledged { ref->digest() });
			else if (auto num = item.asInteger())
				items.emplace_back(AcknowledgedSingle { static_cast<uint64_t>(*num) });
		} else if (item.name == "VER") {
			if (auto ver = item.asText())
				items.emplace_back(Version { *ver });
		} else if (item.name == "INI") {
			if (auto ref = item.asRef())
				items.emplace_back(Initiation { ref->digest() });
		} else if (item.name == "CKS") {
			if (auto cookie = item.asBinary())
				items.emplace_back(CookieSet { *cookie });
		} else if (item.name == "CKE") {
			if (auto cookie = item.asBinary())
				items.emplace_back(CookieEcho { *cookie });
		} else if (item.name == "REQ") {
			if (auto ref = item.asRef())
				items.emplace_back(DataRequest { ref->digest() });
		} else if (item.name == "RSP") {
			if (auto ref = item.asRef())
				items.emplace_back(DataResponse { ref->digest() });
		} else if (item.name == "ANN") {
			if (auto ref = item.asRef())
				items.emplace_back(AnnounceSelf { ref->digest() });
		} else if (item.name == "ANU") {
			if (auto ref = item.asRef())
				items.emplace_back(AnnounceUpdate { ref->digest() });
		} else if (item.name == "CRQ") {
			if (auto ref = item.asRef())
				items.emplace_back(ChannelRequest { ref->digest() });
		} else if (item.name == "CAC") {
			if (auto ref = item.asRef())
				items.emplace_back(ChannelAccept { ref->digest() });
		} else if (item.name == "SVT") {
			if (auto val = item.asUUID())
				items.emplace_back(ServiceType { *val });
		} else if (item.name == "SVR") {
			if (auto ref = item.asRef())
				items.emplace_back(ServiceRef { ref->digest() });
		} else if (item.name == "STO") {
			if (auto num = item.asInteger())
				items.emplace_back( StreamOpen{ static_cast< uint8_t >( *num )});
		}
	}

	return NetworkProtocol::Header(items);
}

PartialObject NetworkProtocol::Header::toObject(const PartialStorage & st) const
{
	vector<PartialRecord::Item> ritems;

	for (const auto & item : items) {
		if (const auto * ptr = get_if<Acknowledged>(&item))
			ritems.emplace_back("ACK", st.ref(ptr->value));

		else if (const auto * ptr = get_if<AcknowledgedSingle>(&item))
			ritems.emplace_back("ACK", Record::Item::Integer(ptr->value));

		else if (const auto * ptr = get_if<Version>(&item))
			ritems.emplace_back("VER", ptr->value);

		else if (const auto * ptr = get_if<Initiation>(&item))
			ritems.emplace_back("INI", st.ref(ptr->value));

		else if (const auto * ptr = get_if<CookieSet>(&item))
			ritems.emplace_back("CKS", ptr->value.value);

		else if (const auto * ptr = get_if<CookieEcho>(&item))
			ritems.emplace_back("CKE", ptr->value.value);

		else if (const auto * ptr = get_if<DataRequest>(&item))
			ritems.emplace_back("REQ", st.ref(ptr->value));

		else if (const auto * ptr = get_if<DataResponse>(&item))
			ritems.emplace_back("RSP", st.ref(ptr->value));

		else if (const auto * ptr = get_if<AnnounceSelf>(&item))
			ritems.emplace_back("ANN", st.ref(ptr->value));

		else if (const auto * ptr = get_if<AnnounceUpdate>(&item))
			ritems.emplace_back("ANU", st.ref(ptr->value));

		else if (const auto * ptr = get_if<ChannelRequest>(&item))
			ritems.emplace_back("CRQ", st.ref(ptr->value));

		else if (const auto * ptr = get_if<ChannelAccept>(&item))
			ritems.emplace_back("CAC", st.ref(ptr->value));

		else if (const auto * ptr = get_if<ServiceType>(&item))
			ritems.emplace_back("SVT", ptr->value);

		else if (const auto * ptr = get_if<ServiceRef>(&item))
			ritems.emplace_back("SVR", st.ref(ptr->value));

		else if (const auto * ptr = get_if< StreamOpen >( &item ))
			ritems.emplace_back("STO", Record::Item::Integer( ptr->value ));
	}

	return PartialObject(PartialRecord(std::move(ritems)));
}

bool NetworkProtocol::Header::isAcknowledged() const
{
	for (const auto & item : items) {
		if (holds_alternative<Acknowledged>(item)
		 || holds_alternative<AcknowledgedSingle>(item)
		 || holds_alternative<Version>(item)
		 || holds_alternative<Initiation>(item)
		 || holds_alternative<CookieSet>(item)
		 || holds_alternative<CookieEcho>(item)
		   )
			continue;

		return true;
	}
	return false;
}

}