Files @ r25849:38205b3e59c6
Branch filter:

Location: cpp/openttd-patchpack/source/src/network/network_coordinator.cpp

Patric Stout
Feature: allow the use of TURN to connect client and server together

TURN is a last resort, used only if all other methods failed.
TURN is a relay approach to connect client and server together, where
openttd.org (by default) is the middleman.

It is very unlikely either the client or server cannot connect to
the STUN server, as they are both already connected to the Game
Coordinator. But in the odd case it does fail, estabilishing the
connection fails without any further possibility to recover.
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/*
 * This file is part of OpenTTD.
 * OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
 * OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
 * See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see <http://www.gnu.org/licenses/>.
 */

/** @file network_coordinator.cpp Game Coordinator sending/receiving part of the network protocol. */

#include "../stdafx.h"
#include "../debug.h"
#include "../error.h"
#include "../rev.h"
#include "../settings_type.h"
#include "../strings_func.h"
#include "../window_func.h"
#include "../window_type.h"
#include "network.h"
#include "network_coordinator.h"
#include "network_gamelist.h"
#include "network_gui.h"
#include "network_internal.h"
#include "network_server.h"
#include "network_stun.h"
#include "table/strings.h"

#include "../safeguards.h"

static const auto NETWORK_COORDINATOR_DELAY_BETWEEN_UPDATES = std::chrono::seconds(30); ///< How many time between updates the server sends to the Game Coordinator.
ClientNetworkCoordinatorSocketHandler _network_coordinator_client; ///< The connection to the Game Coordinator.
ConnectionType _network_server_connection_type = CONNECTION_TYPE_UNKNOWN; ///< What type of connection the Game Coordinator detected we are on.
std::string _network_server_invite_code = ""; ///< Our invite code as indicated by the Game Coordinator.

/** Connect to a game server by IP:port. */
class NetworkDirectConnecter : public TCPConnecter {
private:
	std::string token;     ///< Token of this connection.
	uint8 tracking_number; ///< Tracking number of this connection.

public:
	/**
	 * Try to establish a direct (hostname:port based) connection.
	 * @param hostname The hostname of the server.
	 * @param port The port of the server.
	 * @param token The token as given by the Game Coordinator to track this connection attempt.
	 * @param tracking_number The tracking number as given by the Game Coordinator to track this connection attempt.
	 */
	NetworkDirectConnecter(const std::string &hostname, uint16 port, const std::string &token, uint8 tracking_number) : TCPConnecter(hostname, port), token(token), tracking_number(tracking_number) {}

	void OnFailure() override
	{
		_network_coordinator_client.ConnectFailure(this->token, this->tracking_number);
	}

	void OnConnect(SOCKET s) override
	{
		NetworkAddress address = NetworkAddress::GetPeerAddress(s);
		_network_coordinator_client.ConnectSuccess(this->token, s, address);
	}
};

/** Connecter used after STUN exchange to connect from both sides to each other. */
class NetworkReuseStunConnecter : public TCPConnecter {
private:
	std::string token;     ///< Token of this connection.
	uint8 tracking_number; ///< Tracking number of this connection.
	uint8 family;          ///< Family of this connection.

public:
	/**
	 * Try to establish a STUN-based connection.
	 * @param hostname The hostname of the peer.
	 * @param port The port of the peer.
	 * @param bind_address The local bind address used for this connection.
	 * @param token The connection token.
	 * @param tracking_number The tracking number of the connection.
	 * @param family The family this connection is using.
	 */
	NetworkReuseStunConnecter(const std::string &hostname, uint16 port, const NetworkAddress &bind_address, std::string token, uint8 tracking_number, uint8 family) :
		TCPConnecter(hostname, port, bind_address),
		token(token),
		tracking_number(tracking_number),
		family(family)
	{
	}

	void OnFailure() override
	{
		/* Close the STUN connection too, as it is no longer of use. */
		_network_coordinator_client.CloseStunHandler(this->token, this->family);

		_network_coordinator_client.ConnectFailure(this->token, this->tracking_number);
	}

	void OnConnect(SOCKET s) override
	{
		NetworkAddress address = NetworkAddress::GetPeerAddress(s);
		_network_coordinator_client.ConnectSuccess(this->token, s, address);
	}
};

/** Connect to the Game Coordinator server. */
class NetworkCoordinatorConnecter : TCPConnecter {
public:
	/**
	 * Initiate the connecting.
	 * @param connection_string The address of the Game Coordinator server.
	 */
	NetworkCoordinatorConnecter(const std::string &connection_string) : TCPConnecter(connection_string, NETWORK_COORDINATOR_SERVER_PORT) {}

	void OnFailure() override
	{
		_network_coordinator_client.connecting = false;
		_network_coordinator_client.CloseConnection(true);
	}

	void OnConnect(SOCKET s) override
	{
		assert(_network_coordinator_client.sock == INVALID_SOCKET);

		_network_coordinator_client.sock = s;
		_network_coordinator_client.last_activity = std::chrono::steady_clock::now();
		_network_coordinator_client.connecting = false;
	}
};

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_ERROR(Packet *p)
{
	NetworkCoordinatorErrorType error = (NetworkCoordinatorErrorType)p->Recv_uint8();
	std::string detail = p->Recv_string(NETWORK_ERROR_DETAIL_LENGTH);

	switch (error) {
		case NETWORK_COORDINATOR_ERROR_UNKNOWN:
			this->CloseConnection();
			return false;

		case NETWORK_COORDINATOR_ERROR_REGISTRATION_FAILED:
			SetDParamStr(0, detail);
			ShowErrorMessage(STR_NETWORK_ERROR_COORDINATOR_REGISTRATION_FAILED, STR_JUST_RAW_STRING, WL_ERROR);

			/* To prevent that we constantly try to reconnect, switch to local game. */
			_settings_client.network.server_game_type = SERVER_GAME_TYPE_LOCAL;

			this->CloseConnection();
			return false;

		case NETWORK_COORDINATOR_ERROR_INVALID_INVITE_CODE: {
			auto connecter_pre_it = this->connecter_pre.find(detail);
			if (connecter_pre_it != this->connecter_pre.end()) {
				connecter_pre_it->second->SetFailure();
				this->connecter_pre.erase(connecter_pre_it);
			}

			/* Mark the server as offline. */
			NetworkGameList *item = NetworkGameListAddItem(detail);
			item->online = false;

			UpdateNetworkGameWindow();
			return true;
		}

		default:
			Debug(net, 0, "Invalid error type {} received from Game Coordinator", error);
			this->CloseConnection();
			return false;
	}
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_REGISTER_ACK(Packet *p)
{
	/* Schedule sending an update. */
	this->next_update = std::chrono::steady_clock::now();

	_settings_client.network.server_invite_code = p->Recv_string(NETWORK_INVITE_CODE_LENGTH);
	_settings_client.network.server_invite_code_secret = p->Recv_string(NETWORK_INVITE_CODE_SECRET_LENGTH);
	_network_server_connection_type = (ConnectionType)p->Recv_uint8();

	if (_network_server_connection_type == CONNECTION_TYPE_ISOLATED) {
		ShowErrorMessage(STR_NETWORK_ERROR_COORDINATOR_ISOLATED, STR_NETWORK_ERROR_COORDINATOR_ISOLATED_DETAIL, WL_ERROR);
	}

	/* Users can change the invite code in the settings, but this has no effect
	 * on the invite code as assigned by the server. So
	 * _network_server_invite_code contains the current invite code,
	 * and _settings_client.network.server_invite_code contains the one we will
	 * attempt to re-use when registering again. */
	_network_server_invite_code = _settings_client.network.server_invite_code;

	SetWindowDirty(WC_CLIENT_LIST, 0);

	if (_network_dedicated) {
		std::string connection_type;
		switch (_network_server_connection_type) {
			case CONNECTION_TYPE_ISOLATED: connection_type = "Remote players can't connect"; break;
			case CONNECTION_TYPE_DIRECT:   connection_type = "Public"; break;
			case CONNECTION_TYPE_STUN:     connection_type = "Behind NAT"; break;
			case CONNECTION_TYPE_TURN:     connection_type = "Via relay"; break;

			case CONNECTION_TYPE_UNKNOWN: // Never returned from Game Coordinator.
			default: connection_type = "Unknown"; break; // Should never happen, but don't fail if it does.
		}

		std::string game_type;
		switch (_settings_client.network.server_game_type) {
			case SERVER_GAME_TYPE_INVITE_ONLY: game_type = "Invite only"; break;
			case SERVER_GAME_TYPE_PUBLIC: game_type = "Public"; break;

			case SERVER_GAME_TYPE_LOCAL: // Impossible to register local servers.
			default: game_type = "Unknown"; break; // Should never happen, but don't fail if it does.
		}

		Debug(net, 3, "----------------------------------------");
		Debug(net, 3, "Your server is now registered with the Game Coordinator:");
		Debug(net, 3, "  Game type:       {}", game_type);
		Debug(net, 3, "  Connection type: {}", connection_type);
		Debug(net, 3, "  Invite code:     {}", _network_server_invite_code);
		Debug(net, 3, "----------------------------------------");
	} else {
		Debug(net, 3, "Game Coordinator registered our server with invite code '{}'", _network_server_invite_code);
	}

	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_LISTING(Packet *p)
{
	uint8 servers = p->Recv_uint16();

	/* End of list; we can now remove all expired items from the list. */
	if (servers == 0) {
		NetworkGameListRemoveExpired();
		return true;
	}

	for (; servers > 0; servers--) {
		std::string connection_string = p->Recv_string(NETWORK_HOSTNAME_PORT_LENGTH);

		/* Read the NetworkGameInfo from the packet. */
		NetworkGameInfo ngi = {};
		DeserializeNetworkGameInfo(p, &ngi, &this->newgrf_lookup_table);

		/* Now we know the connection string, we can add it to our list. */
		NetworkGameList *item = NetworkGameListAddItem(connection_string);

		/* Clear any existing GRFConfig chain. */
		ClearGRFConfigList(&item->info.grfconfig);
		/* Copy the new NetworkGameInfo info. */
		item->info = ngi;
		/* Check for compatability with the client. */
		CheckGameCompatibility(item->info);
		/* Mark server as online. */
		item->online = true;
		/* Mark the item as up-to-date. */
		item->version = _network_game_list_version;
	}

	UpdateNetworkGameWindow();
	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_CONNECTING(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);
	std::string invite_code = p->Recv_string(NETWORK_INVITE_CODE_LENGTH);

	/* Find the connecter based on the invite code. */
	auto connecter_pre_it = this->connecter_pre.find(invite_code);
	if (connecter_pre_it == this->connecter_pre.end()) {
		this->CloseConnection();
		return false;
	}

	/* Now store it based on the token. */
	this->connecter[token] = connecter_pre_it->second;
	this->connecter_pre.erase(connecter_pre_it);

	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_CONNECT_FAILED(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);
	this->CloseToken(token);

	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_DIRECT_CONNECT(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);
	uint8 tracking_number = p->Recv_uint8();
	std::string hostname = p->Recv_string(NETWORK_HOSTNAME_LENGTH);
	uint16 port = p->Recv_uint16();

	/* Ensure all other pending connection attempts are killed. */
	if (this->game_connecter != nullptr) {
		this->game_connecter->Kill();
		this->game_connecter = nullptr;
	}

	this->game_connecter = new NetworkDirectConnecter(hostname, port, token, tracking_number);
	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_STUN_REQUEST(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);

	this->stun_handlers[token][AF_INET6] = ClientNetworkStunSocketHandler::Stun(token, AF_INET6);
	this->stun_handlers[token][AF_INET] = ClientNetworkStunSocketHandler::Stun(token, AF_INET);
	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_STUN_CONNECT(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);
	uint8 tracking_number = p->Recv_uint8();
	uint8 family = p->Recv_uint8();
	std::string host = p->Recv_string(NETWORK_HOSTNAME_PORT_LENGTH);
	uint16 port = p->Recv_uint16();

	/* Check if we know this token. */
	auto stun_it = this->stun_handlers.find(token);
	if (stun_it == this->stun_handlers.end()) return true;
	auto family_it = stun_it->second.find(family);
	if (family_it == stun_it->second.end()) return true;

	/* Ensure all other pending connection attempts are killed. */
	if (this->game_connecter != nullptr) {
		this->game_connecter->Kill();
		this->game_connecter = nullptr;
	}

	/* We now mark the connection as closed, but we do not really close the
	 * socket yet. We do this when the NetworkReuseStunConnecter is connected.
	 * This prevents any NAT to already remove the route while we create the
	 * second connection on top of the first. */
	family_it->second->CloseConnection(false);

	/* Connect to our peer from the same local address as we use for the
	 * STUN server. This means that if there is any NAT in the local network,
	 * the public ip:port is still pointing to the local address, and as such
	 * a connection can be established. */
	this->game_connecter = new NetworkReuseStunConnecter(host, port, family_it->second->local_addr, token, tracking_number, family);
	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_NEWGRF_LOOKUP(Packet *p)
{
	this->newgrf_lookup_table_cursor = p->Recv_uint32();

	uint16 newgrfs = p->Recv_uint16();
	for (; newgrfs> 0; newgrfs--) {
		uint32 index = p->Recv_uint32();
		DeserializeGRFIdentifierWithName(p, &this->newgrf_lookup_table[index]);
	}
	return true;
}

bool ClientNetworkCoordinatorSocketHandler::Receive_GC_TURN_CONNECT(Packet *p)
{
	std::string token = p->Recv_string(NETWORK_TOKEN_LENGTH);
	uint8 tracking_number = p->Recv_uint8();
	std::string ticket = p->Recv_string(NETWORK_TOKEN_LENGTH);
	std::string connection_string = p->Recv_string(NETWORK_HOSTNAME_PORT_LENGTH);

	/* Ensure all other pending connection attempts are killed. */
	if (this->game_connecter != nullptr) {
		this->game_connecter->Kill();
		this->game_connecter = nullptr;
	}

	this->turn_handlers[token] = ClientNetworkTurnSocketHandler::Turn(token, tracking_number, ticket, connection_string);

	if (!_network_server) {
		switch (_settings_client.network.use_relay_service) {
			case URS_NEVER:
				this->ConnectFailure(token, 0);
				break;

			case URS_ASK:
				ShowNetworkAskRelay(connection_string, token);
				break;

			case URS_ALLOW:
				this->StartTurnConnection(token);
				break;
		}
	} else {
		this->StartTurnConnection(token);
	}

	return true;
}

void ClientNetworkCoordinatorSocketHandler::StartTurnConnection(std::string &token)
{
	auto turn_it = this->turn_handlers.find(token);
	if (turn_it == this->turn_handlers.end()) return;

	turn_it->second->Connect();
}

void ClientNetworkCoordinatorSocketHandler::Connect()
{
	/* We are either already connected or are trying to connect. */
	if (this->sock != INVALID_SOCKET || this->connecting) return;

	this->Reopen();

	this->connecting = true;
	this->last_activity = std::chrono::steady_clock::now();

	new NetworkCoordinatorConnecter(NetworkCoordinatorConnectionString());
}

NetworkRecvStatus ClientNetworkCoordinatorSocketHandler::CloseConnection(bool error)
{
	NetworkCoordinatorSocketHandler::CloseConnection(error);

	this->CloseSocket();
	this->connecting = false;

	_network_server_connection_type = CONNECTION_TYPE_UNKNOWN;
	this->next_update = {};

	this->CloseAllConnections();

	SetWindowDirty(WC_CLIENT_LIST, 0);

	return NETWORK_RECV_STATUS_OKAY;
}

/**
 * Register our server to receive our invite code.
 */
void ClientNetworkCoordinatorSocketHandler::Register()
{
	_network_server_connection_type = CONNECTION_TYPE_UNKNOWN;
	this->next_update = {};

	SetWindowDirty(WC_CLIENT_LIST, 0);

	this->Connect();

	Packet *p = new Packet(PACKET_COORDINATOR_SERVER_REGISTER);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	p->Send_uint8(_settings_client.network.server_game_type);
	p->Send_uint16(_settings_client.network.server_port);
	if (_settings_client.network.server_invite_code.empty() || _settings_client.network.server_invite_code_secret.empty()) {
		p->Send_string("");
		p->Send_string("");
	} else {
		p->Send_string(_settings_client.network.server_invite_code);
		p->Send_string(_settings_client.network.server_invite_code_secret);
	}

	this->SendPacket(p);
}

/**
 * Send an update of our server status to the Game Coordinator.
 */
void ClientNetworkCoordinatorSocketHandler::SendServerUpdate()
{
	Debug(net, 6, "Sending server update to Game Coordinator");

	Packet *p = new Packet(PACKET_COORDINATOR_SERVER_UPDATE, TCP_MTU);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	SerializeNetworkGameInfo(p, GetCurrentNetworkServerGameInfo(), this->next_update.time_since_epoch() != std::chrono::nanoseconds::zero());

	this->SendPacket(p);

	this->next_update = std::chrono::steady_clock::now() + NETWORK_COORDINATOR_DELAY_BETWEEN_UPDATES;
}

/**
 * Request a listing of all public servers.
 */
void ClientNetworkCoordinatorSocketHandler::GetListing()
{
	this->Connect();

	_network_game_list_version++;

	Packet *p = new Packet(PACKET_COORDINATOR_CLIENT_LISTING);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	p->Send_uint8(NETWORK_GAME_INFO_VERSION);
	p->Send_string(_openttd_revision);
	p->Send_uint32(this->newgrf_lookup_table_cursor);

	this->SendPacket(p);
}

/**
 * Join a server based on an invite code.
 * @param invite_code The invite code of the server to connect to.
 * @param connecter The connecter of the request.
 */
void ClientNetworkCoordinatorSocketHandler::ConnectToServer(const std::string &invite_code, TCPServerConnecter *connecter)
{
	assert(StrStartsWith(invite_code, "+"));

	if (this->connecter_pre.find(invite_code) != this->connecter_pre.end()) {
		/* If someone is hammering the refresh key, one can sent out two
		 * requests for the same invite code. There isn't really a great way
		 * of handling this, so just ignore this request. */
		connecter->SetFailure();
		return;
	}

	/* Initially we store based on invite code; on first reply we know the
	 * token, and will start using that key instead. */
	this->connecter_pre[invite_code] = connecter;

	this->Connect();

	Packet *p = new Packet(PACKET_COORDINATOR_CLIENT_CONNECT);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	p->Send_string(invite_code);

	this->SendPacket(p);
}

/**
 * Callback from a Connecter to let the Game Coordinator know the connection failed.
 * @param token Token of the connecter that failed.
 * @param tracking_number Tracking number of the connecter that failed.
 */
void ClientNetworkCoordinatorSocketHandler::ConnectFailure(const std::string &token, uint8 tracking_number)
{
	/* Connecter will destroy itself. */
	this->game_connecter = nullptr;

	Packet *p = new Packet(PACKET_COORDINATOR_SERCLI_CONNECT_FAILED);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	p->Send_string(token);
	p->Send_uint8(tracking_number);

	this->SendPacket(p);

	/* We do not close the associated connecter here yet, as the
	 * Game Coordinator might have other methods of connecting available. */
}

/**
 * Callback from a Connecter to let the Game Coordinator know the connection
 * to the game server is established.
 * @param token Token of the connecter that succeeded.
 * @param sock The socket that the connecter can now use.
 */
void ClientNetworkCoordinatorSocketHandler::ConnectSuccess(const std::string &token, SOCKET sock, NetworkAddress &address)
{
	/* Connecter will destroy itself. */
	this->game_connecter = nullptr;

	if (_network_server) {
		if (!ServerNetworkGameSocketHandler::ValidateClient(sock, address)) return;
		Debug(net, 3, "[{}] Client connected from {} on frame {}", ServerNetworkGameSocketHandler::GetName(), address.GetHostname(), _frame_counter);
		ServerNetworkGameSocketHandler::AcceptConnection(sock, address);
	} else {
		/* The client informs the Game Coordinator about the success. The server
		 * doesn't have to, as it is implied by the client telling. */
		Packet *p = new Packet(PACKET_COORDINATOR_CLIENT_CONNECTED);
		p->Send_uint8(NETWORK_COORDINATOR_VERSION);
		p->Send_string(token);
		this->SendPacket(p);

		/* Find the connecter; it can happen it no longer exist, in cases where
		 * we aborted the connect but the Game Coordinator was already in the
		 * processes of connecting us. */
		auto connecter_it = this->connecter.find(token);
		if (connecter_it != this->connecter.end()) {
			connecter_it->second->SetConnected(sock);
			this->connecter.erase(connecter_it);
		}
	}

	/* Close all remaining connections. */
	this->CloseToken(token);
}

/**
 * Callback from the STUN connecter to inform the Game Coordinator about the
 * result of the STUN.
 *
 * This helps the Game Coordinator not to wait for a timeout on its end, but
 * rather react as soon as the client/server knows the result.
 */
void ClientNetworkCoordinatorSocketHandler::StunResult(const std::string &token, uint8 family, bool result)
{
	Packet *p = new Packet(PACKET_COORDINATOR_SERCLI_STUN_RESULT);
	p->Send_uint8(NETWORK_COORDINATOR_VERSION);
	p->Send_string(token);
	p->Send_uint8(family);
	p->Send_bool(result);
	this->SendPacket(p);
}

/**
 * Close the STUN handler.
 * @param token The token used for the STUN handlers.
 * @param family The family of STUN handlers to close. AF_UNSPEC to close all STUN handlers for this token.
 */
void ClientNetworkCoordinatorSocketHandler::CloseStunHandler(const std::string &token, uint8 family)
{
	auto stun_it = this->stun_handlers.find(token);
	if (stun_it == this->stun_handlers.end()) return;

	if (family == AF_UNSPEC) {
		for (auto &[family, stun_handler] : stun_it->second) {
			stun_handler->CloseConnection();
			stun_handler->CloseSocket();
		}

		this->stun_handlers.erase(stun_it);
	} else {
		auto family_it = stun_it->second.find(family);
		if (family_it == stun_it->second.end()) return;

		family_it->second->CloseConnection();
		family_it->second->CloseSocket();

		stun_it->second.erase(family_it);
	}
}

/**
 * Close the TURN handler.
 * @param token The token used for the TURN handler.
 */
void ClientNetworkCoordinatorSocketHandler::CloseTurnHandler(const std::string &token)
{
	CloseWindowByClass(WC_NETWORK_ASK_RELAY);

	auto turn_it = this->turn_handlers.find(token);
	if (turn_it == this->turn_handlers.end()) return;

	turn_it->second->CloseConnection();
	turn_it->second->CloseSocket();

	/* We don't remove turn_handler here, as we can be called from within that
	 * turn_handler instance, so our object cannot be free'd yet. Instead, we
	 * check later if the connection is closed, and free the object then. */
}

/**
 * Close everything related to this connection token.
 * @param token The connection token to close.
 */
void ClientNetworkCoordinatorSocketHandler::CloseToken(const std::string &token)
{
	/* Close all remaining STUN / TURN connections. */
	this->CloseStunHandler(token);
	this->CloseTurnHandler(token);

	/* Close the caller of the connection attempt. */
	auto connecter_it = this->connecter.find(token);
	if (connecter_it != this->connecter.end()) {
		connecter_it->second->SetFailure();
		this->connecter.erase(connecter_it);
	}
}

/**
 * Close all pending connection tokens.
 */
void ClientNetworkCoordinatorSocketHandler::CloseAllConnections()
{
	/* Ensure all other pending connection attempts are also killed. */
	if (this->game_connecter != nullptr) {
		this->game_connecter->Kill();
		this->game_connecter = nullptr;
	}

	/* Mark any pending connecters as failed. */
	for (auto &[token, it] : this->connecter) {
		this->CloseStunHandler(token);
		this->CloseTurnHandler(token);
		it->SetFailure();

		/* Inform the Game Coordinator he can stop trying to connect us to the server. */
		this->ConnectFailure(token, 0);
	}
	this->stun_handlers.clear();
	this->turn_handlers.clear();
	this->connecter.clear();

	/* Also close any pending invite-code requests. */
	for (auto &[invite_code, it] : this->connecter_pre) {
		it->SetFailure();
	}
	this->connecter_pre.clear();
}

/**
 * Check whether we received/can send some data from/to the Game Coordinator server and
 * when that's the case handle it appropriately.
 */
void ClientNetworkCoordinatorSocketHandler::SendReceive()
{
	/* Private games are not listed via the Game Coordinator. */
	if (_network_server && _settings_client.network.server_game_type == SERVER_GAME_TYPE_LOCAL) {
		if (this->sock != INVALID_SOCKET) {
			this->CloseConnection();
		}
		return;
	}

	static int last_attempt_backoff = 1;
	static bool first_reconnect = true;

	if (this->sock == INVALID_SOCKET) {
		static std::chrono::steady_clock::time_point last_attempt = {};

		/* Don't auto-reconnect when we are not a server. */
		if (!_network_server) return;
		/* Don't reconnect if we are connecting. */
		if (this->connecting) return;
		/* Throttle how often we try to reconnect. */
		if (std::chrono::steady_clock::now() < last_attempt + std::chrono::seconds(1) * last_attempt_backoff) return;

		last_attempt = std::chrono::steady_clock::now();
		/* Delay reconnecting with up to 32 seconds. */
		if (last_attempt_backoff < 32) {
			last_attempt_backoff *= 2;
		}

		/* Do not reconnect on the first attempt, but only initialize the
		 * last_attempt variables.  Otherwise after an outage all servers
		 * reconnect at the same time, potentially overwhelming the
		 * Game Coordinator. */
		if (first_reconnect) {
			first_reconnect = false;
			return;
		}

		Debug(net, 1, "Connection with Game Coordinator lost; reconnecting...");
		this->Register();
		return;
	}

	last_attempt_backoff = 1;
	first_reconnect = true;

	if (_network_server && _network_server_connection_type != CONNECTION_TYPE_UNKNOWN && std::chrono::steady_clock::now() > this->next_update) {
		this->SendServerUpdate();
	}

	if (!_network_server && std::chrono::steady_clock::now() > this->last_activity + IDLE_TIMEOUT) {
		this->CloseConnection();
		return;
	}

	if (this->CanSendReceive()) {
		if (this->ReceivePackets()) {
			this->last_activity = std::chrono::steady_clock::now();
		}
	}

	this->SendPackets();

	for (const auto &[token, families] : this->stun_handlers) {
		for (const auto &[family, stun_handler] : families) {
			stun_handler->SendReceive();
		}
	}

	/* Check for handlers that are not connecting nor connected. Destroy those objects. */
	for (auto turn_it = this->turn_handlers.begin(); turn_it != this->turn_handlers.end(); /* nothing */) {
		if (turn_it->second->connect_started && turn_it->second->connecter == nullptr && !turn_it->second->IsConnected()) {
			turn_it = this->turn_handlers.erase(turn_it);
		} else {
			turn_it++;
		}
	}

	for (const auto &[token, turn_handler] : this->turn_handlers) {
		turn_handler->SendReceive();
	}
}