gbe_fork/dll/dll/steam_networking_sockets.h

2170 lines
99 KiB
C++

/* Copyright (C) 2019 Mr Goldberg
This file is part of the Goldberg Emulator
The Goldberg Emulator is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 3 of the License, or (at your option) any later version.
The Goldberg Emulator 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the Goldberg Emulator; if not, see
<http://www.gnu.org/licenses/>. */
#include "base.h"
struct Listen_Socket {
HSteamListenSocket socket_id;
int virtual_port;
int real_port;
CSteamID created_by;
};
enum connect_socket_status {
CONNECT_SOCKET_NO_CONNECTION,
CONNECT_SOCKET_CONNECTING,
CONNECT_SOCKET_NOT_ACCEPTED,
CONNECT_SOCKET_CONNECTED,
CONNECT_SOCKET_CLOSED,
CONNECT_SOCKET_TIMEDOUT
};
struct compare_snm_for_queue {
bool operator()(Networking_Sockets &left, Networking_Sockets &right) {
return left.message_number() > right.message_number();
}
};
struct Connect_Socket {
int virtual_port;
int real_port;
SteamNetworkingIdentity remote_identity;
HSteamNetConnection remote_id;
HSteamListenSocket listen_socket_id;
enum connect_socket_status status;
int64 user_data;
std::priority_queue<Networking_Sockets, std::vector<Networking_Sockets>, compare_snm_for_queue> data;
HSteamNetPollGroup poll_group;
unsigned long long packet_send_counter;
CSteamID created_by;
std::chrono::steady_clock::time_point connect_request_last_sent;
unsigned connect_requests_sent;
};
struct shared_between_client_server {
std::vector<struct Listen_Socket> listen_sockets;
std::map<HSteamNetConnection, struct Connect_Socket> connect_sockets;
std::map<HSteamNetPollGroup, std::list<HSteamNetConnection>> poll_groups;
unsigned used;
};
class Steam_Networking_Sockets :
public ISteamNetworkingSockets001,
public ISteamNetworkingSockets002,
public ISteamNetworkingSockets003,
public ISteamNetworkingSockets004,
public ISteamNetworkingSockets006,
public ISteamNetworkingSockets008,
public ISteamNetworkingSockets009,
public ISteamNetworkingSockets
{
class Settings *settings;
class Networking *network;
class SteamCallResults *callback_results;
class SteamCallBacks *callbacks;
class RunEveryRunCB *run_every_runcb;
struct shared_between_client_server *s;
std::chrono::steady_clock::time_point created;
static const int SNS_DISABLED_PORT = -1;
public:
static void steam_callback(void *object, Common_Message *msg)
{
// PRINT_DEBUG_ENTRY();
Steam_Networking_Sockets *steam_networkingsockets = (Steam_Networking_Sockets *)object;
steam_networkingsockets->Callback(msg);
}
static void steam_run_every_runcb(void *object)
{
// PRINT_DEBUG_ENTRY();
Steam_Networking_Sockets *steam_networkingsockets = (Steam_Networking_Sockets *)object;
steam_networkingsockets->RunCallbacks();
}
Steam_Networking_Sockets(class Settings *settings, class Networking *network, class SteamCallResults *callback_results, class SteamCallBacks *callbacks, class RunEveryRunCB *run_every_runcb, shared_between_client_server *sbcs)
{
this->settings = settings;
this->network = network;
this->run_every_runcb = run_every_runcb;
this->network->setCallback(CALLBACK_ID_USER_STATUS, settings->get_local_steam_id(), &Steam_Networking_Sockets::steam_callback, this);
this->network->setCallback(CALLBACK_ID_NETWORKING_SOCKETS, settings->get_local_steam_id(), &Steam_Networking_Sockets::steam_callback, this);
this->run_every_runcb->add(&Steam_Networking_Sockets::steam_run_every_runcb, this);
this->callback_results = callback_results;
this->callbacks = callbacks;
if (!sbcs) {
this->s = new shared_between_client_server();
this->s->used = 0;
} else {
this->s = sbcs;
this->s->used += 1;
}
this->created = std::chrono::steady_clock::now();
}
~Steam_Networking_Sockets()
{
this->network->rmCallback(CALLBACK_ID_USER_STATUS, settings->get_local_steam_id(), &Steam_Networking_Sockets::steam_callback, this);
this->network->rmCallback(CALLBACK_ID_NETWORKING_SOCKETS, settings->get_local_steam_id(), &Steam_Networking_Sockets::steam_callback, this);
this->run_every_runcb->remove(&Steam_Networking_Sockets::steam_run_every_runcb, this);
if (this->s->used) {
this->s->used -= 1;
} else {
delete this->s;
}
}
static unsigned long get_socket_id()
{
static unsigned long socket_id;
socket_id++;
return socket_id;
}
shared_between_client_server *get_shared_between_client_server()
{
return s;
}
HSteamListenSocket new_listen_socket(int nSteamConnectVirtualPort, int real_port)
{
HSteamListenSocket socket_id = get_socket_id();
if (socket_id == k_HSteamListenSocket_Invalid) ++socket_id;
CSteamID steam_id = settings->get_local_steam_id();
auto conn = std::find_if(s->listen_sockets.begin(), s->listen_sockets.end(), [&nSteamConnectVirtualPort,&steam_id](struct Listen_Socket const& conn) { return conn.virtual_port == nSteamConnectVirtualPort && conn.created_by == steam_id;});
if (conn != s->listen_sockets.end()) return k_HSteamListenSocket_Invalid;
struct Listen_Socket listen_socket;
listen_socket.socket_id = socket_id;
listen_socket.virtual_port = nSteamConnectVirtualPort;
listen_socket.real_port = real_port;
listen_socket.created_by = steam_id;
s->listen_sockets.push_back(listen_socket);
return socket_id;
}
struct Listen_Socket *get_connection_socket(HSteamListenSocket id)
{
auto conn = std::find_if(s->listen_sockets.begin(), s->listen_sockets.end(), [&id](struct Listen_Socket const& conn) { return conn.socket_id == id;});
if (conn == s->listen_sockets.end()) return NULL;
return &(*conn);
}
bool send_packet_new_connection(HSteamNetConnection m_hConn)
{
auto connect_socket = s->connect_sockets.find(m_hConn);
if (connect_socket == s->connect_sockets.end()) return false;
//TODO: right now this only supports connecting with steam id, might need to make ip/port connections work in the future when I find a game that uses them.
Common_Message msg;
msg.set_source_id(connect_socket->second.created_by.ConvertToUint64());
msg.set_allocated_networking_sockets(new Networking_Sockets);
if (connect_socket->second.status == CONNECT_SOCKET_CONNECTING) {
msg.mutable_networking_sockets()->set_type(Networking_Sockets::CONNECTION_REQUEST);
} else if (connect_socket->second.status == CONNECT_SOCKET_CONNECTED) {
msg.mutable_networking_sockets()->set_type(Networking_Sockets::CONNECTION_ACCEPTED);
}
msg.mutable_networking_sockets()->set_virtual_port(connect_socket->second.virtual_port);
msg.mutable_networking_sockets()->set_real_port(connect_socket->second.real_port);
msg.mutable_networking_sockets()->set_connection_id_from(connect_socket->first);
msg.mutable_networking_sockets()->set_connection_id(connect_socket->second.remote_id);
uint64_t steam_id = connect_socket->second.remote_identity.GetSteamID64();
if (steam_id) {
msg.set_dest_id(steam_id);
return network->sendTo(&msg, true);
}
const SteamNetworkingIPAddr *ip_addr = connect_socket->second.remote_identity.GetIPAddr();
if (ip_addr) {
return network->sendToIPPort(&msg, ip_addr->GetIPv4(), ip_addr->m_port, true);
}
return false;
}
HSteamNetConnection new_connect_socket(SteamNetworkingIdentity remote_identity, int virtual_port, int real_port, enum connect_socket_status status=CONNECT_SOCKET_CONNECTING, HSteamListenSocket listen_socket_id=k_HSteamListenSocket_Invalid, HSteamNetConnection remote_id=k_HSteamNetConnection_Invalid)
{
Connect_Socket socket = {};
socket.remote_identity = remote_identity;
socket.virtual_port = virtual_port;
socket.real_port = real_port;
socket.listen_socket_id = listen_socket_id;
socket.remote_id = remote_id;
socket.status = status;
socket.user_data = -1;
socket.poll_group = k_HSteamNetPollGroup_Invalid;
socket.created_by = settings->get_local_steam_id();
socket.connect_request_last_sent = std::chrono::steady_clock::now();
socket.connect_requests_sent = 0;
socket.packet_send_counter = 1;
HSteamNetConnection socket_id = get_socket_id();
if (socket_id == k_HSteamNetConnection_Invalid) ++socket_id;
if (s->connect_sockets.insert(std::make_pair(socket_id, socket)).second == false) {
return k_HSteamNetConnection_Invalid;
}
return socket_id;
}
ESteamNetworkingConnectionState convert_status(enum connect_socket_status old_status)
{
if (old_status == CONNECT_SOCKET_NO_CONNECTION) return k_ESteamNetworkingConnectionState_None;
if (old_status == CONNECT_SOCKET_CONNECTING) return k_ESteamNetworkingConnectionState_Connecting;
if (old_status == CONNECT_SOCKET_NOT_ACCEPTED) return k_ESteamNetworkingConnectionState_Connecting;
if (old_status == CONNECT_SOCKET_CONNECTED) return k_ESteamNetworkingConnectionState_Connected;
if (old_status == CONNECT_SOCKET_CLOSED) return k_ESteamNetworkingConnectionState_ClosedByPeer;
if (old_status == CONNECT_SOCKET_TIMEDOUT) return k_ESteamNetworkingConnectionState_ProblemDetectedLocally;
return k_ESteamNetworkingConnectionState_None;
}
void set_steamnetconnectioninfo(std::map<HSteamNetConnection, Connect_Socket>::iterator connect_socket, SteamNetConnectionInfo_t *pInfo)
{
pInfo->m_identityRemote = connect_socket->second.remote_identity;
pInfo->m_nUserData = connect_socket->second.user_data;
pInfo->m_hListenSocket = connect_socket->second.listen_socket_id;
pInfo->m_addrRemote.Clear(); //TODO
if (connect_socket->second.real_port != SNS_DISABLED_PORT) {
pInfo->m_addrRemote.SetIPv4(network->getIP(connect_socket->second.remote_identity.GetSteamID()), connect_socket->first);
}
pInfo->m_idPOPRemote = 0;
pInfo->m_idPOPRelay = 0;
pInfo->m_eState = convert_status(connect_socket->second.status);
pInfo->m_eEndReason = 0; //TODO
pInfo->m_szEndDebug[0] = 0;
sprintf(pInfo->m_szConnectionDescription, "%u", connect_socket->first);
//Note some games might not allocate a struct the whole size of SteamNetConnectionInfo_t when calling GetConnectionInfo
//keep this in mind in future interface updates
}
void launch_callback(HSteamNetConnection m_hConn, enum connect_socket_status old_status)
{
auto connect_socket = s->connect_sockets.find(m_hConn);
if (connect_socket == s->connect_sockets.end()) return;
struct SteamNetConnectionStatusChangedCallback_t data = {};
data.m_hConn = connect_socket->first;
data.m_eOldState = convert_status(old_status);
set_steamnetconnectioninfo(connect_socket, &data.m_info);
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
/// Creates a "server" socket that listens for clients to connect to, either by calling
/// ConnectSocketBySteamID or ConnectSocketByIPv4Address.
///
/// nSteamConnectVirtualPort specifies how clients can connect to this socket using
/// ConnectBySteamID. A negative value indicates that this functionality is
/// disabled and clients must connect by IP address. It's very common for applications
/// to only have one listening socket; in that case, use zero. If you need to open
/// multiple listen sockets and have clients be able to connect to one or the other, then
/// nSteamConnectVirtualPort should be a small integer constant unique to each listen socket
/// you create.
///
/// In the open-source version of this API, you must pass -1 for nSteamConnectVirtualPort
///
/// If you want clients to connect to you by your IPv4 addresses using
/// ConnectByIPv4Address, then you must set nPort to be nonzero. Steam will
/// bind a UDP socket to the specified local port, and clients will send packets using
/// ordinary IP routing. It's up to you to take care of NAT, protecting your server
/// from DoS, etc. If you don't need clients to connect to you by IP, then set nPort=0.
/// Use nIP if you wish to bind to a particular local interface. Typically you will use 0,
/// which means to listen on all interfaces, and accept the default outbound IP address.
/// If nPort is zero, then nIP must also be zero.
///
/// A SocketStatusCallback_t callback when another client attempts a connection.
HSteamListenSocket CreateListenSocket( int nSteamConnectVirtualPort, uint32 nIP, uint16 nPort )
{
PRINT_DEBUG("%i %u %u", nSteamConnectVirtualPort, nIP, nPort);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(nSteamConnectVirtualPort, nPort);
}
/// Creates a "server" socket that listens for clients to connect to by
/// calling ConnectByIPAddress, over ordinary UDP (IPv4 or IPv6)
///
/// You must select a specific local port to listen on and set it
/// the port field of the local address.
///
/// Usually you wil set the IP portion of the address to zero, (SteamNetworkingIPAddr::Clear()).
/// This means that you will not bind to any particular local interface. In addition,
/// if possible the socket will be bound in "dual stack" mode, which means that it can
/// accept both IPv4 and IPv6 clients. If you wish to bind a particular interface, then
/// set the local address to the appropriate IPv4 or IPv6 IP.
///
/// When a client attempts to connect, a SteamNetConnectionStatusChangedCallback_t
/// will be posted. The connection will be in the connecting state.
HSteamListenSocket CreateListenSocketIP( const SteamNetworkingIPAddr &localAddress )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(SNS_DISABLED_PORT, localAddress.m_port);
}
HSteamListenSocket CreateListenSocketIP( const SteamNetworkingIPAddr *localAddress )
{
PRINT_DEBUG("old1");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(SNS_DISABLED_PORT, localAddress->m_port);
}
HSteamListenSocket CreateListenSocketIP( const SteamNetworkingIPAddr &localAddress, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(SNS_DISABLED_PORT, localAddress.m_port);
}
/// Creates a connection and begins talking to a "server" over UDP at the
/// given IPv4 or IPv6 address. The remote host must be listening with a
/// matching call to CreateListenSocketIP on the specified port.
///
/// A SteamNetConnectionStatusChangedCallback_t callback will be triggered when we start
/// connecting, and then another one on either timeout or successful connection.
///
/// If the server does not have any identity configured, then their network address
/// will be the only identity in use. Or, the network host may provide a platform-specific
/// identity with or without a valid certificate to authenticate that identity. (These
/// details will be contained in the SteamNetConnectionStatusChangedCallback_t.) It's
/// up to your application to decide whether to allow the connection.
///
/// By default, all connections will get basic encryption sufficient to prevent
/// casual eavesdropping. But note that without certificates (or a shared secret
/// distributed through some other out-of-band mechanism), you don't have any
/// way of knowing who is actually on the other end, and thus are vulnerable to
/// man-in-the-middle attacks.
HSteamNetConnection ConnectByIPAddress( const SteamNetworkingIPAddr &address )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
SteamNetworkingIdentity ip_id;
ip_id.SetIPAddr(address);
HSteamNetConnection socket = new_connect_socket(ip_id, SNS_DISABLED_PORT, address.m_port);
send_packet_new_connection(socket);
return socket;
}
HSteamNetConnection ConnectByIPAddress( const SteamNetworkingIPAddr *address )
{
PRINT_DEBUG("old1");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
SteamNetworkingIdentity ip_id;
ip_id.SetIPAddr(*address);
HSteamNetConnection socket = new_connect_socket(ip_id, SNS_DISABLED_PORT, address->m_port);
send_packet_new_connection(socket);
return socket;
}
HSteamNetConnection ConnectByIPAddress( const SteamNetworkingIPAddr &address, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG("%X", address.GetIPv4());
std::lock_guard<std::recursive_mutex> lock(global_mutex);
SteamNetworkingIdentity ip_id;
ip_id.SetIPAddr(address);
HSteamNetConnection socket = new_connect_socket(ip_id, SNS_DISABLED_PORT, address.m_port);
send_packet_new_connection(socket);
return socket;
}
/// Like CreateListenSocketIP, but clients will connect using ConnectP2P
///
/// nVirtualPort specifies how clients can connect to this socket using
/// ConnectP2P. It's very common for applications to only have one listening socket;
/// in that case, use zero. If you need to open multiple listen sockets and have clients
/// be able to connect to one or the other, then nVirtualPort should be a small integer (<1000)
/// unique to each listen socket you create.
///
/// If you use this, you probably want to call ISteamNetworkingUtils::InitializeRelayNetworkAccess()
/// when your app initializes
HSteamListenSocket CreateListenSocketP2P( int nVirtualPort )
{
PRINT_DEBUG("old %i", nVirtualPort);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(nVirtualPort, SNS_DISABLED_PORT);
}
HSteamListenSocket CreateListenSocketP2P( int nVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG("%i", nVirtualPort);
//TODO config options
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(nVirtualPort, SNS_DISABLED_PORT);
}
/// Begin connecting to a server that is identified using a platform-specific identifier.
/// This requires some sort of third party rendezvous service, and will depend on the
/// platform and what other libraries and services you are integrating with.
///
/// At the time of this writing, there is only one supported rendezvous service: Steam.
/// Set the SteamID (whether "user" or "gameserver") and Steam will determine if the
/// client is online and facilitate a relay connection. Note that all P2P connections on
/// Steam are currently relayed.
///
/// If you use this, you probably want to call ISteamNetworkingUtils::InitializeRelayNetworkAccess()
/// when your app initializes
HSteamNetConnection ConnectP2P( const SteamNetworkingIdentity &identityRemote, int nVirtualPort )
{
PRINT_DEBUG("old %i", nVirtualPort);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
const SteamNetworkingIPAddr *ip = identityRemote.GetIPAddr();
if (identityRemote.m_eType == k_ESteamNetworkingIdentityType_SteamID) {
PRINT_DEBUG("%llu", identityRemote.GetSteamID64());
//steam id identity
} else if (ip) {
PRINT_DEBUG("%u:%u ipv4? %u", ip->GetIPv4(), ip->m_port, ip->IsIPv4());
//ip addr
} else {
return k_HSteamNetConnection_Invalid;
}
HSteamNetConnection socket = new_connect_socket(identityRemote, nVirtualPort, SNS_DISABLED_PORT);
send_packet_new_connection(socket);
return socket;
}
HSteamNetConnection ConnectP2P( const SteamNetworkingIdentity *identityRemote, int nVirtualPort )
{
PRINT_DEBUG("old1");
return ConnectP2P(*identityRemote, nVirtualPort);
}
HSteamNetConnection ConnectP2P( const SteamNetworkingIdentity &identityRemote, int nVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG("%i", nVirtualPort);
//TODO config options
return ConnectP2P(identityRemote, nVirtualPort);
}
/// Creates a connection and begins talking to a remote destination. The remote host
/// must be listening with a matching call to CreateListenSocket.
///
/// Use ConnectBySteamID to connect using the SteamID (client or game server) as the network address.
/// Use ConnectByIPv4Address to connect by IP address.
///
/// A SteamNetConnectionStatusChangedCallback_t callback will be triggered when we start connecting,
/// and then another one on timeout or successful connection
//#ifndef STEAMNETWORKINGSOCKETS_OPENSOURCE
HSteamNetConnection ConnectBySteamID( CSteamID steamIDTarget, int nVirtualPort )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamNetConnection_Invalid;
}
//#endif
HSteamNetConnection ConnectByIPv4Address( uint32 nIP, uint16 nPort )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamNetConnection_Invalid;
}
/// Accept an incoming connection that has been received on a listen socket.
///
/// When a connection attempt is received (perhaps after a few basic handshake
/// packets have been exchanged to prevent trivial spoofing), a connection interface
/// object is created in the k_ESteamNetworkingConnectionState_Connecting state
/// and a SteamNetConnectionStatusChangedCallback_t is posted. At this point, your
/// application MUST either accept or close the connection. (It may not ignore it.)
/// Accepting the connection will transition it either into the connected state,
/// of the finding route state, depending on the connection type.
///
/// You should take action within a second or two, because accepting the connection is
/// what actually sends the reply notifying the client that they are connected. If you
/// delay taking action, from the client's perspective it is the same as the network
/// being unresponsive, and the client may timeout the connection attempt. In other
/// words, the client cannot distinguish between a delay caused by network problems
/// and a delay caused by the application.
///
/// This means that if your application goes for more than a few seconds without
/// processing callbacks (for example, while loading a map), then there is a chance
/// that a client may attempt to connect in that interval and fail due to timeout.
///
/// If the application does not respond to the connection attempt in a timely manner,
/// and we stop receiving communication from the client, the connection attempt will
/// be timed out locally, transitioning the connection to the
/// k_ESteamNetworkingConnectionState_ProblemDetectedLocally state. The client may also
/// close the connection before it is accepted, and a transition to the
/// k_ESteamNetworkingConnectionState_ClosedByPeer is also possible depending the exact
/// sequence of events.
///
/// Returns k_EResultInvalidParam if the handle is invalid.
/// Returns k_EResultInvalidState if the connection is not in the appropriate state.
/// (Remember that the connection state could change in between the time that the
/// notification being posted to the queue and when it is received by the application.)
EResult AcceptConnection( HSteamNetConnection hConn )
{
PRINT_DEBUG("%u", hConn);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return k_EResultInvalidParam;
if (connect_socket->second.status != CONNECT_SOCKET_NOT_ACCEPTED) return k_EResultInvalidState;
connect_socket->second.status = CONNECT_SOCKET_CONNECTED;
send_packet_new_connection(connect_socket->first);
launch_callback(connect_socket->first, CONNECT_SOCKET_NOT_ACCEPTED);
return k_EResultOK;
}
/// Disconnects from the remote host and invalidates the connection handle.
/// Any unread data on the connection is discarded.
///
/// nReason is an application defined code that will be received on the other
/// end and recorded (when possible) in backend analytics. The value should
/// come from a restricted range. (See ESteamNetConnectionEnd.) If you don't need
/// to communicate any information to the remote host, and do not want analytics to
/// be able to distinguish "normal" connection terminations from "exceptional" ones,
/// You may pass zero, in which case the generic value of
/// k_ESteamNetConnectionEnd_App_Generic will be used.
///
/// pszDebug is an optional human-readable diagnostic string that will be received
/// by the remote host and recorded (when possible) in backend analytics.
///
/// If you wish to put the socket into a "linger" state, where an attempt is made to
/// flush any remaining sent data, use bEnableLinger=true. Otherwise reliable data
/// is not flushed.
///
/// If the connection has already ended and you are just freeing up the
/// connection interface, the reason code, debug string, and linger flag are
/// ignored.
bool CloseConnection( HSteamNetConnection hPeer, int nReason, const char *pszDebug, bool bEnableLinger )
{
PRINT_DEBUG("%u", hPeer);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hPeer);
if (connect_socket == s->connect_sockets.end()) return false;
if (connect_socket->second.status != CONNECT_SOCKET_CLOSED && connect_socket->second.status != CONNECT_SOCKET_TIMEDOUT) {
//TODO send/nReason and pszDebug
Common_Message msg;
msg.set_source_id(connect_socket->second.created_by.ConvertToUint64());
msg.set_dest_id(connect_socket->second.remote_identity.GetSteamID64());
msg.set_allocated_networking_sockets(new Networking_Sockets);
msg.mutable_networking_sockets()->set_type(Networking_Sockets::CONNECTION_END);
msg.mutable_networking_sockets()->set_virtual_port(connect_socket->second.virtual_port);
msg.mutable_networking_sockets()->set_real_port(connect_socket->second.real_port);
msg.mutable_networking_sockets()->set_connection_id_from(connect_socket->first);
msg.mutable_networking_sockets()->set_connection_id(connect_socket->second.remote_id);
network->sendTo(&msg, true);
}
s->connect_sockets.erase(connect_socket);
return true;
}
/// Destroy a listen socket, and all the client sockets generated by accepting connections
/// on the listen socket.
///
/// pszNotifyRemoteReason determines what cleanup actions are performed on the client
/// sockets being destroyed. (See DestroySocket for more details.)
///
/// Note that if cleanup is requested and you have requested the listen socket bound to a
/// particular local port to facilitate direct UDP/IPv4 connections, then the underlying UDP
/// socket must remain open until all clients have been cleaned up.
bool CloseListenSocket( HSteamListenSocket hSocket, const char *pszNotifyRemoteReason )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Destroy a listen socket. All the connections that were accepting on the listen
/// socket are closed ungracefully.
bool CloseListenSocket( HSteamListenSocket hSocket )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto conn = std::find_if(s->listen_sockets.begin(), s->listen_sockets.end(), [&hSocket](struct Listen_Socket const& conn) { return conn.socket_id == hSocket;});
if (conn == s->listen_sockets.end()) return false;
std::queue<HSteamNetConnection> to_close;
auto socket_conn = std::begin(s->connect_sockets);
while (socket_conn != std::end(s->connect_sockets)) {
if (socket_conn->second.listen_socket_id == hSocket) {
to_close.push(socket_conn->first);
}
++socket_conn;
}
while (to_close.size()) {
CloseConnection(to_close.front(), 0, "", false);
to_close.pop();
}
s->listen_sockets.erase(conn);
return true;
}
/// Set connection user data. Returns false if the handle is invalid.
bool SetConnectionUserData( HSteamNetConnection hPeer, int64 nUserData )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hPeer);
if (connect_socket == s->connect_sockets.end()) return false;
connect_socket->second.user_data = nUserData;
return true;
}
/// Fetch connection user data. Returns -1 if handle is invalid
/// or if you haven't set any userdata on the connection.
int64 GetConnectionUserData( HSteamNetConnection hPeer )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hPeer);
if (connect_socket == s->connect_sockets.end()) return -1;
return connect_socket->second.user_data;
}
/// Set a name for the connection, used mostly for debugging
void SetConnectionName( HSteamNetConnection hPeer, const char *pszName )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
}
/// Fetch connection name. Returns false if handle is invalid
bool GetConnectionName( HSteamNetConnection hPeer, char *pszName, int nMaxLen )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Send a message to the remote host on the connected socket.
///
/// eSendType determines the delivery guarantees that will be provided,
/// when data should be buffered, etc.
///
/// Note that the semantics we use for messages are not precisely
/// the same as the semantics of a standard "stream" socket.
/// (SOCK_STREAM) For an ordinary stream socket, the boundaries
/// between chunks are not considered relevant, and the sizes of
/// the chunks of data written will not necessarily match up to
/// the sizes of the chunks that are returned by the reads on
/// the other end. The remote host might read a partial chunk,
/// or chunks might be coalesced. For the message semantics
/// used here, however, the sizes WILL match. Each send call
/// will match a successful read call on the remote host
/// one-for-one. If you are porting existing stream-oriented
/// code to the semantics of reliable messages, your code should
/// work the same, since reliable message semantics are more
/// strict than stream semantics. The only caveat is related to
/// performance: there is per-message overhead to retain the
/// messages sizes, and so if your code sends many small chunks
/// of data, performance will suffer. Any code based on stream
/// sockets that does not write excessively small chunks will
/// work without any changes.
EResult SendMessageToConnection( HSteamNetConnection hConn, const void *pData, uint32 cbData, ESteamNetworkingSendType eSendType )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_EResultFail;
}
/// Send a message to the remote host on the specified connection.
///
/// nSendFlags determines the delivery guarantees that will be provided,
/// when data should be buffered, etc. E.g. k_nSteamNetworkingSend_Unreliable
///
/// Note that the semantics we use for messages are not precisely
/// the same as the semantics of a standard "stream" socket.
/// (SOCK_STREAM) For an ordinary stream socket, the boundaries
/// between chunks are not considered relevant, and the sizes of
/// the chunks of data written will not necessarily match up to
/// the sizes of the chunks that are returned by the reads on
/// the other end. The remote host might read a partial chunk,
/// or chunks might be coalesced. For the message semantics
/// used here, however, the sizes WILL match. Each send call
/// will match a successful read call on the remote host
/// one-for-one. If you are porting existing stream-oriented
/// code to the semantics of reliable messages, your code should
/// work the same, since reliable message semantics are more
/// strict than stream semantics. The only caveat is related to
/// performance: there is per-message overhead to retain the
/// message sizes, and so if your code sends many small chunks
/// of data, performance will suffer. Any code based on stream
/// sockets that does not write excessively small chunks will
/// work without any changes.
///
/// The pOutMessageNumber is an optional pointer to receive the
/// message number assigned to the message, if sending was successful.
///
/// Returns:
/// - k_EResultInvalidParam: invalid connection handle, or the individual message is too big.
/// (See k_cbMaxSteamNetworkingSocketsMessageSizeSend)
/// - k_EResultInvalidState: connection is in an invalid state
/// - k_EResultNoConnection: connection has ended
/// - k_EResultIgnored: You used k_nSteamNetworkingSend_NoDelay, and the message was dropped because
/// we were not ready to send it.
/// - k_EResultLimitExceeded: there was already too much data queued to be sent.
/// (See k_ESteamNetworkingConfig_SendBufferSize)
EResult SendMessageToConnection( HSteamNetConnection hConn, const void *pData, uint32 cbData, int nSendFlags, int64 *pOutMessageNumber )
{
PRINT_DEBUG("%u, len %u, flags %i", hConn, cbData, nSendFlags);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return k_EResultInvalidParam;
if (connect_socket->second.status == CONNECT_SOCKET_CLOSED) return k_EResultNoConnection;
if (connect_socket->second.status == CONNECT_SOCKET_TIMEDOUT) return k_EResultNoConnection;
if (connect_socket->second.status != CONNECT_SOCKET_CONNECTED && connect_socket->second.status != CONNECT_SOCKET_CONNECTING) return k_EResultInvalidState;
Common_Message msg;
msg.set_source_id(connect_socket->second.created_by.ConvertToUint64());
msg.set_dest_id(connect_socket->second.remote_identity.GetSteamID64());
msg.set_allocated_networking_sockets(new Networking_Sockets);
msg.mutable_networking_sockets()->set_type(Networking_Sockets::DATA);
msg.mutable_networking_sockets()->set_virtual_port(connect_socket->second.virtual_port);
msg.mutable_networking_sockets()->set_real_port(connect_socket->second.real_port);
msg.mutable_networking_sockets()->set_connection_id_from(connect_socket->first);
msg.mutable_networking_sockets()->set_connection_id(connect_socket->second.remote_id);
msg.mutable_networking_sockets()->set_data(pData, cbData);
uint64 message_number = connect_socket->second.packet_send_counter;
msg.mutable_networking_sockets()->set_message_number(message_number);
connect_socket->second.packet_send_counter += 1;
bool reliable = false;
if (nSendFlags & k_nSteamNetworkingSend_Reliable) reliable = true;
if (network->sendTo(&msg, reliable)) {
if (pOutMessageNumber) *pOutMessageNumber = message_number;
return k_EResultOK;
}
return k_EResultFail;
}
EResult SendMessageToConnection( HSteamNetConnection hConn, const void *pData, uint32 cbData, int nSendFlags )
{
PRINT_DEBUG("old %u, len %u, flags %i", hConn, cbData, nSendFlags);
return SendMessageToConnection(hConn, pData, cbData, nSendFlags, NULL);
}
/// Send one or more messages without copying the message payload.
/// This is the most efficient way to send messages. To use this
/// function, you must first allocate a message object using
/// ISteamNetworkingUtils::AllocateMessage. (Do not declare one
/// on the stack or allocate your own.)
///
/// You should fill in the message payload. You can either let
/// it allocate the buffer for you and then fill in the payload,
/// or if you already have a buffer allocated, you can just point
/// m_pData at your buffer and set the callback to the appropriate function
/// to free it. Note that if you use your own buffer, it MUST remain valid
/// until the callback is executed. And also note that your callback can be
/// invoked at ant time from any thread (perhaps even before SendMessages
/// returns!), so it MUST be fast and threadsafe.
///
/// You MUST also fill in:
/// - m_conn - the handle of the connection to send the message to
/// - m_nFlags - bitmask of k_nSteamNetworkingSend_xxx flags.
///
/// All other fields are currently reserved and should not be modified.
///
/// The library will take ownership of the message structures. They may
/// be modified or become invalid at any time, so you must not read them
/// after passing them to this function.
///
/// pOutMessageNumberOrResult is an optional array that will receive,
/// for each message, the message number that was assigned to the message
/// if sending was successful. If sending failed, then a negative EResult
/// valid is placed into the array. For example, the array will hold
/// -k_EResultInvalidState if the connection was in an invalid state.
/// See ISteamNetworkingSockets::SendMessageToConnection for possible
/// failure codes.
void SendMessages( int nMessages, SteamNetworkingMessage_t *const *pMessages, int64 *pOutMessageNumberOrResult )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
for (int i = 0; i < nMessages; ++i) {
int64 out_number = 0;
int result = SendMessageToConnection(pMessages[i]->m_conn, pMessages[i]->m_pData, pMessages[i]->m_cbSize, pMessages[i]->m_nFlags, &out_number);
if (pOutMessageNumberOrResult) {
if (result == k_EResultOK) {
pOutMessageNumberOrResult[i] = out_number;
} else {
pOutMessageNumberOrResult[i] = -result;
}
}
pMessages[i]->m_pfnFreeData(pMessages[i]);
pMessages[i]->Release();
}
}
/// If Nagle is enabled (its on by default) then when calling
/// SendMessageToConnection the message will be queued up the Nagle time
/// before being sent to merge small messages into the same packet.
///
/// Call this function to flush any queued messages and send them immediately
/// on the next transmission time (often that means right now).
EResult FlushMessagesOnConnection( HSteamNetConnection hConn )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_EResultOK;
}
static void free_steam_message_data(SteamNetworkingMessage_t *pMsg)
{
free(pMsg->m_pData);
pMsg->m_pData = NULL;
}
static void delete_steam_message(SteamNetworkingMessage_t *pMsg)
{
if (pMsg->m_pfnFreeData) pMsg->m_pfnFreeData(pMsg);
delete pMsg;
}
SteamNetworkingMessage_t *get_steam_message_connection(HSteamNetConnection hConn)
{
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return NULL;
if (connect_socket->second.data.empty()) return NULL;
SteamNetworkingMessage_t *pMsg = new SteamNetworkingMessage_t();
unsigned long size = connect_socket->second.data.top().data().size();
pMsg->m_pData = malloc(size);
pMsg->m_cbSize = size;
memcpy(pMsg->m_pData, connect_socket->second.data.top().data().data(), size);
pMsg->m_conn = hConn;
pMsg->m_identityPeer = connect_socket->second.remote_identity;
pMsg->m_nConnUserData = connect_socket->second.user_data;
pMsg->m_usecTimeReceived = std::chrono::duration_cast<std::chrono::microseconds>(std::chrono::steady_clock::now() - created).count();
//TODO: check where messagenumber starts
pMsg->m_nMessageNumber = connect_socket->second.data.top().message_number();
pMsg->m_pfnFreeData = &free_steam_message_data;
pMsg->m_pfnRelease = &delete_steam_message;
pMsg->m_nChannel = 0;
connect_socket->second.data.pop();
PRINT_DEBUG("get_steam_message_connection %u %lu, %llu", hConn, size, pMsg->m_nMessageNumber);
return pMsg;
}
/// Fetch the next available message(s) from the connection, if any.
/// Returns the number of messages returned into your array, up to nMaxMessages.
/// If the connection handle is invalid, -1 is returned.
///
/// The order of the messages returned in the array is relevant.
/// Reliable messages will be received in the order they were sent (and with the
/// same sizes --- see SendMessageToConnection for on this subtle difference from a stream socket).
///
/// Unreliable messages may be dropped, or delivered out of order withrespect to
/// each other or with respect to reliable messages. The same unreliable message
/// may be received multiple times.
///
/// If any messages are returned, you MUST call SteamNetworkingMessage_t::Release() on each
/// of them free up resources after you are done. It is safe to keep the object alive for
/// a little while (put it into some queue, etc), and you may call Release() from any thread.
int ReceiveMessagesOnConnection( HSteamNetConnection hConn, SteamNetworkingMessage_t **ppOutMessages, int nMaxMessages )
{
PRINT_DEBUG("%u %i", hConn, nMaxMessages);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!ppOutMessages || !nMaxMessages) return 0;
SteamNetworkingMessage_t *msg = NULL;
int messages = 0;
while (messages < nMaxMessages && (msg = get_steam_message_connection(hConn))) {
ppOutMessages[messages] = msg;
++messages;
}
PRINT_DEBUG("messages %u", messages);
return messages;
}
/// Same as ReceiveMessagesOnConnection, but will return the next message available
/// on any connection that was accepted through the specified listen socket. Examine
/// SteamNetworkingMessage_t::m_conn to know which client connection.
///
/// Delivery order of messages among different clients is not defined. They may
/// be returned in an order different from what they were actually received. (Delivery
/// order of messages from the same client is well defined, and thus the order of the
/// messages is relevant!)
int ReceiveMessagesOnListenSocket( HSteamListenSocket hSocket, SteamNetworkingMessage_t **ppOutMessages, int nMaxMessages )
{
PRINT_DEBUG("%u %i", hSocket, nMaxMessages);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!ppOutMessages || !nMaxMessages) return 0;
SteamNetworkingMessage_t *msg = NULL;
int messages = 0;
auto socket_conn = std::begin(s->connect_sockets);
while (socket_conn != std::end(s->connect_sockets) && messages < nMaxMessages) {
if (socket_conn->second.listen_socket_id == hSocket) {
while (messages < nMaxMessages && (msg = get_steam_message_connection(socket_conn->first))) {
ppOutMessages[messages] = msg;
++messages;
}
}
++socket_conn;
}
return messages;
}
/// Returns basic information about the high-level state of the connection.
bool GetConnectionInfo( HSteamNetConnection hConn, SteamNetConnectionInfo_t *pInfo )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!pInfo) return false;
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return false;
set_steamnetconnectioninfo(connect_socket, pInfo);
//Note some games might not allocate a struct the whole size of SteamNetConnectionInfo_t
//keep this in mind in future interface updates
return true;
}
/// Returns a small set of information about the real-time state of the connection
/// and the queue status of each lane.
///
/// - pStatus may be NULL if the information is not desired. (E.g. you are only interested
/// in the lane information.)
/// - On entry, nLanes specifies the length of the pLanes array. This may be 0
/// if you do not wish to receive any lane data. It's OK for this to be smaller than
/// the total number of configured lanes.
/// - pLanes points to an array that will receive lane-specific info. It can be NULL
/// if this is not needed.
///
/// Return value:
/// - k_EResultNoConnection - connection handle is invalid or connection has been closed.
/// - k_EResultInvalidParam - nLanes is bad
EResult GetConnectionRealTimeStatus( HSteamNetConnection hConn, SteamNetConnectionRealTimeStatus_t *pStatus, int nLanes, SteamNetConnectionRealTimeLaneStatus_t *pLanes )
{
PRINT_DEBUG("%s %u %p %i %p", __FUNCTION__, hConn, pStatus, nLanes, pLanes);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return k_EResultNoConnection;
if (pStatus) {
pStatus->m_eState = convert_status(connect_socket->second.status);
pStatus->m_nPing = 10; //TODO: calculate real numbers?
pStatus->m_flConnectionQualityLocal = 1.0;
pStatus->m_flConnectionQualityRemote = 1.0;
//TODO: rest
pStatus->m_flOutPacketsPerSec = 0.0;
pStatus->m_flOutBytesPerSec = 0.0;
pStatus->m_flInPacketsPerSec = 0.0;
pStatus->m_flInBytesPerSec = 0.0;
pStatus->m_cbSentUnackedReliable = 0.0;
pStatus->m_usecQueueTime = 0.0;
//Note some games (volcanoids) might not allocate a struct the whole size of SteamNetworkingQuickConnectionStatus
//keep this in mind in future interface updates
//NOTE: need to implement GetQuickConnectionStatus seperately if this changes.
}
//TODO: lanes
return k_EResultOK;
}
/// Fetch the next available message(s) from the socket, if any.
/// Returns the number of messages returned into your array, up to nMaxMessages.
/// If the connection handle is invalid, -1 is returned.
///
/// The order of the messages returned in the array is relevant.
/// Reliable messages will be received in the order they were sent (and with the
/// same sizes --- see SendMessageToConnection for on this subtle difference from a stream socket).
///
/// FIXME - We're still debating the exact set of guarantees for unreliable, so this might change.
/// Unreliable messages may not be received. The order of delivery of unreliable messages
/// is NOT specified. They may be received out of order with respect to each other or
/// reliable messages. They may be received multiple times!
///
/// If any messages are returned, you MUST call Release() to each of them free up resources
/// after you are done. It is safe to keep the object alive for a little while (put it
/// into some queue, etc), and you may call Release() from any thread.
int ReceiveMessagesOnConnection( HSteamNetConnection hConn, SteamNetworkingMessage001_t **ppOutMessages, int nMaxMessages )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
/// Same as ReceiveMessagesOnConnection, but will return the next message available
/// on any client socket that was accepted through the specified listen socket. Examine
/// SteamNetworkingMessage_t::m_conn to know which client connection.
///
/// Delivery order of messages among different clients is not defined. They may
/// be returned in an order different from what they were actually received. (Delivery
/// order of messages from the same client is well defined, and thus the order of the
/// messages is relevant!)
int ReceiveMessagesOnListenSocket( HSteamListenSocket hSocket, SteamNetworkingMessage001_t **ppOutMessages, int nMaxMessages )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
/// Returns information about the specified connection.
bool GetConnectionInfo( HSteamNetConnection hConn, SteamNetConnectionInfo001_t *pInfo )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Returns brief set of connection status that you might want to display
/// to the user in game.
bool GetQuickConnectionStatus( HSteamNetConnection hConn, SteamNetworkingQuickConnectionStatus *pStats )
{
PRINT_DEBUG_ENTRY();
if (!pStats)
return false;
return GetConnectionRealTimeStatus(hConn, pStats, 0, NULL) == k_EResultOK;
}
/// Returns detailed connection stats in text format. Useful
/// for dumping to a log, etc.
///
/// Returns:
/// -1 failure (bad connection handle)
/// 0 OK, your buffer was filled in and '\0'-terminated
/// >0 Your buffer was either nullptr, or it was too small and the text got truncated. Try again with a buffer of at least N bytes.
int GetDetailedConnectionStatus( HSteamNetConnection hConn, char *pszBuf, int cbBuf )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
/// Returns local IP and port that a listen socket created using CreateListenSocketIP is bound to.
///
/// An IPv6 address of ::0 means "any IPv4 or IPv6"
/// An IPv6 address of ::ffff:0000:0000 means "any IPv4"
bool GetListenSocketAddress( HSteamListenSocket hSocket, SteamNetworkingIPAddr *address )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Returns information about the listen socket.
///
/// *pnIP and *pnPort will be 0 if the socket is set to listen for connections based
/// on SteamID only. If your listen socket accepts connections on IPv4, then both
/// fields will return nonzero, even if you originally passed a zero IP. However,
/// note that the address returned may be a private address (e.g. 10.0.0.x or 192.168.x.x),
/// and may not be reachable by a general host on the Internet.
bool GetListenSocketInfo( HSteamListenSocket hSocket, uint32 *pnIP, uint16 *pnPort )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct Listen_Socket *socket = get_connection_socket(hSocket);
if (!socket) return false;
if (pnIP) *pnIP = 0;//socket->ip;
if (pnPort) *pnPort = 0;//socket->port;
return true;
}
/// Create a pair of connections that are talking to each other, e.g. a loopback connection.
/// This is very useful for testing, or so that your client/server code can work the same
/// even when you are running a local "server".
///
/// The two connections will immediately be placed into the connected state, and no callbacks
/// will be posted immediately. After this, if you close either connection, the other connection
/// will receive a callback, exactly as if they were communicating over the network. You must
/// close *both* sides in order to fully clean up the resources!
///
/// By default, internal buffers are used, completely bypassing the network, the chopping up of
/// messages into packets, encryption, copying the payload, etc. This means that loopback
/// packets, by default, will not simulate lag or loss. Passing true for bUseNetworkLoopback will
/// cause the socket pair to send packets through the local network loopback device (127.0.0.1)
/// on ephemeral ports. Fake lag and loss are supported in this case, and CPU time is expended
/// to encrypt and decrypt.
///
/// The SteamID assigned to both ends of the connection will be the SteamID of this interface.
bool CreateSocketPair( HSteamNetConnection *pOutConnection1, HSteamNetConnection *pOutConnection2, bool bUseNetworkLoopback )
{
PRINT_DEBUG("old");
return CreateSocketPair(pOutConnection1, pOutConnection2, bUseNetworkLoopback, NULL, NULL);
}
/// Create a pair of connections that are talking to each other, e.g. a loopback connection.
/// This is very useful for testing, or so that your client/server code can work the same
/// even when you are running a local "server".
///
/// The two connections will immediately be placed into the connected state, and no callbacks
/// will be posted immediately. After this, if you close either connection, the other connection
/// will receive a callback, exactly as if they were communicating over the network. You must
/// close *both* sides in order to fully clean up the resources!
///
/// By default, internal buffers are used, completely bypassing the network, the chopping up of
/// messages into packets, encryption, copying the payload, etc. This means that loopback
/// packets, by default, will not simulate lag or loss. Passing true for bUseNetworkLoopback will
/// cause the socket pair to send packets through the local network loopback device (127.0.0.1)
/// on ephemeral ports. Fake lag and loss are supported in this case, and CPU time is expended
/// to encrypt and decrypt.
///
/// If you wish to assign a specific identity to either connection, you may pass a particular
/// identity. Otherwise, if you pass nullptr, the respective connection will assume a generic
/// "localhost" identity. If you use real network loopback, this might be translated to the
/// actual bound loopback port. Otherwise, the port will be zero.
bool CreateSocketPair( HSteamNetConnection *pOutConnection1, HSteamNetConnection *pOutConnection2, bool bUseNetworkLoopback, const SteamNetworkingIdentity *pIdentity1, const SteamNetworkingIdentity *pIdentity2 )
{
PRINT_DEBUG("%u %p %p", bUseNetworkLoopback, pIdentity1, pIdentity2);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!pOutConnection1 || !pOutConnection1) return false;
SteamNetworkingIdentity remote_identity;
remote_identity.SetSteamID(settings->get_local_steam_id());
HSteamNetConnection con1 = new_connect_socket(remote_identity, 0, SNS_DISABLED_PORT, CONNECT_SOCKET_CONNECTED, k_HSteamListenSocket_Invalid, k_HSteamNetConnection_Invalid);
HSteamNetConnection con2 = new_connect_socket(remote_identity, 0, SNS_DISABLED_PORT, CONNECT_SOCKET_CONNECTED, k_HSteamListenSocket_Invalid, con1);
s->connect_sockets[con1].remote_id = con2;
*pOutConnection1 = con1;
*pOutConnection2 = con2;
return true;
}
/// Configure multiple outbound messages streams ("lanes") on a connection, and
/// control head-of-line blocking between them. Messages within a given lane
/// are always sent in the order they are queued, but messages from different
/// lanes may be sent out of order. Each lane has its own message number
/// sequence. The first message sent on each lane will be assigned the number 1.
///
/// Each lane has a "priority". Lower priority lanes will only be processed
/// when all higher-priority lanes are empty. The magnitudes of the priority
/// values are not relevant, only their sort order. Higher numeric values
/// take priority over lower numeric values.
///
/// Each lane also is assigned a weight, which controls the approximate proportion
/// of the bandwidth that will be consumed by the lane, relative to other lanes
/// of the same priority. (This is assuming the lane stays busy. An idle lane
/// does not build up "credits" to be be spent once a message is queued.)
/// This value is only meaningful as a proportion, relative to other lanes with
/// the same priority. For lanes with different priorities, the strict priority
/// order will prevail, and their weights relative to each other are not relevant.
/// Thus, if a lane has a unique priority value, the weight value for that lane is
/// not relevant.
///
/// Example: 3 lanes, with priorities [ 0, 10, 10 ] and weights [ (NA), 20, 5 ].
/// Messages sent on the first will always be sent first, before messages in the
/// other two lanes. Its weight value is irrelevant, since there are no other
/// lanes with priority=0. The other two lanes will share bandwidth, with the second
/// and third lanes sharing bandwidth using a ratio of approximately 4:1.
/// (The weights [ NA, 4, 1 ] would be equivalent.)
///
/// Notes:
/// - At the time of this writing, some code has performance cost that is linear
/// in the number of lanes, so keep the number of lanes to an absolute minimum.
/// 3 or so is fine; >8 is a lot. The max number of lanes on Steam is 255,
/// which is a very large number and not recommended! If you are compiling this
/// library from source, see STEAMNETWORKINGSOCKETS_MAX_LANES.)
/// - Lane priority values may be any int. Their absolute value is not relevant,
/// only the order matters.
/// - Weights must be positive, and due to implementation details, they are restricted
/// to 16-bit values. The absolute magnitudes don't matter, just the proportions.
/// - Messages sent on a lane index other than 0 have a small overhead on the wire,
/// so for maximum wire efficiency, lane 0 should be the "most common" lane, regardless
/// of priorities or weights.
/// - A connection has a single lane by default. Calling this function with
/// nNumLanes=1 is legal, but pointless, since the priority and weight values are
/// irrelevant in that case.
/// - You may reconfigure connection lanes at any time, however reducing the number of
/// lanes is not allowed.
/// - Reconfiguring lanes might restart any bandwidth sharing balancing. Usually you
/// will call this function once, near the start of the connection, perhaps after
/// exchanging a few messages.
/// - To assign all lanes the same priority, you may use pLanePriorities=NULL.
/// - If you wish all lanes with the same priority to share bandwidth equally (or
/// if no two lanes have the same priority value, and thus priority values are
/// irrelevant), you may use pLaneWeights=NULL
/// - Priorities and weights determine the order that messages are SENT on the wire.
/// There are NO GUARANTEES on the order that messages are RECEIVED! Due to packet
/// loss, out-of-order delivery, and subtle details of packet serialization, messages
/// might still be received slightly out-of-order! The *only* strong guarantee is that
/// *reliable* messages on the *same lane* will be delivered in the order they are sent.
/// - Each host configures the lanes for the packets they send; the lanes for the flow
/// in one direction are completely unrelated to the lanes in the opposite direction.
///
/// Return value:
/// - k_EResultNoConnection - bad hConn
/// - k_EResultInvalidParam - Invalid number of lanes, bad weights, or you tried to reduce the number of lanes
/// - k_EResultInvalidState - Connection is already dead, etc
///
/// See also:
/// SteamNetworkingMessage_t::m_idxLane
EResult ConfigureConnectionLanes( HSteamNetConnection hConn, int nNumLanes, const int *pLanePriorities, const uint16 *pLaneWeights )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) return k_EResultNoConnection;
//TODO
return k_EResultOK;
}
/// Get the identity assigned to this interface.
/// E.g. on Steam, this is the user's SteamID, or for the gameserver interface, the SteamID assigned
/// to the gameserver. Returns false and sets the result to an invalid identity if we don't know
/// our identity yet. (E.g. GameServer has not logged in. On Steam, the user will know their SteamID
/// even if they are not signed into Steam.)
bool GetIdentity( SteamNetworkingIdentity *pIdentity )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!pIdentity) return false;
pIdentity->SetSteamID(settings->get_local_steam_id());
return true;
}
/// Indicate our desire to be ready participate in authenticated communications.
/// If we are currently not ready, then steps will be taken to obtain the necessary
/// certificates. (This includes a certificate for us, as well as any CA certificates
/// needed to authenticate peers.)
///
/// You can call this at program init time if you know that you are going to
/// be making authenticated connections, so that we will be ready immediately when
/// those connections are attempted. (Note that essentially all connections require
/// authentication, with the exception of ordinary UDP connections with authentication
/// disabled using k_ESteamNetworkingConfig_IP_AllowWithoutAuth.) If you don't call
/// this function, we will wait until a feature is utilized that that necessitates
/// these resources.
///
/// You can also call this function to force a retry, if failure has occurred.
/// Once we make an attempt and fail, we will not automatically retry.
/// In this respect, the behavior of the system after trying and failing is the same
/// as before the first attempt: attempting authenticated communication or calling
/// this function will call the system to attempt to acquire the necessary resources.
///
/// You can use GetAuthenticationStatus or listen for SteamNetAuthenticationStatus_t
/// to monitor the status.
///
/// Returns the current value that would be returned from GetAuthenticationStatus.
ESteamNetworkingAvailability InitAuthentication()
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_ESteamNetworkingAvailability_Current;
}
/// Query our readiness to participate in authenticated communications. A
/// SteamNetAuthenticationStatus_t callback is posted any time this status changes,
/// but you can use this function to query it at any time.
///
/// The value of SteamNetAuthenticationStatus_t::m_eAvail is returned. If you only
/// want this high level status, you can pass NULL for pDetails. If you want further
/// details, pass non-NULL to receive them.
ESteamNetworkingAvailability GetAuthenticationStatus( SteamNetAuthenticationStatus_t *pDetails )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_ESteamNetworkingAvailability_Current;
}
/// Create a new poll group.
///
/// You should destroy the poll group when you are done using DestroyPollGroup
HSteamNetPollGroup CreatePollGroup()
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
static HSteamNetPollGroup poll_group_counter;
++poll_group_counter;
HSteamNetPollGroup poll_group_number = poll_group_counter;
s->poll_groups[poll_group_number] = std::list<HSteamNetConnection>();
return poll_group_number;
}
/// Destroy a poll group created with CreatePollGroup().
///
/// If there are any connections in the poll group, they are removed from the group,
/// and left in a state where they are not part of any poll group.
/// Returns false if passed an invalid poll group handle.
bool DestroyPollGroup( HSteamNetPollGroup hPollGroup )
{
PRINT_DEBUG_ENTRY();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto group = s->poll_groups.find(hPollGroup);
if (group == s->poll_groups.end()) {
return false;
}
for (auto c : group->second) {
auto connect_socket = s->connect_sockets.find(c);
if (connect_socket != s->connect_sockets.end()) {
connect_socket->second.poll_group = k_HSteamNetPollGroup_Invalid;
}
}
s->poll_groups.erase(group);
return true;
}
/// Assign a connection to a poll group. Note that a connection may only belong to a
/// single poll group. Adding a connection to a poll group implicitly removes it from
/// any other poll group it is in.
///
/// You can pass k_HSteamNetPollGroup_Invalid to remove a connection from its current
/// poll group without adding it to a new poll group.
///
/// If there are received messages currently pending on the connection, an attempt
/// is made to add them to the queue of messages for the poll group in approximately
/// the order that would have applied if the connection was already part of the poll
/// group at the time that the messages were received.
///
/// Returns false if the connection handle is invalid, or if the poll group handle
/// is invalid (and not k_HSteamNetPollGroup_Invalid).
bool SetConnectionPollGroup( HSteamNetConnection hConn, HSteamNetPollGroup hPollGroup )
{
PRINT_DEBUG("%u %u", hConn, hPollGroup);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto connect_socket = s->connect_sockets.find(hConn);
if (connect_socket == s->connect_sockets.end()) {
return false;
}
auto group = s->poll_groups.find(hPollGroup);
if (group == s->poll_groups.end() && hPollGroup != k_HSteamNetPollGroup_Invalid) {
return false;
}
HSteamNetPollGroup old_poll_group = connect_socket->second.poll_group;
if (old_poll_group != k_HSteamNetPollGroup_Invalid) {
auto group = s->poll_groups.find(hPollGroup);
if (group != s->poll_groups.end()) {
group->second.remove(hConn);
}
}
connect_socket->second.poll_group = hPollGroup;
if (hPollGroup == k_HSteamNetPollGroup_Invalid) {
return true;
}
group->second.push_back(hConn);
return true;
}
/// Same as ReceiveMessagesOnConnection, but will return the next messages available
/// on any connection in the poll group. Examine SteamNetworkingMessage_t::m_conn
/// to know which connection. (SteamNetworkingMessage_t::m_nConnUserData might also
/// be useful.)
///
/// Delivery order of messages among different connections will usually match the
/// order that the last packet was received which completed the message. But this
/// is not a strong guarantee, especially for packets received right as a connection
/// is being assigned to poll group.
///
/// Delivery order of messages on the same connection is well defined and the
/// same guarantees are present as mentioned in ReceiveMessagesOnConnection.
/// (But the messages are not grouped by connection, so they will not necessarily
/// appear consecutively in the list; they may be interleaved with messages for
/// other connections.)
int ReceiveMessagesOnPollGroup( HSteamNetPollGroup hPollGroup, SteamNetworkingMessage_t **ppOutMessages, int nMaxMessages )
{
PRINT_DEBUG("%u %i", hPollGroup, nMaxMessages);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto group = s->poll_groups.find(hPollGroup);
if (group == s->poll_groups.end()) {
return 0;
}
SteamNetworkingMessage_t *msg = NULL;
int messages = 0;
for (auto c : group->second) {
while (messages < nMaxMessages && (msg = get_steam_message_connection(c))) {
ppOutMessages[messages] = msg;
++messages;
}
}
PRINT_DEBUG("out %i", messages);
return messages;
}
//#ifndef STEAMNETWORKINGSOCKETS_OPENSOURCE
//
// Clients connecting to dedicated servers hosted in a data center,
// using central-authority-granted tickets.
//
/// Called when we receive a ticket from our central matchmaking system. Puts the
/// ticket into a persistent cache, and optionally returns the parsed ticket.
///
/// See stamdatagram_ticketgen.h for more details.
bool ReceivedRelayAuthTicket( const void *pvTicket, int cbTicket, SteamDatagramRelayAuthTicket *pOutParsedTicket )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Search cache for a ticket to talk to the server on the specified virtual port.
/// If found, returns the number of second until the ticket expires, and optionally
/// the complete cracked ticket. Returns 0 if we don't have a ticket.
///
/// Typically this is useful just to confirm that you have a ticket, before you
/// call ConnectToHostedDedicatedServer to connect to the server.
int FindRelayAuthTicketForServer( CSteamID steamID, int nVirtualPort, SteamDatagramRelayAuthTicket *pOutParsedTicket )
{
PRINT_DEBUG("old");
return 0;
}
/// Search cache for a ticket to talk to the server on the specified virtual port.
/// If found, returns the number of seconds until the ticket expires, and optionally
/// the complete cracked ticket. Returns 0 if we don't have a ticket.
///
/// Typically this is useful just to confirm that you have a ticket, before you
/// call ConnectToHostedDedicatedServer to connect to the server.
int FindRelayAuthTicketForServer( const SteamNetworkingIdentity *identityGameServer, int nVirtualPort, SteamDatagramRelayAuthTicket *pOutParsedTicket )
{
PRINT_DEBUG("old1");
return 0;
}
int FindRelayAuthTicketForServer( const SteamNetworkingIdentity &identityGameServer, int nVirtualPort, SteamDatagramRelayAuthTicket *pOutParsedTicket )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return 0;
}
/// Client call to connect to a server hosted in a Valve data center, on the specified virtual
/// port. You must have placed a ticket for this server into the cache, or else this connect attempt will fail!
///
/// You may wonder why tickets are stored in a cache, instead of simply being passed as an argument
/// here. The reason is to make reconnection to a gameserver robust, even if the client computer loses
/// connection to Steam or the central backend, or the app is restarted or crashes, etc.
///
/// If you use this, you probably want to call ISteamNetworkingUtils::InitializeRelayNetworkAccess()
/// when your app initializes
HSteamNetConnection ConnectToHostedDedicatedServer( const SteamNetworkingIdentity &identityTarget, int nVirtualPort )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamListenSocket_Invalid;
}
HSteamNetConnection ConnectToHostedDedicatedServer( const SteamNetworkingIdentity *identityTarget, int nVirtualPort )
{
PRINT_DEBUG("old1");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamListenSocket_Invalid;
}
/// Client call to connect to a server hosted in a Valve data center, on the specified virtual
/// port. You should have received a ticket for this server, or else this connect call will fail!
///
/// You may wonder why tickets are stored in a cache, instead of simply being passed as an argument
/// here. The reason is to make reconnection to a gameserver robust, even if the client computer loses
/// connection to Steam or the central backend, or the app is restarted or crashes, etc.
HSteamNetConnection ConnectToHostedDedicatedServer( CSteamID steamIDTarget, int nVirtualPort )
{
PRINT_DEBUG("older");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamListenSocket_Invalid;
}
HSteamNetConnection ConnectToHostedDedicatedServer( const SteamNetworkingIdentity &identityTarget, int nVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamListenSocket_Invalid;
}
//
// Servers hosted in Valve data centers
//
/// Returns the value of the SDR_LISTEN_PORT environment variable.
uint16 GetHostedDedicatedServerPort()
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
//TODO?
return 27054;
}
/// If you are running in a production data center, this will return the data
/// center code. Returns 0 otherwise.
SteamNetworkingPOPID GetHostedDedicatedServerPOPID()
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return 0;
}
/// Return info about the hosted server. You will need to send this information to your
/// backend, and put it in tickets, so that the relays will know how to forward traffic from
/// clients to your server. See SteamDatagramRelayAuthTicket for more info.
///
/// NOTE ABOUT DEVELOPMENT ENVIRONMENTS:
/// In production in our data centers, these parameters are configured via environment variables.
/// In development, the only one you need to set is SDR_LISTEN_PORT, which is the local port you
/// want to listen on. Furthermore, if you are running your server behind a corporate firewall,
/// you probably will not be able to put the routing information returned by this function into
/// tickets. Instead, it should be a public internet address that the relays can use to send
/// data to your server. So you might just end up hardcoding a public address and setup port
/// forwarding on your corporate firewall. In that case, the port you put into the ticket
/// needs to be the public-facing port opened on your firewall, if it is different from the
/// actual server port.
///
/// This function will fail if SteamDatagramServer_Init has not been called.
///
/// Returns false if the SDR_LISTEN_PORT environment variable is not set.
bool GetHostedDedicatedServerAddress001( SteamDatagramHostedAddress *pRouting )
{
PRINT_DEBUG("%p", pRouting);
return GetHostedDedicatedServerAddress(pRouting) == k_EResultOK;
}
/// Return info about the hosted server. This contains the PoPID of the server,
/// and opaque routing information that can be used by the relays to send traffic
/// to your server.
///
/// You will need to send this information to your backend, and put it in tickets,
/// so that the relays will know how to forward traffic from
/// clients to your server. See SteamDatagramRelayAuthTicket for more info.
///
/// Also, note that the routing information is contained in SteamDatagramGameCoordinatorServerLogin,
/// so if possible, it's preferred to use GetGameCoordinatorServerLogin to send this info
/// to your game coordinator service, and also login securely at the same time.
///
/// On a successful exit, k_EResultOK is returned
///
/// Unsuccessful exit:
/// - Something other than k_EResultOK is returned.
/// - k_EResultInvalidState: We are not configured to listen for SDR (SDR_LISTEN_SOCKET
/// is not set.)
/// - k_EResultPending: we do not (yet) have the authentication information needed.
/// (See GetAuthenticationStatus.) If you use environment variables to pre-fetch
/// the network config, this data should always be available immediately.
/// - A non-localized diagnostic debug message will be placed in m_data that describes
/// the cause of the failure.
///
/// NOTE: The returned blob is not encrypted. Send it to your backend, but don't
/// directly share it with clients.
virtual EResult GetHostedDedicatedServerAddress( SteamDatagramHostedAddress *pRouting )
{
PRINT_DEBUG("%p", pRouting);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
pRouting->SetDevAddress(network->getOwnIP(), 27054);
return k_EResultOK;
}
/// Create a listen socket on the specified virtual port. The physical UDP port to use
/// will be determined by the SDR_LISTEN_PORT environment variable. If a UDP port is not
/// configured, this call will fail.
///
/// Note that this call MUST be made through the SteamNetworkingSocketsGameServer() interface
HSteamListenSocket CreateHostedDedicatedServerListenSocket( int nVirtualPort )
{
PRINT_DEBUG("old %i", nVirtualPort);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(nVirtualPort, SNS_DISABLED_PORT);
}
/// Create a listen socket on the specified virtual port. The physical UDP port to use
/// will be determined by the SDR_LISTEN_PORT environment variable. If a UDP port is not
/// configured, this call will fail.
///
/// Note that this call MUST be made through the SteamGameServerNetworkingSockets() interface
///
/// If you need to set any initial config options, pass them here. See
/// SteamNetworkingConfigValue_t for more about why this is preferable to
/// setting the options "immediately" after creation.
HSteamListenSocket CreateHostedDedicatedServerListenSocket( int nVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG("old %i", nVirtualPort);
//TODO config options
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return new_listen_socket(nVirtualPort, SNS_DISABLED_PORT);
}
//#endif // #ifndef STEAMNETWORKINGSOCKETS_OPENSOURCE
//
// Gets some debug text from the connection
//
bool GetConnectionDebugText( HSteamNetConnection hConn, char *pOut, int nOutCCH )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
//
// Set and get configuration values, see ESteamNetworkingConfigurationValue for individual descriptions.
//
// Returns the value or -1 is eConfigValue is invalid
int32 GetConfigurationValue( ESteamNetworkingConfigurationValue eConfigValue )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
// Returns true if successfully set
bool SetConfigurationValue( ESteamNetworkingConfigurationValue eConfigValue, int32 nValue )
{
PRINT_DEBUG("%i: %i", eConfigValue, nValue);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return true;
}
// Return the name of an int configuration value, or NULL if config value isn't known
const char *GetConfigurationValueName( ESteamNetworkingConfigurationValue eConfigValue )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return NULL;
}
//
// Set and get configuration strings, see ESteamNetworkingConfigurationString for individual descriptions.
//
// Get the configuration string, returns length of string needed if pDest is nullpr or destSize is 0
// returns -1 if the eConfigValue is invalid
int32 GetConfigurationString( ESteamNetworkingConfigurationString eConfigString, char *pDest, int32 destSize )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
bool SetConfigurationString( ESteamNetworkingConfigurationString eConfigString, const char *pString )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
// Return the name of a string configuration value, or NULL if config value isn't known
const char *GetConfigurationStringName( ESteamNetworkingConfigurationString eConfigString )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return NULL;
}
//
// Set and get configuration values, see ESteamNetworkingConnectionConfigurationValue for individual descriptions.
//
// Returns the value or -1 is eConfigValue is invalid
int32 GetConnectionConfigurationValue( HSteamNetConnection hConn, ESteamNetworkingConnectionConfigurationValue eConfigValue )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return -1;
}
// Returns true if successfully set
bool SetConnectionConfigurationValue( HSteamNetConnection hConn, ESteamNetworkingConnectionConfigurationValue eConfigValue, int32 nValue )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Generate an authentication blob that can be used to securely login with
/// your backend, using SteamDatagram_ParseHostedServerLogin. (See
/// steamdatagram_gamecoordinator.h)
///
/// Before calling the function:
/// - Populate the app data in pLoginInfo (m_cbAppData and m_appData). You can leave
/// all other fields uninitialized.
/// - *pcbSignedBlob contains the size of the buffer at pBlob. (It should be
/// at least k_cbMaxSteamDatagramGameCoordinatorServerLoginSerialized.)
///
/// On a successful exit:
/// - k_EResultOK is returned
/// - All of the remaining fields of pLoginInfo will be filled out.
/// - *pcbSignedBlob contains the size of the serialized blob that has been
/// placed into pBlob.
///
/// Unsuccessful exit:
/// - Something other than k_EResultOK is returned.
/// - k_EResultNotLoggedOn: you are not logged in (yet)
/// - See GetHostedDedicatedServerAddress for more potential failure return values.
/// - A non-localized diagnostic debug message will be placed in pBlob that describes
/// the cause of the failure.
///
/// This works by signing the contents of the SteamDatagramGameCoordinatorServerLogin
/// with the cert that is issued to this server. In dev environments, it's OK if you do
/// not have a cert. (You will need to enable insecure dev login in SteamDatagram_ParseHostedServerLogin.)
/// Otherwise, you will need a signed cert.
///
/// NOTE: The routing blob returned here is not encrypted. Send it to your backend
/// and don't share it directly with clients.
EResult GetGameCoordinatorServerLogin( SteamDatagramGameCoordinatorServerLogin *pLoginInfo, int *pcbSignedBlob, void *pBlob )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_EResultFail;
}
//
// Relayed connections using custom signaling protocol
//
// This is used if you have your own method of sending out-of-band
// signaling / rendezvous messages through a mutually trusted channel.
//
/// Create a P2P "client" connection that does signaling over a custom
/// rendezvous/signaling channel.
///
/// pSignaling points to a new object that you create just for this connection.
/// It must stay valid until Release() is called. Once you pass the
/// object to this function, it assumes ownership. Release() will be called
/// from within the function call if the call fails. Furthermore, until Release()
/// is called, you should be prepared for methods to be invoked on your
/// object from any thread! You need to make sure your object is threadsafe!
/// Furthermore, you should make sure that dispatching the methods is done
/// as quickly as possible.
///
/// This function will immediately construct a connection in the "connecting"
/// state. Soon after (perhaps before this function returns, perhaps in another thread),
/// the connection will begin sending signaling messages by calling
/// ISteamNetworkingConnectionCustomSignaling::SendSignal.
///
/// When the remote peer accepts the connection (See
/// ISteamNetworkingCustomSignalingRecvContext::OnConnectRequest),
/// it will begin sending signaling messages. When these messages are received,
/// you can pass them to the connection using ReceivedP2PCustomSignal.
///
/// If you know the identity of the peer that you expect to be on the other end,
/// you can pass their identity to improve debug output or just detect bugs.
/// If you don't know their identity yet, you can pass NULL, and their
/// identity will be established in the connection handshake.
///
/// If you use this, you probably want to call ISteamNetworkingUtils::InitRelayNetworkAccess()
/// when your app initializes
///
/// If you need to set any initial config options, pass them here. See
/// SteamNetworkingConfigValue_t for more about why this is preferable to
/// setting the options "immediately" after creation.
HSteamNetConnection ConnectP2PCustomSignaling( ISteamNetworkingConnectionCustomSignaling *pSignaling, const SteamNetworkingIdentity *pPeerIdentity, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
//return ConnectP2PCustomSignaling(pSignaling, pPeerIdentity, 0, nOptions, pOptions);
return k_HSteamNetConnection_Invalid;
}
//HSteamNetConnection ConnectP2PCustomSignaling( ISteamNetworkingConnectionCustomSignaling *pSignaling, const SteamNetworkingIdentity *pPeerIdentity, int nRemoteVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
HSteamNetConnection ConnectP2PCustomSignaling( ISteamNetworkingConnectionSignaling *pSignaling, const SteamNetworkingIdentity *pPeerIdentity, int nRemoteVirtualPort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamNetConnection_Invalid;
}
/// Called when custom signaling has received a message. When your
/// signaling channel receives a message, it should save off whatever
/// routing information was in the envelope into the context object,
/// and then pass the payload to this function.
///
/// A few different things can happen next, depending on the message:
///
/// - If the signal is associated with existing connection, it is dealt
/// with immediately. If any replies need to be sent, they will be
/// dispatched using the ISteamNetworkingConnectionCustomSignaling
/// associated with the connection.
/// - If the message represents a connection request (and the request
/// is not redundant for an existing connection), a new connection
/// will be created, and ReceivedConnectRequest will be called on your
/// context object to determine how to proceed.
/// - Otherwise, the message is for a connection that does not
/// exist (anymore). In this case, we *may* call SendRejectionReply
/// on your context object.
///
/// In any case, we will not save off pContext or access it after this
/// function returns.
///
/// Returns true if the message was parsed and dispatched without anything
/// unusual or suspicious happening. Returns false if there was some problem
/// with the message that prevented ordinary handling. (Debug output will
/// usually have more information.)
///
/// If you expect to be using relayed connections, then you probably want
/// to call ISteamNetworkingUtils::InitRelayNetworkAccess() when your app initializes
bool ReceivedP2PCustomSignal( const void *pMsg, int cbMsg, ISteamNetworkingCustomSignalingRecvContext *pContext )
{
PRINT_DEBUG("old");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
bool ReceivedP2PCustomSignal( const void *pMsg, int cbMsg, ISteamNetworkingSignalingRecvContext *pContext )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
//
// Certificate provision by the application. On Steam, we normally handle all this automatically
// and you will not need to use these advanced functions.
//
/// Get blob that describes a certificate request. You can send this to your game coordinator.
/// Upon entry, *pcbBlob should contain the size of the buffer. On successful exit, it will
/// return the number of bytes that were populated. You can pass pBlob=NULL to query for the required
/// size. (256 bytes is a very conservative estimate.)
///
/// Pass this blob to your game coordinator and call SteamDatagram_CreateCert.
bool GetCertificateRequest( int *pcbBlob, void *pBlob, SteamNetworkingErrMsg &errMsg )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Set the certificate. The certificate blob should be the output of
/// SteamDatagram_CreateCert.
bool SetCertificate( const void *pCertificate, int cbCertificate, SteamNetworkingErrMsg &errMsg )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Reset the identity associated with this instance.
/// Any open connections are closed. Any previous certificates, etc are discarded.
/// You can pass a specific identity that you want to use, or you can pass NULL,
/// in which case the identity will be invalid until you set it using SetCertificate
///
/// NOTE: This function is not actually supported on Steam! It is included
/// for use on other platforms where the active user can sign out and
/// a new user can sign in.
void ResetIdentity( const SteamNetworkingIdentity *pIdentity )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
}
//
// "FakeIP" system.
//
// A FakeIP is essentially a temporary, arbitrary identifier that
// happens to be a valid IPv4 address. The purpose of this system is to make it
// easy to integrate with existing code that identifies hosts using IPv4 addresses.
// The FakeIP address will never actually be used to send or receive any packets
// on the Internet, it is strictly an identifier.
//
// FakeIP addresses are designed to (hopefully) pass through existing code as
// transparently as possible, while conflicting with "real" addresses that might
// be in use on networks (both the Internet and LANs) in the same code as little
// as possible. At the time this comment is being written, they come from the
// 169.254.0.0/16 range, and the port number will always be >1024. HOWEVER,
// this is subject to change! Do not make assumptions about these addresses,
// or your code might break in the future. In particular, you should use
// functions such as ISteamNetworkingUtils::IsFakeIP to determine if an IP
// address is a "fake" one used by this system.
//
/// Begin asynchronous process of allocating a fake IPv4 address that other
/// peers can use to contact us via P2P. IP addresses returned by this
/// function are globally unique for a given appid.
///
/// nNumPorts is the numbers of ports you wish to reserve. This is useful
/// for the same reason that listening on multiple UDP ports is useful for
/// different types of traffic. Because these allocations come from a global
/// namespace, there is a relatively strict limit on the maximum number of
/// ports you may request. (At the time of this writing, the limit is 4.)
/// The Port assignments are *not* guaranteed to have any particular order
/// or relationship! Do *not* assume they are contiguous, even though that
/// may often occur in practice.
///
/// Returns false if a request was already in progress, true if a new request
/// was started. A SteamNetworkingFakeIPResult_t will be posted when the request
/// completes.
///
/// For gameservers, you *must* call this after initializing the SDK but before
/// beginning login. Steam needs to know in advance that FakeIP will be used.
/// Everywhere your public IP would normally appear (such as the server browser) will be
/// replaced by the FakeIP, and the fake port at index 0. The request is actually queued
/// until the logon completes, so you must not wait until the allocation completes
/// before logging in. Except for trivial failures that can be detected locally
/// (e.g. invalid parameter), a SteamNetworkingFakeIPResult_t callback (whether success or
/// failure) will not be posted until after we have logged in. Furthermore, it is assumed
/// that FakeIP allocation is essential for your application to function, and so failure
/// will not be reported until *several* retries have been attempted. This process may
/// last several minutes. It is *highly* recommended to treat failure as fatal.
///
/// To communicate using a connection-oriented (TCP-style) API:
/// - Server creates a listen socket using CreateListenSocketP2PFakeIP
/// - Client connects using ConnectByIPAddress, passing in the FakeIP address.
/// - The connection will behave mostly like a P2P connection. The identities
/// that appear in SteamNetConnectionInfo_t will be the FakeIP identity until
/// we know the real identity. Then it will be the real identity. If the
/// SteamNetConnectionInfo_t::m_addrRemote is valid, it will be a real IPv4
/// address of a NAT-punched connection. Otherwise, it will not be valid.
///
/// To communicate using an ad-hoc sendto/recv from (UDP-style) API,
/// use CreateFakeUDPPort.
bool BeginAsyncRequestFakeIP( int nNumPorts )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return false;
}
/// Return info about the FakeIP and port(s) that we have been assigned,
/// if any. idxFirstPort is currently reserved and must be zero.
/// Make sure and check SteamNetworkingFakeIPResult_t::m_eResult
void GetFakeIP( int idxFirstPort, SteamNetworkingFakeIPResult_t *pInfo )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
}
/// Create a listen socket that will listen for P2P connections sent
/// to our FakeIP. A peer can initiate connections to this listen
/// socket by calling ConnectByIPAddress.
///
/// idxFakePort refers to the *index* of the fake port requested,
/// not the actual port number. For example, pass 0 to refer to the
/// first port in the reservation. You must call this only after calling
/// BeginAsyncRequestFakeIP. However, you do not need to wait for the
/// request to complete before creating the listen socket.
HSteamListenSocket CreateListenSocketP2PFakeIP( int idxFakePort, int nOptions, const SteamNetworkingConfigValue_t *pOptions )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_HSteamListenSocket_Invalid;
}
/// If the connection was initiated using the "FakeIP" system, then we
/// we can get an IP address for the remote host. If the remote host had
/// a global FakeIP at the time the connection was established, this
/// function will return that global IP. Otherwise, a FakeIP that is
/// unique locally will be allocated from the local FakeIP address space,
/// and that will be returned.
///
/// The allocation of local FakeIPs attempts to assign addresses in
/// a consistent manner. If multiple connections are made to the
/// same remote host, they *probably* will return the same FakeIP.
/// However, since the namespace is limited, this cannot be guaranteed.
///
/// On failure, returns:
/// - k_EResultInvalidParam: invalid connection handle
/// - k_EResultIPNotFound: This connection wasn't made using FakeIP system
EResult GetRemoteFakeIPForConnection( HSteamNetConnection hConn, SteamNetworkingIPAddr *pOutAddr )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return k_EResultNone;
}
/// Get an interface that can be used like a UDP port to send/receive
/// datagrams to a FakeIP address. This is intended to make it easy
/// to port existing UDP-based code to take advantage of SDR.
///
/// idxFakeServerPort refers to the *index* of the port allocated using
/// BeginAsyncRequestFakeIP and is used to create "server" ports. You may
/// call this before the allocation has completed. However, any attempts
/// to send packets will fail until the allocation has succeeded. When
/// the peer receives packets sent from this interface, the from address
/// of the packet will be the globally-unique FakeIP. If you call this
/// function multiple times and pass the same (nonnegative) fake port index,
/// the same object will be returned, and this object is not reference counted.
///
/// To create a "client" port (e.g. the equivalent of an ephemeral UDP port)
/// pass -1. In this case, a distinct object will be returned for each call.
/// When the peer receives packets sent from this interface, the peer will
/// assign a FakeIP from its own locally-controlled namespace.
ISteamNetworkingFakeUDPPort *CreateFakeUDPPort( int idxFakeServerPort )
{
PRINT_DEBUG_TODO();
std::lock_guard<std::recursive_mutex> lock(global_mutex);
return NULL;
}
// TEMP KLUDGE Call to invoke all queued callbacks.
// Eventually this function will go away, and callwacks will be ordinary Steamworks callbacks.
// You should call this at the same time you call SteamAPI_RunCallbacks and SteamGameServer_RunCallbacks
// to minimize potential changes in timing when that change happens.
void RunCallbacks( ISteamNetworkingSocketsCallbacks *pCallbacks )
{
// PRINT_DEBUG_ENTRY();
}
void RunCallbacks()
{
// PRINT_DEBUG_ENTRY();
//TODO: timeout unaccepted connections after a few seconds or so
auto current_time = std::chrono::steady_clock::now();
auto socket_conn = std::begin(s->connect_sockets);
while (socket_conn != std::end(s->connect_sockets)) {
if (socket_conn->second.connect_requests_sent < 10 && socket_conn->second.status == CONNECT_SOCKET_CONNECTING && (std::chrono::duration_cast<std::chrono::milliseconds>(current_time - socket_conn->second.connect_request_last_sent).count() > 3000)) {
send_packet_new_connection(socket_conn->first);
socket_conn->second.connect_request_last_sent = current_time;
socket_conn->second.connect_requests_sent += 1;
}
++socket_conn;
}
}
void Callback(Common_Message *msg)
{
// PRINT_DEBUG_ENTRY();
if (msg->has_low_level()) {
if (msg->low_level().type() == Low_Level::CONNECT) {
}
if (msg->low_level().type() == Low_Level::DISCONNECT) {
for (auto & connect_socket : s->connect_sockets) {
if (connect_socket.second.remote_identity.GetSteamID64() == msg->source_id()) {
enum connect_socket_status old_status = connect_socket.second.status;
connect_socket.second.status = CONNECT_SOCKET_TIMEDOUT;
launch_callback(connect_socket.first, old_status);
}
}
}
}
if (msg->has_networking_sockets()) {
PRINT_DEBUG("got network socket msg %u " "%" PRIu64 "", msg->networking_sockets().type(), msg->source_id());
if (msg->networking_sockets().type() == Networking_Sockets::CONNECTION_REQUEST) {
int virtual_port = msg->networking_sockets().virtual_port();
int real_port = msg->networking_sockets().real_port();
uint64 dest_id = msg->dest_id();
std::vector<Listen_Socket>::iterator conn;
if (virtual_port == SNS_DISABLED_PORT) {
conn = std::find_if(s->listen_sockets.begin(), s->listen_sockets.end(), [&real_port,&dest_id](struct Listen_Socket const& conn) { return conn.real_port == real_port && dest_id == conn.created_by.ConvertToUint64();});
} else {
conn = std::find_if(s->listen_sockets.begin(), s->listen_sockets.end(), [&virtual_port,&dest_id](struct Listen_Socket const& conn) { return conn.virtual_port == virtual_port && dest_id == conn.created_by.ConvertToUint64();});
}
if (conn != s->listen_sockets.end()) {
auto connect_socket = std::find_if(s->connect_sockets.begin(), s->connect_sockets.end(), [msg](const auto &in) {return in.second.remote_identity.GetSteamID64() == msg->source_id() && (in.second.status == CONNECT_SOCKET_NOT_ACCEPTED || in.second.status == CONNECT_SOCKET_CONNECTED) && in.second.remote_id == msg->networking_sockets().connection_id_from();});
if (connect_socket == s->connect_sockets.end()) {
SteamNetworkingIdentity identity;
identity.SetSteamID64(msg->source_id());
HSteamNetConnection new_connection = new_connect_socket(identity, virtual_port, real_port, CONNECT_SOCKET_NOT_ACCEPTED, conn->socket_id, msg->networking_sockets().connection_id_from());
launch_callback(new_connection, CONNECT_SOCKET_NO_CONNECTION);
}
}
} else if (msg->networking_sockets().type() == Networking_Sockets::CONNECTION_ACCEPTED) {
auto connect_socket = s->connect_sockets.find(msg->networking_sockets().connection_id());
if (connect_socket != s->connect_sockets.end()) {
if (connect_socket->second.remote_identity.GetSteamID64() == 0) {
connect_socket->second.remote_identity.SetSteamID64(msg->source_id());
}
if (connect_socket->second.remote_identity.GetSteamID64() == msg->source_id() && connect_socket->second.status == CONNECT_SOCKET_CONNECTING) {
connect_socket->second.remote_id = msg->networking_sockets().connection_id_from();
connect_socket->second.status = CONNECT_SOCKET_CONNECTED;
launch_callback(connect_socket->first, CONNECT_SOCKET_CONNECTING);
}
}
} else if (msg->networking_sockets().type() == Networking_Sockets::DATA) {
auto connect_socket = s->connect_sockets.find(msg->networking_sockets().connection_id());
if (connect_socket != s->connect_sockets.end()) {
if (connect_socket->second.remote_identity.GetSteamID64() == msg->source_id() && (connect_socket->second.status == CONNECT_SOCKET_CONNECTED)) {
PRINT_DEBUG("got data len %zu, num " "%" PRIu64 " on connection %u", msg->networking_sockets().data().size(), msg->networking_sockets().message_number(), connect_socket->first);
connect_socket->second.data.push(msg->networking_sockets());
}
} else {
connect_socket = std::find_if(s->connect_sockets.begin(), s->connect_sockets.end(), [msg](const auto &in) {return in.second.remote_identity.GetSteamID64() == msg->source_id() && (in.second.status == CONNECT_SOCKET_NOT_ACCEPTED || in.second.status == CONNECT_SOCKET_CONNECTED) && in.second.remote_id == msg->networking_sockets().connection_id_from();});
if (connect_socket != s->connect_sockets.end()) {
PRINT_DEBUG("got data len %zu, num " "%" PRIu64 " on not accepted connection %u", msg->networking_sockets().data().size(), msg->networking_sockets().message_number(), connect_socket->first);
connect_socket->second.data.push(msg->networking_sockets());
}
}
} else if (msg->networking_sockets().type() == Networking_Sockets::CONNECTION_END) {
auto connect_socket = s->connect_sockets.find(msg->networking_sockets().connection_id());
if (connect_socket != s->connect_sockets.end()) {
if (connect_socket->second.remote_identity.GetSteamID64() == msg->source_id() && connect_socket->second.status == CONNECT_SOCKET_CONNECTED) {
enum connect_socket_status old_status = connect_socket->second.status;
connect_socket->second.status = CONNECT_SOCKET_CLOSED;
launch_callback(connect_socket->first, old_status);
}
}
}
}
}
};