gbe_fork/dll/steam_networking.h

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/* 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"
//packet timeout in seconds for non connections
#define ORPHANED_PACKET_TIMEOUT (20)
#define NEW_CONNECTION_TIMEOUT (20.0)
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//kingdom 2 crowns doesn't work with a 0.3 delay or lower
#define NEW_CONNECTION_DELAY (0.4)
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#define OLD_CHANNEL_NUMBER 1
struct Steam_Networking_Connection {
CSteamID remote;
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std::set<int> open_channels;
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};
struct steam_listen_socket {
SNetListenSocket_t id;
int nVirtualP2PPort;
uint32 nIP;
uint16 nPort;
};
enum steam_socket_connection_status {
SOCKET_CONNECTING,
SOCKET_CONNECTED,
SOCKET_DISCONNECTED,
SOCKET_KILLED,
};
struct steam_connection_socket {
SNetSocket_t id;
SNetListenSocket_t listen_id;
enum steam_socket_connection_status status;
CSteamID target;
int nVirtualPort;
uint32 nIP;
uint16 nPort;
SNetSocket_t other_id;
std::vector<Network_Old> data_packets;
};
class Steam_Networking :
public ISteamNetworking001,
public ISteamNetworking002,
public ISteamNetworking003,
public ISteamNetworking004,
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public ISteamNetworking005,
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public ISteamNetworking
{
class Settings *settings;
class Networking *network;
class SteamCallBacks *callbacks;
class RunEveryRunCB *run_every_runcb;
std::recursive_mutex messages_mutex;
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std::vector<Common_Message> messages;
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std::recursive_mutex connections_edit_mutex;
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std::vector<struct Steam_Networking_Connection> connections;
std::vector<struct steam_listen_socket> listen_sockets;
std::vector<struct steam_connection_socket> connection_sockets;
std::map<CSteamID, std::chrono::high_resolution_clock::time_point> new_connection_times;
std::queue<CSteamID> new_connections_to_call_cb;
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bool connection_exists(CSteamID id)
{
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std::lock_guard<std::recursive_mutex> lock(connections_edit_mutex);
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return std::find_if(connections.begin(), connections.end(), [&id](struct Steam_Networking_Connection const& conn) { return conn.remote == id;}) != connections.end();
}
struct Steam_Networking_Connection *get_or_create_connection(CSteamID id)
{
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std::lock_guard<std::recursive_mutex> lock(connections_edit_mutex);
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auto conn = std::find_if(connections.begin(), connections.end(), [&id](struct Steam_Networking_Connection const& conn) { return conn.remote == id;});
if (connections.end() == conn) {
struct Steam_Networking_Connection connection;
connection.remote = id;
connections.push_back(connection);
return &(connections[connections.size() - 1]);
} else {
return &(*conn);
}
}
void remove_connection(CSteamID id)
{
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{
std::lock_guard<std::recursive_mutex> lock(connections_edit_mutex);
auto conn = std::begin(connections);
while (conn != std::end(connections)) {
if (conn->remote == id) {
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conn = connections.erase(conn);
} else {
++conn;
}
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}
}
//pretty sure steam also clears the entire queue of messages for that connection
{
std::lock_guard<std::recursive_mutex> lock(messages_mutex);
auto msg = std::begin(messages);
while (msg != std::end(messages)) {
if (msg->source_id() == id.ConvertToUint64()) {
msg = messages.erase(msg);
} else {
++msg;
}
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}
}
}
SNetSocket_t create_connection_socket(CSteamID target, int nVirtualPort, uint32 nIP, uint16 nPort, SNetListenSocket_t id=0, enum steam_socket_connection_status status=SOCKET_CONNECTING, SNetSocket_t other_id=0)
{
static SNetSocket_t socket_number = 0;
bool found = 0;
do {
++socket_number;
for (auto & c: connection_sockets) {
if (c.id == socket_number || socket_number == 0) {
found = true;
break;
}
}
} while (found);
struct steam_connection_socket socket;
socket.id = socket_number;
socket.listen_id = id;
socket.status = status;
socket.target = target;
socket.nVirtualPort = nVirtualPort;
socket.nIP = nIP;
socket.nPort = nPort;
socket.other_id = other_id;
connection_sockets.push_back(socket);
Common_Message msg;
msg.set_source_id(settings->get_local_steam_id().ConvertToUint64());
msg.set_dest_id(target.ConvertToUint64());
msg.set_allocated_network_old(new Network_Old);
if (nPort) {
msg.mutable_network_old()->set_type(Network_Old::CONNECTION_REQUEST_IP);
msg.mutable_network_old()->set_port(nPort);
} else {
msg.mutable_network_old()->set_type(Network_Old::CONNECTION_REQUEST_STEAMID);
msg.mutable_network_old()->set_port(nVirtualPort);
}
if (socket.status == SOCKET_CONNECTED) {
msg.mutable_network_old()->set_type(Network_Old::CONNECTION_ACCEPTED);
}
msg.mutable_network_old()->set_connection_id(socket.other_id);
msg.mutable_network_old()->set_connection_id_from(socket.id);
if (target.IsValid()) {
network->sendTo(&msg, true);
} else if (nIP) {
network->sendToIPPort(&msg, nIP, nPort, true);
}
return socket.id;
}
struct steam_connection_socket *get_connection_socket(SNetSocket_t id)
{
auto conn = std::find_if(connection_sockets.begin(), connection_sockets.end(), [&id](struct steam_connection_socket const& conn) { return conn.id == id;});
if (conn == connection_sockets.end()) return NULL;
return &(*conn);
}
void remove_killed_connection_sockets()
{
auto socket = std::begin(connection_sockets);
while (socket != std::end(connection_sockets)) {
if (socket->status == SOCKET_KILLED || socket->status == SOCKET_DISCONNECTED) {
socket = connection_sockets.erase(socket);
} else {
++socket;
}
}
}
public:
static void steam_networking_callback(void *object, Common_Message *msg)
{
PRINT_DEBUG("steam_networking_callback\n");
Steam_Networking *steam_networking = (Steam_Networking *)object;
steam_networking->Callback(msg);
}
static void steam_networking_run_every_runcp(void *object)
{
PRINT_DEBUG("steam_networking_run_every_runcp\n");
Steam_Networking *steam_networking = (Steam_Networking *)object;
steam_networking->RunCallbacks();
}
Steam_Networking(class Settings *settings, class Networking *network, class SteamCallBacks *callbacks, class RunEveryRunCB *run_every_runcb)
{
this->settings = settings;
this->network = network;
this->run_every_runcb = run_every_runcb;
this->network->setCallback(CALLBACK_ID_NETWORKING, settings->get_local_steam_id(), &Steam_Networking::steam_networking_callback, this);
this->network->setCallback(CALLBACK_ID_USER_STATUS, settings->get_local_steam_id(), &Steam_Networking::steam_networking_callback, this);
this->run_every_runcb->add(&Steam_Networking::steam_networking_run_every_runcp, this);
this->callbacks = callbacks;
PRINT_DEBUG("steam_networking_contructor %llu messages: %p\n", settings->get_local_steam_id().ConvertToUint64(), &messages);
}
~Steam_Networking()
{
//TODO rm network callbacks
this->run_every_runcb->remove(&Steam_Networking::steam_networking_run_every_runcp, this);
}
////////////////////////////////////////////////////////////////////////////////////////////
// Session-less connection functions
// automatically establishes NAT-traversing or Relay server connections
// Sends a P2P packet to the specified user
// UDP-like, unreliable and a max packet size of 1200 bytes
// the first packet send may be delayed as the NAT-traversal code runs
// if we can't get through to the user, an error will be posted via the callback P2PSessionConnectFail_t
// see EP2PSend enum above for the descriptions of the different ways of sending packets
//
// nChannel is a routing number you can use to help route message to different systems - you'll have to call ReadP2PPacket()
// with the same channel number in order to retrieve the data on the other end
// using different channels to talk to the same user will still use the same underlying p2p connection, saving on resources
bool SendP2PPacket( CSteamID steamIDRemote, const void *pubData, uint32 cubData, EP2PSend eP2PSendType, int nChannel)
{
PRINT_DEBUG("Steam_Networking::SendP2PPacket len %u sendtype: %u channel: %u to: %llu\n", cubData, eP2PSendType, nChannel, steamIDRemote.ConvertToUint64());
std::lock_guard<std::recursive_mutex> lock(global_mutex);
bool reliable = false;
if (eP2PSendType == k_EP2PSendReliable || eP2PSendType == k_EP2PSendReliableWithBuffering) reliable = true;
Common_Message msg;
msg.set_source_id(settings->get_local_steam_id().ConvertToUint64());
msg.set_dest_id(steamIDRemote.ConvertToUint64());
msg.set_allocated_network(new Network);
if (!connection_exists(steamIDRemote)) {
msg.mutable_network()->set_type(Network::NEW_CONNECTION);
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network->sendTo(&msg, true);
}
msg.mutable_network()->set_channel(nChannel);
msg.mutable_network()->set_data(pubData, cubData);
msg.mutable_network()->set_type(Network::DATA);
struct Steam_Networking_Connection *conn = get_or_create_connection(steamIDRemote);
new_connection_times.erase(steamIDRemote);
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conn->open_channels.insert(nChannel);
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bool ret = network->sendTo(&msg, reliable);
PRINT_DEBUG("Sent message with size: %zu %u\n", msg.network().data().size(), ret);
return ret;
}
bool SendP2PPacket( CSteamID steamIDRemote, const void *pubData, uint32 cubData, EP2PSend eP2PSendType ) {
PRINT_DEBUG("Steam_Networking::SendP2PPacket old\n");
return SendP2PPacket(steamIDRemote, pubData, cubData, eP2PSendType, OLD_CHANNEL_NUMBER);
}
// returns true if any data is available for read, and the amount of data that will need to be read
bool IsP2PPacketAvailable( uint32 *pcubMsgSize, int nChannel)
{
PRINT_DEBUG("Steam_Networking::IsP2PPacketAvailable channel: %i\n", nChannel);
std::lock_guard<std::recursive_mutex> lock(messages_mutex);
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//Not sure if this should be here because it slightly screws up games that don't like such low "pings"
//Commenting it out for now because it looks like it causes a bug where 20xx gets stuck in an infinite receive packet loop
//this->network->Run();
//RunCallbacks();
PRINT_DEBUG("Messages %zu %p\n", messages.size(), &messages);
for (auto &msg : messages) {
if (connection_exists((uint64)msg.source_id()) && msg.mutable_network()->channel() == nChannel && msg.network().processed()) {
uint32 size = msg.mutable_network()->data().size();
if (pcubMsgSize) *pcubMsgSize = size;
PRINT_DEBUG("available with size: %lu\n", size);
return true;
}
}
PRINT_DEBUG("Not available\n");
if (pcubMsgSize) *pcubMsgSize = 0;
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return false;
}
bool IsP2PPacketAvailable( uint32 *pcubMsgSize)
{
PRINT_DEBUG("Steam_Networking::IsP2PPacketAvailable old\n");
return IsP2PPacketAvailable(pcubMsgSize, OLD_CHANNEL_NUMBER);
}
// reads in a packet that has been sent from another user via SendP2PPacket()
// returns the size of the message and the steamID of the user who sent it in the last two parameters
// if the buffer passed in is too small, the message will be truncated
// this call is not blocking, and will return false if no data is available
bool ReadP2PPacket( void *pubDest, uint32 cubDest, uint32 *pcubMsgSize, CSteamID *psteamIDRemote, int nChannel)
{
PRINT_DEBUG("Steam_Networking::ReadP2PPacket %u %i\n", cubDest, nChannel);
std::lock_guard<std::recursive_mutex> lock(messages_mutex);
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//Not sure if this should be here because it slightly screws up games that don't like such low "pings"
//Commenting it out for now because it looks like it causes a bug where 20xx gets stuck in an infinite receive packet loop
//this->network->Run();
//RunCallbacks();
bool read = false;
PRINT_DEBUG("Number messages %zu\n", messages.size());
auto msg = std::begin(messages);
while (msg != std::end(messages)) {
if (connection_exists((uint64)msg->source_id()) && msg->network().channel() == nChannel && msg->network().processed()) {
uint32 msg_size = msg->network().data().size();
if (msg_size > cubDest) msg_size = cubDest;
if (pcubMsgSize) *pcubMsgSize = msg_size;
memcpy(pubDest, msg->network().data().data(), msg_size);
#ifndef EMU_RELEASE_BUILD
for (int i = 0; i < msg_size; ++i) {
PRINT_DEBUG("%02hhX", ((char*)pubDest)[i]);
}PRINT_DEBUG("\n");
#endif
*psteamIDRemote = CSteamID((uint64)msg->source_id());
PRINT_DEBUG("Steam_Networking::ReadP2PPacket len %u channel: %u from: %llu\n", msg_size, nChannel, msg->source_id());
msg = messages.erase(msg);
return true;
}
++msg;
}
if (pcubMsgSize) *pcubMsgSize = 0;
if (psteamIDRemote) *psteamIDRemote = k_steamIDNil;
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return false;
}
bool ReadP2PPacket( void *pubDest, uint32 cubDest, uint32 *pcubMsgSize, CSteamID *psteamIDRemote)
{
PRINT_DEBUG("Steam_Networking::ReadP2PPacket old\n");
return ReadP2PPacket(pubDest, cubDest, pcubMsgSize, psteamIDRemote, OLD_CHANNEL_NUMBER);
}
// AcceptP2PSessionWithUser() should only be called in response to a P2PSessionRequest_t callback
// P2PSessionRequest_t will be posted if another user tries to send you a packet that you haven't talked to yet
// if you don't want to talk to the user, just ignore the request
// if the user continues to send you packets, another P2PSessionRequest_t will be posted periodically
// this may be called multiple times for a single user
// (if you've called SendP2PPacket() on the other user, this implicitly accepts the session request)
bool AcceptP2PSessionWithUser( CSteamID steamIDRemote )
{
PRINT_DEBUG("Steam_Networking::AcceptP2PSessionWithUser %llu\n", steamIDRemote.ConvertToUint64());
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct Steam_Networking_Connection *conn = get_or_create_connection(steamIDRemote);
if (conn) new_connection_times.erase(steamIDRemote);
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return !!conn;
}
// call CloseP2PSessionWithUser() when you're done talking to a user, will free up resources under-the-hood
// if the remote user tries to send data to you again, another P2PSessionRequest_t callback will be posted
bool CloseP2PSessionWithUser( CSteamID steamIDRemote )
{
PRINT_DEBUG("Steam_Networking::CloseP2PSessionWithUser %llu\n", steamIDRemote.ConvertToUint64());
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!connection_exists(steamIDRemote)) {
return false;
}
remove_connection(steamIDRemote);
return true;
}
// call CloseP2PChannelWithUser() when you're done talking to a user on a specific channel. Once all channels
// open channels to a user have been closed, the open session to the user will be closed and new data from this
// user will trigger a P2PSessionRequest_t callback
bool CloseP2PChannelWithUser( CSteamID steamIDRemote, int nChannel )
{
PRINT_DEBUG("Steam_Networking::CloseP2PChannelWithUser\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!connection_exists(steamIDRemote)) {
return false;
}
struct Steam_Networking_Connection *conn = get_or_create_connection(steamIDRemote);
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conn->open_channels.erase(nChannel);
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if (conn->open_channels.size() == 0) {
remove_connection(steamIDRemote);
}
return true;
}
// fills out P2PSessionState_t structure with details about the underlying connection to the user
// should only needed for debugging purposes
// returns false if no connection exists to the specified user
bool GetP2PSessionState( CSteamID steamIDRemote, P2PSessionState_t *pConnectionState )
{
PRINT_DEBUG("Steam_Networking::GetP2PSessionState %llu\n", steamIDRemote.ConvertToUint64());
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!connection_exists(steamIDRemote) && (steamIDRemote != settings->get_local_steam_id())) {
if (pConnectionState) {
pConnectionState->m_bConnectionActive = false;
pConnectionState->m_bConnecting = false;
pConnectionState->m_eP2PSessionError = 0;
pConnectionState->m_bUsingRelay = false;
pConnectionState->m_nBytesQueuedForSend = 0;
pConnectionState->m_nPacketsQueuedForSend = 0;
pConnectionState->m_nRemoteIP = 0;
pConnectionState->m_nRemotePort = 0;
}
PRINT_DEBUG("No Connection\n");
return false;
}
if (pConnectionState) {
pConnectionState->m_bConnectionActive = true;
pConnectionState->m_bConnecting = false;
pConnectionState->m_eP2PSessionError = 0;
pConnectionState->m_bUsingRelay = false;
pConnectionState->m_nBytesQueuedForSend = 0;
pConnectionState->m_nPacketsQueuedForSend = 0;
pConnectionState->m_nRemoteIP = network->getIP(steamIDRemote);
pConnectionState->m_nRemotePort = 12345;
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}
PRINT_DEBUG("Connection\n");
return true;
}
// Allow P2P connections to fall back to being relayed through the Steam servers if a direct connection
// or NAT-traversal cannot be established. Only applies to connections created after setting this value,
// or to existing connections that need to automatically reconnect after this value is set.
//
// P2P packet relay is allowed by default
bool AllowP2PPacketRelay( bool bAllow )
{
PRINT_DEBUG("Steam_Networking::AllowP2PPacketRelay %u\n", bAllow);
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return true;
}
////////////////////////////////////////////////////////////////////////////////////////////
// LISTEN / CONNECT style interface functions
//
// This is an older set of functions designed around the Berkeley TCP sockets model
// it's preferential that you use the above P2P functions, they're more robust
// and these older functions will be removed eventually
//
////////////////////////////////////////////////////////////////////////////////////////////
SNetListenSocket_t socket_number = 0;
// creates a socket and listens others to connect
// will trigger a SocketStatusCallback_t callback on another client connecting
// nVirtualP2PPort is the unique ID that the client will connect to, in case you have multiple ports
// this can usually just be 0 unless you want multiple sets of connections
// unIP is the local IP address to bind to
// pass in 0 if you just want the default local IP
// unPort is the port to use
// pass in 0 if you don't want users to be able to connect via IP/Port, but expect to be always peer-to-peer connections only
SNetListenSocket_t CreateListenSocket( int nVirtualP2PPort, uint32 nIP, uint16 nPort, bool bAllowUseOfPacketRelay )
{
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PRINT_DEBUG("Steam_Networking::CreateListenSocket old %i %u %hu %u\n", nVirtualP2PPort, nIP, nPort, bAllowUseOfPacketRelay);
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std::lock_guard<std::recursive_mutex> lock(global_mutex);
for (auto & c : listen_sockets) {
if (c.nVirtualP2PPort == nVirtualP2PPort || c.nPort == nPort)
return 0;
}
++socket_number;
if (!socket_number) ++socket_number;
struct steam_listen_socket socket;
socket.id = socket_number;
socket.nVirtualP2PPort = nVirtualP2PPort;
socket.nIP = nIP;
socket.nPort = nPort;
listen_sockets.push_back(socket);
return socket.id;
}
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SNetListenSocket_t CreateListenSocket( int nVirtualP2PPort, SteamIPAddress_t nIP, uint16 nPort, bool bAllowUseOfPacketRelay )
{
PRINT_DEBUG("Steam_Networking::CreateListenSocket %i %i %u %hu %u\n", nVirtualP2PPort, nIP.m_eType, nIP.m_unIPv4, nPort, bAllowUseOfPacketRelay);
//TODO: ipv6
return CreateListenSocket(nVirtualP2PPort, nIP.m_unIPv4, nPort, bAllowUseOfPacketRelay);
}
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SNetListenSocket_t CreateListenSocket( int nVirtualP2PPort, uint32 nIP, uint16 nPort )
{
PRINT_DEBUG("Steam_Networking::CreateListenSocket old\n");
return CreateListenSocket(nVirtualP2PPort, nIP, nPort, true);
}
// creates a socket and begin connection to a remote destination
// can connect via a known steamID (client or game server), or directly to an IP
// on success will trigger a SocketStatusCallback_t callback
// on failure or timeout will trigger a SocketStatusCallback_t callback with a failure code in m_eSNetSocketState
SNetSocket_t CreateP2PConnectionSocket( CSteamID steamIDTarget, int nVirtualPort, int nTimeoutSec, bool bAllowUseOfPacketRelay )
{
PRINT_DEBUG("Steam_Networking::CreateP2PConnectionSocket %llu %i %i %u\n", steamIDTarget.ConvertToUint64(), nVirtualPort, nTimeoutSec, bAllowUseOfPacketRelay);
std::lock_guard<std::recursive_mutex> lock(global_mutex);
//TODO: nTimeoutSec
return create_connection_socket(steamIDTarget, nVirtualPort, 0, 0);
}
SNetSocket_t CreateP2PConnectionSocket( CSteamID steamIDTarget, int nVirtualPort, int nTimeoutSec )
{
PRINT_DEBUG("Steam_Networking::CreateP2PConnectionSocket old\n");
return CreateP2PConnectionSocket(steamIDTarget, nVirtualPort, nTimeoutSec, true);
}
SNetSocket_t CreateConnectionSocket( uint32 nIP, uint16 nPort, int nTimeoutSec )
{
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PRINT_DEBUG("Steam_Networking::CreateConnectionSocket_old %u %hu %i\n", nIP, nPort, nTimeoutSec);
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std::lock_guard<std::recursive_mutex> lock(global_mutex);
//TODO: nTimeoutSec
return create_connection_socket((uint64)0, 0, nIP, nPort);
}
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SNetSocket_t CreateConnectionSocket( SteamIPAddress_t nIP, uint16 nPort, int nTimeoutSec )
{
PRINT_DEBUG("Steam_Networking::CreateConnectionSocket %i %u %hu %i\n", nIP.m_eType, nIP.m_unIPv4, nPort, nTimeoutSec);
//TODO: ipv6
return CreateConnectionSocket(nIP.m_unIPv4, nPort, nTimeoutSec);
}
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// disconnects the connection to the socket, if any, and invalidates the handle
// any unread data on the socket will be thrown away
// if bNotifyRemoteEnd is set, socket will not be completely destroyed until the remote end acknowledges the disconnect
bool DestroySocket( SNetSocket_t hSocket, bool bNotifyRemoteEnd )
{
PRINT_DEBUG("Steam_Networking::DestroySocket\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket || socket->status == SOCKET_KILLED) return false;
socket->status = SOCKET_KILLED;
return true;
}
// destroying a listen socket will automatically kill all the regular sockets generated from it
bool DestroyListenSocket( SNetListenSocket_t hSocket, bool bNotifyRemoteEnd )
{
PRINT_DEBUG("Steam_Networking::DestroyListenSocket\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto c = std::begin(listen_sockets);
while (c != std::end(listen_sockets)) {
if (c->id == hSocket) {
c = listen_sockets.erase(c);
for (auto & socket : connection_sockets) {
if (socket.listen_id == hSocket) {
socket.status = SOCKET_KILLED;
}
}
return true;
} else {
++c;
}
}
return false;
}
// sending data
// must be a handle to a connected socket
// data is all sent via UDP, and thus send sizes are limited to 1200 bytes; after this, many routers will start dropping packets
// use the reliable flag with caution; although the resend rate is pretty aggressive,
// it can still cause stalls in receiving data (like TCP)
bool SendDataOnSocket( SNetSocket_t hSocket, void *pubData, uint32 cubData, bool bReliable )
{
PRINT_DEBUG("Steam_Networking::SendDataOnSocket\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket || socket->status != SOCKET_CONNECTED) return false;
Common_Message msg;
msg.set_source_id(settings->get_local_steam_id().ConvertToUint64());
msg.set_dest_id(socket->target.ConvertToUint64());
msg.set_allocated_network_old(new Network_Old);
msg.mutable_network_old()->set_type(Network_Old::DATA);
msg.mutable_network_old()->set_connection_id(socket->other_id);
msg.mutable_network_old()->set_data(pubData, cubData);
return network->sendTo(&msg, bReliable);
}
// receiving data
// returns false if there is no data remaining
// fills out *pcubMsgSize with the size of the next message, in bytes
bool IsDataAvailableOnSocket( SNetSocket_t hSocket, uint32 *pcubMsgSize )
{
PRINT_DEBUG("Steam_Networking::IsDataAvailableOnSocket\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket) {
if (pcubMsgSize) *pcubMsgSize = 0;
return false;
}
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if (socket->data_packets.size() == 0) return false;
if (pcubMsgSize) *pcubMsgSize = socket->data_packets[0].data().size();
return true;
}
// fills in pubDest with the contents of the message
// messages are always complete, of the same size as was sent (i.e. packetized, not streaming)
// if *pcubMsgSize < cubDest, only partial data is written
// returns false if no data is available
bool RetrieveDataFromSocket( SNetSocket_t hSocket, void *pubDest, uint32 cubDest, uint32 *pcubMsgSize )
{
PRINT_DEBUG("Steam_Networking::RetrieveDataFromSocket\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket || socket->data_packets.size() == 0) return false;
auto msg = std::begin(socket->data_packets);
if (msg != std::end(socket->data_packets)) {
uint32 msg_size = msg->data().size();
if (msg_size > cubDest) msg_size = cubDest;
if (pcubMsgSize) *pcubMsgSize = msg_size;
memcpy(pubDest, msg->data().data(), msg_size);
msg = socket->data_packets.erase(msg);
return true;
}
return false;
}
// checks for data from any socket that has been connected off this listen socket
// returns false if there is no data remaining
// fills out *pcubMsgSize with the size of the next message, in bytes
// fills out *phSocket with the socket that data is available on
bool IsDataAvailable( SNetListenSocket_t hListenSocket, uint32 *pcubMsgSize, SNetSocket_t *phSocket )
{
PRINT_DEBUG("Steam_Networking::IsDataAvailable\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!hListenSocket) return false;
for (auto & socket : connection_sockets) {
if (socket.listen_id == hListenSocket && socket.data_packets.size()) {
if (pcubMsgSize) *pcubMsgSize = socket.data_packets[0].data().size();
if (phSocket) *phSocket = socket.id;
return true;
}
}
return false;
}
// retrieves data from any socket that has been connected off this listen socket
// fills in pubDest with the contents of the message
// messages are always complete, of the same size as was sent (i.e. packetized, not streaming)
// if *pcubMsgSize < cubDest, only partial data is written
// returns false if no data is available
// fills out *phSocket with the socket that data is available on
bool RetrieveData( SNetListenSocket_t hListenSocket, void *pubDest, uint32 cubDest, uint32 *pcubMsgSize, SNetSocket_t *phSocket )
{
PRINT_DEBUG("Steam_Networking::RetrieveData\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
if (!hListenSocket) return false;
for (auto & socket : connection_sockets) {
if (socket.listen_id == hListenSocket && socket.data_packets.size()) {
auto msg = std::begin(socket.data_packets);
if (msg != std::end(socket.data_packets)) {
uint32 msg_size = msg->data().size();
if (msg_size > cubDest) msg_size = cubDest;
if (pcubMsgSize) *pcubMsgSize = msg_size;
if (phSocket) *phSocket = socket.id;
memcpy(pubDest, msg->data().data(), msg_size);
msg = socket.data_packets.erase(msg);
return true;
}
}
}
return false;
}
// returns information about the specified socket, filling out the contents of the pointers
bool GetSocketInfo( SNetSocket_t hSocket, CSteamID *pSteamIDRemote, int *peSocketStatus, uint32 *punIPRemote, uint16 *punPortRemote )
{
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PRINT_DEBUG("Steam_Networking::GetSocketInfo_old\n");
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std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket) return false;
if (pSteamIDRemote) *pSteamIDRemote = socket->target;
if (peSocketStatus) {
//TODO: I'm not sure what peSocketStatus is supposed to be but I'm guessing it's ESNetSocketState
if (socket->status == SOCKET_CONNECTED) {
*peSocketStatus = k_ESNetSocketStateConnected;
} else if (socket->status == SOCKET_CONNECTING) {
*peSocketStatus = k_ESNetSocketStateInitiated;
} else if (socket->status == SOCKET_DISCONNECTED) {
*peSocketStatus = k_ESNetSocketStateDisconnecting;
} else if (socket->status == SOCKET_KILLED) {
*peSocketStatus = k_ESNetSocketStateConnectionBroken;
} else {
*peSocketStatus = k_ESNetSocketStateInvalid;
}
}
if (punIPRemote) *punIPRemote = socket->nIP;
if (punPortRemote) *punPortRemote = socket->nPort;
return true;
}
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bool GetSocketInfo( SNetSocket_t hSocket, CSteamID *pSteamIDRemote, int *peSocketStatus, SteamIPAddress_t *punIPRemote, uint16 *punPortRemote )
{
PRINT_DEBUG("Steam_Networking::GetSocketInfo\n");
//TODO: ipv6
uint32 *ip_remote = NULL;
if (punIPRemote) {
ip_remote = &(punIPRemote->m_unIPv4);
}
bool ret = GetSocketInfo(hSocket, pSteamIDRemote, peSocketStatus, ip_remote, punPortRemote );
if (punIPRemote && ret) {
punIPRemote->m_eType = k_ESteamIPTypeIPv4;
}
return ret;
}
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// returns which local port the listen socket is bound to
// *pnIP and *pnPort will be 0 if the socket is set to listen for P2P connections only
bool GetListenSocketInfo( SNetListenSocket_t hListenSocket, uint32 *pnIP, uint16 *pnPort )
{
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PRINT_DEBUG("Steam_Networking::GetListenSocketInfo_old\n");
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std::lock_guard<std::recursive_mutex> lock(global_mutex);
auto conn = std::find_if(listen_sockets.begin(), listen_sockets.end(), [&hListenSocket](struct steam_listen_socket const& conn) { return conn.id == hListenSocket;});
if (conn == listen_sockets.end()) return false;
if (pnIP) *pnIP = conn->nIP;
if (pnPort) *pnPort = conn->nPort;
return true;
}
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bool GetListenSocketInfo( SNetListenSocket_t hListenSocket, SteamIPAddress_t *pnIP, uint16 *pnPort )
{
PRINT_DEBUG("Steam_Networking::GetListenSocketInfo\n");
//TODO: ipv6
uint32 *ip = NULL;
if (pnIP) {
ip = &(pnIP->m_unIPv4);
}
bool ret = GetListenSocketInfo(hListenSocket, ip, pnPort );
if (pnIP && ret) {
pnIP->m_eType = k_ESteamIPTypeIPv4;
}
return ret;
}
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// returns true to describe how the socket ended up connecting
ESNetSocketConnectionType GetSocketConnectionType( SNetSocket_t hSocket )
{
PRINT_DEBUG("Steam_Networking::GetSocketConnectionType\n");
std::lock_guard<std::recursive_mutex> lock(global_mutex);
struct steam_connection_socket *socket = get_connection_socket(hSocket);
if (!socket || socket->status != SOCKET_CONNECTED) return k_ESNetSocketConnectionTypeNotConnected;
else return k_ESNetSocketConnectionTypeUDP;
}
// max packet size, in bytes
int GetMaxPacketSize( SNetSocket_t hSocket )
{
PRINT_DEBUG("Steam_Networking::GetMaxPacketSize\n");
return 1500;
}
void RunCallbacks()
{
uint64 current_time = std::chrono::duration_cast<std::chrono::duration<uint64>>(std::chrono::system_clock::now().time_since_epoch()).count();
{
std::lock_guard<std::recursive_mutex> lock(messages_mutex);
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for (auto &msg : messages) {
CSteamID source_id((uint64)msg.source_id());
if (!msg.network().processed()) {
if (!connection_exists(source_id)) {
if (new_connection_times.find(source_id) == new_connection_times.end()) {
new_connections_to_call_cb.push(source_id);
new_connection_times[source_id] = std::chrono::high_resolution_clock::now();
}
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} else {
struct Steam_Networking_Connection *conn = get_or_create_connection(source_id);
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conn->open_channels.insert(msg.network().channel());
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}
msg.mutable_network()->set_processed(true);
msg.mutable_network()->set_time_processed(current_time);
}
}
auto msg = std::begin(messages);
while (msg != std::end(messages)) {
bool deleted = false;
if (msg->network().processed()) {
if (!connection_exists((uint64)msg->source_id())) {
if (msg->network().time_processed() + ORPHANED_PACKET_TIMEOUT < current_time) {
deleted = true;
}
}
}
if (deleted) {
msg = messages.erase(msg);
} else {
++msg;
}
}
}
while (!new_connections_to_call_cb.empty()) {
CSteamID source_id = new_connections_to_call_cb.front();
auto t = new_connection_times.find(source_id);
if (t == new_connection_times.end()) {
new_connections_to_call_cb.pop();
continue;
}
if (!check_timedout(t->second, NEW_CONNECTION_DELAY)) {
break;
}
P2PSessionRequest_t data;
memset(&data, 0, sizeof(data));
data.m_steamIDRemote = source_id;
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
new_connections_to_call_cb.pop();
}
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//TODO: not sure if sockets should be wiped right away
remove_killed_connection_sockets();
for(auto it = new_connection_times.begin(); it != new_connection_times.end(); ) {
if (std::chrono::duration_cast<std::chrono::duration<double>>(std::chrono::high_resolution_clock::now() - it->second).count() > NEW_CONNECTION_TIMEOUT) {
it = new_connection_times.erase(it);
//TODO send packet to other side to tell them connection has "failed".
} else {
++it;
}
}
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}
void Callback(Common_Message *msg)
{
if (msg->has_network()) {
#ifndef EMU_RELEASE_BUILD
PRINT_DEBUG("Steam_Networking: got msg from: %llu to: %llu size %zu type %u | messages %p: %zu\n", msg->source_id(), msg->dest_id(), msg->network().data().size(), msg->network().type(), &messages, messages.size());
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for (int i = 0; i < msg->network().data().size(); ++i) {
PRINT_DEBUG("%02hhX", msg->network().data().data()[i]);
}PRINT_DEBUG("\n");
#endif
std::lock_guard<std::recursive_mutex> lock(messages_mutex);
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if (msg->network().type() == Network::DATA) {
messages.push_back(Common_Message(*msg));
}
if (msg->network().type() == Network::NEW_CONNECTION) {
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auto msg_temp = std::begin(messages);
while (msg_temp != std::end(messages)) {
//only delete processed to handle unreliable message arriving at the same time.
if (msg_temp->source_id() == msg->source_id() && msg_temp->network().processed()) {
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msg_temp = messages.erase(msg_temp);
} else {
++msg_temp;
}
}
}
}
if (msg->has_network_old()) {
PRINT_DEBUG("Steam_Networking: got network socket msg %u\n", msg->network_old().type());
if (msg->network_old().type() == Network_Old::CONNECTION_REQUEST_IP) {
for (auto & listen : listen_sockets) {
if (listen.nPort == msg->network_old().port()) {
SNetSocket_t new_sock = create_connection_socket((uint64)msg->source_id(), 0, 0, msg->network_old().port(), listen.id, SOCKET_CONNECTED, msg->network_old().connection_id_from());
if (new_sock) {
struct SocketStatusCallback_t data;
data.m_hSocket = new_sock;
data.m_hListenSocket = listen.id;
data.m_steamIDRemote = (uint64)msg->source_id();
data.m_eSNetSocketState = k_ESNetSocketStateConnected; //TODO is this the right state?
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
}
}
} else if (msg->network_old().type() == Network_Old::CONNECTION_REQUEST_STEAMID) {
for (auto & listen : listen_sockets) {
if (listen.nVirtualP2PPort == msg->network_old().port()) {
SNetSocket_t new_sock = create_connection_socket((uint64)msg->source_id(), msg->network_old().port(), 0, 0, listen.id, SOCKET_CONNECTED, msg->network_old().connection_id_from());
if (new_sock) {
struct SocketStatusCallback_t data;
data.m_hSocket = new_sock;
data.m_hListenSocket = listen.id;
data.m_steamIDRemote = (uint64)msg->source_id();
data.m_eSNetSocketState = k_ESNetSocketStateConnected; //TODO is this the right state?
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
}
}
} else if (msg->network_old().type() == Network_Old::CONNECTION_ACCEPTED) {
struct steam_connection_socket *socket = get_connection_socket(msg->network_old().connection_id());
if (socket && socket->nPort && socket->status == SOCKET_CONNECTING && !socket->target.IsValid()) {
socket->target = (uint64)msg->source_id();
}
if (socket && socket->status == SOCKET_CONNECTING && msg->source_id() == socket->target.ConvertToUint64()) {
socket->status = SOCKET_CONNECTED;
socket->other_id = msg->network_old().connection_id_from();
struct SocketStatusCallback_t data;
data.m_hSocket = socket->id;
data.m_hListenSocket = socket->listen_id;
data.m_steamIDRemote = socket->target;
data.m_eSNetSocketState = k_ESNetSocketStateConnected; //TODO is this the right state?
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
} else if (msg->network_old().type() == Network_Old::CONNECTION_END) {
struct steam_connection_socket *socket = get_connection_socket(msg->network_old().connection_id());
if (socket && socket->status == SOCKET_CONNECTED && msg->source_id() == socket->target.ConvertToUint64()) {
struct SocketStatusCallback_t data;
socket->status = SOCKET_DISCONNECTED;
data.m_hSocket = socket->id;
data.m_hListenSocket = socket->listen_id;
data.m_steamIDRemote = socket->target;
data.m_eSNetSocketState = k_ESNetSocketStateRemoteEndDisconnected; //TODO is this the right state?
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
} else if (msg->network_old().type() == Network_Old::DATA) {
struct steam_connection_socket *socket = get_connection_socket(msg->network_old().connection_id());
if (socket && socket->status == SOCKET_CONNECTED && msg->source_id() == socket->target.ConvertToUint64()) {
socket->data_packets.push_back(msg->network_old());
}
}
}
if (msg->has_low_level()) {
if (msg->low_level().type() == Low_Level::DISCONNECT) {
CSteamID source_id((uint64)msg->source_id());
if (connection_exists(source_id)) {
P2PSessionConnectFail_t data;
data.m_steamIDRemote = source_id;
data.m_eP2PSessionError = k_EP2PSessionErrorDestinationNotLoggedIn;
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
for (auto & socket : connection_sockets) {
if (socket.target.ConvertToUint64() == msg->source_id()) {
struct SocketStatusCallback_t data;
socket.status = SOCKET_DISCONNECTED;
data.m_hSocket = socket.id;
data.m_hListenSocket = socket.listen_id;
data.m_steamIDRemote = socket.target;
data.m_eSNetSocketState = k_ESNetSocketStateConnectionBroken; //TODO is this the right state?
callbacks->addCBResult(data.k_iCallback, &data, sizeof(data));
}
}
} else
if (msg->low_level().type() == Low_Level::CONNECT) {
}
}
}
};