cemu-DS4Windows/DS4Windows/DS4Control/UdpServer.cs
2019-07-02 02:06:32 -05:00

703 lines
26 KiB
C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Net;
using System.Net.NetworkInformation;
using System.Net.Sockets;
using System.ComponentModel;
using System.Threading;
namespace DS4Windows
{
public enum DsState : byte
{
[Description("Disconnected")]
Disconnected = 0x00,
[Description("Reserved")]
Reserved = 0x01,
[Description("Connected")]
Connected = 0x02
};
public enum DsConnection : byte
{
[Description("None")]
None = 0x00,
[Description("Usb")]
Usb = 0x01,
[Description("Bluetooth")]
Bluetooth = 0x02
};
public enum DsModel : byte
{
[Description("None")]
None = 0,
[Description("DualShock 3")]
DS3 = 1,
[Description("DualShock 4")]
DS4 = 2,
[Description("Generic Gamepad")]
Generic = 3
}
public enum DsBattery : byte
{
None = 0x00,
Dying = 0x01,
Low = 0x02,
Medium = 0x03,
High = 0x04,
Full = 0x05,
Charging = 0xEE,
Charged = 0xEF
};
public struct DualShockPadMeta
{
public byte PadId;
public DsState PadState;
public DsConnection ConnectionType;
public DsModel Model;
public PhysicalAddress PadMacAddress;
public DsBattery BatteryStatus;
public bool IsActive;
}
class UdpServer
{
private Socket udpSock;
private uint serverId;
private bool running;
private byte[] recvBuffer = new byte[1024];
private SocketAsyncEventArgs[] argsList;
private int listInd = 0;
private ReaderWriterLockSlim poolLock = new ReaderWriterLockSlim();
public delegate void GetPadDetail(int padIdx, ref DualShockPadMeta meta);
private GetPadDetail portInfoGet;
public UdpServer(GetPadDetail getPadDetailDel)
{
portInfoGet = getPadDetailDel;
argsList = new SocketAsyncEventArgs[40];
for (int num = 0; num < 40; num++)
{
SocketAsyncEventArgs args = new SocketAsyncEventArgs();
args.SetBuffer(new byte[100], 0, 100);
argsList[num] = args;
}
}
enum MessageType
{
DSUC_VersionReq = 0x100000,
DSUS_VersionRsp = 0x100000,
DSUC_ListPorts = 0x100001,
DSUS_PortInfo = 0x100001,
DSUC_PadDataReq = 0x100002,
DSUS_PadDataRsp = 0x100002,
};
private const ushort MaxProtocolVersion = 1001;
class ClientRequestTimes
{
DateTime allPads;
DateTime[] padIds;
Dictionary<PhysicalAddress, DateTime> padMacs;
public DateTime AllPadsTime { get { return allPads; } }
public DateTime[] PadIdsTime { get { return padIds; } }
public Dictionary<PhysicalAddress, DateTime> PadMacsTime { get { return padMacs; } }
public ClientRequestTimes()
{
allPads = DateTime.MinValue;
padIds = new DateTime[4];
for (int i = 0; i < padIds.Length; i++)
padIds[i] = DateTime.MinValue;
padMacs = new Dictionary<PhysicalAddress, DateTime>();
}
public void RequestPadInfo(byte regFlags, byte idToReg, PhysicalAddress macToReg)
{
if (regFlags == 0)
allPads = DateTime.UtcNow;
else
{
if ((regFlags & 0x01) != 0) //id valid
{
if (idToReg < padIds.Length)
padIds[idToReg] = DateTime.UtcNow;
}
if ((regFlags & 0x02) != 0) //mac valid
{
padMacs[macToReg] = DateTime.UtcNow;
}
}
}
}
private Dictionary<IPEndPoint, ClientRequestTimes> clients = new Dictionary<IPEndPoint, ClientRequestTimes>();
private int BeginPacket(byte[] packetBuf, ushort reqProtocolVersion = MaxProtocolVersion)
{
int currIdx = 0;
packetBuf[currIdx++] = (byte)'D';
packetBuf[currIdx++] = (byte)'S';
packetBuf[currIdx++] = (byte)'U';
packetBuf[currIdx++] = (byte)'S';
Array.Copy(BitConverter.GetBytes((ushort)reqProtocolVersion), 0, packetBuf, currIdx, 2);
currIdx += 2;
Array.Copy(BitConverter.GetBytes((ushort)packetBuf.Length - 16), 0, packetBuf, currIdx, 2);
currIdx += 2;
Array.Clear(packetBuf, currIdx, 4); //place for crc
currIdx += 4;
Array.Copy(BitConverter.GetBytes((uint)serverId), 0, packetBuf, currIdx, 4);
currIdx += 4;
return currIdx;
}
private void FinishPacket(byte[] packetBuf)
{
Array.Clear(packetBuf, 8, 4);
//uint crcCalc = Crc32Algorithm.Compute(packetBuf);
uint seed = Crc32Algorithm.DefaultSeed;
uint crcCalc = ~Crc32Algorithm.CalculateBasicHash(ref seed, ref packetBuf, 0, packetBuf.Length);
Array.Copy(BitConverter.GetBytes((uint)crcCalc), 0, packetBuf, 8, 4);
}
private void SendPacket(IPEndPoint clientEP, byte[] usefulData, ushort reqProtocolVersion = MaxProtocolVersion)
{
byte[] packetData = new byte[usefulData.Length + 16];
int currIdx = BeginPacket(packetData, reqProtocolVersion);
Array.Copy(usefulData, 0, packetData, currIdx, usefulData.Length);
FinishPacket(packetData);
//try { udpSock.SendTo(packetData, clientEP); }
int temp = 0;
poolLock.EnterWriteLock();
temp = listInd;
listInd = ++listInd % 40;
SocketAsyncEventArgs args = argsList[temp];
poolLock.ExitWriteLock();
args.RemoteEndPoint = clientEP;
Array.Copy(packetData, args.Buffer, packetData.Length);
//args.SetBuffer(packetData, 0, packetData.Length);
try {
udpSock.SendToAsync(args);
}
catch (Exception e) { }
}
private void ProcessIncoming(byte[] localMsg, IPEndPoint clientEP)
{
try
{
int currIdx = 0;
if (localMsg[0] != 'D' || localMsg[1] != 'S' || localMsg[2] != 'U' || localMsg[3] != 'C')
return;
else
currIdx += 4;
uint protocolVer = BitConverter.ToUInt16(localMsg, currIdx);
currIdx += 2;
if (protocolVer > MaxProtocolVersion)
return;
uint packetSize = BitConverter.ToUInt16(localMsg, currIdx);
currIdx += 2;
if (packetSize < 0)
return;
packetSize += 16; //size of header
if (packetSize > localMsg.Length)
return;
else if (packetSize < localMsg.Length)
{
byte[] newMsg = new byte[packetSize];
Array.Copy(localMsg, newMsg, packetSize);
localMsg = newMsg;
}
uint crcValue = BitConverter.ToUInt32(localMsg, currIdx);
//zero out the crc32 in the packet once we got it since that's whats needed for calculation
localMsg[currIdx++] = 0;
localMsg[currIdx++] = 0;
localMsg[currIdx++] = 0;
localMsg[currIdx++] = 0;
uint crcCalc = Crc32Algorithm.Compute(localMsg);
if (crcValue != crcCalc)
return;
uint clientId = BitConverter.ToUInt32(localMsg, currIdx);
currIdx += 4;
uint messageType = BitConverter.ToUInt32(localMsg, currIdx);
currIdx += 4;
if (messageType == (uint)MessageType.DSUC_VersionReq)
{
byte[] outputData = new byte[8];
int outIdx = 0;
Array.Copy(BitConverter.GetBytes((uint)MessageType.DSUS_VersionRsp), 0, outputData, outIdx, 4);
outIdx += 4;
Array.Copy(BitConverter.GetBytes((ushort)MaxProtocolVersion), 0, outputData, outIdx, 2);
outIdx += 2;
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
SendPacket(clientEP, outputData, 1001);
}
else if (messageType == (uint)MessageType.DSUC_ListPorts)
{
int numPadRequests = BitConverter.ToInt32(localMsg, currIdx);
currIdx += 4;
if (numPadRequests < 0 || numPadRequests > 4)
return;
int requestsIdx = currIdx;
for (int i = 0; i < numPadRequests; i++)
{
byte currRequest = localMsg[requestsIdx + i];
if (currRequest >= 4)
return;
}
byte[] outputData = new byte[16];
for (byte i = 0; i < numPadRequests; i++)
{
byte currRequest = localMsg[requestsIdx + i];
DualShockPadMeta padData = new DualShockPadMeta();
portInfoGet(currRequest, ref padData);
int outIdx = 0;
Array.Copy(BitConverter.GetBytes((uint)MessageType.DSUS_PortInfo), 0, outputData, outIdx, 4);
outIdx += 4;
outputData[outIdx++] = (byte)padData.PadId;
outputData[outIdx++] = (byte)padData.PadState;
outputData[outIdx++] = (byte)padData.Model;
outputData[outIdx++] = (byte)padData.ConnectionType;
byte[] addressBytes = null;
if (padData.PadMacAddress != null)
addressBytes = padData.PadMacAddress.GetAddressBytes();
if (addressBytes != null && addressBytes.Length == 6)
{
outputData[outIdx++] = addressBytes[0];
outputData[outIdx++] = addressBytes[1];
outputData[outIdx++] = addressBytes[2];
outputData[outIdx++] = addressBytes[3];
outputData[outIdx++] = addressBytes[4];
outputData[outIdx++] = addressBytes[5];
}
else
{
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
outputData[outIdx++] = 0;
}
outputData[outIdx++] = (byte)padData.BatteryStatus;
outputData[outIdx++] = 0;
SendPacket(clientEP, outputData, 1001);
}
}
else if (messageType == (uint)MessageType.DSUC_PadDataReq)
{
byte regFlags = localMsg[currIdx++];
byte idToReg = localMsg[currIdx++];
PhysicalAddress macToReg = null;
{
byte[] macBytes = new byte[6];
Array.Copy(localMsg, currIdx, macBytes, 0, macBytes.Length);
currIdx += macBytes.Length;
macToReg = new PhysicalAddress(macBytes);
}
lock (clients)
{
if (clients.ContainsKey(clientEP))
clients[clientEP].RequestPadInfo(regFlags, idToReg, macToReg);
else
{
var clientTimes = new ClientRequestTimes();
clientTimes.RequestPadInfo(regFlags, idToReg, macToReg);
clients[clientEP] = clientTimes;
}
}
}
}
catch (Exception e) { }
}
private void ReceiveCallback(IAsyncResult iar)
{
byte[] localMsg = null;
EndPoint clientEP = new IPEndPoint(IPAddress.Any, 0);
try
{
//Get the received message.
Socket recvSock = (Socket)iar.AsyncState;
int msgLen = recvSock.EndReceiveFrom(iar, ref clientEP);
localMsg = new byte[msgLen];
Array.Copy(recvBuffer, localMsg, msgLen);
}
catch (Exception e) { }
//Start another receive as soon as we copied the data
StartReceive();
//Process the data if its valid
if (localMsg != null)
ProcessIncoming(localMsg, (IPEndPoint)clientEP);
}
private void StartReceive()
{
try
{
if (running)
{
//Start listening for a new message.
EndPoint newClientEP = new IPEndPoint(IPAddress.Any, 0);
udpSock.BeginReceiveFrom(recvBuffer, 0, recvBuffer.Length, SocketFlags.None, ref newClientEP, ReceiveCallback, udpSock);
}
}
catch (SocketException ex)
{
uint IOC_IN = 0x80000000;
uint IOC_VENDOR = 0x18000000;
uint SIO_UDP_CONNRESET = IOC_IN | IOC_VENDOR | 12;
udpSock.IOControl((int)SIO_UDP_CONNRESET, new byte[] { Convert.ToByte(false) }, null);
StartReceive();
}
}
public void Start(int port, string listenAddress = "")
{
if (running)
{
if (udpSock != null)
{
udpSock.Close();
udpSock = null;
}
running = false;
}
udpSock = new Socket(AddressFamily.InterNetwork, SocketType.Dgram, ProtocolType.Udp);
try
{
IPAddress udpListenIPAddress;
if (listenAddress == "127.0.0.1" || listenAddress == "")
{
// Listen on local looback interface (default option). Does not allow remote client connections
udpListenIPAddress = IPAddress.Loopback;
}
else if (listenAddress == "0.0.0.0")
{
// Listen on all IPV4 interfaces.
// Remote client connections allowed. If the local network is not "safe" then may not be a good idea, because at the moment incoming connections are not authenticated in any way
udpListenIPAddress = IPAddress.Any;
}
else
{
// Listen on a specific hostname or IPV4 interface address. If the hostname has multiple interfaces then use the first IPV4 address because it is usually the primary IP addr.
// Remote client connections allowed.
IPAddress[] ipAddresses = Dns.GetHostAddresses(listenAddress);
udpListenIPAddress = null;
foreach (IPAddress ip4 in ipAddresses.Where(ip => ip.AddressFamily == System.Net.Sockets.AddressFamily.InterNetwork))
{
udpListenIPAddress = ip4;
break;
}
if (udpListenIPAddress == null) throw new SocketException(10049 /*WSAEADDRNOTAVAIL*/);
}
udpSock.Bind(new IPEndPoint(udpListenIPAddress, port));
}
catch (SocketException ex)
{
udpSock.Close();
udpSock = null;
throw ex;
}
byte[] randomBuf = new byte[4];
new Random().NextBytes(randomBuf);
serverId = BitConverter.ToUInt32(randomBuf, 0);
running = true;
StartReceive();
}
public void Stop()
{
running = false;
if (udpSock != null)
{
udpSock.Close();
udpSock = null;
}
}
private bool ReportToBuffer(DS4State hidReport, byte[] outputData, ref int outIdx)
{
unchecked
{
outputData[outIdx] = 0;
if (hidReport.DpadLeft) outputData[outIdx] |= 0x80;
if (hidReport.DpadDown) outputData[outIdx] |= 0x40;
if (hidReport.DpadRight) outputData[outIdx] |= 0x20;
if (hidReport.DpadUp) outputData[outIdx] |= 0x10;
if (hidReport.Options) outputData[outIdx] |= 0x08;
if (hidReport.R3) outputData[outIdx] |= 0x04;
if (hidReport.L3) outputData[outIdx] |= 0x02;
if (hidReport.Share) outputData[outIdx] |= 0x01;
outputData[++outIdx] = 0;
if (hidReport.Square) outputData[outIdx] |= 0x80;
if (hidReport.Cross) outputData[outIdx] |= 0x40;
if (hidReport.Circle) outputData[outIdx] |= 0x20;
if (hidReport.Triangle) outputData[outIdx] |= 0x10;
if (hidReport.R1) outputData[outIdx] |= 0x08;
if (hidReport.L1) outputData[outIdx] |= 0x04;
if (hidReport.R2Btn) outputData[outIdx] |= 0x02;
if (hidReport.L2Btn) outputData[outIdx] |= 0x01;
outputData[++outIdx] = (hidReport.PS) ? (byte)1 : (byte)0;
outputData[++outIdx] = (hidReport.TouchButton) ? (byte)1 : (byte)0;
//Left stick
outputData[++outIdx] = hidReport.LX;
outputData[++outIdx] = hidReport.LY;
outputData[outIdx] = (byte)(255 - outputData[outIdx]); //invert Y by convention
//Right stick
outputData[++outIdx] = hidReport.RX;
outputData[++outIdx] = hidReport.RY;
outputData[outIdx] = (byte)(255 - outputData[outIdx]); //invert Y by convention
//we don't have analog buttons on DS4 :(
outputData[++outIdx] = hidReport.DpadLeft ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.DpadDown ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.DpadRight ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.DpadUp ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.Square ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.Cross ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.Circle ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.Triangle ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.R1 ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.L1 ? (byte)0xFF : (byte)0x00;
outputData[++outIdx] = hidReport.R2;
outputData[++outIdx] = hidReport.L2;
outIdx++;
//DS4 only: touchpad points
for (int i = 0; i < 2; i++)
{
var tpad = (i == 0) ? hidReport.TrackPadTouch0 : hidReport.TrackPadTouch1;
outputData[outIdx++] = tpad.IsActive ? (byte)1 : (byte)0;
outputData[outIdx++] = (byte)tpad.Id;
Array.Copy(BitConverter.GetBytes((ushort)tpad.X), 0, outputData, outIdx, 2);
outIdx += 2;
Array.Copy(BitConverter.GetBytes((ushort)tpad.Y), 0, outputData, outIdx, 2);
outIdx += 2;
}
//motion timestamp
if (hidReport.Motion != null)
Array.Copy(BitConverter.GetBytes((ulong)hidReport.totalMicroSec), 0, outputData, outIdx, 8);
else
Array.Clear(outputData, outIdx, 8);
outIdx += 8;
//accelerometer
if (hidReport.Motion != null)
{
Array.Copy(BitConverter.GetBytes((float)hidReport.Motion.accelXG), 0, outputData, outIdx, 4);
outIdx += 4;
Array.Copy(BitConverter.GetBytes((float)hidReport.Motion.accelYG), 0, outputData, outIdx, 4);
outIdx += 4;
Array.Copy(BitConverter.GetBytes((float)-hidReport.Motion.accelZG), 0, outputData, outIdx, 4);
outIdx += 4;
}
else
{
Array.Clear(outputData, outIdx, 12);
outIdx += 12;
}
//gyroscope
if (hidReport.Motion != null)
{
Array.Copy(BitConverter.GetBytes((float)hidReport.Motion.angVelPitch), 0, outputData, outIdx, 4);
outIdx += 4;
Array.Copy(BitConverter.GetBytes((float)hidReport.Motion.angVelYaw), 0, outputData, outIdx, 4);
outIdx += 4;
Array.Copy(BitConverter.GetBytes((float)hidReport.Motion.angVelRoll), 0, outputData, outIdx, 4);
outIdx += 4;
}
else
{
Array.Clear(outputData, outIdx, 12);
outIdx += 12;
}
}
return true;
}
public void NewReportIncoming(ref DualShockPadMeta padMeta, DS4State hidReport, byte[] outputData)
{
if (!running)
return;
var clientsList = new List<IPEndPoint>();
var now = DateTime.UtcNow;
lock (clients)
{
var clientsToDelete = new List<IPEndPoint>();
foreach (var cl in clients)
{
const double TimeoutLimit = 5;
if ((now - cl.Value.AllPadsTime).TotalSeconds < TimeoutLimit)
clientsList.Add(cl.Key);
else if ((padMeta.PadId < cl.Value.PadIdsTime.Length) &&
(now - cl.Value.PadIdsTime[(byte)padMeta.PadId]).TotalSeconds < TimeoutLimit)
clientsList.Add(cl.Key);
else if (cl.Value.PadMacsTime.ContainsKey(padMeta.PadMacAddress) &&
(now - cl.Value.PadMacsTime[padMeta.PadMacAddress]).TotalSeconds < TimeoutLimit)
clientsList.Add(cl.Key);
else //check if this client is totally dead, and remove it if so
{
bool clientOk = false;
for (int i = 0; i < cl.Value.PadIdsTime.Length; i++)
{
var dur = (now - cl.Value.PadIdsTime[i]).TotalSeconds;
if (dur < TimeoutLimit)
{
clientOk = true;
break;
}
}
if (!clientOk)
{
foreach (var dict in cl.Value.PadMacsTime)
{
var dur = (now - dict.Value).TotalSeconds;
if (dur < TimeoutLimit)
{
clientOk = true;
break;
}
}
if (!clientOk)
clientsToDelete.Add(cl.Key);
}
}
}
foreach (var delCl in clientsToDelete)
{
clients.Remove(delCl);
}
clientsToDelete.Clear();
clientsToDelete = null;
}
if (clientsList.Count <= 0)
return;
unchecked
{
//byte[] outputData = new byte[100];
int outIdx = BeginPacket(outputData, 1001);
Array.Copy(BitConverter.GetBytes((uint)MessageType.DSUS_PadDataRsp), 0, outputData, outIdx, 4);
outIdx += 4;
outputData[outIdx++] = (byte)padMeta.PadId;
outputData[outIdx++] = (byte)padMeta.PadState;
outputData[outIdx++] = (byte)padMeta.Model;
outputData[outIdx++] = (byte)padMeta.ConnectionType;
{
byte[] padMac = padMeta.PadMacAddress.GetAddressBytes();
outputData[outIdx++] = padMac[0];
outputData[outIdx++] = padMac[1];
outputData[outIdx++] = padMac[2];
outputData[outIdx++] = padMac[3];
outputData[outIdx++] = padMac[4];
outputData[outIdx++] = padMac[5];
}
outputData[outIdx++] = (byte)padMeta.BatteryStatus;
outputData[outIdx++] = padMeta.IsActive ? (byte)1 : (byte)0;
Array.Copy(BitConverter.GetBytes((uint)hidReport.PacketCounter), 0, outputData, outIdx, 4);
outIdx += 4;
if (!ReportToBuffer(hidReport, outputData, ref outIdx))
return;
else
FinishPacket(outputData);
foreach (var cl in clientsList)
{
//try { udpSock.SendTo(outputData, cl); }
int temp = 0;
poolLock.EnterWriteLock();
temp = listInd;
listInd = ++listInd % 40;
SocketAsyncEventArgs args = argsList[temp];
poolLock.ExitWriteLock();
args.RemoteEndPoint = cl;
Array.Copy(outputData, args.Buffer, outputData.Length);
try {
udpSock.SendToAsync(args);
}
catch (SocketException ex) { }
}
}
clientsList.Clear();
clientsList = null;
}
}
}