public bool Bind(int port, bool reuseAddress)
{
_udpSocketv4 = new Socket(AddressFamily.InterNetwork, SocketType.Dgram, ProtocolType.Udp);
_udpSocketv4.Blocking = false;
_udpSocketv4.ReceiveBufferSize = NetConstants.SocketBufferSize;
_udpSocketv4.SendBufferSize = NetConstants.SocketBufferSize;
_udpSocketv4.SetSocketOption(SocketOptionLevel.IP, SocketOptionName.IpTimeToLive, NetConstants.SocketTTL);
if (reuseAddress)
{
_udpSocketv4.SetSocketOption(SocketOptionLevel.Socket, SocketOptionName.ReuseAddress, true);
}
#if !NETCORE
_udpSocketv4.DontFragment = true;
#endif
try
{
_udpSocketv4.SetSocketOption(SocketOptionLevel.Socket, SocketOptionName.Broadcast, 1);
}
catch (SocketException e)
{
NetUtils.DebugWriteError("Broadcast error: {0}", e.ToString());
}
if (!BindSocket(_udpSocketv4, new IPEndPoint(IPAddress.Any, port)))
{
return(false);
}
_port = ((IPEndPoint)_udpSocketv4.LocalEndPoint).Port;
_running = true;
_threadv4 = new Thread(ReceiveLogic);
_threadv4.Name = "SocketThreadv4(" + _port + ")";
_threadv4.IsBackground = true;
_threadv4.Start(_udpSocketv4);
//Check IPv6 support
if (!IPv6Support)
{
return(true);
}
_udpSocketv6 = new Socket(AddressFamily.InterNetworkV6, SocketType.Dgram, ProtocolType.Udp);
_udpSocketv6.Blocking = false;
_udpSocketv6.ReceiveBufferSize = NetConstants.SocketBufferSize;
_udpSocketv6.SendBufferSize = NetConstants.SocketBufferSize;
if (reuseAddress)
{
_udpSocketv6.SetSocketOption(SocketOptionLevel.Socket, SocketOptionName.ReuseAddress, true);
}
//Use one port for two sockets
if (BindSocket(_udpSocketv6, new IPEndPoint(IPAddress.IPv6Any, _port)))
{
try
{
#if !ENABLE_IL2CPP
_udpSocketv6.SetSocketOption(
SocketOptionLevel.IPv6,
SocketOptionName.AddMembership,
new IPv6MulticastOption(MulticastAddressV6));
#endif
}
catch (Exception)
{
// Unity3d throws exception - ignored
}
_threadv6 = new Thread(ReceiveLogic);
_threadv6.Name = "SocketThreadv6(" + _port + ")";
_threadv6.IsBackground = true;
_threadv6.Start(_udpSocketv6);
}
return(true);
}
//Process incoming packet
internal void ProcessPacket(NetPacket packet)
{
_timeSinceLastPacket = 0;
NetUtils.DebugWrite("[RR]PacketProperty: {0}", packet.Property);
switch (packet.Property)
{
case PacketProperty.ConnectRequest:
//response with connect
long newId = BitConverter.ToInt64(packet.RawData, NetConstants.RequestConnectIdIndex);
if (newId > _connectId)
{
_connectId = newId;
}
NetUtils.DebugWrite("ConnectRequest LastId: {0}, NewId: {1}, EP: {2}", ConnectId, newId, _remoteEndPoint);
SendConnectAccept();
_packetPool.Recycle(packet);
break;
case PacketProperty.Merged:
int pos = NetConstants.HeaderSize;
while (pos < packet.Size)
{
ushort size = BitConverter.ToUInt16(packet.RawData, pos);
pos += 2;
NetPacket mergedPacket = _packetPool.GetAndRead(packet.RawData, pos, size);
if (mergedPacket == null)
{
_packetPool.Recycle(packet);
break;
}
pos += size;
ProcessPacket(mergedPacket);
}
break;
//If we get ping, send pong
case PacketProperty.Ping:
if (NetUtils.RelativeSequenceNumber(packet.Sequence, _remotePingSequence) < 0)
{
_packetPool.Recycle(packet);
break;
}
NetUtils.DebugWrite("[PP]Ping receive, send pong");
_remotePingSequence = packet.Sequence;
_packetPool.Recycle(packet);
//send
CreateAndSend(PacketProperty.Pong, _remotePingSequence);
break;
//If we get pong, calculate ping time and rtt
case PacketProperty.Pong:
if (NetUtils.RelativeSequenceNumber(packet.Sequence, _pingSequence) < 0)
{
_packetPool.Recycle(packet);
break;
}
_pingSequence = packet.Sequence;
int rtt = (int)(DateTime.UtcNow - _pingTimeStart).TotalMilliseconds;
UpdateRoundTripTime(rtt);
NetUtils.DebugWrite("[PP]Ping: {0}", rtt);
_packetPool.Recycle(packet);
break;
//Process ack
case PacketProperty.AckReliable:
_reliableUnorderedChannel.ProcessAck(packet);
_packetPool.Recycle(packet);
break;
case PacketProperty.AckReliableOrdered:
_reliableOrderedChannel.ProcessAck(packet);
_packetPool.Recycle(packet);
break;
//Process in order packets
case PacketProperty.Sequenced:
_sequencedChannel.ProcessPacket(packet);
break;
case PacketProperty.Reliable:
_reliableUnorderedChannel.ProcessPacket(packet);
break;
case PacketProperty.ReliableOrdered:
_reliableOrderedChannel.ProcessPacket(packet);
break;
//Simple packet without acks
case PacketProperty.Unreliable:
AddIncomingPacket(packet);
return;
case PacketProperty.MtuCheck:
case PacketProperty.MtuOk:
ProcessMtuPacket(packet);
break;
default:
NetUtils.DebugWriteError("Error! Unexpected packet type: " + packet.Property);
break;
}
}
private void DataReceived(byte[] reusableBuffer, int count, NetEndPoint remoteEndPoint)
{
#if STATS_ENABLED
Statistics.PacketsReceived++;
Statistics.BytesReceived += (uint)count;
#endif
//Try read packet
NetPacket packet = _netPacketPool.GetAndRead(reusableBuffer, 0, count);
if (packet == null)
{
NetUtils.DebugWriteError("[NM] DataReceived: bad!");
return;
}
//Check unconnected
switch (packet.Property)
{
case PacketProperty.DiscoveryRequest:
if (DiscoveryEnabled)
{
var netEvent = CreateEvent(NetEventType.DiscoveryRequest);
netEvent.RemoteEndPoint = remoteEndPoint;
netEvent.DataReader.SetSource(packet.RawData, NetConstants.HeaderSize, count);
EnqueueEvent(netEvent);
}
return;
case PacketProperty.DiscoveryResponse:
{
var netEvent = CreateEvent(NetEventType.DiscoveryResponse);
netEvent.RemoteEndPoint = remoteEndPoint;
netEvent.DataReader.SetSource(packet.RawData, NetConstants.HeaderSize, count);
EnqueueEvent(netEvent);
}
return;
case PacketProperty.UnconnectedMessage:
if (UnconnectedMessagesEnabled)
{
var netEvent = CreateEvent(NetEventType.ReceiveUnconnected);
netEvent.RemoteEndPoint = remoteEndPoint;
netEvent.DataReader.SetSource(packet.RawData, NetConstants.HeaderSize, count);
EnqueueEvent(netEvent);
}
return;
case PacketProperty.NatIntroduction:
case PacketProperty.NatIntroductionRequest:
case PacketProperty.NatPunchMessage:
{
if (NatPunchEnabled)
{
NatPunchModule.ProcessMessage(remoteEndPoint, packet);
}
return;
}
}
//Check normal packets
NetPeer netPeer;
//Check peers
Monitor.Enter(_peers);
int peersCount = _peers.Count;
if (_peers.TryGetValue(remoteEndPoint, out netPeer))
{
Monitor.Exit(_peers);
//Send
if (packet.Property == PacketProperty.Disconnect)
{
if (BitConverter.ToInt64(packet.RawData, 1) != netPeer.ConnectId)
{
//Old or incorrect disconnect
_netPacketPool.Recycle(packet);
return;
}
var netEvent = CreateEvent(NetEventType.Disconnect);
netPeer.SetDisconnectedState();
netEvent.Peer = netPeer;
netEvent.DataReader.SetSource(packet.RawData, 9, packet.Size);
netEvent.DisconnectReason = DisconnectReason.RemoteConnectionClose;
EnqueueEvent(netEvent);
_peers.Remove(netPeer.EndPoint);
//do not recycle because no sense)
}
else if (packet.Property == PacketProperty.ConnectAccept)
{
if (netPeer.ProcessConnectAccept(packet))
{
var connectEvent = CreateEvent(NetEventType.Connect);
connectEvent.Peer = netPeer;
EnqueueEvent(connectEvent);
}
_netPacketPool.Recycle(packet);
}
else
{
netPeer.ProcessPacket(packet);
}
return;
}
try
{
if (peersCount < _maxConnections && packet.Property == PacketProperty.ConnectRequest)
{
int protoId = BitConverter.ToInt32(packet.RawData, 1);
if (protoId != NetConstants.ProtocolId)
{
NetUtils.DebugWrite(ConsoleColor.Cyan,
"[NM] Peer connect reject. Invalid protocol ID: " + protoId);
return;
}
string peerKey = Encoding.UTF8.GetString(packet.RawData, 13, packet.Size - 13);
if (peerKey != ConnectKey)
{
NetUtils.DebugWrite(ConsoleColor.Cyan, "[NM] Peer connect reject. Invalid key: " + peerKey);
return;
}
//Getting new id for peer
long connectionId = BitConverter.ToInt64(packet.RawData, 5);
//response with id
netPeer = new NetPeer(this, remoteEndPoint, connectionId);
NetUtils.DebugWrite(ConsoleColor.Cyan, "[NM] Received peer connect request Id: {0}, EP: {1}",
netPeer.ConnectId, remoteEndPoint);
//clean incoming packet
_netPacketPool.Recycle(packet);
_peers.Add(remoteEndPoint, netPeer);
var netEvent = CreateEvent(NetEventType.Connect);
netEvent.Peer = netPeer;
EnqueueEvent(netEvent);
}
}
finally
{
Monitor.Exit(_peers);
}
}
internal void AddIncomingPacket(NetPacket p)
{
if (p.IsFragmented)
{
NetUtils.DebugWrite("Fragment. Id: {0}, Part: {1}, Total: {2}", p.FragmentId, p.FragmentPart, p.FragmentsTotal);
//Get needed array from dictionary
ushort packetFragId = p.FragmentId;
IncomingFragments incomingFragments;
if (!_holdedFragments.TryGetValue(packetFragId, out incomingFragments))
{
incomingFragments = new IncomingFragments
{
Fragments = new NetPacket[p.FragmentsTotal]
};
_holdedFragments.Add(packetFragId, incomingFragments);
}
//Cache
var fragments = incomingFragments.Fragments;
//Error check
if (p.FragmentPart >= fragments.Length || fragments[p.FragmentPart] != null)
{
_packetPool.Recycle(p);
NetUtils.DebugWriteError("Invalid fragment packet");
return;
}
//Fill array
fragments[p.FragmentPart] = p;
//Increase received fragments count
incomingFragments.ReceivedCount++;
//Increase total size
int dataOffset = p.GetHeaderSize() + NetConstants.FragmentHeaderSize;
incomingFragments.TotalSize += p.Size - dataOffset;
//Check for finish
if (incomingFragments.ReceivedCount != fragments.Length)
{
return;
}
NetUtils.DebugWrite("Received all fragments!");
NetPacket resultingPacket = _packetPool.Get(p.Property, incomingFragments.TotalSize);
int resultingPacketOffset = resultingPacket.GetHeaderSize();
int firstFragmentSize = fragments[0].Size - dataOffset;
for (int i = 0; i < incomingFragments.ReceivedCount; i++)
{
//Create resulting big packet
int fragmentSize = fragments[i].Size - dataOffset;
Buffer.BlockCopy(
fragments[i].RawData,
dataOffset,
resultingPacket.RawData,
resultingPacketOffset + firstFragmentSize * i,
fragmentSize);
//Free memory
_packetPool.Recycle(fragments[i]);
fragments[i] = null;
}
//Send to process
_peerListener.ReceiveFromPeer(resultingPacket, _remoteEndPoint);
//Clear memory
_packetPool.Recycle(resultingPacket);
_holdedFragments.Remove(packetFragId);
}
else //Just simple packet
{
_peerListener.ReceiveFromPeer(p, _remoteEndPoint);
_packetPool.Recycle(p);
}
}
