private NetReceiverChannelBase CreateReceiverChannel(NetMessageType tp)
{
m_peer.VerifyNetworkThread();
// create receiver channel
NetReceiverChannelBase chan;
NetDeliveryMethod method = NetUtility.GetDeliveryMethod(tp);
switch (method)
{
case NetDeliveryMethod.Unreliable:
chan = new NetUnreliableUnorderedReceiver(this);
break;
case NetDeliveryMethod.ReliableOrdered:
chan = new NetReliableOrderedReceiver(this, NetConstants.ReliableOrderedWindowSize);
break;
case NetDeliveryMethod.UnreliableSequenced:
chan = new NetUnreliableSequencedReceiver(this);
break;
case NetDeliveryMethod.ReliableUnordered:
chan = new NetReliableUnorderedReceiver(this, NetConstants.ReliableOrderedWindowSize);
break;
case NetDeliveryMethod.ReliableSequenced:
chan = new NetReliableSequencedReceiver(this, NetConstants.ReliableSequencedWindowSize);
break;
default:
throw new NetException("Unhandled NetDeliveryMethod!");
}
int channelSlot = (int)tp - 1;
NetException.Assert(m_receiveChannels[channelSlot] == null);
m_receiveChannels[channelSlot] = chan;
return(chan);
}
internal override void ReceiveMessage(NetIncomingMessage message)
{
int nr = message.m_sequenceNumber;
int relate = NetUtility.RelativeSequenceNumber(nr, m_windowStart);
// ack no matter what
m_connection.QueueAck(message.m_receivedMessageType, nr);
if (relate == 0)
{
// Log("Received message #" + message.SequenceNumber + " right on time");
//
// excellent, right on time
//
AdvanceWindow();
m_peer.ReleaseMessage(message);
return;
}
if (relate < 0)
{
m_peer.LogVerbose("Received message #" + message.m_sequenceNumber + " DROPPING LATE or DUPE");
return;
}
// relate > 0 = early message
if (relate > m_windowSize)
{
// too early message!
m_peer.LogDebug("Received " + message + " TOO EARLY! Expected " + m_windowStart);
return;
}
// ok
m_windowStart = (m_windowStart + relate) % NetConstants.NumSequenceNumbers;
m_peer.ReleaseMessage(message);
return;
}
/// <summary>
/// Add a forwarding rule to the router using UPnP
/// </summary>
public bool ForwardPort(int port, string description)
{
if (m_serviceUrl == null && !m_discoveryComplete.WaitOne(c_discoveryTimeOutMillis))
{
return(false);
}
IPAddress mask;
var client = NetUtility.GetMyAddress(out mask);
if (client == null)
{
return(false);
}
try
{
XmlDocument xdoc = SOAPRequest(m_serviceUrl,
"<u:AddPortMapping xmlns:u=\"urn:schemas-upnp-org:service:WANIPConnection:1\">" +
"<NewRemoteHost></NewRemoteHost><NewExternalPort>" + port.ToString() + "</NewExternalPort>" +
"<NewProtocol>" + ProtocolType.Udp.ToString().ToUpper() + "</NewProtocol>" +
"<NewInternalPort>" + port.ToString() + "</NewInternalPort>" +
"<NewInternalClient>" + client.ToString() + "</NewInternalClient>" +
"<NewEnabled>1</NewEnabled>" +
"<NewPortMappingDescription>" + description + "</NewPortMappingDescription>" +
"<NewLeaseDuration>0</NewLeaseDuration>" +
"</u:AddPortMapping>",
"AddPortMapping");
m_peer.LogDebug("Sent UPnP port forward request");
System.Threading.Thread.Sleep(50);
}
catch (Exception ex)
{
m_peer.LogWarning("UPnP port forward failed: " + ex.Message);
return(false);
}
return(true);
}
/// <summary>
/// Writes all properties with specified binding in alphabetical order using reflection
/// </summary>
public void WriteAllProperties(object ob, BindingFlags flags)
{
if (ob == null)
{
return;
}
Type tp = ob.GetType();
PropertyInfo[] fields = tp.GetProperties(flags);
NetUtility.SortMembersList(fields);
foreach (PropertyInfo fi in fields)
{
MethodInfo getMethod = fi.GetGetMethod((flags & BindingFlags.NonPublic) == BindingFlags.NonPublic);
object value = getMethod.Invoke(ob, null);
// find the appropriate Write method
MethodInfo writeMethod;
if (s_writeMethods.TryGetValue(fi.PropertyType, out writeMethod))
{
writeMethod.Invoke(this, new object[] { value });
}
}
}
/// <summary>
/// Create a connection to a remote endpoint
/// </summary>
public NetConnection Connect(string host, int port, NetOutgoingMessage hailMessage)
{
return(Connect(new IPEndPoint(NetUtility.Resolve(host), port), hailMessage));
}
/// <summary>
/// Create a connection to a remote endpoint
/// </summary>
public NetConnection Connect(string host, int port)
{
return(Connect(new IPEndPoint(NetUtility.Resolve(host), port), null));
}
private void InitializeNetwork()
{
lock (m_initializeLock)
{
m_configuration.Lock();
if (m_status == NetPeerStatus.Running)
{
return;
}
if (m_configuration.m_enableUPnP)
{
m_upnp = new NetUPnP(this);
}
InitializePools();
m_releasedIncomingMessages.Clear();
m_unsentUnconnectedMessages.Clear();
m_handshakes.Clear();
// bind to socket
IPEndPoint iep = null;
iep = new IPEndPoint(m_configuration.LocalAddress, m_configuration.Port);
EndPoint ep = (EndPoint)iep;
m_socket = new PlatformSocket();
m_socket.ReceiveBufferSize = m_configuration.ReceiveBufferSize;
m_socket.SendBufferSize = m_configuration.SendBufferSize;
m_socket.Blocking = false;
m_socket.Bind(ep);
m_socket.Setup();
IPEndPoint boundEp = m_socket.LocalEndPoint as IPEndPoint;
LogDebug("Socket bound to " + boundEp + ": " + m_socket.IsBound);
m_listenPort = boundEp.Port;
m_receiveBuffer = new byte[m_configuration.ReceiveBufferSize];
m_sendBuffer = new byte[m_configuration.SendBufferSize];
m_readHelperMessage = new NetIncomingMessage(NetIncomingMessageType.Error);
m_readHelperMessage.m_data = m_receiveBuffer;
byte[] macBytes = new byte[8];
NetRandom.Instance.NextBytes(macBytes);
#if IS_FULL_NET_AVAILABLE
try
{
System.Net.NetworkInformation.PhysicalAddress pa = NetUtility.GetMacAddress();
if (pa != null)
{
macBytes = pa.GetAddressBytes();
LogVerbose("Mac address is " + NetUtility.ToHexString(macBytes));
}
else
{
LogWarning("Failed to get Mac address");
}
}
catch (NotSupportedException)
{
// not supported; lets just keep the random bytes set above
}
#endif
byte[] epBytes = BitConverter.GetBytes(boundEp.GetHashCode());
byte[] combined = new byte[epBytes.Length + macBytes.Length];
Array.Copy(epBytes, 0, combined, 0, epBytes.Length);
Array.Copy(macBytes, 0, combined, epBytes.Length, macBytes.Length);
#if WINDOWS_PHONE
SHA1 s = new SHA1Managed();
m_uniqueIdentifier = BitConverter.ToInt64(s.ComputeHash(combined), 0);
#else
m_uniqueIdentifier = BitConverter.ToInt64(SHA1.Create().ComputeHash(combined), 0);
#endif
m_status = NetPeerStatus.Running;
}
}
private void Heartbeat()
{
VerifyNetworkThread();
double dnow = NetTime.Now;
float now = (float)dnow;
double delta = dnow - m_lastHeartbeat;
int maxCHBpS = 1250 - m_connections.Count;
if (maxCHBpS < 250)
{
maxCHBpS = 250;
}
if (delta > (1.0 / (double)maxCHBpS)) // max connection heartbeats/second max
{
m_frameCounter++;
m_lastHeartbeat = dnow;
// do handshake heartbeats
if ((m_frameCounter % 3) == 0)
{
foreach (var kvp in m_handshakes)
{
NetConnection conn = kvp.Value as NetConnection;
#if DEBUG
// sanity check
if (kvp.Key != kvp.Key)
{
LogWarning("Sanity fail! Connection in handshake list under wrong key!");
}
#endif
conn.UnconnectedHeartbeat(now);
if (conn.m_status == NetConnectionStatus.Connected || conn.m_status == NetConnectionStatus.Disconnected)
{
#if DEBUG
// sanity check
if (conn.m_status == NetConnectionStatus.Disconnected && m_handshakes.ContainsKey(conn.RemoteEndpoint))
{
LogWarning("Sanity fail! Handshakes list contained disconnected connection!");
m_handshakes.Remove(conn.RemoteEndpoint);
}
#endif
break; // collection has been modified
}
}
}
#if DEBUG
SendDelayedPackets();
#endif
// do connection heartbeats
lock (m_connections)
{
foreach (NetConnection conn in m_connections)
{
conn.Heartbeat(now, m_frameCounter);
if (conn.m_status == NetConnectionStatus.Disconnected)
{
//
// remove connection
//
m_connections.Remove(conn);
m_connectionLookup.Remove(conn.RemoteEndpoint);
break; // can't continue iteration here
}
}
}
// send unsent unconnected messages
NetTuple <IPEndPoint, NetOutgoingMessage> unsent;
while (m_unsentUnconnectedMessages.TryDequeue(out unsent))
{
NetOutgoingMessage om = unsent.Item2;
#if DEBUG
if (om.m_messageType == NetMessageType.NatPunchMessage)
{
LogDebug("Sending Nat Punch Message to " + unsent.Item1.ToString());
}
#endif
bool connReset;
int len = om.Encode(m_sendBuffer, 0, 0);
SendPacket(len, unsent.Item1, 1, out connReset);
Interlocked.Decrement(ref om.m_recyclingCount);
if (om.m_recyclingCount <= 0)
{
Recycle(om);
}
}
}
//
// read from socket
//
if (m_socket == null)
{
return;
}
if (!m_socket.Poll(1000)) // wait up to 1 ms for data to arrive
{
return;
}
//if (m_socket == null || m_socket.Available < 1)
// return;
do
{
int bytesReceived = 0;
try
{
bytesReceived = m_socket.ReceiveFrom(m_receiveBuffer, 0, m_receiveBuffer.Length, ref m_senderRemote);
}
catch (SocketException sx)
{
if (sx.SocketErrorCode == SocketError.ConnectionReset)
{
// connection reset by peer, aka connection forcibly closed aka "ICMP port unreachable"
// we should shut down the connection; but m_senderRemote seemingly cannot be trusted, so which connection should we shut down?!
// So, what to do?
return;
}
LogWarning(sx.ToString());
return;
}
if (bytesReceived < NetConstants.HeaderByteSize)
{
return;
}
//LogVerbose("Received " + bytesReceived + " bytes");
IPEndPoint ipsender = (IPEndPoint)m_senderRemote;
if (ipsender.Port == 1900)
{
// UPnP response
try
{
string resp = System.Text.Encoding.UTF8.GetString(m_receiveBuffer, 0, bytesReceived);
if (resp.Contains("upnp:rootdevice"))
{
resp = resp.Substring(resp.ToLower().IndexOf("location:") + 9);
resp = resp.Substring(0, resp.IndexOf("\r")).Trim();
m_upnp.ExtractServiceUrl(resp);
return;
}
}
catch { }
}
NetConnection sender = null;
m_connectionLookup.TryGetValue(ipsender, out sender);
double receiveTime = NetTime.Now;
//
// parse packet into messages
//
int numMessages = 0;
int ptr = 0;
while ((bytesReceived - ptr) >= NetConstants.HeaderByteSize)
{
// decode header
// 8 bits - NetMessageType
// 1 bit - Fragment?
// 15 bits - Sequence number
// 16 bits - Payload length in bits
numMessages++;
NetMessageType tp = (NetMessageType)m_receiveBuffer[ptr++];
byte low = m_receiveBuffer[ptr++];
byte high = m_receiveBuffer[ptr++];
bool isFragment = ((low & 1) == 1);
ushort sequenceNumber = (ushort)((low >> 1) | (((int)high) << 7));
ushort payloadBitLength = (ushort)(m_receiveBuffer[ptr++] | (m_receiveBuffer[ptr++] << 8));
int payloadByteLength = NetUtility.BytesToHoldBits(payloadBitLength);
if (bytesReceived - ptr < payloadByteLength)
{
LogWarning("Malformed packet; stated payload length " + payloadByteLength + ", remaining bytes " + (bytesReceived - ptr));
return;
}
try
{
NetException.Assert(tp <NetMessageType.Unused1 || tp> NetMessageType.Unused29);
if (tp >= NetMessageType.LibraryError)
{
if (sender != null)
{
sender.ReceivedLibraryMessage(tp, ptr, payloadByteLength);
}
else
{
ReceivedUnconnectedLibraryMessage(receiveTime, ipsender, tp, ptr, payloadByteLength);
}
}
else
{
if (sender == null && !m_configuration.IsMessageTypeEnabled(NetIncomingMessageType.UnconnectedData))
{
return; // dropping unconnected message since it's not enabled
}
NetIncomingMessage msg = CreateIncomingMessage(NetIncomingMessageType.Data, payloadByteLength);
msg.m_isFragment = isFragment;
msg.m_receiveTime = receiveTime;
msg.m_sequenceNumber = sequenceNumber;
msg.m_receivedMessageType = tp;
msg.m_senderConnection = sender;
msg.m_senderEndpoint = ipsender;
msg.m_bitLength = payloadBitLength;
Buffer.BlockCopy(m_receiveBuffer, ptr, msg.m_data, 0, payloadByteLength);
if (sender != null)
{
if (tp == NetMessageType.Unconnected)
{
// We're connected; but we can still send unconnected messages to this peer
msg.m_incomingMessageType = NetIncomingMessageType.UnconnectedData;
ReleaseMessage(msg);
}
else
{
// connected application (non-library) message
sender.ReceivedMessage(msg);
}
}
else
{
// at this point we know the message type is enabled
// unconnected application (non-library) message
msg.m_incomingMessageType = NetIncomingMessageType.UnconnectedData;
ReleaseMessage(msg);
}
}
}
catch (Exception ex)
{
LogError("Packet parsing error: " + ex.Message + " from " + ipsender);
}
ptr += payloadByteLength;
}
m_statistics.PacketReceived(bytesReceived, numMessages);
if (sender != null)
{
sender.m_statistics.PacketReceived(bytesReceived, numMessages);
}
} while (m_socket.Available > 0);
}
private void HandleReleasedFragment(NetIncomingMessage im)
{
//
// read fragmentation header and combine fragments
//
int group;
int totalBits;
int chunkByteSize;
int chunkNumber;
int ptr = NetFragmentationHelper.ReadHeader(
im.m_data, 0,
out group,
out totalBits,
out chunkByteSize,
out chunkNumber
);
NetException.Assert(im.LengthBytes > ptr);
NetException.Assert(group > 0);
NetException.Assert(totalBits > 0);
NetException.Assert(chunkByteSize > 0);
int totalBytes = NetUtility.BytesToHoldBits((int)totalBits);
int totalNumChunks = totalBytes / chunkByteSize;
if (totalNumChunks * chunkByteSize < totalBytes)
{
totalNumChunks++;
}
NetException.Assert(chunkNumber < totalNumChunks);
if (chunkNumber >= totalNumChunks)
{
LogWarning("Index out of bounds for chunk " + chunkNumber + " (total chunks " + totalNumChunks + ")");
return;
}
Dictionary <int, ReceivedFragmentGroup> groups;
if (!m_receivedFragmentGroups.TryGetValue(im.SenderConnection, out groups))
{
groups = new Dictionary <int, ReceivedFragmentGroup>();
m_receivedFragmentGroups[im.SenderConnection] = groups;
}
ReceivedFragmentGroup info;
if (!groups.TryGetValue(group, out info))
{
info = new ReceivedFragmentGroup();
info.Data = new byte[totalBytes];
info.ReceivedChunks = new NetBitVector(totalNumChunks);
groups[group] = info;
}
info.ReceivedChunks[chunkNumber] = true;
info.LastReceived = (float)NetTime.Now;
// copy to data
int offset = (chunkNumber * chunkByteSize);
Buffer.BlockCopy(im.m_data, ptr, info.Data, offset, im.LengthBytes - ptr);
int cnt = info.ReceivedChunks.Count();
//LogVerbose("Found fragment #" + chunkNumber + " in group " + group + " offset " + offset + " of total bits " + totalBits + " (total chunks done " + cnt + ")");
LogVerbose("Received fragment " + chunkNumber + " of " + totalNumChunks + " (" + cnt + " chunks received)");
if (info.ReceivedChunks.Count() == totalNumChunks)
{
// Done! Transform this incoming message
im.m_data = info.Data;
im.m_bitLength = (int)totalBits;
im.m_isFragment = false;
LogVerbose("Fragment group #" + group + " fully received in " + totalNumChunks + " chunks (" + totalBits + " bits)");
ReleaseMessage(im);
}
else
{
// data has been copied; recycle this incoming message
Recycle(im);
}
return;
}
internal void ReceivedHandshake(double now, NetMessageType tp, int ptr, int payloadLength)
{
m_peer.VerifyNetworkThread();
byte[] hail;
switch (tp)
{
case NetMessageType.Connect:
if (m_status == NetConnectionStatus.None)
{
// Whee! Server full has already been checked
bool ok = ValidateHandshakeData(ptr, payloadLength, out hail);
if (ok)
{
if (hail != null)
{
m_remoteHailMessage = m_peer.CreateIncomingMessage(NetIncomingMessageType.Data, hail);
m_remoteHailMessage.LengthBits = (hail.Length * 8);
}
else
{
m_remoteHailMessage = null;
}
if (m_peerConfiguration.IsMessageTypeEnabled(NetIncomingMessageType.ConnectionApproval))
{
// ok, let's not add connection just yet
NetIncomingMessage appMsg = m_peer.CreateIncomingMessage(NetIncomingMessageType.ConnectionApproval, (m_remoteHailMessage == null ? 0 : m_remoteHailMessage.LengthBytes));
appMsg.m_receiveTime = now;
appMsg.m_senderConnection = this;
appMsg.m_senderEndpoint = this.m_remoteEndpoint;
if (m_remoteHailMessage != null)
{
appMsg.Write(m_remoteHailMessage.m_data, 0, m_remoteHailMessage.LengthBytes);
}
m_peer.ReleaseMessage(appMsg);
return;
}
SendConnectResponse((float)now, true);
}
return;
}
if (m_status == NetConnectionStatus.RespondedConnect)
{
// our ConnectResponse must have been lost
SendConnectResponse((float)now, true);
return;
}
m_peer.LogDebug("Unhandled Connect: " + tp + ", status is " + m_status + " length: " + payloadLength);
break;
case NetMessageType.ConnectResponse:
switch (m_status)
{
case NetConnectionStatus.InitiatedConnect:
// awesome
bool ok = ValidateHandshakeData(ptr, payloadLength, out hail);
if (ok)
{
if (hail != null)
{
m_remoteHailMessage = m_peer.CreateIncomingMessage(NetIncomingMessageType.Data, hail);
m_remoteHailMessage.LengthBits = (hail.Length * 8);
}
else
{
m_remoteHailMessage = null;
}
m_peer.AcceptConnection(this);
SendConnectionEstablished();
return;
}
break;
case NetConnectionStatus.RespondedConnect:
// hello, wtf?
break;
case NetConnectionStatus.Disconnecting:
case NetConnectionStatus.Disconnected:
case NetConnectionStatus.None:
// wtf? anyway, bye!
break;
case NetConnectionStatus.Connected:
// my ConnectionEstablished must have been lost, send another one
SendConnectionEstablished();
return;
}
break;
case NetMessageType.ConnectionEstablished:
switch (m_status)
{
case NetConnectionStatus.Connected:
// ok...
break;
case NetConnectionStatus.Disconnected:
case NetConnectionStatus.Disconnecting:
case NetConnectionStatus.None:
// too bad, almost made it
break;
case NetConnectionStatus.InitiatedConnect:
// weird, should have been ConnectResponse...
break;
case NetConnectionStatus.RespondedConnect:
// awesome
NetIncomingMessage msg = m_peer.SetupReadHelperMessage(ptr, payloadLength);
InitializeRemoteTimeOffset(msg.ReadSingle());
m_peer.AcceptConnection(this);
InitializePing();
SetStatus(NetConnectionStatus.Connected, "Connected to " + NetUtility.ToHexString(m_remoteUniqueIdentifier));
return;
}
break;
case NetMessageType.Disconnect:
// ouch
string reason = "Ouch";
try
{
NetIncomingMessage inc = m_peer.SetupReadHelperMessage(ptr, payloadLength);
reason = inc.ReadString();
}
catch
{
}
ExecuteDisconnect(reason, false);
break;
case NetMessageType.Discovery:
m_peer.HandleIncomingDiscoveryRequest(now, m_remoteEndpoint, ptr, payloadLength);
return;
case NetMessageType.DiscoveryResponse:
m_peer.HandleIncomingDiscoveryResponse(now, m_remoteEndpoint, ptr, payloadLength);
return;
case NetMessageType.Ping:
// silently ignore
return;
default:
m_peer.LogDebug("Unhandled type during handshake: " + tp + " length: " + payloadLength);
break;
}
}
internal override void ReceiveMessage(NetIncomingMessage message)
{
int relate = NetUtility.RelativeSequenceNumber(message.m_sequenceNumber, m_windowStart);
// ack no matter what
m_connection.QueueAck(message.m_receivedMessageType, message.m_sequenceNumber);
if (relate == 0)
{
// Log("Received message #" + message.SequenceNumber + " right on time");
//
// excellent, right on time
//
m_peer.LogVerbose("Received RIGHT-ON-TIME " + message);
AdvanceWindow();
m_peer.ReleaseMessage(message);
// release withheld messages
int nextSeqNr = (message.m_sequenceNumber + 1) % NetConstants.NumSequenceNumbers;
while (m_earlyReceived[nextSeqNr % m_windowSize])
{
//message = m_withheldMessages[nextSeqNr % m_windowSize];
//NetException.Assert(message != null);
// remove it from withheld messages
//m_withheldMessages[nextSeqNr % m_windowSize] = null;
//m_peer.LogVerbose("Releasing withheld message #" + message);
//m_peer.ReleaseMessage(message);
AdvanceWindow();
nextSeqNr++;
}
return;
}
if (relate < 0)
{
// duplicate
m_peer.LogVerbose("Received message #" + message.m_sequenceNumber + " DROPPING DUPLICATE");
return;
}
// relate > 0 = early message
if (relate > m_windowSize)
{
// too early message!
m_peer.LogDebug("Received " + message + " TOO EARLY! Expected " + m_windowStart);
return;
}
m_earlyReceived.Set(message.m_sequenceNumber % m_windowSize, true);
//m_peer.LogVerbose("Received " + message + " WITHHOLDING, waiting for " + m_windowStart);
//m_withheldMessages[message.m_sequenceNumber % m_windowSize] = message;
m_peer.ReleaseMessage(message);
}
// remoteWindowStart is remote expected sequence number; everything below this has arrived properly
// seqNr is the actual nr received
internal override void ReceiveAcknowledge(float now, int seqNr)
{
// late (dupe), on time or early ack?
int relate = NetUtility.RelativeSequenceNumber(seqNr, m_windowStart);
if (relate < 0)
{
//m_connection.m_peer.LogDebug("Received late/dupe ack for #" + seqNr);
return; // late/duplicate ack
}
if (relate == 0)
{
//m_connection.m_peer.LogDebug("Received right-on-time ack for #" + seqNr);
// ack arrived right on time
NetException.Assert(seqNr == m_windowStart);
m_receivedAcks[m_windowStart] = false;
DestoreMessage(m_windowStart % m_windowSize);
m_windowStart = (m_windowStart + 1) % NetConstants.NumSequenceNumbers;
// advance window if we already have early acks
while (m_receivedAcks.Get(m_windowStart))
{
//m_connection.m_peer.LogDebug("Using early ack for #" + m_windowStart + "...");
m_receivedAcks[m_windowStart] = false;
NetException.Assert(m_storedMessages[m_windowStart % m_windowSize].Message == null); // should already be destored
m_windowStart = (m_windowStart + 1) % NetConstants.NumSequenceNumbers;
//m_connection.m_peer.LogDebug("Advancing window to #" + m_windowStart);
}
return;
}
//
// early ack... (if it has been sent!)
//
// If it has been sent either the m_windowStart message was lost
// ... or the ack for that message was lost
//
//m_connection.m_peer.LogDebug("Received early ack for #" + seqNr);
int sendRelate = NetUtility.RelativeSequenceNumber(seqNr, m_sendStart);
if (sendRelate <= 0)
{
// yes, we've sent this message - it's an early (but valid) ack
if (m_receivedAcks[seqNr])
{
// we've already destored/been acked for this message
}
else
{
DestoreMessage(seqNr % m_windowSize);
m_receivedAcks[seqNr] = true;
}
}
else if (sendRelate > 0)
{
// uh... we haven't sent this message yet? Weird, dupe or error...
return;
}
// Ok, lets resend all missing acks
int rnr = seqNr;
do
{
rnr--;
if (rnr < 0)
{
rnr = NetConstants.NumSequenceNumbers - 1;
}
if (m_receivedAcks[rnr])
{
// m_connection.m_peer.LogDebug("Not resending #" + rnr + " (since we got ack)");
}
else
{
int slot = rnr % m_windowSize;
NetException.Assert(m_storedMessages[slot].Message != null);
if (m_storedMessages[slot].NumSent == 1)
{
// just sent once; resend immediately since we found gap in ack sequence
NetOutgoingMessage rmsg = m_storedMessages[slot].Message;
//m_connection.m_peer.LogVerbose("Resending #" + rnr + " (" + rmsg + ")");
if (now - m_storedMessages[slot].LastSent < (m_resendDelay * 0.35f))
{
// already resent recently
}
else
{
m_storedMessages[slot].LastSent = now;
m_storedMessages[slot].NumSent++;
m_connection.m_statistics.MessageResent(MessageResendReason.HoleInSequence);
m_connection.QueueSendMessage(rmsg, rnr);
}
}
}
} while (rnr != m_windowStart);
}
