private static async Task Server(HandshakeState handshakeState)
{
var buffer = new byte[Protocol.MaxMessageLength];
// Receive the first handshake message from the client.
var received = await clientToServer.Receive();
handshakeState.ReadMessage(received, buffer);
// Send the second handshake message to the client.
var(bytesWritten, _, transport) = handshakeState.WriteMessage(null, buffer);
await serverToClient.Send(Slice(buffer, bytesWritten));
// Handshake complete, switch to transport mode.
using (transport)
{
for (;;)
{
// Receive the message from the client.
var request = await clientToServer.Receive();
var bytesRead = transport.ReadMessage(request, buffer);
// Echo the message back to the client.
bytesWritten = transport.WriteMessage(Slice(buffer, bytesRead), buffer);
await serverToClient.Send(Slice(buffer, bytesWritten));
}
}
}
private static async Task Client(HandshakeState state)
{
var buffer = new byte[Protocol.MaxMessageLength];
// Send the first handshake message to the server.
var(bytesWritten, _, _) = state.WriteMessage(null, buffer);
await clientToServer.Send(Slice(buffer, bytesWritten));
// Receive the second handshake message from the server.
var received = await serverToClient.Receive();
var(_, _, transport) = state.ReadMessage(received, buffer);
// Handshake complete, switch to transport mode.
using (transport)
{
foreach (var message in messages)
{
Memory <byte> request = Encoding.UTF8.GetBytes(message);
// Send the message to the server.
bytesWritten = transport.WriteMessage(request.Span, buffer);
await clientToServer.Send(Slice(buffer, bytesWritten));
// Receive the response and print it to the standard output.
var response = await serverToClient.Receive();
var bytesRead = transport.ReadMessage(response, buffer);
Console.WriteLine(Encoding.UTF8.GetString(Slice(buffer, bytesRead)));
}
}
}
/// <summary>
/// Asynchronously writes the negotiation data and the handshake message to the input stream.
/// </summary>
/// <param name="negotiationData">The negotiation data.</param>
/// <param name="messageBody">The message body to encrypt.</param>
/// <param name="paddedLength">
/// If this message has an encrypted payload and the length of the
/// <paramref name="messageBody"/> is less than <paramref name="paddedLength"/>,
/// <paramref name="messageBody"/> is padded to make its
/// length equal to <paramref name="paddedLength"/>.
/// </param>
/// <param name="cancellationToken">The token to monitor for cancellation requests.</param>
/// <returns>A task that represents the asynchronous write operation.</returns>
/// <exception cref="ObjectDisposedException">
/// Thrown if either the current instance, or the output stream has already been disposed.
/// </exception>
/// <exception cref="InvalidOperationException">
/// Thrown if the call to this method was unexpected in the current state of this object.
/// </exception>
/// <exception cref="ArgumentException">
/// Thrown if either the negotiation data, or the Noise message was greater
/// than <see cref="Protocol.MaxMessageLength"/> bytes in length.
/// </exception>
/// <exception cref="IOException">Thrown if an I/O error occurs.</exception>
/// <exception cref="NotSupportedException">Thrown if the stream does not support reading.</exception>
/// <remarks>
/// This method can also throw all exceptions that <see cref="Protocol.Create(ProtocolConfig)"/>
/// and <see cref="HandshakeState.Fallback(Protocol, ProtocolConfig)"/> methods can throw.
/// See <see cref="Protocol"/> and <see cref="HandshakeState"/> documentation for more details.
/// </remarks>
public async Task WriteHandshakeMessageAsync(
Memory <byte> negotiationData = default,
Memory <byte> messageBody = default,
ushort paddedLength = default,
CancellationToken cancellationToken = default)
{
ThrowIfDisposed();
if (this.transport != null)
{
throw new InvalidOperationException($"Cannot call {nameof(WriteHandshakeMessageAsync)} after the handshake has been completed.");
}
if (negotiationData.Length > Protocol.MaxMessageLength)
{
throw new ArgumentException($"Negotiation data must be less than or equal to {Protocol.MaxMessageLength} bytes in length.");
}
if (messageBody.Length > Protocol.MaxMessageLength)
{
throw new ArgumentException($"Handshake message must be less than or equal to {Protocol.MaxMessageLength} bytes in length.");
}
ProcessMessage(HandshakeOperation.WriteNegotiationData, negotiationData);
InitializeHandshakeState();
// negotiation_data_len (2 bytes)
// negotiation_data
// noise_message_len (2 bytes)
// noise_message
int negotiationLength = LenFieldSize + negotiationData.Length;
int maxNoiseLength = LenFieldSize + Protocol.MaxMessageLength;
// Prevent the buffer from going to the LOH (it may be greater than 85000 bytes).
var pool = ArrayPool <byte> .Shared;
var buffer = pool.Rent(negotiationLength + maxNoiseLength);
try
{
Memory <byte> plaintext = messageBody;
if (isNextMessageEncrypted)
{
plaintext = new byte[LenFieldSize + Math.Max(messageBody.Length, paddedLength)];
WritePacket(messageBody.Span, plaintext.Span);
}
var ciphertext = buffer.AsMemory(negotiationLength + LenFieldSize);
var(bytesWritten, handshakeHash, transport) = handshakeState.WriteMessage(plaintext.Span, ciphertext.Span);
isNextMessageEncrypted = true;
if (transport != null)
{
handshakeState.Dispose();
handshakeState = null;
this.handshakeHash = handshakeHash;
this.transport = transport;
}
WritePacket(negotiationData.Span, buffer);
BinaryPrimitives.WriteUInt16BigEndian(buffer.AsSpan(negotiationLength), (ushort)bytesWritten);
ProcessMessage(HandshakeOperation.WriteHandshakeMessage, ciphertext.Slice(0, bytesWritten));
int noiseLength = LenFieldSize + bytesWritten;
int handshakeLength = negotiationLength + noiseLength;
await stream.WriteAsync(buffer, 0, handshakeLength, cancellationToken).ConfigureAwait(false);
}
finally
{
pool.Return(buffer);
}
}
/// <summary>
/// Perform handshake protocol if it has not been already run.
/// </summary>
/// <remarks>
/// Most uses of this package need not call Handshake explicitly:
/// the first Read or Write will call it automatically.
/// </remarks>
internal void HandShake()
{
// Locking the handshakeMutex
this.handshakeMutex.WaitOne();
HandshakeState handshakeState = null;
try
{
Strobe c1;
Strobe c2;
byte[] receivedPayload = null;
// did we already go through the handshake?
if (this.handshakeComplite)
{
return;
}
KeyPair remoteKeyPair = null;
if (this.config.RemoteKey != null)
{
if (this.config.RemoteKey.Length != Asymmetric.DhLen)
{
throw new Exception($"disco: the provided remote key is not {Asymmetric.DhLen}-byte");
}
remoteKeyPair = new KeyPair {
PublicKey = new byte[this.config.RemoteKey.Length]
};
Array.Copy(this.config.RemoteKey, remoteKeyPair.PublicKey, this.config.RemoteKey.Length);
}
handshakeState = DiscoHelper.InitializeDisco(
this.config.HandshakePattern,
this.isClient,
this.config.Prologue,
this.config.KeyPair,
null,
remoteKeyPair,
null);
// pre-shared key
handshakeState.Psk = this.config.PreSharedKey;
do
{
// start handshake
if (handshakeState.ShouldWrite)
{
// we're writing the next message pattern
// if it's the message pattern and we're sending a static key, we also send a proof
// TODO: is this the best way of sending a proof :/ ?
byte[] bufToWrite;
if (handshakeState.MessagePatterns.Length <= 2 && this.config.StaticPublicKeyProof != null)
{
(c1, c2) = handshakeState.WriteMessage(this.config.StaticPublicKeyProof, out bufToWrite);
}
else
{
(c1, c2) = handshakeState.WriteMessage(new byte[] { }, out bufToWrite);
}
// header (length)
var length = new[] { (byte)(bufToWrite.Length >> 8), (byte)(bufToWrite.Length % 256) };
// write
var dataToWrite = length.Concat(bufToWrite).ToArray();
this.connectionStream.Write(dataToWrite, 0, dataToWrite.Length);
}
else
{
var bufHeader = this.ReadFromUntil(this.connectionStream, 2);
var length = (bufHeader[0] << 8) | bufHeader[1];
if (length > Config.NoiseMessageLength)
{
throw new Exception("disco: Disco message received exceeds DiscoMessageLength");
}
var noiseMessage = this.ReadFromUntil(this.connectionStream, length);
(c1, c2) = handshakeState.ReadMessage(noiseMessage, out receivedPayload);
}
}while (c1 == null);
// Has the other peer been authenticated so far?
if (!this.isRemoteAuthenticated && this.config.PublicKeyVerifier != null)
{
byte isRemoteStaticKeySet = 0;
// test if remote static key is empty
foreach (var val in handshakeState.Rs.PublicKey)
{
isRemoteStaticKeySet |= val;
}
if (isRemoteStaticKeySet != 0)
{
// a remote static key has been received. Verify it
if (!this.config.PublicKeyVerifier(handshakeState.Rs.PublicKey, receivedPayload))
{
throw new Exception("disco: the received public key could not be authenticated");
}
this.isRemoteAuthenticated = true;
this.RemotePublicKey = handshakeState.Rs.PublicKey;
}
}
// Processing the final handshake message returns two CipherState objects
// the first for encrypting transport messages from initiator to responder
// and the second for messages in the other direction.
if (c2 != null)
{
if (this.isClient)
{
(this.strobeOut, this.strobeIn) = (c1, c2);
}
else
{
(this.strobeOut, this.strobeIn) = (c2, c1);
}
}
else
{
this.IsHalfDuplex = true;
this.strobeIn = c1;
this.strobeOut = c1;
}
// TODO: preserve c.hs.symmetricState.h
// At that point the HandshakeState should be deleted except for the hash value h, which may be used for post-handshake channel binding (see Section 11.2).
handshakeState.Dispose();
// no errors :)
this.handshakeComplite = true;
}
finally
{
handshakeState?.Dispose();
this.handshakeMutex.ReleaseMutex();
}
}
