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added pipe based benchmak

release/3.x.x
Jan Eggers 6 jaren geleden
bovenliggende
fd50e4e260
commit
cadf9f797f
11 gewijzigde bestanden met toevoegingen van 633 en 8 verwijderingen
Zij-aan-zij weergave
Diff opties
Statistieken weergeven Download Patch-bestand Download Diff-bestand
  1. +3
    -0
      MQTTnet.sln
  2. +2
    -0
      Tests/MQTTnet.Benchmarks/MQTTnet.Benchmarks.csproj
  3. +31
    -8
      Tests/MQTTnet.Benchmarks/MqttTcpChannelBenchmark.cs
  4. +4
    -0
      Tests/MQTTnet.Benchmarks/Program.cs
  5. +24
    -0
      Tests/MQTTnet.Benchmarks/Tcp/BufferExtensions.cs
  6. +41
    -0
      Tests/MQTTnet.Benchmarks/Tcp/DuplexPipe.cs
  7. +71
    -0
      Tests/MQTTnet.Benchmarks/Tcp/SocketAwaitable.cs
  8. +39
    -0
      Tests/MQTTnet.Benchmarks/Tcp/SocketReceiver.cs
  9. +99
    -0
      Tests/MQTTnet.Benchmarks/Tcp/SocketSender.cs
  10. +247
    -0
      Tests/MQTTnet.Benchmarks/Tcp/TcpConnection.cs
  11. +72
    -0
      Tests/MQTTnet.Benchmarks/TcpPipesBenchmark.cs

+ 3
- 0
MQTTnet.sln Bestand weergeven

@@ -41,6 +41,9 @@ EndProject
Project("{9A19103F-16F7-4668-BE54-9A1E7A4F7556}") = "MQTTnet.Benchmarks", "Tests\MQTTnet.Benchmarks\MQTTnet.Benchmarks.csproj", "{998D04DD-7CB0-45F5-A393-E2495C16399E}"
EndProject
Global
GlobalSection(Performance) = preSolution
HasPerformanceSessions = true
EndGlobalSection
GlobalSection(SolutionConfigurationPlatforms) = preSolution
Debug|Any CPU = Debug|Any CPU
Debug|ARM = Debug|ARM


+ 2
- 0
Tests/MQTTnet.Benchmarks/MQTTnet.Benchmarks.csproj Bestand weergeven

@@ -4,10 +4,12 @@
<OutputType>Exe</OutputType>
<DebugType>Full</DebugType>
<TargetFramework>net461</TargetFramework>
<LangVersion>7.2</LangVersion>
</PropertyGroup>

<ItemGroup>
<PackageReference Include="BenchmarkDotNet" Version="0.10.14" />
<PackageReference Include="System.IO.Pipelines" Version="4.5.0" />
</ItemGroup>

<ItemGroup>


+ 31
- 8
Tests/MQTTnet.Benchmarks/MqttTcpChannelBenchmark.cs Bestand weergeven

@@ -1,11 +1,11 @@
using BenchmarkDotNet.Attributes;
using MQTTnet.Adapter;
using MQTTnet.Channel;
using MQTTnet.Client;
using MQTTnet.Diagnostics;
using MQTTnet.Implementations;
using MQTTnet.Server;
using System.Threading;
using System.Threading.Tasks;

namespace MQTTnet.Benchmarks
{
@@ -13,8 +13,10 @@ namespace MQTTnet.Benchmarks
public class MqttTcpChannelBenchmark
{
private IMqttServer _mqttServer;
private IMqttChannel _clientChannel;
private IMqttChannel _serverChannel;

private IMqttChannel _clientChannel;

[GlobalSetup]
public void Setup()
@@ -31,22 +33,43 @@ namespace MQTTnet.Benchmarks
var clientOptions = new MqttClientOptionsBuilder()
.WithTcpServer("localhost").Build();

_clientChannel = new MqttTcpChannel((MqttClientTcpOptions)clientOptions.ChannelOptions);
var tcpOptions = (MqttClientTcpOptions) clientOptions.ChannelOptions;
_clientChannel = new MqttTcpChannel(tcpOptions);

_clientChannel.ConnectAsync(CancellationToken.None).GetAwaiter().GetResult();
}
[Benchmark]
public void Send_10000_Chunks()
public async Task Send_10000_Chunks()
{
var size = 5;
var iterations = 10000;
for (var i = 0; i < iterations; i++)

await Task.WhenAll(WriteAsync(iterations, size), ReadAsync(iterations, size));
}

private async Task ReadAsync(int iterations, int size)
{
await Task.Yield();

var expected = iterations * size;
long read = 0;

while (read < expected)
{
_serverChannel.WriteAsync(new byte[size], 0, size, CancellationToken.None).GetAwaiter().GetResult();
_clientChannel.ReadAsync(new byte[size], 0, size, CancellationToken.None).GetAwaiter().GetResult();
var readresult = await _clientChannel.ReadAsync(new byte[size], 0, size, CancellationToken.None).ConfigureAwait(false);
read += readresult;
}
}

private async Task WriteAsync(int iterations, int size)
{
await Task.Yield();
for (var i = 0; i < iterations; i++)
{
await _serverChannel.WriteAsync(new byte[size], 0, size, CancellationToken.None).ConfigureAwait(false);
}
}
}
}

+ 4
- 0
Tests/MQTTnet.Benchmarks/Program.cs Bestand weergeven

@@ -15,6 +15,7 @@ namespace MQTTnet.Benchmarks
Console.WriteLine("4 = TopicFilterComparerBenchmark");
Console.WriteLine("5 = ChannelAdapterBenchmark");
Console.WriteLine("6 = MqttTcpChannelBenchmark");
Console.WriteLine("7 = TcpPipesBenchmark");

var pressedKey = Console.ReadKey(true);
switch (pressedKey.KeyChar)
@@ -37,6 +38,9 @@ namespace MQTTnet.Benchmarks
case '6':
BenchmarkRunner.Run<MqttTcpChannelBenchmark>();
break;
case '7':
BenchmarkRunner.Run<TcpPipesBenchmark>();
break;
}

Console.ReadLine();


+ 24
- 0
Tests/MQTTnet.Benchmarks/Tcp/BufferExtensions.cs Bestand weergeven

@@ -0,0 +1,24 @@
using System;
using System.Collections.Generic;
using System.Runtime.InteropServices;
using System.Text;

namespace Playground.Client.Mqtt.Tcp
{
public static class BufferExtensions
{
public static ArraySegment<byte> GetArray(this Memory<byte> memory)
{
return ((ReadOnlyMemory<byte>)memory).GetArray();
}

public static ArraySegment<byte> GetArray(this ReadOnlyMemory<byte> memory)
{
if (!MemoryMarshal.TryGetArray(memory, out var result))
{
throw new InvalidOperationException("Buffer backed by array was expected");
}
return result;
}
}
}

+ 41
- 0
Tests/MQTTnet.Benchmarks/Tcp/DuplexPipe.cs Bestand weergeven

@@ -0,0 +1,41 @@
using System.IO.Pipelines;

namespace MQTTnet.Benchmarks.Tcp
{
public class DuplexPipe : IDuplexPipe
{
public DuplexPipe(PipeReader reader, PipeWriter writer)
{
Input = reader;
Output = writer;
}

public PipeReader Input { get; }

public PipeWriter Output { get; }

public static DuplexPipePair CreateConnectionPair(PipeOptions inputOptions, PipeOptions outputOptions)
{
var input = new Pipe(inputOptions);
var output = new Pipe(outputOptions);

var transportToApplication = new DuplexPipe(output.Reader, input.Writer);
var applicationToTransport = new DuplexPipe(input.Reader, output.Writer);

return new DuplexPipePair(applicationToTransport, transportToApplication);
}

// This class exists to work around issues with value tuple on .NET Framework
public readonly struct DuplexPipePair
{
public IDuplexPipe Transport { get; }
public IDuplexPipe Application { get; }

public DuplexPipePair(IDuplexPipe transport, IDuplexPipe application)
{
Transport = transport;
Application = application;
}
}
}
}

+ 71
- 0
Tests/MQTTnet.Benchmarks/Tcp/SocketAwaitable.cs Bestand weergeven

@@ -0,0 +1,71 @@
using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.IO.Pipelines;
using System.Net.Sockets;
using System.Runtime.CompilerServices;
using System.Text;
using System.Threading;
using System.Threading.Tasks;

namespace Playground.Client.Mqtt.Tcp
{
public class SocketAwaitable : ICriticalNotifyCompletion
{
private static readonly Action _callbackCompleted = () => { };

private readonly PipeScheduler _ioScheduler;

private Action _callback;
private int _bytesTransferred;
private SocketError _error;

public SocketAwaitable(PipeScheduler ioScheduler)
{
_ioScheduler = ioScheduler;
}

public SocketAwaitable GetAwaiter() => this;
public bool IsCompleted => ReferenceEquals(_callback, _callbackCompleted);

public int GetResult()
{
Debug.Assert(ReferenceEquals(_callback, _callbackCompleted));

_callback = null;

if (_error != SocketError.Success)
{
throw new SocketException((int)_error);
}

return _bytesTransferred;
}

public void OnCompleted(Action continuation)
{
if (ReferenceEquals(_callback, _callbackCompleted) ||
ReferenceEquals(Interlocked.CompareExchange(ref _callback, continuation, null), _callbackCompleted))
{
Task.Run(continuation);
}
}

public void UnsafeOnCompleted(Action continuation)
{
OnCompleted(continuation);
}

public void Complete(int bytesTransferred, SocketError socketError)
{
_error = socketError;
_bytesTransferred = bytesTransferred;
var continuation = Interlocked.Exchange(ref _callback, _callbackCompleted);

if (continuation != null)
{
_ioScheduler.Schedule(state => ((Action)state)(), continuation);
}
}
}
}

+ 39
- 0
Tests/MQTTnet.Benchmarks/Tcp/SocketReceiver.cs Bestand weergeven

@@ -0,0 +1,39 @@
using System;
using System.IO.Pipelines;
using System.Net.Sockets;
using Playground.Client.Mqtt.Tcp;

namespace MQTTnet.Benchmarks.Tcp
{
public class SocketReceiver
{
private readonly Socket _socket;
private readonly SocketAsyncEventArgs _eventArgs = new SocketAsyncEventArgs();
private readonly SocketAwaitable _awaitable;

public SocketReceiver(Socket socket, PipeScheduler scheduler)
{
_socket = socket;
_awaitable = new SocketAwaitable(scheduler);
_eventArgs.UserToken = _awaitable;
_eventArgs.Completed += (_, e) => ((SocketAwaitable)e.UserToken).Complete(e.BytesTransferred, e.SocketError);
}

public SocketAwaitable ReceiveAsync(Memory<byte> buffer)
{
#if NETCOREAPP2_1
_eventArgs.SetBuffer(buffer);
#else
var segment = buffer.GetArray();

_eventArgs.SetBuffer(segment.Array, segment.Offset, segment.Count);
#endif
if (!_socket.ReceiveAsync(_eventArgs))
{
_awaitable.Complete(_eventArgs.BytesTransferred, _eventArgs.SocketError);
}

return _awaitable;
}
}
}

+ 99
- 0
Tests/MQTTnet.Benchmarks/Tcp/SocketSender.cs Bestand weergeven

@@ -0,0 +1,99 @@
using System;
using System.Buffers;
using System.Collections.Generic;
using System.Diagnostics;
using System.IO.Pipelines;
using System.Net.Sockets;
using Playground.Client.Mqtt.Tcp;

namespace MQTTnet.Benchmarks.Tcp
{
public class SocketSender
{
private readonly Socket _socket;
private readonly SocketAsyncEventArgs _eventArgs = new SocketAsyncEventArgs();
private readonly SocketAwaitable _awaitable;

private List<ArraySegment<byte>> _bufferList;

public SocketSender(Socket socket, PipeScheduler scheduler)
{
_socket = socket;
_awaitable = new SocketAwaitable(scheduler);
_eventArgs.UserToken = _awaitable;
_eventArgs.Completed += (_, e) => ((SocketAwaitable)e.UserToken).Complete(e.BytesTransferred, e.SocketError);
}

public SocketAwaitable SendAsync(in ReadOnlySequence<byte> buffers)
{
if (buffers.IsSingleSegment)
{
return SendAsync(buffers.First);
}

#if NETCOREAPP2_1
if (!_eventArgs.MemoryBuffer.Equals(Memory<byte>.Empty))
#else
if (_eventArgs.Buffer != null)
#endif
{
_eventArgs.SetBuffer(null, 0, 0);
}

_eventArgs.BufferList = GetBufferList(buffers);

if (!_socket.SendAsync(_eventArgs))
{
_awaitable.Complete(_eventArgs.BytesTransferred, _eventArgs.SocketError);
}

return _awaitable;
}

private SocketAwaitable SendAsync(ReadOnlyMemory<byte> memory)
{
// The BufferList getter is much less expensive then the setter.
if (_eventArgs.BufferList != null)
{
_eventArgs.BufferList = null;
}

#if NETCOREAPP2_1
_eventArgs.SetBuffer(MemoryMarshal.AsMemory(memory));
#else
var segment = memory.GetArray();

_eventArgs.SetBuffer(segment.Array, segment.Offset, segment.Count);
#endif
if (!_socket.SendAsync(_eventArgs))
{
_awaitable.Complete(_eventArgs.BytesTransferred, _eventArgs.SocketError);
}

return _awaitable;
}

private List<ArraySegment<byte>> GetBufferList(in ReadOnlySequence<byte> buffer)
{
Debug.Assert(!buffer.IsEmpty);
Debug.Assert(!buffer.IsSingleSegment);

if (_bufferList == null)
{
_bufferList = new List<ArraySegment<byte>>();
}
else
{
// Buffers are pooled, so it's OK to root them until the next multi-buffer write.
_bufferList.Clear();
}

foreach (var b in buffer)
{
_bufferList.Add(b.GetArray());
}

return _bufferList;
}
}
}

+ 247
- 0
Tests/MQTTnet.Benchmarks/Tcp/TcpConnection.cs Bestand weergeven

@@ -0,0 +1,247 @@
using System;
using System.Collections.Generic;
using System.IO;
using System.IO.Pipelines;
using System.Net;
using System.Net.Sockets;
using System.Threading.Tasks;
using MQTTnet.Exceptions;
using Playground.Client.Mqtt.Tcp;

namespace MQTTnet.Benchmarks.Tcp
{
public class TcpConnection
{
private readonly Socket _socket;
private volatile bool _aborted;
private readonly EndPoint _endPoint;
private IDuplexPipe _application;
private IDuplexPipe _transport;
private readonly SocketSender _sender;
private readonly SocketReceiver _receiver;

public TcpConnection(EndPoint endPoint)
{
_socket = new Socket(SocketType.Stream, ProtocolType.Tcp);
_endPoint = endPoint;

_sender = new SocketSender(_socket, PipeScheduler.ThreadPool);
_receiver = new SocketReceiver(_socket, PipeScheduler.ThreadPool);
}

public TcpConnection(Socket socket)
{
_socket = socket;
_endPoint = socket.RemoteEndPoint;

_sender = new SocketSender(_socket, PipeScheduler.ThreadPool);
_receiver = new SocketReceiver(_socket, PipeScheduler.ThreadPool);
}

public Task DisposeAsync()
{
_transport?.Output.Complete();
_transport?.Input.Complete();

_socket?.Dispose();

return Task.CompletedTask;
}

public async Task<IDuplexPipe> StartAsync()
{
if (!_socket.Connected)
{
await _socket.ConnectAsync(_endPoint);
}

var pair = DuplexPipe.CreateConnectionPair(PipeOptions.Default, PipeOptions.Default);

_transport = pair.Transport;
_application = pair.Application;

_ = ExecuteAsync();

return pair.Transport;
}

private async Task ExecuteAsync()
{
Exception sendError = null;
try
{
// Spawn send and receive logic
var receiveTask = DoReceive();
var sendTask = DoSend();

// If the sending task completes then close the receive
// We don't need to do this in the other direction because the kestrel
// will trigger the output closing once the input is complete.
if (await Task.WhenAny(receiveTask, sendTask) == sendTask)
{
// Tell the reader it's being aborted
_socket.Dispose();
}

// Now wait for both to complete
await receiveTask;
sendError = await sendTask;

// Dispose the socket(should noop if already called)
_socket.Dispose();
}
catch (Exception ex)
{
Console.WriteLine($"Unexpected exception in {nameof(TcpConnection)}.{nameof(StartAsync)}: " + ex);
}
finally
{
// Complete the output after disposing the socket
_application.Input.Complete(sendError);
}
}
private async Task DoReceive()
{
Exception error = null;

try
{
await ProcessReceives();
}
catch (SocketException ex) when (ex.SocketErrorCode == SocketError.ConnectionReset)
{
error = new MqttCommunicationException(ex);
}
catch (SocketException ex) when (ex.SocketErrorCode == SocketError.OperationAborted ||
ex.SocketErrorCode == SocketError.ConnectionAborted ||
ex.SocketErrorCode == SocketError.Interrupted ||
ex.SocketErrorCode == SocketError.InvalidArgument)
{
if (!_aborted)
{
// Calling Dispose after ReceiveAsync can cause an "InvalidArgument" error on *nix.
//error = new MqttCommunicationException();
}
}
catch (ObjectDisposedException)
{
if (!_aborted)
{
//error = new MqttCommunicationException();
}
}
catch (IOException ex)
{
error = ex;
}
catch (Exception ex)
{
error = new IOException(ex.Message, ex);
}
finally
{
if (_aborted)
{
//error = error ?? new MqttCommunicationException();
}

_application.Output.Complete(error);
}
}

private async Task ProcessReceives()
{
while (true)
{
// Ensure we have some reasonable amount of buffer space
var buffer = _application.Output.GetMemory();

var bytesReceived = await _receiver.ReceiveAsync(buffer);

if (bytesReceived == 0)
{
// FIN
break;
}

_application.Output.Advance(bytesReceived);

var flushTask = _application.Output.FlushAsync();

if (!flushTask.IsCompleted)
{
await flushTask;
}

var result = flushTask.GetAwaiter().GetResult();
if (result.IsCompleted)
{
// Pipe consumer is shut down, do we stop writing
break;
}
}
}

private async Task<Exception> DoSend()
{
Exception error = null;

try
{
await ProcessSends();
}
catch (SocketException ex) when (ex.SocketErrorCode == SocketError.OperationAborted)
{
error = null;
}
catch (ObjectDisposedException)
{
error = null;
}
catch (IOException ex)
{
error = ex;
}
catch (Exception ex)
{
error = new IOException(ex.Message, ex);
}
finally
{
_aborted = true;
_socket.Shutdown(SocketShutdown.Both);
}

return error;
}

private async Task ProcessSends()
{
while (true)
{
// Wait for data to write from the pipe producer
var result = await _application.Input.ReadAsync();
var buffer = result.Buffer;

if (result.IsCanceled)
{
break;
}

var end = buffer.End;
var isCompleted = result.IsCompleted;
if (!buffer.IsEmpty)
{
await _sender.SendAsync(buffer);
}

_application.Input.AdvanceTo(end);

if (isCompleted)
{
break;
}
}
}
}
}

+ 72
- 0
Tests/MQTTnet.Benchmarks/TcpPipesBenchmark.cs Bestand weergeven

@@ -0,0 +1,72 @@
using System.IO.Pipelines;
using System.Net;
using System.Net.Sockets;
using System.Threading;
using System.Threading.Tasks;
using BenchmarkDotNet.Attributes;
using MQTTnet.Benchmarks.Tcp;

namespace MQTTnet.Benchmarks
{
[MemoryDiagnoser]
public class TcpPipesBenchmark
{
private IDuplexPipe _client;
private IDuplexPipe _server;

[GlobalSetup]
public void Setup()
{
var server = new TcpListener(IPAddress.Any, 1883);

server.Start(1);

var task = Task.Run(() => server.AcceptSocket());

var clientConnection = new TcpConnection(new IPEndPoint(IPAddress.Loopback, 1883));

_client = clientConnection.StartAsync().GetAwaiter().GetResult();

var serverConnection = new TcpConnection(task.GetAwaiter().GetResult());
_server = serverConnection.StartAsync().GetAwaiter().GetResult();
}


[Benchmark]
public async Task Send_10000_Chunks_Pipe()
{
var size = 5;
var iterations = 10000;

await Task.WhenAll(WriteAsync(iterations, size), ReadAsync(iterations, size));
}

private async Task ReadAsync(int iterations, int size)
{
await Task.Yield();

var expected = iterations * size;
long read = 0;
var input = _client.Input;

while (read < expected)
{
var readresult = await input.ReadAsync(CancellationToken.None).ConfigureAwait(false);
input.AdvanceTo(readresult.Buffer.End);
read += readresult.Buffer.Length;
}
}

private async Task WriteAsync(int iterations, int size)
{
await Task.Yield();

var output = _server.Output;

for (var i = 0; i < iterations; i++)
{
await output.WriteAsync(new byte[size], CancellationToken.None).ConfigureAwait(false);
}
}
}
}

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