This is a C# implementation of the Binance websocket API found here:

https://github.com/binance-exchange/binance-official-api-docs/blob/master/web-socket-streams.md

Releases and breaking changes

Apache License 2.0

• installation via NuGet (Binance.Client.Websocket)
• public and authenticated API
• targeting .NET Standard 2.0 (.NET Core, Linux/MacOS compatible)
• reactive extensions (Rx.NET)
• integrated logging abstraction (LibLog)

var exitEvent = new ManualResetEvent(false);
var url = BinanceValues.ApiWebsocketUrl;

using (var communicator = new BinanceWebsocketCommunicator(url))
{
    using (var client = new BinanceWebsocketClient(communicator))
    {
        client.Streams.TradesStream.Subscribe(response =>
        {
            var trade = response.Data;
            Console.WriteLine($"Trade executed [{trade.Symbol}] price: {trade.Price}");
        });

        client.SetSubscriptions(
            new TradeSubscription("btcusdt"),
            new TradeSubscription("ethbtc"),
            new TradeSubscription("bnbbtc"),
            );
        await communicator.Start();

        exitEvent.WaitOne(TimeSpan.FromSeconds(30));
    }
}

More usage examples:

• console sample (link)
• integration tests (link)
• desktop sample (link)

Pull Requests are welcome!

Extensions All order books together, etc.

Bitmex

Bitfinex

Coinbase

There is a built-in reconnection which invokes after 1 minute (default) of not receiving any messages from the server. It is possible to configure that timeout via communicator.ReconnectTimeoutMs. Also, there is a stream ReconnectionHappened which sends information about a type of reconnection. However, if you are subscribed to low rate channels, it is very likely that you will encounter that timeout - higher the timeout to a few minutes or call PingRequest by your own every few seconds.

In the case of Binance outage, there is a built-in functionality which slows down reconnection requests (could be configured via communicator.ErrorReconnectTimeoutMs, the default is 1 minute).

The library is prepared for backtesting. The dependency between Client and Communicator is via abstraction IBinanceCommunicator. There are two communicator implementations:

• BinanceWebsocketCommunicator - a realtime communication with Binance via websocket API.
• BinanceFileCommunicator - a simulated communication, raw data are loaded from files and streamed. If you are interested in buying historical raw data (trades, order book events), contact me.

Feel free to implement IBinanceCommunicator on your own, for example, load raw data from database, cache, etc.

Usage:

var communicator = new BinanceFileCommunicator();
communicator.FileNames = new[]
{
    "data/binance_raw_btcusdt_2018-11-13.txt"
};
communicator.Delimiter = ";;";

var client = new BinanceWebsocketClient(communicator);
client.Streams.TradesStream.Subscribe(response =>
{
    // do something with trade
});

await communicator.Start();

Observables from Reactive Extensions are single threaded by default. It means that your code inside subscriptions is called synchronously and as soon as the message comes from websocket API. It brings a great advantage of not to worry about synchronization, but if your code takes a longer time to execute it will block the receiving method, buffer the messages and may end up losing messages. For that reason consider to handle messages on the other thread and unblock receiving thread as soon as possible. I've prepared a few examples for you:

Every subscription code is called on a main websocket thread. Every subscription is synchronized together. No parallel execution. It will block the receiving thread.

client
    .Streams
    .TradesStream
    .Subscribe(trade => { code1 });

client
    .Streams
    .BookStream
    .Subscribe(book => { code2 });

// 'code1' and 'code2' are called in a correct order, according to websocket flow
// ----- code1 ----- code1 ----- ----- code1
// ----- ----- code2 ----- code2 code2 -----

Every single subscription code is called on a separate thread. Every single subscription is synchronized, but different subscriptions are called in parallel.

client
    .Streams
    .TradesStream
    .ObserveOn(TaskPoolScheduler.Default)
    .Subscribe(trade => { code1 });

client
    .Streams
    .BookStream
    .ObserveOn(TaskPoolScheduler.Default)
    .Subscribe(book => { code2 });

// 'code1' and 'code2' are called in parallel, do not follow websocket flow
// ----- code1 ----- code1 ----- code1 -----
// ----- code2 code2 ----- code2 code2 code2

In case you want to run your subscription code on the separate thread but still want to follow websocket flow through every subscription, use synchronization with gates:

private static readonly object GATE1 = new object();
client
    .Streams
    .TradesStream
    .ObserveOn(TaskPoolScheduler.Default)
    .Synchronize(GATE1)
    .Subscribe(trade => { code1 });

client
    .Streams
    .BookStream
    .ObserveOn(TaskPoolScheduler.Default)
    .Synchronize(GATE1)
    .Subscribe(book => { code2 });

// 'code1' and 'code2' are called concurrently and follow websocket flow
// ----- code1 ----- code1 ----- ----- code1
// ----- ----- code2 ----- code2 code2 ----

Using async/await in your subscribe methods is a bit tricky. Subscribe from Rx.NET doesn't await tasks, so it won't block stream execution and cause sometimes undesired concurrency. For example:

client
    .Streams
    .TradesStream
    .Subscribe(async trade => {
        // do smth 1
        await Task.Delay(5000); // waits 5 sec, could be HTTP call or something else
        // do smth 2
    });

That await Task.Delay won't block stream and subscribe method will be called multiple times concurrently. If you want to buffer messages and process them one-by-one, then use this:

client
    .Streams
    .TradesStream
    .Select(trade => Observable.FromAsync(async () => {
        // do smth 1
        await Task.Delay(5000); // waits 5 sec, could be HTTP call or something else
        // do smth 2
    }))
    .Concat() // executes sequentially
    .Subscribe();

If you want to process them concurrently (avoid synchronization), then use this

client
    .Streams
    .TradesStream
    .Select(trade => Observable.FromAsync(async () => {
        // do smth 1
        await Task.Delay(5000); // waits 5 sec, could be HTTP call or something else
        // do smth 2
    }))
    .Merge() // executes concurrently
    // .Merge(4) you can limit concurrency with a parameter
    // .Merge(1) is same as .Concat()
    // .Merge(0) is invalid (throws exception)
    .Subscribe();

More info on Github issue.

Don't worry about websocket connection, those sequential execution via .Concat() or .Merge(1) has no effect on receiving messages. It won't affect receiving thread, only buffers messages inside TradesStream.

But beware of producer-consumer problem when the consumer will be too slow. Here is a StackOverflow issue with an example how to ignore/discard buffered messages and always process only the last one.

Due to the large amount of questions about integration of this library into a desktop application (old full .NET Framework), I've prepared WinForms example (link).

I do consulting, please don't hesitate to contact me if you have a custom solution you would like me to implement (web, [email protected])

Donations gratefully accepted.