If you have been working with .NET events then you should be familiar with the following pattern (overly simplified for brevity):

public sealed class OrderSubscriber { private readonly IOrderPublisher _publisher; public OrderSubscriber(IOrderPublisher publisher) { _publisher = publisher; _publisher.NewOrder += OnNewOrder; } private void OnNewOrder(object sender, OrderPlacedEventArgs eArgs) { /* do something with the order */ } } public sealed class OrderPublisher : IOrderPublisher { public event EventHandler<OrderPlacedEventArgs> NewOrder; public void Publish() { var snapshot = NewOrder; if (snapshot == null) { return; } snapshot(this, new OrderPlacedEventArgs()); } } public sealed class OrderPlacedEventArgs : EventArgs { ... not really important }

What we have here is a simple publisher publishing an OrderPlaced event and a subscriber which handles the orders when the events are published. I have seen this pattern being used in many code bases and is pretty much the standard way of writing pub-sub applications in the enterprise. However, there are a couple of things that I do not like about this approach.

The main problem is the direct coupling between the publisher and the subscriber meaning as the application grows, we will not be able to introduce new subscribers, publishers or events without having to break a few places; We have to inherit from EventArgs for our OrderPlaced event; this restriction was removed in .NET 4.5 but .NET 4 is still strong in many enterprises plus I think we can do better; We also have to worry about NewOrder delegate not being null and making sure there is at least one subscriber before publishing. There are many ways to make that part cleaner (specially in C# 6) but why do this when we can do better!

So how can we improve what we currently have?

Event Aggregator

An Event Aggregator is a service which sits between your publishers and subscribers acting as an intermediary pushing your messages (events) from one entity to another.

Martin Fowler describes it as:

An Event Aggregator is a simple element of indirection. In its simplest form you have it register with all the source objects you are interested in, and have all target objects register with the Event Aggregator. The Event Aggregator responds to any event from a source object by propagating that event to the target objects.

Here is a diagram to make it even more clear:

So what this means is that your publishers and subscribers are no longer coupled together and they only need to hold a reference to the Event Aggregator .

Easy Message Hub

I hope by now you accept the benefits that the Event Aggregator pattern can bring to your publishers and subscribers. I very much like this pattern and how it can result in a much cleaner code-base. In my journey to find a suitable implementation in C# , I found a number of candidates:

But they either lacked the optimal performance or the kind of API I was hoping for; So I came up with the Easy.MessageHub .

The API surface-area is very simple, there is the MessageHub representing the EventAggregator which can be registered as an IMessageHub using your favourite IOC framework and injected in your publishers, subscribers or anyone else who might be interested in the messages coming in or going out.

In it's simplest form one could publish using:

var hub = new MessageHub(); // OrderPlaced and OrderDeleted both inherit from Order hub.Publish(new OrderPlaced()); hub.Publish(new OrderDeleted()); // let us send a string message on the same hub hub.Publish("A Very Important Message!");

And for the subscription:

Action<Order> onNewOrder = o => { /* do whatever you want with the Order */ }; var token = hub.Subscribe(onNewOrder);

To Un-Subscribe:

// By Token hub.Unsubscribe(token); hub.IsSubscribed(token); // returns false // Clear all subscriptions hub.ClearSubscriptions();

There is also the concept of global event handler allowing you to have a single hook into every message that is published by the hub perhaps for the purpose of logging, audit etc.

Action<Type, object> logHandler = (type, msg) => logger.Log("Type of message: {0}, Message: {1}", type, msg); hub.RegisterGlobalHandler(logHandler);

And finally if any of the subscribers throw an exception while receiving a message, instead of breaking all the others you can subscribe to the error by:

Action<Guid, Exception> errorHandler = (token, e) => logger.Log("Token: {0}, Error: {1}", token, e); hub.RegisterGlobalErrorHandler(errorHandler);

Now armed with our new friend, we can rewrite the original example as:

public sealed class OrderSubscriber { private readonly IMessageHub _hub; private readonly Guid _subscriptionToken; public OrderSubscriber(IMessageHub hub) { _hub = hub; _subscriptionToken = _hub.Subscribe<Order>(OnNewOrder); } public void Unsubscribe() { _hub.Unsubscribe(_subscriptionToken); } private void OnNewOrder(Order order) { /* do something with the order */ } } public sealed class OrderPublisher { private readonly IMessageHub _hub; public OrderPublisher(IMessageHub hub) { _hub = hub; } public void Publish() { _hub.Publish(new OrderPlaced()); } } public class Order { } public sealed class OrderPlaced : Order { }

Note in this version:

Publishers and Subscribers no longer hold a reference to each other therefore reducing coupling.

Any class can now be an event e.g. Order , OrderPlaced ;

, ; We are no longer limited to using .NET events or EventArgs ;

or ; MessageHub is mockable therefore publisher and subscriber can easily be tested;

is mockable therefore publisher and subscriber can easily be tested; We do not need to check if the publisher has any subscribers before publishing, we just fire the message and the MessageHub takes care of the rest.

The source together with some benchmarking and usage examples are available on GitHub and NuGet package available HERE.

As of v3.0.0 the library supports .Net Core (.Net 3.5 & netstandard1.0)

Goodluck and happy messaging!