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== The Event Bus
:toc: left
The {@link io.vertx.core.eventbus.EventBus event bus} is the *nervous system* of Vert.x.
There is a single event bus instance for every Vert.x instance and it is obtained using the method {@link io.vertx.core.Vertx#eventBus}.
The event bus allows different parts of your application to communicate with each other, irrespective of what language they are written in,
and whether they're in the same Vert.x instance, or in a different Vert.x instance.
It can even be bridged to allow client-side JavaScript running in a browser to communicate on the same event bus.
The event bus forms a distributed peer-to-peer messaging system spanning multiple server nodes and multiple browsers.
The event bus supports publish/subscribe, point-to-point, and request-response messaging.
The event bus API is very simple. It basically involves registering handlers, unregistering handlers and
sending and publishing messages.
First some theory:
=== The Theory
==== Addressing
Messages are sent on the event bus to an *address*.
Vert.x doesn't bother with any fancy addressing schemes. In Vert.x an address is simply a string.
Any string is valid. However, it is wise to use some kind of scheme, _e.g._ using periods to demarcate a namespace.
Some examples of valid addresses are +europe.news.feed1+, +acme.games.pacman+, +sausages+, and +X+.
==== Handlers
Messages are received by handlers. You register a handler at an address.
Many different handlers can be registered at the same address.
A single handler can be registered at many different addresses.
==== Publish / subscribe messaging
The event bus supports *publishing* messages.
Messages are published to an address. Publishing means delivering the message
to all handlers that are registered at that address.
This is the familiar *publish/subscribe* messaging pattern.
==== Point-to-point and Request-Response messaging
The event bus also supports *point-to-point* messaging.
Messages are sent to an address. Vert.x will then route them to just one of the handlers registered at that address.
If there is more than one handler registered at the address, one will be chosen using a non-strict round-robin algorithm.
With point-to-point messaging, an optional reply handler can be specified when sending the message.
When a message is received by a recipient, and has been handled, the recipient can optionally decide to reply to
the message. If they do so, the reply handler will be called.
When the reply is received back by the sender, it too can be replied to. This can be repeated _ad infinitum_,
and allows a dialog to be set up between two different verticles.
This is a common messaging pattern called the *request-response* pattern.
==== Best-effort delivery
Vert.x does its best to deliver messages and won't consciously throw them away. This is called *best-effort* delivery.
However, in case of failure of all or parts of the event bus, there is a possibility messages might be lost.
If your application cares about lost messages, you should code your handlers to be idempotent, and your senders
to retry after recovery.
==== Types of messages
Out of the box Vert.x allows any primitive/simple type, String, or {@link io.vertx.core.buffer.Buffer buffers} to
be sent as messages.
However, it's a convention and common practice in Vert.x to send messages as http://json.org/[JSON]
JSON is very easy to create, read and parse in all the languages that Vert.x supports, so it has become a kind of
_lingua franca_ for Vert.x.
However, you are not forced to use JSON if you don't want to.
The event bus is very flexible and also supports sending arbitrary objects over the event bus.
You can do this by defining a {@link io.vertx.core.eventbus.MessageCodec codec} for the objects you want to send.
=== The Event Bus API
Let's jump into the API.
==== Getting the event bus
You get a reference to the event bus as follows:
[source,$lang]
----
{@link examples.EventBusExamples#example0_5}
----
There is a single instance of the event bus per Vert.x instance.
==== Registering Handlers
This simplest way to register a handler is using {@link io.vertx.core.eventbus.EventBus#consumer(String,io.vertx.core.Handler)}.
Here's an example:
[source,$lang]
----
{@link examples.EventBusExamples#example1}
----
When a message arrives for your handler, your handler will be called, passing in the {@link io.vertx.core.eventbus.Message message}.
The object returned from call to +consumer()+ is an instance of {@link io.vertx.core.eventbus.MessageConsumer}.
This object can subsequently be used to unregister the handler, or use the handler as a stream.
Alternatively you can use {@link io.vertx.core.eventbus.EventBus#consumer(String,io.vertx.core.Handler)} to
return a +MessageConsumer+ with no handler set, and then set the handler on that. For example:
[source,$lang]
----
{@link examples.EventBusExamples#example2}
----
When registering a handler on a clustered event bus, it can take some time for the registration to reach all
nodes of the cluster.
If you want to be notified when this has completed, you can register a {@link io.vertx.core.eventbus.MessageConsumer#completionHandler completion handler}
on the +MessageConsumer+ object.
[source,$lang]
----
{@link examples.EventBusExamples#example3}
----
==== Un-registering Handlers
To unregister a handler, call {@link io.vertx.core.eventbus.MessageConsumer#unregister}.
If you are on a clustered event bus, un-registering can take some time to propagate across the nodes. If you want to
be notified when this is complete, use {@link io.vertx.core.eventbus.MessageConsumer#unregister(io.vertx.core.Handler)}.
[source,$lang]
----
{@link examples.EventBusExamples#example4}
----
==== Publishing messages
Publishing a message is simple. Just use {@link io.vertx.core.eventbus.EventBus#publish} specifying the
address to publish it to.
[source,$lang]
----
{@link examples.EventBusExamples#example5}
----
That message will then be delivered to all handlers registered against the address +news.uk.sport+.
==== Sending messages
Sending a message will result in only one handler registered at the address receiving the message.
This is the point-to-point messaging pattern. The handler is chosen in a non-strict round-robin fashion.
You can send a message with {@link io.vertx.core.eventbus.EventBus#send}.
[source,$lang]
----
{@link examples.EventBusExamples#example6}
----
include::override/eventbus_headers.adoc[]
==== Message ordering
Vert.x will deliver messages to any particular handler in the same order they were sent from any particular sender.
==== The Message object
The object you receive in a message handler is a {@link io.vertx.core.eventbus.Message}.
The {@link io.vertx.core.eventbus.Message#body} of the message corresponds to the object that was sent or published.
The headers of the message are available with {@link io.vertx.core.eventbus.Message#headers}.
==== Acknowledging messages / sending replies
When using {@link io.vertx.core.eventbus.EventBus#send} the event bus attempts to deliver the message to a
{@link io.vertx.core.eventbus.MessageConsumer} registered with the event bus.
In some cases it's useful for the sender to know when the consumer has received the message and "processed" it using
*request-response* pattern.
To acknowledge that the message has been processed, the consumer can reply to the message by calling
{@link io.vertx.core.eventbus.Message#reply}.
When this happens it causes a reply to be sent back to the sender and the reply handler is invoked with the reply.
An example will make this clear:
The receiver:
[source,$lang]
----
{@link examples.EventBusExamples#example8}
----
The sender:
[source,$lang]
----
{@link examples.EventBusExamples#example9}
----
The reply can contain a message body which can contain useful information.
What the "processing" actually means is application-defined and depends entirely on what the message consumer does
and is not something that the Vert.x event bus itself knows or cares about.
Some examples:
* A simple message consumer which implements a service which returns the time of the day would acknowledge with a message
containing the time of day in the reply body
* A message consumer which implements a persistent queue, might acknowledge with `true` if the message was successfully
persisted in storage, or `false` if not.
* A message consumer which processes an order might acknowledge with `true` when the order has been successfully processed
so it can be deleted from the database
==== Sending with timeouts
When sending a message with a reply handler, you can specify a timeout in the {@link io.vertx.core.eventbus.DeliveryOptions}.
If a reply is not received within that time, the reply handler will be called with a failure.
The default timeout is 30 seconds.
==== Send Failures
Message sends can fail for other reasons, including:
* There are no handlers available to send the message to
* The recipient has explicitly failed the message using {@link io.vertx.core.eventbus.Message#fail}
In all cases, the reply handler will be called with the specific failure.
include::override/eventbus.adoc[]
==== Clustered Event Bus
The event bus doesn't just exist in a single Vert.x instance. By clustering different Vert.x instances together on
your network they can form a single, distributed event bus.
==== Clustering programmatically
If you're creating your Vert.x instance programmatically you get a clustered event bus by configuring the Vert.x
instance as clustered;
[source,$lang]
----
{@link examples.EventBusExamples#example12}
----
You should also make sure you have a {@link io.vertx.core.spi.cluster.ClusterManager} implementation on your classpath, for example the Hazelcast cluster manager.
==== Clustering on the command line
You can run Vert.x clustered on the command line with
----
vertx run my-verticle.js -cluster
----
=== Automatic clean-up in verticles
If you're registering event bus handlers from inside verticles, those handlers will be automatically unregistered
when the verticle is undeployed.
== Configuring the event bus
include::override/configuring-eventbus.adoc[]