This part of the reference documentation details the various components that comprise Spring AMQP. The main chapter covers the core classes to develop an AMQP application. This part also includes a chapter about the sample applications.
In this chapter, we will explore the interfaces and classes that are the essential components for developing applications with Spring AMQP.
Spring AMQP consists of a handful of modules, each represented by a JAR in the distribution.
These modules are: spring-amqp, and spring-rabbit.
The spring-amqp module contains the org.springframework.amqp.core
package.
Within that package, you will find the classes that represent the core AMQP "model".
Our intention is to provide generic abstractions that do not rely on any particular AMQP broker implementation or client library.
End user code will be more portable across vendor implementations as it can be developed against the abstraction layer only.
These abstractions are then used implemented by broker-specific modules, such as spring-rabbit.
There is currently only a RabbitMQ implementation; however the abstractions have been validated in .NET using Apache Qpid in addition to RabbitMQ.
Since AMQP operates at the protocol level in principle, the RabbitMQ client can be used with any broker that supports the same protocol version, but we do not test any other brokers at present.
The overview here assumes that you are already familiar with the basics of the AMQP specification. If you are not, then have a look at the resources listed in Chapter 5, Other Resources
The 0-8 and 0-9-1 AMQP specifications do not define a Message class or interface.
Instead, when performing an operation such as basicPublish()
, the content is passed as a byte-array argument and additional properties are passed in as separate arguments.
Spring AMQP defines a Message class as part of a more general AMQP domain model representation.
The purpose of the Message class is to simply encapsulate the body and properties within a single instance so that the API can in turn be simpler.
The Message class definition is quite straightforward.
public class Message { private final MessageProperties messageProperties; private final byte[] body; public Message(byte[] body, MessageProperties messageProperties) { this.body = body; this.messageProperties = messageProperties; } public byte[] getBody() { return this.body; } public MessageProperties getMessageProperties() { return this.messageProperties; } }
The MessageProperties
interface defines several common properties such as messageId, timestamp, contentType, and several more.
Those properties can also be extended with user-defined headers by calling the setHeader(String
key, Object value)
method.
The Exchange
interface represents an AMQP Exchange, which is what a Message Producer sends to.
Each Exchange within a virtual host of a broker will have a unique name as well as a few other properties:
public interface Exchange { String getName(); String getExchangeType(); boolean isDurable(); boolean isAutoDelete(); Map<String, Object> getArguments(); }
As you can see, an Exchange also has a type represented by constants defined in ExchangeTypes
.
The basic types are: Direct
, Topic
, Fanout
, and Headers
.
In the core package you will find implementations of the Exchange
interface for each of those types.
The behavior varies across these Exchange types in terms of how they handle bindings to Queues.
For example, a Direct exchange allows for a Queue to be bound by a fixed routing key (often the Queue’s name).
A Topic exchange supports bindings with routing patterns that may include the * and # wildcards for exactly-one and zero-or-more, respectively.
The Fanout exchange publishes to all Queues that are bound to it without taking any routing key into consideration.
For much more information about these and the other Exchange types, check out Chapter 5, Other Resources.
Note | |
---|---|
The AMQP specification also requires that any broker provide a "default" Direct Exchange that has no name. All Queues that are declared will be bound to that default Exchange with their names as routing keys. You will learn more about the default Exchange’s usage within Spring AMQP in Section 3.1.4, “AmqpTemplate”. |
The Queue
class represents the component from which a Message Consumer receives Messages.
Like the various Exchange classes, our implementation is intended to be an abstract representation of this core AMQP type.
public class Queue { private final String name; private volatile boolean durable; private volatile boolean exclusive; private volatile boolean autoDelete; private volatile Map<String, Object> arguments; /** * The queue is durable, non-exclusive and non auto-delete. * * @param name the name of the queue. */ public Queue(String name) { this(name, true, false, false); } // Getters and Setters omitted for brevity }
Notice that the constructor takes the Queue name. Depending on the implementation, the admin template may provide methods for generating a uniquely named Queue. Such Queues can be useful as a "reply-to" address or other temporary situations. For that reason, the exclusive and autoDelete properties of an auto-generated Queue would both be set to true.
Note | |
---|---|
See the section on queues in Section 3.1.10, “Configuring the broker” for information about declaring queues using namespace support, including queue arguments. |
Given that a producer sends to an Exchange and a consumer receives from a Queue, the bindings that connect Queues to Exchanges are critical for connecting those producers and consumers via messaging.
In Spring AMQP, we define a Binding
class to represent those connections.
Let’s review the basic options for binding Queues to Exchanges.
You can bind a Queue to a DirectExchange with a fixed routing key.
new Binding(someQueue, someDirectExchange, "foo.bar")
You can bind a Queue to a TopicExchange with a routing pattern.
new Binding(someQueue, someTopicExchange, "foo.*")
You can bind a Queue to a FanoutExchange with no routing key.
new Binding(someQueue, someFanoutExchange)
We also provide a BindingBuilder
to facilitate a "fluent API" style.
Binding b = BindingBuilder.bind(someQueue).to(someTopicExchange).with("foo.*");
Note | |
---|---|
The BindingBuilder class is shown above for clarity, but this style works well when using a static import for the bind() method. |
By itself, an instance of the Binding class is just holding the data about a connection.
In other words, it is not an "active" component.
However, as you will see later in Section 3.1.10, “Configuring the broker”, Binding instances can be used by the AmqpAdmin
class to actually trigger the binding actions on the broker.
Also, as you will see in that same section, the Binding instances can be defined using Spring’s @Bean
-style within @Configuration
classes.
There is also a convenient base class which further simplifies that approach for generating AMQP-related bean definitions and recognizes the Queues, Exchanges, and Bindings so that they will all be declared on the AMQP broker upon application startup.
The AmqpTemplate
is also defined within the core package.
As one of the main components involved in actual AMQP messaging, it is discussed in detail in its own section (see Section 3.1.4, “AmqpTemplate”).
Whereas the AMQP model we described in the previous section is generic and applicable to all implementations, when we get into the management of resources, the details are specific to the broker implementation. Therefore, in this section, we will be focusing on code that exists only within our "spring-rabbit" module since at this point, RabbitMQ is the only supported implementation.
The central component for managing a connection to the RabbitMQ broker is the ConnectionFactory
interface.
The responsibility of a ConnectionFactory
implementation is to provide an instance of org.springframework.amqp.rabbit.connection.Connection
which is a wrapper for com.rabbitmq.client.Connection
.
The only concrete implementation we provide is CachingConnectionFactory
which, by default, establishes a single connection proxy that can be shared by the application.
Sharing of the connection is possible since the "unit of work" for messaging with AMQP is actually a "channel" (in some ways, this is similar to the relationship between a Connection and a Session in JMS).
As you can imagine, the connection instance provides a createChannel
method.
The CachingConnectionFactory
implementation supports caching of those channels, and it maintains separate caches for channels based on whether they are transactional or not.
When creating an instance of CachingConnectionFactory
, the hostname can be provided via the constructor.
The username and password properties should be provided as well.
If you would like to configure the size of the channel cache (the default is 25), you could call the
setChannelCacheSize()
method here as well.
Starting with version 1.3, the CachingConnectionFactory
can be configured to cache connections as well as just channels.
In this case, each call to createConnection()
creates a new connection (or retrieves an idle one from the cache).
Closing a connection returns it to the cache (if the cache size has not been reached).
Channels created on such connections are cached too.
The use of separate connections might be useful in some environments, such as consuming from an HA cluster, in
conjunction with a load balancer, to connect to different cluster members.
Set the cacheMode
to CacheMode.CONNECTION
.
Note | |
---|---|
This does not limit the number of connections, it specifies how many idle open connections are allowed. |
Starting with version 1.5.5, a new property connectionLimit
is provided.
When this is set, it limits the total number of connections allowed.
When set, if the limit is reached, the channelCheckoutTimeLimit
is used to wait for a connection to become idle.
If the time is exceeded, an AmqpTimeoutException
is thrown.
Important | |
---|---|
When the cache mode is Also, at the time of writing, the |
It is important to understand that the cache size is (by default) not a limit, but merely the number of channels that can be cached. With a cache size of, say, 10, any number of channels can actually be in use. If more than 10 channels are being used and they are all returned to the cache, 10 will go in the cache; the remainder will be physically closed.
Starting with version 1.6, the default channel cache size has been increased from 1 to 25. In high volume, multi-threaded, environments, a small cache means that channels are created and closed at a high rate. Increasing the default cache size will avoid this overhead. You should monitor the channels in use via the RabbitMQ Admin UI and consider increasing the cache size further if you see many channels being created and closed. The cache will only grow on-demand (to suit the concurrency requirements of the application) so this change will not impact existing low-volume applications.
Starting with version 1.4.2, the CachingConnectionFactory
has a property channelCheckoutTimeout
.
When this property is greater than zero, the channelCacheSize
becomes a limit on the number of channels that can be created on a connection.
If the limit is reached, calling threads will block until a channel is available or this timeout is reached, in which case a AmqpTimeoutException
is thrown.
Warning | |
---|---|
Channels used within the framework (e.g.
|
CachingConnectionFactory connectionFactory = new CachingConnectionFactory("somehost"); connectionFactory.setUsername("guest"); connectionFactory.setPassword("guest"); Connection connection = connectionFactory.createConnection();
When using XML, the configuration might look like this:
<bean id="connectionFactory" class="org.springframework.amqp.rabbit.connection.CachingConnectionFactory"> <constructor-arg value="somehost"/> <property name="username" value="guest"/> <property name="password" value="guest"/> </bean>
Note | |
---|---|
There is also a |
A ConnectionFactory
can be created quickly and conveniently using the rabbit namespace:
<rabbit:connection-factory id="connectionFactory"/>
In most cases this will be preferable since the framework can choose the best defaults for you.
The created instance will be a CachingConnectionFactory
.
Keep in mind that the default cache size for channels is 25.
If you want more channels to be cached set a larger value via the channelCacheSize property.
In XML it would look like this:
<bean id="connectionFactory" class="org.springframework.amqp.rabbit.connection.CachingConnectionFactory"> <constructor-arg value="somehost"/> <property name="username" value="guest"/> <property name="password" value="guest"/> <property name="channelCacheSize" value="50"/> </bean>
And with the namespace you can just add the channel-cache-size attribute:
<rabbit:connection-factory id="connectionFactory" channel-cache-size="50"/>
The default cache mode is CHANNEL, but you can configure it to cache connections instead; in this case, we use connection-cache-size
:
<rabbit:connection-factory id="connectionFactory" cache-mode="CONNECTION" connection-cache-size="25"/>
Host and port attributes can be provided using the namespace
<rabbit:connection-factory id="connectionFactory" host="somehost" port="5672"/>
Alternatively, if running in a clustered environment, use the addresses attribute.
<rabbit:connection-factory id="connectionFactory" addresses="host1:5672,host2:5672"/>
Here’s an example with a custom thread factory that prefixes thread names with rabbitmq-
.
<rabbit:connection-factory id="multiHost" virtual-host="/bar" addresses="host1:1234,host2,host3:4567" thread-factory="tf" channel-cache-size="10" username="user" password="password" /> <bean id="tf" class="org.springframework.scheduling.concurrent.CustomizableThreadFactory"> <constructor-arg value="rabbitmq-" /> </bean>
Starting with version 1.7 a ConnectionNameStrategy
is provided for the injection into the AbstractionConnectionFactory
.
The generated name is used for the application-specific identification of the target RabbitMQ connection.
The connection name is displayed in the management UI if RabbitMQ server supports it.
This value doesn’t have to be unique and cannot be used as a connection identifier e.g. in HTTP API requests.
This value is supposed to be human-readable and is a part of ClientProperties
under connection_name
key.
Can be used as a simple Lambda:
connectionFactory.setConnectionNameStrategy(connectionFactory -> "MY_CONNECTION");
The ConnectionFactory
argument can be used to distinguish target connection names by some logic.
By default a beanName
of the AbstractConnectionFactory
and an internal counter are used to generate connection_name
.
The <rabbit:connection-factory>
namespace component is also supplied with the connection-name-strategy
attribute.
The CachingConnectionFactory
uses an instance of the Rabbit client ConnectionFactory
; a number of configuration properties are passed through (host, port, userName, password, requestedHeartBeat,
connectionTimeout
for example) when setting the equivalent property on the CachingConnectionFactory
.
To set other properties (clientProperties
for example), define an instance of the rabbit factory and provide a reference to it using the appropriate constructor of the CachingConnectionFactory
.
When using the namespace as described above, provide a reference to the configured factory in the connection-factory
attribute.
For convenience, a factory bean is provided to assist in configuring the connection factory in a Spring application context, as discussed in the next section.
<rabbit:connection-factory id="connectionFactory" connection-factory="rabbitConnectionFactory"/>
Starting with version 1.4, a convenient RabbitConnectionFactoryBean
is provided to enable convenient configuration of SSL properties on the underlying client connection factory, using dependency injection.
Other setters simply delegate to the underlying factory.
Previously you had to configure the SSL options programmatically.
<rabbit:connection-factory id="rabbitConnectionFactory" connection-factory="clientConnectionFactory" host="${host}" port="${port}" virtual-host="${vhost}" username="${username}" password="${password}" /> <bean id="clientConnectionFactory" class="org.springframework.xd.dirt.integration.rabbit.RabbitConnectionFactoryBean"> <property name="useSSL" value="true" /> <property name="sslPropertiesLocation" value="file:/secrets/rabbitSSL.properties"/> </bean>
Refer to the RabbitMQ Documentation for information about configuring SSL.
Omit the keyStore
and trustStore
configuration to connect over SSL without certificate validation.
Key and trust store configuration can be provided as follows:
The sslPropertiesLocation
property is a Spring Resource
pointing to a properties file containing the following keys:
keyStore=file:/secret/keycert.p12 trustStore=file:/secret/trustStore keyStore.passPhrase=secret trustStore.passPhrase=secret
The keyStore
and truststore
are Spring Resources
pointing to the stores.
Typically this properties file will be secured by the operating system with the application having read access.
Starting with Spring AMQP version 1.5, these properties can be set directly on the factory bean.
If both discrete properties and sslPropertiesLocation
is provided, properties in the latter will override the
discrete values.
Starting with version 1.3, the AbstractRoutingConnectionFactory
has been introduced.
This provides a mechanism to configure mappings for several ConnectionFactories
and determine a target ConnectionFactory
by some lookupKey
at runtime.
Typically, the implementation checks a thread-bound context.
For convenience, Spring AMQP provides the SimpleRoutingConnectionFactory
, which gets the current thread-bound lookupKey
from the SimpleResourceHolder
:
<bean id="connectionFactory" class="org.springframework.amqp.rabbit.connection.SimpleRoutingConnectionFactory"> <property name="targetConnectionFactories"> <map> <entry key="#{connectionFactory1.virtualHost}" ref="connectionFactory1"/> <entry key="#{connectionFactory2.virtualHost}" ref="connectionFactory2"/> </map> </property> </bean> <rabbit:template id="template" connection-factory="connectionFactory" />
public class MyService { @Autowired private RabbitTemplate rabbitTemplate; public void service(String vHost, String payload) { SimpleResourceHolder.bind(rabbitTemplate.getConnectionFactory(), vHost); rabbitTemplate.convertAndSend(payload); SimpleResourceHolder.unbind(rabbitTemplate.getConnectionFactory()); } }
It is important to unbind the resource after use.
For more information see the JavaDocs of AbstractRoutingConnectionFactory
.
Starting with version 1.4, the RabbitTemplate
supports the SpEL sendConnectionFactorySelectorExpression
and receiveConnectionFactorySelectorExpression
properties, which are evaluated on each AMQP protocol interaction operation (send
, sendAndReceive
, receive
or receiveAndReply
), resolving to a lookupKey
value for the provided AbstractRoutingConnectionFactory
.
Bean references, such as "@vHostResolver.getVHost(#root)"
can be used in the expression.
For send
operations, the Message to be sent is the root evaluation object; for receive
operations, the queueName is the root evaluation object.
The routing algorithm is: If the selector expression is null
, or is evaluated to null
, or the provided ConnectionFactory
isn’t an instance of AbstractRoutingConnectionFactory
, everything works as before, relying on the provided ConnectionFactory
implementation.
The same occurs if the evaluation result isn’t null
, but there is no target ConnectionFactory
for that lookupKey
and the AbstractRoutingConnectionFactory
is configured with lenientFallback = true
.
Of course, in the case of an AbstractRoutingConnectionFactory
it does fallback to its routing
implementation based on determineCurrentLookupKey()
.
But, if lenientFallback = false
, an IllegalStateException
is thrown.
The Namespace support also provides the send-connection-factory-selector-expression
and receive-connection-factory-selector-expression
attributes on the <rabbit:template>
component.
Also starting with version 1.4, you can configure a routing connection factory in a SimpleMessageListenerContainer
.
In that case, the list of queue names is used as the lookup key.
For example, if you configure the container with setQueueNames("foo", "bar")
, the lookup key will be "[foo,bar]"
(no spaces).
When using HA queues in a cluster, for the best performance, it can be desirable to connect to the physical broker
where the master queue resides.
While the CachingConnectionFactory
can be configured with multiple broker addresses; this is to fail over and the
client will attempt to connect in order.
The LocalizedQueueConnectionFactory
uses the REST API provided by the admin plugin to determine which node the
queue is mastered.
It then creates (or retrieves from a cache) a CachingConnectionFactory
that will connect to just that node.
If the connection fails, the new master node is determined and the consumer connects to it.
The LocalizedQueueConnectionFactory
is configured with a default connection factory, in case the physical location
of the queue cannot be determined, in which case it will connect as normal to the cluster.
The LocalizedQueueConnectionFactory
is a RoutingConnectionFactory
and the SimpleMessageListenerContainer
uses the
queue names as the lookup key as discussed in the section called “Routing Connection Factory” above.
Note | |
---|---|
For this reason (the use of the queue name for the lookup), the |
Note | |
---|---|
The RabbitMQ management plugin must be enabled on each node. |
Caution | |
---|---|
This connection factory is intended for long-lived connections, such as those used by the
|
Here is an example configuration, using Spring Boot’s RabbitProperties to configure the factories:
@Autowired private RabbitProperties props; private final String[] adminUris = { "http://host1:15672", "http://host2:15672" }; private final String[] nodes = { "rabbit@host1", "rabbit@host2" }; @Bean public ConnectionFactory defaultConnectionFactory() { CachingConnectionFactory cf = new CachingConnectionFactory(); cf.setAddresses(this.props.getAddresses()); cf.setUsername(this.props.getUsername()); cf.setPassword(this.props.getPassword()); cf.setVirtualHost(this.props.getVirtualHost()); return cf; } @Bean public ConnectionFactory queueAffinityCF( @Qualifier("defaultConnectionFactory") ConnectionFactory defaultCF) { return new LocalizedQueueConnectionFactory(defaultCF, StringUtils.commaDelimitedListToStringArray(this.props.getAddresses()), this.adminUris, this.nodes, this.props.getVirtualHost(), this.props.getUsername(), this.props.getPassword(), false, null); }
Notice that the first three parameters are arrays of addresses
, adminUris
and nodes
.
These are positional in that when a container attempts to connect to a queue, it determines on which node the queue is
mastered and connects to the address in the same array position.
Confirmed and returned messages are supported by setting the CachingConnectionFactory
's publisherConfirms
and publisherReturns
properties to 'true' respectively.
When these options are set, Channel
s created by the factory are wrapped in an PublisherCallbackChannel
, which is used to facilitate the callbacks.
When such a channel is obtained, the client can register a PublisherCallbackChannel.Listener
with the Channel
.
The PublisherCallbackChannel
implementation contains logic to route a confirm/return to the appropriate listener.
These features are explained further in the following sections.
Tip | |
---|---|
For some more background information, please see the following blog post by the RabbitMQ team titled Introducing Publisher Confirms. |
A mechanism to enable users to control logging levels was introduced in version 1.5.
The CachingConnectionFactory
uses a default strategy to log channel closures as follows:
basic.consume
is refused due to an exclusive consumer condition, it is logged at
INFO level.
To modify this behavior, inject a custom ConditionalExceptionLogger
into the
CachingConnectionFactory
in its closeExceptionLogger
property.
Staring with version 1.6, the CachingConnectionFactory
now provides cache statistics via the getCacheProperties()
method.
These statistics can be used to tune the cache to optimize it in production.
For example, the high water marks can be used to determine whether the cache size should be increased.
If it equals the cache size, you might want to consider increasing further.
Table 3.1. Cache properties for CacheMode.CHANNEL
Property | Meaning |
---|---|
channelCacheSize | The currently configured maximum channels that are allowed to be idle. |
localPort | The local port for the connection (if available). This can be used to correlate with connections/channels on the RabbitMQ Admin UI. |
idleChannelsTx | The number of transactional channels that are currently idle (cached). |
idleChannelsNotTx | The number of non-transactional channels that are currently idle (cached). |
idleChannelsTxHighWater | The maximum number of transactional channels that have been concurrently idle (cached). |
idleChannelsNotTxHighWater | The maximum number of non-transactional channels have been concurrently idle (cached). |
Table 3.2. Cache properties for CacheMode.CONNECTION
Property | Meaning |
---|---|
openConnections | The number of connection objects representing connections to brokers. |
channelCacheSize | The currently configured maximum channels that are allowed to be idle. |
connectionCacheSize | The currently configured maximum connections that are allowed to be idle. |
idleConnections | The number of connections that are currently idle. |
idleConnectionsHighWater | The maximum number of connections that have been concurrently idle. |
idleChannelsTx:<localPort> | The number of transactional channels that are currently idle (cached) for this connection. The localPort part of the property name can be used to correlate with connections/channels on the RabbitMQ Admin UI. |
idleChannelsNotTx:<localPort> | The number of non-transactional channels that are currently idle (cached) for this connection. The localPort part of the property name can be used to correlate with connections/channels on the RabbitMQ Admin UI. |
idleChannelsTxHighWater: <localPort> | The maximum number of transactional channels that have been concurrently idle (cached). The localPort part of the property name can be used to correlate with connections/channels on the RabbitMQ Admin UI. |
idleChannelsNotTxHighWater: <localPort> | The maximum number of non-transactional channels have been concurrently idle (cached). The localPort part of the property name can be used to correlate with connections/channels on the RabbitMQ Admin UI. |
The cacheMode
property (CHANNEL
or CONNECTION
is also included).
Since the first version of Spring AMQP, the framework has provided its own connection and channel recovery in the event of a broker failure.
Also, as discussed in Section 3.1.10, “Configuring the broker”, the RabbitAdmin
will re-declare any infrastructure beans (queues etc) when the connection is re-established.
It therefore does not rely on the Auto Recovery that is now provided by the amqp-client
library.
Spring AMQP now uses the 4.0.x
version of amqp-client
, which has auto recovery enabled by default.
Spring AMQP can still use its own recovery mechanisms if you wish, disabling it in the client, (by setting the automaticRecoveryEnabled
property on the underlying RabbitMQ connectionFactory
to false
).
However, the framework is completely compatible with auto recovery being enabled.
This means any consumers you create within your code (perhaps via RabbitTemplate.execute()
) can be recovered automatically.
The CachingConnectionFactory
now allows you to access the underlying connection factory to allow, for example,
setting custom client properties:
connectionFactory.getRabbitConnectionFactory().getClientProperties().put("foo", "bar");
These properties appear in the RabbitMQ Admin UI when viewing the connection.
As with many other high-level abstractions provided by the Spring Framework and related projects, Spring AMQP provides a "template" that plays a central role.
The interface that defines the main operations is called AmqpTemplate
.
Those operations cover the general behavior for sending and receiving Messages.
In other words, they are not unique to any implementation, hence the "AMQP" in the name.
On the other hand, there are implementations of that interface that are tied to implementations of the AMQP protocol.
Unlike JMS, which is an interface-level API itself, AMQP is a wire-level protocol.
The implementations of that protocol provide their own client libraries, so each implementation of the template interface will depend on a particular client library.
Currently, there is only a single implementation: RabbitTemplate
.
In the examples that follow, you will often see usage of an "AmqpTemplate", but when you look at the configuration examples, or any code excerpts where the template is instantiated and/or setters are invoked, you will see the implementation type (e.g.
"RabbitTemplate").
As mentioned above, the AmqpTemplate
interface defines all of the basic operations for sending and receiving Messages.
We will explore Message sending and reception, respectively, in the two sections that follow.
See also the section called “AsyncRabbitTemplate”.
Starting with version 1.3 you can now configure the RabbitTemplate
to use a RetryTemplate
to help with handling problems with broker connectivity.
Refer to the spring-retry project for complete information; the following is just one example that uses an exponential back off policy and the default SimpleRetryPolicy
which will make three attempts before throwing the exception to the caller.
Using the XML namespace:
<rabbit:template id="template" connection-factory="connectionFactory" retry-template="retryTemplate"/> <bean id="retryTemplate" class="org.springframework.retry.support.RetryTemplate"> <property name="backOffPolicy"> <bean class="org.springframework.retry.backoff.ExponentialBackOffPolicy"> <property name="initialInterval" value="500" /> <property name="multiplier" value="10.0" /> <property name="maxInterval" value="10000" /> </bean> </property> </bean>
Using @Configuration
:
@Bean public AmqpTemplate rabbitTemplate(); RabbitTemplate template = new RabbitTemplate(connectionFactory()); RetryTemplate retryTemplate = new RetryTemplate(); ExponentialBackOffPolicy backOffPolicy = new ExponentialBackOffPolicy(); backOffPolicy.setInitialInterval(500); backOffPolicy.setMultiplier(10.0); backOffPolicy.setMaxInterval(10000); retryTemplate.setBackOffPolicy(backOffPolicy); template.setRetryTemplate(retryTemplate); return template; }
Starting with version 1.4, in addition to the retryTemplate
property, the recoveryCallback
option is supported on the RabbitTemplate
.
It is used as a second argument for the RetryTemplate.execute(RetryCallback<T, E> retryCallback,
RecoveryCallback<T>recoveryCallback)
.
Note | |
---|---|
The |
retryTemplate.execute( new RetryCallback<Object, Exception>() { @Override public Object doWithRetry(RetryContext context) throws Exception { context.setAttribute("message", message); return rabbitTemplate.convertAndSend(exchange, routingKey, message); } }, new RecoveryCallback<Object>() { @Override public Object recover(RetryContext context) throws Exception { Object message = context.getAttribute("message"); Throwable t = context.getLastThrowable(); // Do something with message return null; } }); }
In this case, you would not inject a RetryTemplate
into the RabbitTemplate
.
The RabbitTemplate
implementation of AmqpTemplate
supports Publisher Confirms and Returns.
For returned messages, the template’s mandatory
property must be set to true
, or the mandatory-expression
must evaluate to true
for a particular message.
This feature requires a CachingConnectionFactory
that has its publisherReturns
property set to true (see the section called “Publisher Confirms and Returns”).
Returns are sent to to the client by it registering a RabbitTemplate.ReturnCallback
by calling setReturnCallback(ReturnCallback callback)
.
The callback must implement this method:
void returnedMessage(Message message, int replyCode, String replyText, String exchange, String routingKey);
Only one ReturnCallback
is supported by each RabbitTemplate
.
See also the section called “Reply Timeout”.
For Publisher Confirms (aka Publisher Acknowledgements), the template requires a CachingConnectionFactory
that has its publisherConfirms
property set to true.
Confirms are sent to to the client by it registering a RabbitTemplate.ConfirmCallback
by calling setConfirmCallback(ConfirmCallback callback)
.
The callback must implement this method:
void confirm(CorrelationData correlationData, boolean ack, String cause);
The CorrelationData
is an object supplied by the client when sending the original message.
The ack
is true for an ack
and false for a nack
.
For nack
s, the cause may contain a reason for the nack, if it is available when the nack
is generated.
An example is when sending a message to a non-existent exchange.
In that case the broker closes the channel; the reason for the closure is included in the cause
.
cause
was added in version 1.4.
Only one ConfirmCallback
is supported by a RabbitTemplate
.
Note | |
---|---|
When a rabbit template send operation completes, the channel is closed; this would preclude the reception of confirms or returns in the case when the connection factory cache is full (when there is space in the cache, the channel is not physically closed and the returns/confirms will proceed as normal).
When the cache is full, the framework defers the close for up to 5 seconds, in order to allow time for the confirms/returns to be received.
When using confirms, the channel will be closed when the last confirm is received.
When using only returns, the channel will remain open for the full 5 seconds.
It is generally recommended to set the connection factory’s |
Starting with version 1.4 RabbitMessagingTemplate
, built on top of RabbitTemplate
, provides an integration with the Spring Framework messaging abstraction, i.e.
org.springframework.messaging.Message
.
This allows you to send and receive messages using the spring-messaging
Message<?>
abstraction.
This abstraction is used by other Spring projects such as Spring Integration and Spring’s STOMP support.
There are two message converters involved; one to convert between a spring-messaging Message<?>
and Spring AMQP’s Message
abstraction, and one to convert between Spring AMQP’s Message
abstraction and the format required by the underlying RabbitMQ client library.
By default, the message payload is converted by the provided RabbitTemplate
's message converter.
Alternatively, you can inject a custom MessagingMessageConverter
with some other payload converter:
MessagingMessageConverter amqpMessageConverter = new MessagingMessageConverter();
amqpMessageConverter.setPayloadConverter(myPayloadConverter);
rabbitMessagingTempalte.setAmqpMessageConverter(amqpMessageConverter);
Starting with version 1.6, the template now supports a user-id-expression
(userIdExpression
when using Java configuration).
If a message is sent, the user id property is set (if not already set) after evaluating this expression.
The root object for the evaluation is the message to be sent.
Examples:
<rabbit:template ... user-id-expression="'guest'" /> <rabbit:template ... user-id-expression="@myConnectionFactory.username" />
The first example is a literal expression; the second obtains the username
property from a connection factory bean in the application context.
When sending a Message, one can use any of the following methods:
void send(Message message) throws AmqpException; void send(String routingKey, Message message) throws AmqpException; void send(String exchange, String routingKey, Message message) throws AmqpException;
We can begin our discussion with the last method listed above since it is actually the most explicit. It allows an AMQP Exchange name to be provided at runtime along with a routing key. The last parameter is the callback that is responsible for actual creating of the Message instance. An example of using this method to send a Message might look this this:
amqpTemplate.send("marketData.topic", "quotes.nasdaq.FOO", new Message("12.34".getBytes(), someProperties));
The "exchange" property can be set on the template itself if you plan to use that template instance to send to the same exchange most or all of the time. In such cases, the second method listed above may be used instead. The following example is functionally equivalent to the previous one:
amqpTemplate.setExchange("marketData.topic"); amqpTemplate.send("quotes.nasdaq.FOO", new Message("12.34".getBytes(), someProperties));
If both the "exchange" and "routingKey" properties are set on the template, then the method accepting only the Message
may be used:
amqpTemplate.setExchange("marketData.topic"); amqpTemplate.setRoutingKey("quotes.nasdaq.FOO"); amqpTemplate.send(new Message("12.34".getBytes(), someProperties));
A better way of thinking about the exchange and routing key properties is that the explicit method parameters will always override the template’s default values. In fact, even if you do not explicitly set those properties on the template, there are always default values in place. In both cases, the default is an empty String, but that is actually a sensible default. As far as the routing key is concerned, it’s not always necessary in the first place (e.g. a Fanout Exchange). Furthermore, a Queue may be bound to an Exchange with an empty String. Those are both legitimate scenarios for reliance on the default empty String value for the routing key property of the template. As far as the Exchange name is concerned, the empty String is quite commonly used because the AMQP specification defines the "default Exchange" as having no name. Since all Queues are automatically bound to that default Exchange (which is a Direct Exchange) using their name as the binding value, that second method above can be used for simple point-to-point Messaging to any Queue through the default Exchange. Simply provide the queue name as the "routingKey" - either by providing the method parameter at runtime:
RabbitTemplate template = new RabbitTemplate(); // using default no-name Exchange template.send("queue.helloWorld", new Message("Hello World".getBytes(), someProperties));
Or, if you prefer to create a template that will be used for publishing primarily or exclusively to a single Queue, the following is perfectly reasonable:
RabbitTemplate template = new RabbitTemplate(); // using default no-name Exchange template.setRoutingKey("queue.helloWorld"); // but we'll always send to this Queue template.send(new Message("Hello World".getBytes(), someProperties));
Starting with version 1.3, a message builder API is provided by the MessageBuilder
and MessagePropertiesBuilder
; they provides a convenient "fluent" means of creating a message or message properties:
Message message = MessageBuilder.withBody("foo".getBytes()) .setContentType(MessageProperties.CONTENT_TYPE_TEXT_PLAIN) .setMessageId("123") .setHeader("bar", "baz") .build();
or
MessageProperties props = MessagePropertiesBuilder.newInstance() .setContentType(MessageProperties.CONTENT_TYPE_TEXT_PLAIN) .setMessageId("123") .setHeader("bar", "baz") .build(); Message message = MessageBuilder.withBody("foo".getBytes()) .andProperties(props) .build();
Each of the properties defined on the MessageProperties can be set.
Other methods include setHeader(String key, String value)
, removeHeader(String key)
, removeHeaders()
, and copyProperties(MessageProperties properties)
.
Each property setting method has a set*IfAbsent()
variant.
In the cases where a default initial value exists, the method is named set*IfAbsentOrDefault()
.
Five static methods are provided to create an initial message builder:
public static MessageBuilder withBody(byte[] body) public static MessageBuilder withClonedBody(byte[] body) public static MessageBuilder withBody(byte[] body, int from, int to) public static MessageBuilder fromMessage(Message message) public static MessageBuilder fromClonedMessage(Message message)
The message created by the builder will have a body that is a direct reference to the argument. | |
The message created by the builder will have a body that is a new array containing a copy of bytes in the argument. | |
The message created by the builder will have a body that is a new array containing the range of bytes from the argument.
See | |
The message created by the builder will have a body that is a direct reference to the body of the argument.
The argument’s properties are copied to a new | |
The message created by the builder will have a body that is a new array containing a copy of the argument’s body.
The argument’s properties are copied to a new |
public static MessagePropertiesBuilder newInstance() public static MessagePropertiesBuilder fromProperties(MessageProperties properties) public static MessagePropertiesBuilder fromClonedProperties(MessageProperties properties)
A new message properties object is initialized with default values. | |
The builder is initialized with, and | |
The argument’s properties are copied to a new |
With the RabbitTemplate
implementation of AmqpTemplate
, each of the send()
methods has an overloaded version that takes an additional CorrelationData
object.
When publisher confirms are enabled, this object is returned in the callback described in Section 3.1.4, “AmqpTemplate”.
This allows the sender to correlate a confirm (ack or nack) with the sent message.
Starting with version 1.6.7, the CorrelationAwareMessagePostProcessor
interface was introduced, allowing the correlation data to be modified after the message has been converted:
Message postProcessMessage(Message message, Correlation correlation);
Also starting with version 1.6.7 a new callback interface is provided CorrelationDataPostProcessor
; this is invoked after all MessagePostProcessor
s (provided in the send()
method as well as those provided in setBeforePublishPostProcessors()
).
Implementations can update or replace the correlation data supplied in the send()
method (if any).
The Message
and original CorrelationData
(if any) are provided as arguments.
CorrelationData postProcess(Message message, CorrelationData correlationData);
When the template’s mandatory
property is true returned messages are provided by the callback described in Section 3.1.4, “AmqpTemplate”.
Starting with version 1.4 the RabbitTemplate
supports the SpEL mandatoryExpression
property, which is evaluated against each request message, as the root evaluation object, resolving to a boolean
value.
Bean references, such as "@myBean.isMandatory(#root)"
can be used in the expression.
Publisher returns can also be used internally by the RabbitTemplate
in send and receive operations.
See the section called “Reply Timeout” for more information.
Starting with version 1.4.2, the BatchingRabbitTemplate
has been introduced.
This is a subclass of RabbitTemplate
with an overridden send
method that batches messages according to the
BatchingStrategy
; only when a batch is complete is the message sent to RabbitMQ.
public interface BatchingStrategy { MessageBatch addToBatch(String exchange, String routingKey, Message message); Date nextRelease(); Collection<MessageBatch> releaseBatches(); }
Caution | |
---|---|
Batched data is held in memory; unsent messages can be lost in the event of a system failure. |
A SimpleBatchingStrategy
is provided.
It supports sending messages to a single exchange/routing key. It has properties:
batchSize
- the number of messages in a batch before it is sent
bufferLimit
- the maximum size of the batched message; this will preempt the batchSize
if exceeded, and cause a partial batch to be sent
timeout
- a time after which a partial batch will be sent when there is no new activity adding messages to the batch
The SimpleBatchingStrategy
formats the batch by preceding each embedded message with a 4 byte binary length.
This is communicated to the receiving system by setting the springBatchFormat
message property to lengthHeader4
.
Important | |
---|---|
Batched messages are automatically de-batched by listener containers (using the |
Message reception is always a little more complicated than sending.
There are two ways to receive a Message
.
The simpler option is to poll for a single Message
at a time with a polling method call.
The more complicated yet more common approach is to register a listener that will receive Messages
on-demand, asynchronously.
We will look at an example of each approach in the next two sub-sections.
The AmqpTemplate
itself can be used for polled Message reception.
By default, if no message is available, null
is returned immediately; there is no blocking.
Starting with version 1.5, you can now set a receiveTimeout
, in milliseconds, and the receive methods will block for
up to that long, waiting for a message.
A value less than zero means block indefinitely (or at least until the
connection to the broker is lost).
Version 1.6 introduced variants of the receive
methods allowing the timeout to be passed in on each call.
Caution | |
---|---|
Since the receive operation creates a new |
There are four simple receive methods available.
As with the Exchange on the sending side, there is a method that requires a default queue property having been set
directly on the template itself, and there is a method that accepts a queue parameter at runtime.
Version 1.6 introduced variants to accept timeoutMillis
to override receiveTimeout
on a per-request basis.
Message receive() throws AmqpException; Message receive(String queueName) throws AmqpException; Message receive(long timeoutMillis) throws AmqpException; Message receive(String queueName, long timeoutMillis) throws AmqpException;
Just like in the case of sending messages, the AmqpTemplate
has some convenience methods for receiving POJOs instead of Message
instances, and implementations will provide a way to customize the MessageConverter
used to create the Object
returned:
Object receiveAndConvert() throws AmqpException; Object receiveAndConvert(String queueName) throws AmqpException; Message receiveAndConvert(long timeoutMillis) throws AmqpException; Message receiveAndConvert(String queueName, long timeoutMillis) throws AmqpException;
Similar to sendAndReceive
methods, beginning with version 1.3, the AmqpTemplate
has several convenience receiveAndReply
methods for synchronously receiving, processing and replying to messages:
<R, S> boolean receiveAndReply(ReceiveAndReplyCallback<R, S> callback) throws AmqpException; <R, S> boolean receiveAndReply(String queueName, ReceiveAndReplyCallback<R, S> callback) throws AmqpException; <R, S> boolean receiveAndReply(ReceiveAndReplyCallback<R, S> callback, String replyExchange, String replyRoutingKey) throws AmqpException; <R, S> boolean receiveAndReply(String queueName, ReceiveAndReplyCallback<R, S> callback, String replyExchange, String replyRoutingKey) throws AmqpException; <R, S> boolean receiveAndReply(ReceiveAndReplyCallback<R, S> callback, ReplyToAddressCallback<S> replyToAddressCallback) throws AmqpException; <R, S> boolean receiveAndReply(String queueName, ReceiveAndReplyCallback<R, S> callback, ReplyToAddressCallback<S> replyToAddressCallback) throws AmqpException;
The AmqpTemplate
implementation takes care of the receive and reply phases.
In most cases you should provide only an implementation of ReceiveAndReplyCallback
to perform some business logic for the received message and build a reply object or message, if needed.
Note, a ReceiveAndReplyCallback
may return null
.
In this case no reply is sent and receiveAndReply
works like the receive
method.
This allows the same queue to be used for a mixture of messages, some of which may not need a reply.
Automatic message (request and reply) conversion is applied only if the provided callback is not an instance of ReceiveAndReplyMessageCallback
- which provides a raw message exchange contract.
The ReplyToAddressCallback
is useful for cases requiring custom logic to determine the replyTo
address at runtime against the received message and reply from the ReceiveAndReplyCallback
.
By default, replyTo
information in the request message is used to route the reply.
The following is an example of POJO-based receive and reply…
boolean received = this.template.receiveAndReply(ROUTE, new ReceiveAndReplyCallback<Order, Invoice>() { public Invoice handle(Order order) { return processOrder(order); } }); if (received) { log.info("We received an order!"); }
Important | |
---|---|
Spring AMQP also supports annotated-listener endpoints through the use of the |
For asynchronous Message reception, a dedicated component (not the AmqpTemplate
) is involved.
That component is a container for a Message consuming callback.
We will look at the container and its properties in just a moment, but first we should look at the callback since that is where your application code will be integrated with the messaging system.
There are a few options for the callback starting with an implementation of the MessageListener
interface:
public interface MessageListener { void onMessage(Message message); }
If your callback logic depends upon the AMQP Channel instance for any reason, you may instead use the ChannelAwareMessageListener
.
It looks similar but with an extra parameter:
public interface ChannelAwareMessageListener { void onMessage(Message message, Channel channel) throws Exception; }
If you prefer to maintain a stricter separation between your application logic and the messaging API, you can rely upon an adapter implementation that is provided by the framework. This is often referred to as "Message-driven POJO" support. When using the adapter, you only need to provide a reference to the instance that the adapter itself should invoke.
MessageListenerAdapter listener = new MessageListenerAdapter(somePojo); listener.setDefaultListenerMethod("myMethod");
You can subclass the adapter and provide an implementation of getListenerMethodName()
to dynamically select different methods based on the message.
This method has two parameters, the originalMessage
and extractedMessage
, the latter being the result of any conversion.
By default, a SimpleMessageConverter
is configured; see the section called “SimpleMessageConverter” for more information and
information about other converters available.
Starting with version 1.4.2, the original message has properties consumerQueue
and consumerTag
which can be used
to determine which queue a message was received from.
Starting with version 1.5, you can configure a map of consumer queue/tag to method name, to dynamically select the method to call. If no entry is in the map, we fall back to the default listener method.
Now that you’ve seen the various options for the Message-listening callback, we can turn our attention to the container.
Basically, the container handles the "active" responsibilities so that the listener callback can remain passive.
The container is an example of a "lifecycle" component.
It provides methods for starting and stopping.
When configuring the container, you are essentially bridging the gap between an AMQP Queue and the MessageListener
instance.
You must provide a reference to the ConnectionFactory
and the queue name or Queue instance(s) from which that listener should consume Messages.
Here is the most basic example using the default implementation, SimpleMessageListenerContainer
:
SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(); container.setConnectionFactory(rabbitConnectionFactory); container.setQueueNames("some.queue"); container.setMessageListener(new MessageListenerAdapter(somePojo));
As an "active" component, it’s most common to create the listener container with a bean definition so that it can simply run in the background. This can be done via XML:
<rabbit:listener-container connection-factory="rabbitConnectionFactory"> <rabbit:listener queues="some.queue" ref="somePojo" method="handle"/> </rabbit:listener-container>
Or, you may prefer to use the @Configuration style which will look very similar to the actual code snippet above:
@Configuration public class ExampleAmqpConfiguration { @Bean public SimpleMessageListenerContainer messageListenerContainer() { SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(); container.setConnectionFactory(rabbitConnectionFactory()); container.setQueueName("some.queue"); container.setMessageListener(exampleListener()); return container; } @Bean public ConnectionFactory rabbitConnectionFactory() { CachingConnectionFactory connectionFactory = new CachingConnectionFactory("localhost"); connectionFactory.setUsername("guest"); connectionFactory.setPassword("guest"); return connectionFactory; } @Bean public MessageListener exampleListener() { return new MessageListener() { public void onMessage(Message message) { System.out.println("received: " + message); } }; } }
Starting with RabbitMQ Version 3.2, the broker now supports consumer priority (see Using Consumer Priorities with RabbitMQ).
This is enabled by setting the x-priority
argument on the consumer.
The SimpleMessageListenerContainer
now supports setting consumer arguments:
container.setConsumerArguments(Collections. <String, Object> singletonMap("x-priority", Integer.valueOf(10)));
For convenience, the namespace provides the priority
attribute on the listener
element:
<rabbit:listener-container connection-factory="rabbitConnectionFactory"> <rabbit:listener queues="some.queue" ref="somePojo" method="handle" priority="10" /> </rabbit:listener-container>
Starting with version 1.3 the queue(s) on which the container is listening can be modified at runtime; see Section 3.1.18, “Listener Container Queues”.
When a container is configured to listen to auto-delete
queue(s), or the queue has an x-expires
option or the Time-To-Live policy is configured on the Broker, the queue is removed by the broker when the container is stopped (last consumer is cancelled).
Before version 1.3, the container could not be restarted because the queue was missing; the RabbitAdmin
only automatically redeclares queues etc, when the connection is closed/opens, which does not happen when the container is stopped/started.
Starting with version 1.3, the container will now use a RabbitAdmin
to redeclare any missing queues during startup.
You can also use conditional declaration (the section called “Conditional Declaration”) together with an auto-startup="false"
admin to defer queue declaration until the container is started.
<rabbit:queue id="otherAnon" declared-by="containerAdmin" /> <rabbit:direct-exchange name="otherExchange" auto-delete="true" declared-by="containerAdmin"> <rabbit:bindings> <rabbit:binding queue="otherAnon" key="otherAnon" /> </rabbit:bindings> </rabbit:direct-exchange> <rabbit:listener-container id="container2" auto-startup="false"> <rabbit:listener id="listener2" ref="foo" queues="otherAnon" admin="containerAdmin" /> </rabbit:listener-container> <rabbit:admin id="containerAdmin" connection-factory="rabbitConnectionFactory" auto-startup="false" />
In this case, the queue and exchange are declared by containerAdmin
which has auto-startup="false"
so the elements are not declared during context initialization.
Also, the container is not started for the same reason.
When the container is later started, it uses it’s reference to containerAdmin
to declare the elements.
Batched messages are automatically de-batched by listener containers (using the springBatchFormat
message header). Rejecting any message from a batch will cause the entire batch to be rejected.
See the section called “Batching” for more information about batching.
Starting with version 1.5, the SimpleMessageListenerContainer
publishes application events whenever a listener
(consumer) experiences a failure of some kind.
The event ListenerContainerConsumerFailedEvent
has the following properties:
container
- the listener container where the consumer experienced the problem.
reason
- a textual reason for the failure.
fatal
- a boolean indicating whether the failure was fatal; with non-fatal exceptions, the container will attempt
to restart the consumer, according to the retryInterval
.
throwable
- the Throwable
that was caught.
These events can be consumed by implementing ApplicationListener<ListenerContainerConsumerFailedEvent>
.
Note | |
---|---|
System-wide events (such as connection failures) will be published by all consumers when |
If a consumer fails because one if its queues is being used exclusively, by default, as well as publishing the
event, a WARN
log is issued. To change this logging behavior, provide a custom ConditionalExceptionLogger
in the
SimpleMessageListenerContainer
's exclusiveConsumerExceptionLogger
property.
See also the section called “Logging Channel Close Events”.
Fatal errors are always logged at ERROR
level; this it not modifiable.
Starting with version 1.4.5, you can now provide a strategy to generate consumer tags. By default, the consumer tag will be generated by the broker.
public interface ConsumerTagStrategy { String createConsumerTag(String queue); }
The queue is made available so it can (optionally) be used in the tag.
See Section 3.1.15, “Message Listener Container Configuration”.
Starting with version 1.4, the easiest way to receive a message asynchronously is to use the annotated listener endpoint infrastructure. In a nutshell, it allows you to expose a method of a managed bean as a Rabbit listener endpoint.
@Component public class MyService { @RabbitListener(queues = "myQueue") public void processOrder(String data) { ... } }
The idea of the example above is that, whenever a message is available on the org.springframework.amqp.core.Queue
"myQueue", the processOrder
method is invoked accordingly (in this case, with the payload of the message).
The annotated endpoint infrastructure creates a message listener container behind the scenes for each annotated method, using a RabbitListenerContainerFactory
.
In the example above, myQueue
must already exist and be bound to some exchange.
Starting with version 1.5.0, the queue can be declared and bound automatically, as long as a RabbitAdmin
exists
in the application context.
@Component public class MyService { @RabbitListener(bindings = @QueueBinding( value = @Queue(value = "myQueue", durable = "true"), exchange = @Exchange(value = "auto.exch", ignoreDeclarationExceptions = "true"), key = "orderRoutingKey") ) public void processOrder(String data) { ... } @RabbitListener(bindings = @QueueBinding( value = @Queue, exchange = @Exchange(value = "auto.exch"), key = "invoiceRoutingKey") ) public void processInvoice(String data) { ... } }
In the first example, a queue myQueue
will be declared automatically (durable) together with the exchange, if needed,
and bound to the exchange with the routing key.
In the second example, an anonymous (exclusive, auto-delete) queue will be declared and bound.
Multiple QueueBinding
entries can be provided, allowing the listener to listen to multiple queues.
Only DIRECT, FANOUT, TOPIC and HEADERS, exchange types are supported with this mechanism.
Use normal @Bean
definitions when more advanced configuration is required.
Notice ignoreDeclarationExceptions
on the exchange in the first example.
This allows, for example, binding to an existing exchange that might have different settings (such as internal
).
By default the properties of an existing exchange must match.
Starting with version 1.6, you can now specify arguments within @QueueBinding
annotations for queues, exchanges
and bindings. For example:
@RabbitListener(bindings = @QueueBinding( value = @Queue(value = "auto.headers", autoDelete = "true", arguments = @Argument(name = "x-message-ttl", value = "10000", type = "java.lang.Integer")), exchange = @Exchange(value = "auto.headers", type = ExchangeTypes.HEADERS, autoDelete = "true"), arguments = { @Argument(name = "x-match", value = "all"), @Argument(name = "foo", value = "bar"), @Argument(name = "baz") }) ) public String handleWithHeadersExchange(String foo) { ... }
Notice that the x-message-ttl
argument is set to 10 seconds for the queue.
Since the argument type is not String
, we have to specify its type; in this case Integer
.
As with all such declarations, if the queue exists already, the arguments must match those on the queue.
For the header exchange, we set the binding arguments to match messages that have the header foo
set to bar
and
the header baz
must be present with any value.
The x-match
argument means both conditions must be satisfied.
The argument name, value, and type can be property placeholders (${...}
) or SpEL expressions (#{...}
).
The name
must resolve to a String
; the expression for type
must resolve to a Class
or the fully-qualified name of
a class.
The value
must resolve to something that can be converted by the DefaultConversionService
to the type (such as
the x-message-ttl
in the above example).
If a name resolves to null
or an empty String
, that @Argument
is ignored.
Sometimes you may want to use the same configuration for multiple listeners. To reduce the boilerplate configuration, you can use meta-annotations to create your own listener annotation:
@Target({ElementType.TYPE, ElementType.METHOD, ElementType.ANNOTATION_TYPE}) @Retention(RetentionPolicy.RUNTIME) @RabbitListener(bindings = @QueueBinding( value = @Queue, exchange = @Exchange(value = "metaFanout", type = ExchangeTypes.FANOUT))) public @interface MyAnonFanoutListener { } public class MetaListener { @MyAnonFanoutListener public void handle1(String foo) { ... } @MyAnonFanoutListener public void handle2(String foo) { ... } }
In this example, each listener created by the @MyAnonFanoutListener
annotation will bind an anonymous, auto-delete
queue to the fanout exchange metaFanout
.
The meta-annotation mechanism is simple in that attributes on the user-defined annotation are not examined - so
you can’t override settings from the meta-annotation.
Use normal @Bean
definitions when more advanced configuration is required.
To enable support for @RabbitListener
annotations add @EnableRabbit
to one of your @Configuration
classes.
@Configuration @EnableRabbit public class AppConfig { @Bean public SimpleRabbitListenerContainerFactory rabbitListenerContainerFactory() { SimpleRabbitListenerContainerFactory factory = new SimpleRabbitListenerContainerFactory(); factory.setConnectionFactory(connectionFactory()); factory.setConcurrentConsumers(3); factory.setMaxConcurrentConsumers(10); return factory; } }
By default, the infrastructure looks for a bean named rabbitListenerContainerFactory
as the source for the factory to use to create message listener containers.
In this case, and ignoring the RabbitMQ infrastructure setup, the processOrder
method can be invoked with a core poll size of 3 threads and a maximum pool size of 10 threads.
It is possible to customize the listener container factory to use per annotation or an explicit default can be configured by implementing the RabbitListenerConfigurer
interface.
The default is only required if at least one endpoint is registered without a specific container factory.
See the javadoc for full details and examples.
If you prefer XML configuration, use the <rabbit:annotation-driven>
element.
<rabbit:annotation-driven/> <bean id="rabbitListenerContainerFactory" class="org.springframework.amqp.rabbit.config.SimpleRabbitListenerContainerFactory"> <property name="connectionFactory" ref="connectionFactory"/> <property name="concurrentConsumers" value="3"/> <property name="maxConcurrentConsumers" value="10"/> </bean>
There are two conversion steps in the pipeline before invoking the listener.
The first uses a MessageConverter
to convert the incoming Spring AMQP Message
to a spring-messaging Message
.
When the target method is invoked, the message payload is converted, if necessary, to the method parameter type.
The default MessageConverter
for the first step is a Spring AMQP SimpleMessageConverter
that handles conversion to
String
and java.io.Serializable
objects; all others remain as a byte[]
.
In the following discussion, we call this the message converter.
The default converter for the second step is a GenericMessageConverter
which delegates to a conversion service
(an instance of DefaultFormattingConversionService
).
In the following discussion, we call this the method argument converter.
To change the message converter, simply add it as a property to the container factory bean:
@Bean public SimpleRabbitListenerContainerFactory rabbitListenerContainerFactory() { SimpleRabbitListenerContainerFactory factory = new SimpleRabbitListenerContainerFactory(); ... factory.setMessageConverter(new Jackson2JsonMessageConverter()); ... return factory; }
This configures a Jackson2 converter that expects header information to be present to guide the conversion.
You can also consider a ContentTypeDelegatingMessageConverter
which can handle conversion of different content types.
In most cases, it is not necessary to customize the method argument converter unless, for example, you want to use
a custom ConversionService
.
In versions prior to 1.6, the type information to convert the JSON had to be provided in message headers, or a
custom ClassMapper
was required.
Starting with version 1.6, if there are no type information headers, the type can be inferred from the target
method arguments.
Note | |
---|---|
This type inference only works for |
See the section called “Jackson2JsonMessageConverter” for more information.
If you wish to customize the method argument converter, you can do so as follows:
@Configuration @EnableRabbit public class AppConfig implements RabbitListenerConfigurer { ... @Bean public DefaultMessageHandlerMethodFactory myHandlerMethodFactory() { DefaultMessageHandlerMethodFactory factory = new DefaultMessageHandlerMethodFactory(); factory.setMessageConverter(new GenericMessageConverter(myConversionService())); return factory; } @Bean public ConversionService myConversionService() { DefaultConversionService conv = new DefaultConversionService(); conv.addConverter(mySpecialConverter()); return conv; } @Override public void configureRabbitListeners(RabbitListenerEndpointRegistrar registrar) { registrar.setMessageHandlerMethodFactory(myHandlerMethodFactory()); } ... }
Important | |
---|---|
for multi-method listeners (see the section called “Multi-Method Listeners”), the method selection is based on the payload of the message after the message conversion; the method argument converter is only called after the method has been selected. |
RabbitListenerEndpoint
provides a model of a Rabbit endpoint and is responsible for configuring the container for that model.
The infrastructure allows you to configure endpoints programmatically in addition to the ones that are detected by the RabbitListener
annotation.
@Configuration @EnableRabbit public class AppConfig implements RabbitListenerConfigurer { @Override public void configureRabbitListeners(RabbitListenerEndpointRegistrar registrar) { SimpleRabbitListenerEndpoint endpoint = new SimpleRabbitListenerEndpoint(); endpoint.setQueueNames("anotherQueue"); endpoint.setMessageListener(message -> { // processing }); registrar.registerEndpoint(endpoint); } }
In the example above, we used SimpleRabbitListenerEndpoint
which provides the actual MessageListener
to invoke but you could just as well build your own endpoint variant describing a custom invocation mechanism.
It should be noted that you could just as well skip the use of @RabbitListener
altogether and only register your endpoints programmatically through RabbitListenerConfigurer.
So far, we have been injecting a simple String in our endpoint but it can actually have a very flexible method signature.
Let’s rewrite it to inject the Order
with a custom header:
@Component public class MyService { @RabbitListener(queues = "myQueue") public void processOrder(Order order, @Header("order_type") String orderType) { ... } }
These are the main elements you can inject in listener endpoints:
The raw org.springframework.amqp.core.Message
.
The com.rabbitmq.client.Channel
on which the message was received
The org.springframework.messaging.Message
representing the incoming AMQP message.
Note that this message holds both the custom and the standard headers (as defined by AmqpHeaders
).
Note | |
---|---|
Starting with version 1.6, the inbound |
@Header
-annotated method arguments to extract a specific header value, including standard AMQP headers.
@Headers
-annotated argument that must also be assignable to java.util.Map
for getting access to all headers.
A non-annotated element that is not one of the supported types (i.e.
Message
and Channel
) is considered to be the payload.
You can make that explicit by annotating the parameter with @Payload
.
You can also turn on validation by adding an extra @Valid
.
The ability to inject Spring’s Message abstraction is particularly useful to benefit from all the information stored in the transport-specific message without relying on transport-specific API.
@RabbitListener(queues = "myQueue") public void processOrder(Message<Order> order) { ... }
Handling of method arguments is provided by DefaultMessageHandlerMethodFactory
which can be further customized to support additional method arguments.
The conversion and validation support can be customized there as well.
For instance, if we want to make sure our Order is valid before processing it, we can annotate the payload with @Valid
and configure the necessary validator as follows:
@Configuration @EnableRabbit public class AppConfig implements RabbitListenerConfigurer { @Override public void configureRabbitListeners(RabbitListenerEndpointRegistrar registrar) { registrar.setMessageHandlerMethodFactory(myHandlerMethodFactory()); } @Bean public DefaultMessageHandlerMethodFactory myHandlerMethodFactory() { DefaultMessageHandlerMethodFactory factory = new DefaultMessageHandlerMethodFactory(); factory.setValidator(myValidator()); return factory; } }
When using the queues
attribute, you can specify that the associated container can listen to multiple queues.
You can use a @Header
annotation to make the queue name from which a message was received available to the POJO
method:
@Component public class MyService { @RabbitListener(queues = { "queue1", "queue2" } ) public void processOrder(String data, @Header(AmqpHeaders.CONSUMER_QUEUE) String queue) { ... } }
Starting with version 1.5, you can externalize the queue names using property placeholders, and SpEL:
@Component public class MyService { @RabbitListener(queues = "#{'${property.with.comma.delimited.queue.names}'.split(',')}" ) public void processOrder(String data, @Header(AmqpHeaders.CONSUMER_QUEUE) String queue) { ... } }
Prior to version 1.5, only a single queue could be specified this way; each queue needed a separate property.
The existing support in MessageListenerAdapter
already allows your method to have a non-void return type.
When that’s the case, the result of the invocation is encapsulated in a message sent either in the address specified in the ReplyToAddress
header of the original message or in the default address configured on the listener.
That default address can now be set using the @SendTo
annotation of the messaging abstraction.
Assuming our processOrder
method should now return an OrderStatus
, it is possible to write it as follow to automatically send a reply:
@RabbitListener(destination = "myQueue") @SendTo("status") public OrderStatus processOrder(Order order) { // order processing return status; }
If you need to set additional headers in a transport-independent manner, you could return a Message
instead, something like:
@RabbitListener(destination = "myQueue") @SendTo("status") public Message<OrderStatus> processOrder(Order order) { // order processing return MessageBuilder .withPayload(status) .setHeader("code", 1234) .build(); }
The @SendTo
value is assumed as a reply exchange
and routingKey
pair following the pattern exchange/routingKey
,
where one of those parts can be omitted.
The valid values are:
foo/bar
- the replyTo exchange and routingKey.
foo/
- the replyTo exchange and default (empty) routingKey.
bar
or /bar
- the replyTo routingKey and default (empty) exchange.
/
or empty - the replyTo default exchange and default routingKey.
Also @SendTo
can be used without a value
attribute.
This case is equal to an empty sendTo pattern.
@SendTo
is only used if the inbound message does not have a replyToAddress
property.
Starting with version 1.5, the @SendTo
value can be a bean initialization SpEL Expression, for example…
@RabbitListener(queues = "test.sendTo.spel") @SendTo("#{spelReplyTo}") public String capitalizeWithSendToSpel(String foo) { return foo.toUpperCase(); } ... @Bean public String spelReplyTo() { return "test.sendTo.reply.spel"; }
The expression must evaluate to a String
, which can be a simple queue name (sent to the default exchange) or with
the form exchange/routingKey
as discussed above.
Note | |
---|---|
The |
For dynamic reply routing, the message sender should include a reply_to
message property or use the alternate
runtime SpEL expression described below.
Starting with version 1.6, the @SendTo
can be a SpEL expression that is evaluated at runtime against the request
and reply:
@RabbitListener(queues = "test.sendTo.spel") @SendTo("!{'some.reply.queue.with.' + result.queueName}") public Bar capitalizeWithSendToSpel(Foo foo) { return processTheFooAndReturnABar(foo); }
The runtime nature of the SpEL expression is indicated with !{...}
delimiters.
The evaluation context #root
object for the expression has three properties:
request
- the o.s.amqp.core.Message
request object.
source
- the o.s.messaging.Message<?>
after conversion.
result
- the method result.
The context has a map property accessor, a standard type converter and a bean resolver, allowing other beans in the
context to be referenced (e.g. @someBeanName.determineReplyQ(request, result)
).
In summary, #{...}
is evaluated once during initialization, with the #root
object being the application context;
beans are referenced by their names.
!{...}
is evaluated at runtime for each message with the root object having the properties above and beans are
referenced with their names, prefixed by @
.
Starting with version 1.5.0, the @RabbitListener
annotation can now be specified at the class level.
Together with the new @RabbitHandler
annotation, this allows a single listener to invoke different methods, based on
the payload type of the incoming message.
This is best described using an example:
@RabbitListener(id="multi", queues = "someQueue") public class MultiListenerBean { @RabbitHandler @SendTo("my.reply.queue") public String bar(Bar bar) { ... } @RabbitHandler public String baz(Baz baz) { ... } @RabbitHandler public String qux(@Header("amqp_receivedRoutingKey") String rk, @Payload Qux qux) { ... } }
In this case, the individual @RabbitHandler
methods are invoked if the converted payload is a Bar
, Baz
or Qux
.
It is important to understand that the system must be able to identify a unique method based on the payload type.
The type is checked for assignability to a single parameter that has no annotations, or is annotated with the @Payload
annotation.
Notice that the same method signatures apply as discussed in the method-level @RabbitListener
described above.
Notice that the @SendTo
must be specified on each method (if needed); it is not supported at the class level.
Starting with version 1.6, the @RabbitListener
annotation is marked with @Repeatable
.
This means that the annotation can appear on the same annotated element (method or class) multiple times.
In this case, a separate listener container is created for each annotation, each of which invokes the same listener
@Bean
.
Repeatable annotations can be used with Java 8 or above; when using Java 7 or earlier, the same effect can be achieved
by using the @RabbitListeners
"container" annotation, with an array of @RabbitListener
annotations.
If your service is intended to be proxied (e.g. in case of @Transactional
) there are some considerations when
the interface has generic parameters.
With a generic interface and a particular implementation, e.g.:
interface TxService<P> { String handle(P payload, String header); } static class TxServiceImpl implements TxService<Foo> { @Override @RabbitListener(...) public String handle(Foo foo, String rk) { ... } }
you are forced to switch to the CGLIB target class proxy because the actual implementation of the interface
handle
method is a bridge method.
In the case of transaction management, the use of CGLIB is configured using
an annotation option - @EnableTransactionManagement(proxyTargetClass = true)
.
And in this case, all annotations have to be declared on the target method in the implementation:
static class TxServiceImpl implements TxService<Foo> { @Override @Transactional @RabbitListener(...) public String handle(@Payload Foo foo, @Header("amqp_receivedRoutingKey") String rk) { ... } }
Containers created for annotations are not registered with the application context.
You can obtain a collection of all containers by invoking getListenerContainers()
on the
RabbitListenerEndpointRegistry
bean.
You can then iterate over this collection, for example, to stop/start all containers or invoke the Lifecycle
methods
on the registry itself which will invoke the operations on each container.
You can also get a reference to an individual container using its id
, using getListenerContainer(String id)
; for
example registry.getListenerContainer("multi")
for the container created by the snippet above.
Starting with version 1.5.2, you can obtain the id
s of the registered containers with getListenerContainerIds()
.
Starting with version 1.5, you can now assign a group
to the container on the RabbitListener
endpoint.
This provides a mechanism to get a reference to a subset of containers; adding a group
attribute causes a
bean of type Collection<MessageListenerContainer>
to be registered with the context with the group name.
A number of different threads are involved with asynchronous consumers.
Threads from the TaskExecutor
configured in the SimpleMessageListener
are used to invoke the MessageListener
when a new message is delivered by RabbitMQ Client
.
If not configured, a SimpleAsyncTaskExecutor
is used.
If a pooled executor is used, ensure the pool size is sufficient to handle the configured concurrency.
Note | |
---|---|
When using the default |
The Executor
configured in the CachingConnectionFactory
is passed into the RabbitMQ Client
when creating the connection, and its threads are used to deliver new messages to the listener container.
At the time of writing, if this is not configured, the client uses an internal thread pool executor with a pool size of 5.
The RabbitMQ client
uses a ThreadFactory
to create threads for low-level I/O (socket) operations.
To modify this factory, you need to configure the underlying RabbitMQ ConnectionFactory
, as discussed in the section called “Configuring the Underlying Client Connection Factory”.
While efficient, one problem with asynchronous consumers is detecting when they are idle - users might want to take some action if no messages arrive for some period of time.
Starting with version 1.6, it is now possible to configure the listener container to publish a
ListenerContainerIdleEvent
when some time passes with no message delivery.
While the container is idle, an event will be published every idleEventInterval
milliseconds.
To configure this feature, set the idleEventInterval
on the container:
<rabbit:listener-container connection-factory="connectionFactory" ... idle-event-interval="60000" ... > <rabbit:listener id="container1" queue-names="foo" ref="myListener" method="handle" /> </rabbit:listener-container>
@Bean public SimpleMessageListenerContainer(ConnectionFactory connectionFactory) { SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(connectionFactory); ... container.setIdleEventInterval(60000L); ... return container; }
@Bean public SimpleRabbitListenerContainerFactory rabbitListenerContainerFactory() { SimpleRabbitListenerContainerFactory factory = new SimpleRabbitListenerContainerFactory(); factory.setConnectionFactory(rabbitConnectionFactory()); factory.setIdleEventInterval(60000L); ... return factory; }
In each of these cases, an event will be published once per minute while the container is idle.
You can capture these events by implementing ApplicationListener
- either a general listener, or one narrowed to only
receive this specific event.
You can also use @EventListener
, introduced in Spring Framework 4.2.
The following example combines the @RabbitListener
and @EventListener
into a single class.
It’s important to understand that the application listener will get events for all containers so you may need to
check the listener id if you want to take specific action based on which container is idle.
You can also use the @EventListener
condition
for this purpose.
The events have 4 properties:
source
- the listener container instance
id
- the listener id (or container bean name)
idleTime
- the time the container had been idle when the event was published
queueNames
- the names of the queue(s) that the container listens to
public class Listener { @RabbitListener(id="foo", queues="#{queue.name}") public String listen(String foo) { return foo.toUpperCase(); } @EventListener(condition = "event.listenerId == 'foo'") public void onApplicationEvent(ListenerContainerIdleEvent event) { ... } }
Important | |
---|---|
Event listeners will see events for all containers; so, in the example above, we narrow the events received based on the listener ID. |
Caution | |
---|---|
If you wish to use the idle event to stop the lister container, you should not call |
The AmqpTemplate
also defines several methods for sending and receiving Messages that will delegate to a MessageConverter
.
The MessageConverter
itself is quite straightforward.
It provides a single method for each direction: one for converting to a Message and another for converting from a Message.
Notice that when converting to a Message, you may also provide properties in addition to the object.
The "object" parameter typically corresponds to the Message body.
public interface MessageConverter { Message toMessage(Object object, MessageProperties messageProperties) throws MessageConversionException; Object fromMessage(Message message) throws MessageConversionException; }
The relevant Message-sending methods on the AmqpTemplate
are listed below.
They are simpler than the methods we discussed previously because they do not require the Message
instance.
Instead, the MessageConverter
is responsible for "creating" each Message
by converting the provided object to the byte array for the Message
body and then adding any provided MessageProperties
.
void convertAndSend(Object message) throws AmqpException; void convertAndSend(String routingKey, Object message) throws AmqpException; void convertAndSend(String exchange, String routingKey, Object message) throws AmqpException; void convertAndSend(Object message, MessagePostProcessor messagePostProcessor) throws AmqpException; void convertAndSend(String routingKey, Object message, MessagePostProcessor messagePostProcessor) throws AmqpException; void convertAndSend(String exchange, String routingKey, Object message, MessagePostProcessor messagePostProcessor) throws AmqpException;
On the receiving side, there are only two methods: one that accepts the queue name and one that relies on the template’s "queue" property having been set.
Object receiveAndConvert() throws AmqpException; Object receiveAndConvert(String queueName) throws AmqpException;
Note | |
---|---|
The |
The default implementation of the MessageConverter
strategy is called SimpleMessageConverter
.
This is the converter that will be used by an instance of RabbitTemplate if you do not explicitly configure an alternative.
It handles text-based content, serialized Java objects, and simple byte arrays.
If the content type of the input Message begins with "text" (e.g.
"text/plain"), it will also check for the content-encoding property to determine the charset to be used when converting the Message body byte array to a Java String.
If no content-encoding property had been set on the input Message, it will use the "UTF-8" charset by default.
If you need to override that default setting, you can configure an instance of SimpleMessageConverter
, set its "defaultCharset" property and then inject that into a RabbitTemplate
instance.
If the content-type property value of the input Message is set to "application/x-java-serialized-object", the SimpleMessageConverter
will attempt to deserialize (rehydrate) the byte array into a Java object.
While that might be useful for simple prototyping, it’s generally not recommended to rely on Java serialization since it leads to tight coupling between the producer and consumer.
Of course, it also rules out usage of non-Java systems on either side.
With AMQP being a wire-level protocol, it would be unfortunate to lose much of that advantage with such restrictions.
In the next two sections, we’ll explore some alternatives for passing rich domain object content without relying on Java serialization.
For all other content-types, the SimpleMessageConverter
will return the Message body content directly as a byte array.
See the section called “Java Deserialization” for important information.
When converting to a Message from an arbitrary Java Object, the SimpleMessageConverter
likewise deals with byte arrays, Strings, and Serializable instances.
It will convert each of these to bytes (in the case of byte arrays, there is nothing to convert), and it will set the content-type property accordingly.
If the Object to be converted does not match one of those types, the Message body will be null.
This converter is similar to the SimpleMessageConverter
except it can be configured with other Spring Framework
Serializer
and Deserializer
implementations for application/x-java-serialized-object
conversions.
See the section called “Java Deserialization” for important information.
As mentioned in the previous section, relying on Java serialization is generally not recommended.
One rather common alternative that is more flexible and portable across different languages and platforms is JSON
(JavaScript Object Notation).
The converter can be configured on any RabbitTemplate
instance to override its usage of the SimpleMessageConverter
default.
The Jackson2JsonMessageConverter
uses the com.fasterxml.jackson
2.x library.
<bean class="org.springframework.amqp.rabbit.core.RabbitTemplate"> <property name="connectionFactory" ref="rabbitConnectionFactory"/> <property name="messageConverter"> <bean class="org.springframework.amqp.support.converter.Jackson2JsonMessageConverter"> <!-- if necessary, override the DefaultClassMapper --> <property name="classMapper" ref="customClassMapper"/> </bean> </property> </bean>
As shown above, Jackson2JsonMessageConverter
uses a DefaultClassMapper
by default.
Type information is added to (and retrieved from) the MessageProperties
.
If an inbound message does not contain type information in the MessageProperties
, but you know the expected type, you
can configure a static type using the defaultType
property
<bean id="jsonConverterWithDefaultType" class="o.s.amqp.support.converter.Jackson2JsonMessageConverter"> <property name="classMapper"> <bean class="org.springframework.amqp.support.converter.DefaultClassMapper"> <property name="defaultType" value="foo.PurchaseOrder"/> </bean> </property> </bean>
Inbound messages are converted to objects according to the type information added to headers by the sending system.
In versions prior to 1.6, if type information is not present, conversion would fail. Starting with version 1.6, if type information is missing, the converter will convert the JSON using Jackson defaults (usually a map).
Also, starting with version 1.6, when using @RabbitListener
annotations (on methods), the inferred type information
is added to the MessageProperties
; this allows the converter to convert to the argument type of the target method.
This only applies if there is one parameter with no annotations or a single parameter with the @Payload
annotation.
Parameters of type Message
are ignored during the analysis.
Important | |
---|---|
By default, the inferred type information will override the inbound |
Note | |
---|---|
When converting from the |
@RabbitListener public void foo(Foo foo) {...} @RabbitListener public void foo(@Payload Foo foo, @Header("amqp_consumerQueue") String queue) {...} @RabbitListener public void foo(Foo foo, o.s.amqp.core.Message message) {...} @RabbitListener public void foo(Foo foo, o.s.messaging.Message<Foo> message) {...} @RabbitListener public void foo(Foo foo, String bar) {...} @RabbitListener public void foo(Foo foo, o.s.messaging.Message<?> message) {...}
In the first four cases above the converter will attempt to convert to the Foo
type.
The fifth example is invalid because we can’t determine which argument should receive the message payload.
With the sixth example, the Jackson defaults will apply due to the generic type being a WildcardType
.
You can, however, create a custom converter and use the targetMethod
message property to decide which type to convert
the JSON to.
Note | |
---|---|
This type inference can only be achieved when the |
Yet another option is the MarshallingMessageConverter
.
It delegates to the Spring OXM library’s implementations of the Marshaller
and Unmarshaller
strategy interfaces.
You can read more about that library here.
In terms of configuration, it’s most common to provide the constructor argument only since most implementations of Marshaller
will also implement Unmarshaller
.
<bean class="org.springframework.amqp.rabbit.core.RabbitTemplate"> <property name="connectionFactory" ref="rabbitConnectionFactory"/> <property name="messageConverter"> <bean class="org.springframework.amqp.support.converter.MarshallingMessageConverter"> <constructor-arg ref="someImplemenationOfMarshallerAndUnmarshaller"/> </bean> </property> </bean>
This class was introduced in version 1.4.2 and allows delegation to a specific MessageConverter
based on the content type property in the MessageProperties
.
By default, it will delegate to a SimpleMessageConverter
if there is no contentType
property, or a value that matches none of the configured converters.
<bean id="contentTypeConverter" class="ContentTypeDelegatingMessageConverter"> <property name="delegates"> <map> <entry key="application/json" value-ref="jsonMessageConverter" /> <entry key="application/xml" value-ref="xmlMessageConverter" /> </map> </property> </bean>
Important | |
---|---|
There is a possible vulnerability when deserializing java objects from untrusted sources. If you accept messages from untrusted sources with a By default, the white list is empty, meaning all classes will be deserialized. You can set a list of patterns, such as The patterns will be checked in order until a match is found.
If there is no match, a Set the patterns using the |
The MessagePropertiesConverter
strategy interface is used to convert between the Rabbit Client
BasicProperties
and Spring AMQP MessageProperties
. The default implementation
(DefaultMessagePropertiesConverter
) is usually sufficient for most purposes but you can implement your own if needed.
The default properties converter will convert BasicProperties
elements of type LongString
to String
s
when the size is not greater than 1024
bytes. Larger LongString
s are not converted (see below).
This limit can be overridden with a constructor argument.
Starting with version 1.6, headers longer than the long string limit (default 1024) are now left as
LongString
s by default by the DefaultMessagePropertiesConverter
.
You can access the contents via the getBytes[]
, toString()
, or getStream()
methods.
Previously, the DefaultMessagePropertiesConverter
"converted" such headers to a DataInputStream
(actually it just
referenced the LongString
's DataInputStream
).
On output, this header was not converted (except to a String, e.g. java.io.DataInputStream@1d057a39
by calling
toString()
on the stream).
Large incoming LongString
headers are now correctly "converted" on output too (by default).
A new constructor is provided to allow you to configure the converter to work as before:
/** * Construct an instance where LongStrings will be returned * unconverted or as a java.io.DataInputStream when longer than this limit. * Use this constructor with 'true' to restore pre-1.6 behavior. * @param longStringLimit the limit. * @param convertLongLongStrings LongString when false, * DataInputStream when true. * @since 1.6 */ public DefaultMessagePropertiesConverter(int longStringLimit, boolean convertLongLongStrings) { ... }
Also starting with version 1.6, a new property correlationIdString
has been added to MessageProperties
.
Previously, when converting to/from BasicProperties
used by the RabbitMQ client, an unnecessary byte[] <-> String
conversion was performed because MessageProperties.correlationId
is a byte[]
but BasicProperties
uses a
String
. (Ultimately, the RabbitMQ client uses UTF-8 to convert the String to bytes to put in the protocol message).
To provide maximum backwards compatibility, a new property correlationIdPolicy
has been added to the
DefaultMessagePropertiesConverter
.
This takes an DefaultMessagePropertiesConverter.CorrelationIdPolicy
enum argument.
By default it is set to BYTES
which replicates the previous behavior.
For inbound messages:
STRING
- just the correlationIdString
property is mapped
BYTES
- just the correlationId
property is mapped
BOTH
- both properties are mapped
For outbound messages:
STRING
- just the correlationIdString
property is mapped
BYTES
- just the correlationId
property is mapped
BOTH
- Both properties will be considered, with the String property taking precedence
Also starting with version 1.6, the inbound deliveryMode
property is no longer mapped to MessageProperties.deliveryMode
, it is mapped to MessageProperties.receivedDeliveryMode
instead.
Also, the inbound userId
property is no longer mapped to MessageProperties.userId
, it is mapped to MessageProperties.receivedUserId
instead.
These changes are to avoid unexpected propagation of these properties if the same MessageProperties
object is used for an outbound message.
A number of extension points exist where you can perform some processing on a message, either before it is sent to RabbitMQ, or immediately after it is received.
As can be seen in Section 3.1.7, “Message Converters”, one such extension point is in the AmqpTemplate
convertAndReceive
operations, where you can provide a MessagePostProcessor
.
For example, after your POJO has been converted, the MessagePostProcessor
enables you to set custom headers or properties on the Message
.
Starting with version 1.4.2, additional extension points have been added to the RabbitTemplate
- setBeforePublishPostProcessors()
and setAfterReceivePostProcessors()
.
The first enables a post processor to run immediately before sending to RabbitMQ. When using batching (see the section called “Batching”), this is invoked after the batch is assembled and before the batch is sent. The second is invoked immediately after a message is received.
These extension points are used for such features as compression and, for this purpose, several MessagePostProcessor
s are provided:
for compressing messages before sending, and
for decompressing received messages.
Similarly, the SimpleMessageListenerContainer
also has a setAfterReceivePostProcessors()
method, allowing the decompression to be performed after messages are received by the container.
The AmqpTemplate
also provides a variety of sendAndReceive
methods that accept the same argument options that you have seen above for the one-way send operations (exchange, routingKey, and Message).
Those methods are quite useful for request/reply scenarios since they handle the configuration of the necessary "reply-to" property before sending and can listen for the reply message on an exclusive Queue that is created internally for that purpose.
Similar request/reply methods are also available where the MessageConverter
is applied to both the request and reply.
Those methods are named convertSendAndReceive
.
See the Javadoc of AmqpTemplate
for more detail.
Starting with version 1.5.0, each of the sendAndReceive
method variants has an overloaded version that takes CorrelationData
.
Together with a properly configured connection factory, this enables the receipt of publisher confirms for the send side of the operation.
See the section called “Publisher Confirms and Returns” for more information.
By default, the send and receive methods will timeout after 5 seconds and return null.
This can be modified by setting the replyTimeout
property.
Starting with version 1.5, if you set the mandatory
property to true (or the mandatory-expression
evaluates to
true
for a particular message), if the message cannot be delivered to a queue an AmqpMessageReturnedException
will
be thrown.
This exception has returnedMessage
, replyCode
, replyText
properties, as well as the exchange
and
routingKey
used for the send.
Note | |
---|---|
This feature uses publisher returns and is enabled by setting |
Important | |
---|---|
Starting with version 3.4.0, the RabbitMQ server now supports Direct reply-to; this eliminates the main reason for a fixed reply queue (to avoid the need to create a temporary queue for each request).
Starting with Spring AMQP version 1.4.1 Direct reply-to will be used by default (if supported by the server) instead of creating temporary reply queues.
When no |
Reply listeners are still supported with named queues (other than amq.rabbitmq.reply-to
), allowing control of reply concurrency etc.
Starting with version 1.6 if, for some reason, you wish to use a temporary, exclusive, auto-delete queue for each
reply, set the useTemporaryReplyQueues
property to true
.
This property is ignored if you you set a replyAddress
.
The decision whether or not to use direct reply-to can be changed to use different criteria by subclassing
RabbitTemplate
and overriding useDirectReplyTo()
.
The method is called once only; when the first request is sent.
When using a fixed reply queue (other than amq.rabbitmq.reply-to
), it is necessary to provide correlation data so that replies can be correlated to requests.
See RabbitMQ Remote Procedure Call (RPC).
By default, the standard correlationId
property will be used to hold the correlation data.
However, if you wish to use a custom property to hold correlation data, you can set the correlation-key
attribute on the <rabbit-template/>.
Explicitly setting the attribute to correlationId
is the same as omitting the attribute.
Of course, the client and server must use the same header for correlation data.
Note | |
---|---|
Spring AMQP version 1.1 used a custom property |
When using RabbitMQ versions prior to 3.4.0, a new temporary queue is used for each reply. However, a single reply queue can be configured on the template, which can be more efficient, and also allows you to set arguments on that queue. In this case, however, you must also provide a <reply-listener/> sub element. This element provides a listener container for the reply queue, with the template being the listener. All of the Section 3.1.15, “Message Listener Container Configuration” attributes allowed on a <listener-container/> are allowed on the element, except for connection-factory and message-converter, which are inherited from the template’s configuration.
Important | |
---|---|
If you run multiple instances of your application or use multiple |
<rabbit:template id="amqpTemplate" connection-factory="connectionFactory" reply-queue="replies" reply-address="replyEx/routeReply"> <rabbit:reply-listener/> </rabbit:template>
While the container and template share a connection factory, they do not share a channel and therefore requests and replies are not performed within the same transaction (if transactional).
Note | |
---|---|
Prior to version 1.5.0, the |
With this configuration, a SimpleListenerContainer
is used to receive the replies; with the RabbitTemplate
being the MessageListener
.
When defining a template with the <rabbit:template/>
namespace element, as shown above, the parser defines the container and wires in the template as the listener.
Note | |
---|---|
When the template does not use a fixed |
If you define your RabbitTemplate
as a <bean/>
, or using an @Configuration
class to define it as an @Bean
, or when creating the template programmatically, you will need to define and wire up the reply listener container yourself.
If you fail to do this, the template will never receive the replies and will eventually time out and return null as the reply to a call to a sendAndReceive
method.
Starting with version 1.5, the RabbitTemplate
will detect if it has been
configured as a MessageListener
to receive replies.
If not, attempts to send and receive messages with a reply address
will fail with an IllegalStateException
(because the replies will never be received).
Further, if a simple replyAddress
(queue name) is used, the reply listener container will verify that it is listening
to a queue with the same name.
This check cannot be performed if the reply address is an exchange and routing key and a debug log message will be
written.
Important | |
---|---|
When wiring the reply listener and template yourself, it is important to ensure that the template’s |
The following are examples of how to manually wire up the beans.
<bean id="amqpTemplate" class="org.springframework.amqp.rabbit.core.RabbitTemplate"> <constructor-arg ref="connectionFactory" /> <property name="exchange" value="foo.exchange" /> <property name="routingKey" value="foo" /> <property name="replyQueue" ref="replyQ" /> <property name="replyTimeout" value="600000" /> </bean> <bean class="org.springframework.amqp.rabbit.listener.SimpleMessageListenerContainer"> <constructor-arg ref="connectionFactory" /> <property name="queues" ref="replyQ" /> <property name="messageListener" ref="amqpTemplate" /> </bean> <rabbit:queue id="replyQ" name="my.reply.queue" />
@Bean public RabbitTemplate amqpTemplate() { RabbitTemplate rabbitTemplate = new RabbitTemplate(connectionFactory()); rabbitTemplate.setMessageConverter(msgConv()); rabbitTemplate.setReplyQueue(replyQueue()); rabbitTemplate.setReplyTimeout(60000); return rabbitTemplate; } @Bean public SimpleMessageListenerContainer replyListenerContainer() { SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(); container.setConnectionFactory(connectionFactory()); container.setQueues(replyQueue()); container.setMessageListener(amqpTemplate()); return container; } @Bean public Queue replyQueue() { return new Queue("my.reply.queue"); }
A complete example of a RabbitTemplate
wired with a fixed reply queue, together with a "remote" listener container that handles the request and returns the reply is shown in this test case.
Important | |
---|---|
When the reply times out ( |
Prior to version 1.3.6, late replies for timed out messages were simply logged.
Now, if a late reply is received, it is rejected (the template throws an AmqpRejectAndDontRequeueException
).
If the reply queue is configured to send rejected messages to a dead letter exchange, the reply can be retrieved for later analysis.
Simply bind a queue to the configured dead letter exchange with a routing key equal to the reply queue’s name.
Refer to the RabbitMQ Dead Letter Documentation for more information about configuring dead lettering.
You can also take a look at the FixedReplyQueueDeadLetterTests
test case for an example.
Version 1.6 introduced the AsyncRabbitTemplate
.
This has similar sendAndReceive
(and convertSendAndReceive
) methods to those on the AmqpTemplate
but instead of blocking, they return a ListenableFuture
.
The sendAndReceive
methods return a RabbitMessageFuture
; the convertSendAndReceive
methods return a
RabbitConverterFuture
.
You can either synchronously retrieve the result later, by invoking get()
on the future, or you can register a
callback which will be called asynchronously with the result.
@Autowired private AsyncRabbitTemplate template; ... public void doSomeWorkAndGetResultLater() { ... ListenableFuture<String> future = this.template.convertSendAndReceive("foo"); // do some more work String reply = null; try { reply = future.get(); } catch (ExecutionException e) { ... } ... } public void doSomeWorkAndGetResultAsync() { ... RabbitConverterFuture<String> future = this.template.convertSendAndReceive("foo"); future.addCallback(new ListenableFutureCallback<String>() { @Override public void onSuccess(String result) { ... } @Override public void onFailure(Throwable ex) { ... } }); ... }
If mandatory
is set, and the message can’t be delivered, the future will throw an ExecutionException
with a cause of
AmqpMessageReturnedException
which encapsulates the returned message and information about the return.
If enableConfirms
is set, the future will have a property confirm
which is itself a ListenableFuture<Boolean>
with true
indicating a successful publish.
If the confirm future is false, the RabbitFuture
will have a further property nackCause
- the reason for the
failure, if available.
Important | |
---|---|
The publisher confirm is discarded if it is received after the reply - since the reply implies a successful publish. |
Set the receiveTimeout
property on the template to time out replies (it defaults to 30000
- 30 seconds).
If a timeout occurs, the future will be completed with an AmqpReplyTimeoutException
.
The template implements SmartLifecycle
; stopping the template while there are pending replies will cause the
pending Future
s to be canceled.
The Spring Framework has a general remoting capability, allowing Remote Procedure Calls (RPC) using various transports.
Spring-AMQP supports a similar mechanism with a AmqpProxyFactoryBean
on the client and a AmqpInvokerServiceExporter
on the server.
This provides RPC over AMQP.
On the client side, a RabbitTemplate
is used as described above; on the server side, the invoker (configured as a MessageListener
) receives the message, invokes the configured service, and returns the reply using the inbound message’s replyTo
information.
The client factory bean can be injected into any bean (using its serviceInterface
); the client can then invoke methods on the proxy, resulting in remote execution over AMQP.
Note | |
---|---|
With the default |
On the server side, the AmqpInvokerServiceExporter
has both AmqpTemplate
and MessageConverter
properties.
Currently, the template’s MessageConverter
is not used.
If you need to supply a custom message converter, then you should provide it using the messageConverter
property.
On the client side, a custom message converter can be added to the AmqpTemplate
which is provided to the AmqpProxyFactoryBean
using its amqpTemplate
property.
Sample client and server configurations are shown below.
<bean id="client" class="org.springframework.amqp.remoting.client.AmqpProxyFactoryBean"> <property name="amqpTemplate" ref="template" /> <property name="serviceInterface" value="foo.ServiceInterface" /> </bean> <rabbit:connection-factory id="connectionFactory" /> <rabbit:template id="template" connection-factory="connectionFactory" reply-timeout="2000" routing-key="remoting.binding" exchange="remoting.exchange" /> <rabbit:admin connection-factory="connectionFactory" /> <rabbit:queue name="remoting.queue" /> <rabbit:direct-exchange name="remoting.exchange"> <rabbit:bindings> <rabbit:binding queue="remoting.queue" key="remoting.binding" /> </rabbit:bindings> </rabbit:direct-exchange>
<bean id="listener" class="org.springframework.amqp.remoting.service.AmqpInvokerServiceExporter"> <property name="serviceInterface" value="foo.ServiceInterface" /> <property name="service" ref="service" /> <property name="amqpTemplate" ref="template" /> </bean> <bean id="service" class="foo.ServiceImpl" /> <rabbit:connection-factory id="connectionFactory" /> <rabbit:template id="template" connection-factory="connectionFactory" /> <rabbit:queue name="remoting.queue" /> <rabbit:listener-container connection-factory="connectionFactory"> <rabbit:listener ref="listener" queue-names="remoting.queue" /> </rabbit:listener-container>
Important | |
---|---|
The |
Note | |
---|---|
By default, if the request message cannot be delivered, the calling thread will eventually timeout and a
|
The AMQP specification describes how the protocol can be used to configure Queues, Exchanges and Bindings on the broker.
These operations which are portable from the 0.8 specification and higher are present in the AmqpAdmin
interface in the org.springframework.amqp.core
package.
The RabbitMQ implementation of that class is RabbitAdmin
located in the org.springframework.amqp.rabbit.core
package.
The AmqpAdmin interface is based on using the Spring AMQP domain abstractions and is shown below:
public interface AmqpAdmin { // Exchange Operations void declareExchange(Exchange exchange); void deleteExchange(String exchangeName); // Queue Operations Queue declareQueue(); String declareQueue(Queue queue); void deleteQueue(String queueName); void deleteQueue(String queueName, boolean unused, boolean empty); void purgeQueue(String queueName, boolean noWait); // Binding Operations void declareBinding(Binding binding); void removeBinding(Binding binding); Properties getQueueProperties(String queueName); }
The getQueueProperties()
method returns some limited information about the queue (message count and consumer count).
The keys for the properties returned are available as constants in the RabbitTemplate
(QUEUE_NAME
,
QUEUE_MESSAGE_COUNT
, QUEUE_CONSUMER_COUNT
).
The RabbitMQ REST API provides much more information in the QueueInfo
object.
The no-arg declareQueue()
method defines a queue on the broker with a name that is automatically generated.
The additional properties of this auto-generated queue are exclusive=true
, autoDelete=true
, and durable=false
.
The declareQueue(Queue queue)
method takes a Queue
object and returns the name of the declared queue.
If the provided Queue
's name
property is an empty String, the broker declares the queue with a generated name and
that name is returned to the caller.
The Queue
object itself is not changed.
This functionality can only be used programmatically by invoking the RabbitAdmin
directly.
It is not supported for auto-declaration by the admin by defining a queue declaratively in the application context.
This is in contrast to an AnonymousQueue
where the framework generates a unique (UUID
) name and sets durable
to
false
and exclusive
, autoDelete
to true
.
A <rabbit:queue/>
with an empty, or missing, name
attribute will always create an AnonymousQueue
.
See the section called “AnonymousQueue” to understand why AnonymousQueue
is preferred over broker-generated queue names, as well as
how to control the format of the name.
Declarative queues must have fixed names because they might be referenced elsewhere in the context, for example, in a
listener:
<rabbit:listener-container> <rabbit:listener ref="listener" queue-names="#{someQueue.name}" /> </rabbit:listener-container>
See the section called “Automatic Declaration of Exchanges, Queues and Bindings”.
The RabbitMQ implementation of this interface is RabbitAdmin which when configured using Spring XML would look like this:
<rabbit:connection-factory id="connectionFactory"/> <rabbit:admin id="amqpAdmin" connection-factory="connectionFactory"/>
When the CachingConnectionFactory
cache mode is CHANNEL
(the default), the RabbitAdmin
implementation does automatic lazy declaration of Queues
, Exchanges
and Bindings
declared in the same ApplicationContext
.
These components will be declared as s0on as a Connection
is opened to the broker.
There are some namespace features that make this very convenient, e.g.
in the Stocks sample application we have:
<rabbit:queue id="tradeQueue"/> <rabbit:queue id="marketDataQueue"/> <fanout-exchange name="broadcast.responses" xmlns="http://www.springframework.org/schema/rabbit"> <bindings> <binding queue="tradeQueue"/> </bindings> </fanout-exchange> <topic-exchange name="app.stock.marketdata" xmlns="http://www.springframework.org/schema/rabbit"> <bindings> <binding queue="marketDataQueue" pattern="${stocks.quote.pattern}"/> </bindings> </topic-exchange>
In the example above we are using anonymous Queues (actually internally just Queues with names generated by the framework, not by the broker) and refer to them by ID. We can also declare Queues with explicit names, which also serve as identifiers for their bean definitions in the context. E.g.
<rabbit:queue name="stocks.trade.queue"/>
Tip | |
---|---|
You can provide both an id and a name attribute. This allows you to refer to the queue (for example in a binding) by an id that is independent of the queue name. It also allows standard Spring features such as property placeholders, and SpEL expressions for the queue name; these features are not available when using the name as the bean identifier. |
Queues can be configured with additional arguments, for example, x-message-ttl or x-ha-policy.
Using the namespace support, they are provided in the form of a Map of argument name/argument value pairs, using the <rabbit:queue-arguments>
element.
<rabbit:queue name="withArguments"> <rabbit:queue-arguments> <entry key="x-ha-policy" value="all"/> </rabbit:queue-arguments> </rabbit:queue>
By default, the arguments are assumed to be strings. For arguments of other types, the type needs to be provided.
<rabbit:queue name="withArguments"> <rabbit:queue-arguments value-type="java.lang.Long"> <entry key="x-message-ttl" value="100"/> </rabbit:queue-arguments> </rabbit:queue>
When providing arguments of mixed types, the type is provided for each entry element:
<rabbit:queue name="withArguments"> <rabbit:queue-arguments> <entry key="x-message-ttl"> <value type="java.lang.Long">100</value> </entry> <entry key="x-ha-policy" value="all"/> </rabbit:queue-arguments> </rabbit:queue>
With Spring Framework 3.2 and later, this can be declared a little more succinctly:
<rabbit:queue name="withArguments"> <rabbit:queue-arguments> <entry key="x-message-ttl" value="100" value-type="java.lang.Long"/> <entry key="x-ha-policy" value="all"/> </rabbit:queue-arguments> </rabbit:queue>
Important | |
---|---|
The RabbitMQ broker will not allow declaration of a queue with mismatched arguments.
For example, if a |
By default, the RabbitAdmin
will immediately stop processing all declarations when any exception occurs; this could cause downstream issues - such as a listener container failing to initialize because another queue (defined after the one in error) is not declared.
This behavior can be modified by setting the ignore-declaration-exceptions
attribute to true
on the RabbitAdmin
.
This option instructs the RabbitAdmin
to log the exception, and continue declaring other elements.
When configuring the RabbitAdmin
using java, this property is ignoreDeclarationExceptions
.
This is a global setting which applies to all elements, queues, exchanges and bindings have a similar property which
applies to just those elements.
Prior to version 1.6, this property only took effect if an IOException
occurred on the channel - such as when there
is a mismatch between current and desired properties.
Now, this property takes effect on any exception, including TimeoutException
etc.
In addition, any declaration exceptions result in the publishing of a DeclarationExceptionEvent
, which is an
ApplicationEvent
that can be consumed by any ApplicationListener
in the context.
The event contains a reference to the admin, the element that was being declared, and the Throwable
.
Starting with version 1.3 the HeadersExchange
can be configured to match on multiple headers; you can also specify whether any or all headers must match:
<rabbit:headers-exchange name="headers-test"> <rabbit:bindings> <rabbit:binding queue="bucket"> <rabbit:binding-arguments> <entry key="foo" value="bar"/> <entry key="baz" value="qux"/> <entry key="x-match" value="all"/> </rabbit:binding-arguments> </rabbit:binding> </rabbit:bindings> </rabbit:headers-exchange>
Starting with version 1.6 Exchanges
can be configured with an internal
flag (defaults to false
) and such an
Exchange
will be properly configured on the Broker via a RabbitAdmin
(if one is present in the application context).
If the internal
flag is true
for an exchange, RabbitMQ will not allow clients to use the exchange.
This is useful for a dead letter exchange, or exchange-to-exchange binding, where you don’t wish the exchange to be used
directly by publishers.
To see how to use Java to configure the AMQP infrastructure, look at the Stock sample application,
where there is the @Configuration
class AbstractStockRabbitConfiguration
which in turn has
RabbitClientConfiguration
and RabbitServerConfiguration
subclasses.
The code for AbstractStockRabbitConfiguration
is shown below
@Configuration public abstract class AbstractStockAppRabbitConfiguration { @Bean public ConnectionFactory connectionFactory() { CachingConnectionFactory connectionFactory = new CachingConnectionFactory("localhost"); connectionFactory.setUsername("guest"); connectionFactory.setPassword("guest"); return connectionFactory; } @Bean public RabbitTemplate rabbitTemplate() { RabbitTemplate template = new RabbitTemplate(connectionFactory()); template.setMessageConverter(jsonMessageConverter()); configureRabbitTemplate(template); return template; } @Bean public MessageConverter jsonMessageConverter() { return new JsonMessageConverter(); } @Bean public TopicExchange marketDataExchange() { return new TopicExchange("app.stock.marketdata"); } // additional code omitted for brevity }
In the Stock application, the server is configured using the following @Configuration class:
@Configuration public class RabbitServerConfiguration extends AbstractStockAppRabbitConfiguration { @Bean public Queue stockRequestQueue() { return new Queue("app.stock.request"); } }
This is the end of the whole inheritance chain of @Configuration
classes.
The end result is the the TopicExchange and Queue will be declared to the broker upon application startup.
There is no binding of the TopicExchange to a queue in the server configuration, as that is done in the client application.
The stock request queue however is automatically bound to the AMQP default exchange - this behavior is defined by the specification.
The client @Configuration
class is a little more interesting and is shown below.
@Configuration public class RabbitClientConfiguration extends AbstractStockAppRabbitConfiguration { @Value("${stocks.quote.pattern}") private String marketDataRoutingKey; @Bean public Queue marketDataQueue() { return amqpAdmin().declareQueue(); } /** * Binds to the market data exchange. * Interested in any stock quotes * that match its routing key. */ @Bean public Binding marketDataBinding() { return BindingBuilder.bind( marketDataQueue()).to(marketDataExchange()).with(marketDataRoutingKey); } // additional code omitted for brevity }
The client is declaring another queue via the declareQueue()
method on the AmqpAdmin
, and it binds that queue to the market data exchange with a routing pattern that is externalized in a properties file.
Version 1.6 introduces a convenient fluent API for configuring Queue
and Exchange
objects when using Java configuration:
@Bean public Queue queue() { return QueueBuilder.nonDurable("foo") .autoDelete() .exclusive() .withArgument("foo", "bar") .build(); } @Bean public Exchange exchange() { return ExchangeBuilder.directExchange("foo") .autoDelete() .internal() .withArgument("foo", "bar") .build(); }
See the javadocs for org.springframework.amqp.core.QueueBuilder
and org.springframework.amqp.core.ExchangeBuilder
for more information.
Starting with version 1.5, it is now possible to declare multiple entities with one @Bean
, by returing a
collection.
Only collections where the first element is a Declarable
are considered, and only Declarable
elements from such
collections are processed.
@Configuration public static class Config { @Bean public ConnectionFactory cf() { return new CachingConnectionFactory("localhost"); } @Bean public RabbitAdmin admin(ConnectionFactory cf) { return new RabbitAdmin(cf); } @Bean public DirectExchange e1() { return new DirectExchange("e1", false, true); } @Bean public Queue q1() { return new Queue("q1", false, false, true); } @Bean public Binding b1() { return BindingBuilder.bind(q1()).to(e1()).with("k1"); } @Bean public List<Exchange> es() { return Arrays.<Exchange>asList( new DirectExchange("e2", false, true), new DirectExchange("e3", false, true) ); } @Bean public List<Queue> qs() { return Arrays.asList( new Queue("q2", false, false, true), new Queue("q3", false, false, true) ); } @Bean public List<Binding> bs() { return Arrays.asList( new Binding("q2", DestinationType.QUEUE, "e2", "k2", null), new Binding("q3", DestinationType.QUEUE, "e3", "k3", null) ); } @Bean public List<Declarable> ds() { return Arrays.<Declarable>asList( new DirectExchange("e4", false, true), new Queue("q4", false, false, true), new Binding("q4", DestinationType.QUEUE, "e4", "k4", null) ); } }
By default, all queues, exchanges, and bindings are declared by all RabbitAdmin
instances (that have auto-startup="true"
) in the application context.
Note | |
---|---|
Starting with the 1.2 release, it is possible to conditionally declare these elements. This is particularly useful when an application connects to multiple brokers and needs to specify with which broker(s) a particular element should be declared. |
The classes representing these elements implement Declarable
which has two methods: shouldDeclare()
and getDeclaringAdmins()
.
The RabbitAdmin
uses these methods to determine whether a particular instance should actually process the declarations on its Connection
.
The properties are available as attributes in the namespace, as shown in the following examples.
<rabbit:admin id="admin1" connection-factory="CF1" /> <rabbit:admin id="admin2" connection-factory="CF2" /> <rabbit:queue id="declaredByBothAdminsImplicitly" /> <rabbit:queue id="declaredByBothAdmins" declared-by="admin1, admin2" /> <rabbit:queue id="declaredByAdmin1Only" declared-by="admin1" /> <rabbit:queue id="notDeclaredByAny" auto-declare="false" /> <rabbit:direct-exchange name="direct" declared-by="admin1, admin2"> <rabbit:bindings> <rabbit:binding key="foo" queue="bar"/> </rabbit:bindings> </rabbit:direct-exchange>
Note | |
---|---|
The |
Similarly, you can use Java-based @Configuration
to achieve the same effect.
In this example, the components will be declared by admin1
but not admin2
:
@Bean public RabbitAdmin admin() { RabbitAdmin rabbitAdmin = new RabbitAdmin(cf1()); rabbitAdmin.afterPropertiesSet(); return rabbitAdmin; } @Bean public RabbitAdmin admin2() { RabbitAdmin rabbitAdmin = new RabbitAdmin(cf2()); rabbitAdmin.afterPropertiesSet(); return rabbitAdmin; } @Bean public Queue queue() { Queue queue = new Queue("foo"); queue.setAdminsThatShouldDeclare(admin()); return queue; } @Bean public Exchange exchange() { DirectExchange exchange = new DirectExchange("bar"); exchange.setAdminsThatShouldDeclare(admin()); return exchange; } @Bean public Binding binding() { Binding binding = new Binding("foo", DestinationType.QUEUE, exchange().getName(), "foo", null); binding.setAdminsThatShouldDeclare(admin()); return binding; }
In general, when needing a uniquely-named, exclusive, auto-delete queue, it is recommended that the AnonymousQueue
is
used instead of broker-defined queue names (using ""
as a Queue
name will cause the broker to generate the queue
name).
This is because:
AnonymousQueue
with the same
name.
If we used broker-declared queues, the queue name would change.
Starting with version 1.5.3, you can control the format of the queue name used by AnonymousQueue
s.
By default, the queue name is the String representation of a UUID
; for example:
07afcfe9-fe77-4983-8645-0061ec61a47a
.
You can now provide an AnonymousQueue.NamingStrategy
implementation in a constructor argument:
@Bean public Queue anon1() { return new AnonymousQueue(new AnonymousQueue.Base64UrlNamingStrategy()); } @Bean public Queue anon2() { return new AnonymousQueue(new AnonymousQueue.Base64UrlNamingStrategy("foo-")); }
The first will generate a queue name prefixed by spring.gen-
followed by a base64 representation of the UUID
, for
example: spring.gen-MRBv9sqISkuCiPfOYfpo4g
.
The second will generate a queue name prefixed by foo-
followed by a base64 representation of the UUID
.
The base64 encoding uses the "URL and Filename Safe Alphabet" from RFC 4648; trailing padding characters (=
) are
removed.
You can provide your own naming strategy, whereby you can include other information (e.g. application, client host) in the queue name.
Starting with version 1.6, the naming strategy can be specified when using XML configuration;
the naming-strategy
attribute is present on the <rabbit:queue>
element
for a bean reference that implements AnonymousQueue.NamingStrategy
.
<rabbit:queue id="uuidAnon" /> <rabbit:queue id="springAnon" naming-strategy="springNamer" /> <rabbit:queue id="customAnon" naming-strategy="customNamer" /> <bean id="springNamer" class="org.springframework.amqp.core.AnonymousQueue.Base64UrlNamingStrategy" /> <bean id="customNamer" class="org.springframework.amqp.core.AnonymousQueue.Base64UrlNamingStrategy"> <constructor-arg value="custom.gen-" /> </bean>
The first creates names with a String representation of a UUID.
The second creates names like spring.gen-MRBv9sqISkuCiPfOYfpo4g
.
The third creates names like custom.gen-MRBv9sqISkuCiPfOYfpo4g
.
Of course, you can provide your own naming strategy bean.
Version 1.6 introduces support for the Delayed Message Exchange Plugin
Note | |
---|---|
The plugin is currently marked as experimental but has been available for over a year (at the time of writing). If changes to the plugin make it necessary, we will add support for such changes as soon as practical. For that reason, this support in Spring AMQP should be considered experimental, too. This functionality was tested with RabbitMQ 3.6.0 and version 0.0.1 of the plugin. |
To use a RabbitAdmin
to declare an exchange as delayed, simply set the delayed
property on the exchange bean to
true.
The RabbitAdmin
will use the exchange type (Direct
, Fanout
etc) to set the x-delayed-type
argument and
declare the exchange with type x-delayed-message
.
The delayed
property (default false
) is also available when configuring exchange beans using XML.
<rabbit:topic-exchange name="topic" delayed="true" />
To send a delayed message, it’s simply a matter of setting the x-delay
header, via the MessageProperties
:
MessageProperties properties = new MessageProperties(); properties.setDelay(15000); template.send(exchange, routingKey, MessageBuilder.withBody("foo".getBytes()).andProperties(properties).build());
or
rabbitTemplate.convertAndSend(exchange, routingKey, "foo", new MessagePostProcessor() { @Override public Message postProcessMessage(Message message) throws AmqpException { message.getMessageProperties().setDelay(15000); return message; } });
To check if a message was delayed, use the getReceivedDelay()
method on the MessageProperties
.
It is a separate property to avoid unintended propagation to an output message generated from an input message.
When the management plugin is enabled, the RabbitMQ server exposes a REST API to monitor and configure the broker.
A Java Binding for the API is now provided.
In general, you can use that API directly, but a convenience wrapper is provided to use the familiar Spring AMQP Queue
, Exchange
, and Binding
domain objects with the API.
Much more information is available for these objects when using the com.rabbitmq.http.client.Client
API directly
(QueueInfo
, ExchangeInfo
, and BindingInfo
respectively).
The following operations are available on the RabbitManagementTemplate
:
public interface AmqpManagementOperations { void addExchange(Exchange exchange); void addExchange(String vhost, Exchange exchange); void purgeQueue(Queue queue); void purgeQueue(String vhost, Queue queue); void deleteQueue(Queue queue); void deleteQueue(String vhost, Queue queue); Queue getQueue(String name); Queue getQueue(String vhost, String name); List<Queue> getQueues(); List<Queue> getQueues(String vhost); void addQueue(Queue queue); void addQueue(String vhost, Queue queue); void deleteExchange(Exchange exchange); void deleteExchange(String vhost, Exchange exchange); Exchange getExchange(String name); Exchange getExchange(String vhost, String name); List<Exchange> getExchanges(); List<Exchange> getExchanges(String vhost); List<Binding> getBindings(); List<Binding> getBindings(String vhost); List<Binding> getBindingsForExchange(String vhost, String exchange); }
Refer to the javadocs for more information.
Many operations with the RabbitMQ Java client can throw checked Exceptions. For example, there are a lot of cases where IOExceptions may be thrown. The RabbitTemplate, SimpleMessageListenerContainer, and other Spring AMQP components will catch those Exceptions and convert into one of the Exceptions within our runtime hierarchy. Those are defined in the org.springframework.amqp package, and AmqpException is the base of the hierarchy.
When a listener throws an exception, it is wrapped in a ListenerExecutionFailedException
and, normally the message is
rejected and requeued by the broker.
Setting defaultRequeueRejected
to false will cause messages to be discarded (or routed to a dead letter exchange).
As discussed in the section called “Message Listeners and the Asynchronous Case”, the listener can throw an AmqpRejectAndDontRequeueException
to conditionally
control this behavior.
However, there is a class of errors where the listener cannot control the behavior.
When a message that cannot be converted is encountered (for example an invalid content_encoding
header), some
exceptions are thrown before the message reaches user code.
With defaultRequeueRejected
set to true
(default), such messages would be redelivered over and over.
Before version 1.3.2, users needed to write a custom ErrorHandler
, as discussed in Section 3.1.13, “Exception Handling” to avoid
this situation.
Starting with version 1.3.2, the default ErrorHandler
is now a ConditionalRejectingErrorHandler
which will reject
(and not requeue) messages that fail with an irrecoverable error:
o.s.amqp...MessageConversionException
o.s.messaging...MessageConversionException
o.s.messaging...MethodArgumentNotValidException
o.s.messaging...MethodArgumentTypeMismatchException
java.lang.NoSuchMethodException
java.lang.ClassCastException
The first can be thrown when converting the incoming message payload using a MessageConverter
.
The second may be thrown by the conversion service if additional conversion is required when mapping to a
@RabbitListener
method.
The third may be thrown if validation (e.g. @Valid
) is used in the listener and the validation fails.
The fourth may be thrown if the inbound message was converted to a type that is not correct for the target method.
For example, the parameter is declared as Message<Foo>
but Message<Bar>
is received.
The fifth and sixth were added in version 1.6.3.
An instance of this error handler can be configured with a FatalExceptionStrategy
so users can provide their own rules
for conditional message rejection, e.g.
a delegate implementation to the BinaryExceptionClassifier
from Spring Retry (the section called “Message Listeners and the Asynchronous Case”).
In addition, the ListenerExecutionFailedException
now has a failedMessage
property which can be used in the decision.
If the FatalExceptionStrategy.isFatal()
method returns true
, the error handler throws an AmqpRejectAndDontRequeueException
.
The default FatalExceptionStrategy
logs a warning message when an exception is determined to be fatal.
Since version 1.6.3 a convenient way to add user exceptions to the fatal list is to subclass ConditionalRejectingErrorHandler.DefaultExceptionStrategy
and override the method isUserCauseFatal(Throwable cause)
to return true for fatal exceptions.
The Spring Rabbit framework has support for automatic transaction management in the synchronous and asynchronous use cases with a number of different semantics that can be selected declaratively, as is familiar to existing users of Spring transactions. This makes many if not most common messaging patterns very easy to implement.
There are two ways to signal the desired transaction semantics to the framework.
In both the RabbitTemplate
and SimpleMessageListenerContainer
there is a flag channelTransacted
which, if true, tells the framework to use a transactional channel and to end all operations (send or receive) with a commit or rollback depending on the outcome, with an exception signaling a rollback.
Another signal is to provide an external transaction with one of Spring’s PlatformTransactionManager
implementations as a context for the ongoing operation.
If there is already a transaction in progress when the framework is sending or receiving a message, and the channelTransacted
flag is true, then the commit or rollback of the messaging transaction will be deferred until the end of the current transaction.
If the channelTransacted
flag is false, then no transaction semantics apply to the messaging operation (it is auto-acked).
The channelTransacted
flag is a configuration time setting: it is declared and processed once when the AMQP components are created, usually at application startup.
The external transaction is more dynamic in principle because the system responds to the current Thread state at runtime, but in practice is often also a configuration setting, when the transactions are layered onto an application declaratively.
For synchronous use cases with RabbitTemplate
the external transaction is provided by the caller, either declaratively or imperatively according to taste (the usual Spring transaction model).
An example of a declarative approach (usually preferred because it is non-invasive), where the template has been configured with channelTransacted=true
:
@Transactional public void doSomething() { String incoming = rabbitTemplate.receiveAndConvert(); // do some more database processing... String outgoing = processInDatabaseAndExtractReply(incoming); rabbitTemplate.convertAndSend(outgoing); }
A String payload is received, converted and sent as a message body inside a method marked as @Transactional, so if the database processing fails with an exception, the incoming message will be returned to the broker, and the outgoing message will not be sent.
This applies to any operations with the RabbitTemplate
inside a chain of transactional methods (unless the Channel
is directly manipulated to commit the transaction early for instance).
For asynchronous use cases with SimpleMessageListenerContainer
if an external transaction is needed it has to be requested by the container when it sets up the listener.
To signal that an external transaction is required the user provides an implementation of PlatformTransactionManager
to the container when it is configured.
For example:
@Configuration public class ExampleExternalTransactionAmqpConfiguration { @Bean public SimpleMessageListenerContainer messageListenerContainer() { SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(); container.setConnectionFactory(rabbitConnectionFactory()); container.setTransactionManager(transactionManager()); container.setChannelTransacted(true); container.setQueueName("some.queue"); container.setMessageListener(exampleListener()); return container; } }
In the example above, the transaction manager is added as a dependency injected from another bean definition (not shown), and the channelTransacted
flag is also set to true.
The effect is that if the listener fails with an exception the transaction will be rolled back, and the message will also be returned to the broker.
Significantly, if the transaction fails to commit (e.g.
a database constraint error, or connectivity problem), then the AMQP transaction will also be rolled back, and the message will be returned to the broker.
This is sometimes known as a Best Efforts 1 Phase Commit, and is a very powerful pattern for reliable messaging.
If the channelTransacted
flag was set to false in the example above, which is the default, then the external transaction would still be provided for the listener, but all messaging operations would be auto-acked, so the effect is to commit the messaging operations even on a rollback of the business operation.
Prior to version 1.6.6, adding a rollback rule to a container’s transactionAttribute
, when using an external transaction manager (e.g. JDBC) had no effect; exceptions always rolled back the transaction.
Also, when using a transaction advice in the container’s advice chain, conditional rollback was not very useful because all listener exceptions are wrapped in a ListenerExecutionFailedException
.
The first problem has been corrected and the rules are now applied properly.
Further, the ListenerFailedRuleBasedTransactionAttribute
is now provided; it is a subclass of RuleBasedTransactionAttribute
, with the only difference being that it is aware of the ListenerExecutionFailedException
and uses the cause of such exceptions for the rule.
This transaction attribute can be used directly in the container, or via a transaction advice.
An example of using this rule follows:
@Bean public AbstractMessageListenerContainer container() { ... container.setTransactionManager(transactionManager); RuleBasedTransactionAttribute transactionAttribute = new ListenerFailedRuleBasedTransactionAttribute(); transactionAttribute.setRollbackRules(Collections.singletonList( new NoRollbackRuleAttribute(DontRollBackException.class))); container.setTransactionAttribute(transactionAttribute); ... }
AMQP transactions only apply to messages and acks sent to the broker, so when there is a rollback of a Spring transaction and a message has been received, what Spring AMQP has to do is not just rollback the transaction, but also manually reject the message (sort of a nack, but that’s not what the specification calls it).
The action taken on message rejection is independent of transactions and depends on the defaultRequeueRejected
property (default true
).
For more information about rejecting failed messages, see the section called “Message Listeners and the Asynchronous Case”.
For more information about RabbitMQ transactions, and their limitations, refer to RabbitMQ Broker Semantics.
Note | |
---|---|
Prior to RabbitMQ 2.7.0, such messages (and any that are unacked when a channel is closed or aborts) went to the back of the queue on a Rabbit broker, since 2.7.0, rejected messages go to the front of the queue, in a similar manner to JMS rolled back messages. |
The RabbitTransactionManager is an alternative to executing Rabbit operations within, and synchronized with, external transactions. This Transaction Manager is an implementation of the PlatformTransactionManager interface and should be used with a single Rabbit ConnectionFactory.
Important | |
---|---|
This strategy is not able to provide XA transactions, for example in order to share transactions between messaging and database access. |
Application code is required to retrieve the transactional Rabbit resources via ConnectionFactoryUtils.getTransactionalResourceHolder(ConnectionFactory, boolean)
instead of a standard Connection.createChannel()
call with subsequent Channel creation.
When using Spring AMQP’s RabbitTemplate, it will autodetect a thread-bound Channel and automatically participate in its transaction.
With Java Configuration you can setup a new RabbitTransactionManager using:
@Bean public RabbitTransactionManager rabbitTransactionManager() { return new RabbitTransactionManager(connectionFactory); }
If you prefer using XML configuration, declare the following bean in your XML Application Context file:
<bean id="rabbitTxManager" class="org.springframework.amqp.rabbit.transaction.RabbitTransactionManager"> <property name="connectionFactory" ref="connectionFactory"/> </bean>
There are quite a few options for configuring a SimpleMessageListenerContainer
related to transactions and quality of service, and some of them interact with each other.
The table below shows the container property names and their equivalent attribute names (in parentheses) when using the namespace to configure a <rabbit:listener-container/>
.
Some properties are not exposed by the namespace; indicated by N/A
for the attribute.
Table 3.3. Configuration options for a message listener container
Property (Attribute) | Description | ||||||
---|---|---|---|---|---|---|---|
(group) | This is only available when using the namespace.
When specified, a bean of type | ||||||
channelTransacted (channel-transacted) | Boolean flag to signal that all messages should be acknowledged in a transaction (either manually or automatically) | ||||||
acknowledgeMode (acknowledge) |
| ||||||
transactionManager (transaction-manager) | External transaction manager for the operation of the listener.
Also complementary to channelTransacted - if the | ||||||
prefetchCount (prefetch) | The number of messages to accept from the broker in one socket frame.
The higher this is the faster the messages can be delivered, but the higher the risk of non-sequential processing.
Ignored if the | ||||||
shutdownTimeout (N/A) | When a container shuts down (e.g.
if its enclosing | ||||||
txSize (transaction-size) | When used with | ||||||
receiveTimeout (receive-timeout) | The maximum time to wait for each message.
If acknowledgeMode=NONE this has very little effect - the container just spins round and asks for another message.
It has the biggest effect for a transactional | ||||||
autoStartup (auto-startup) | Flag to indicate that the container should start when the | ||||||
phase (phase) | When autoStartup is true, the lifecycle phase within which this container should start and stop. The lower the value the earlier this container will start and the later it will stop. The default is Integer.MAX_VALUE meaning the container will start as late as possible and stop as soon as possible. | ||||||
adviceChain (advice-chain) | An array of AOP Advice to apply to the listener execution.
This can be used to apply additional cross cutting concerns such as automatic retry in the event of broker death.
Note that simple re-connection after an AMQP error is handled by the | ||||||
taskExecutor (task-executor) | A reference to a Spring TaskExecutor (or standard JDK 1.5+ Executor) for executing listener invokers. Default is a SimpleAsyncTaskExecutor, using internally managed threads. | ||||||
errorHandler (error-handler) | A reference to an ErrorHandler strategy for handling any uncaught Exceptions that may occur during the execution of the MessageListener.
Default: | ||||||
concurrentConsumers (concurrency) | The number of concurrent consumers to initially start for each listener. See Section 3.1.16, “Listener Concurrency”. | ||||||
maxConcurrentConsumers (max-concurrency) | The maximum number of concurrent consumers to start, if needed, on demand. Must be greater than or equal to concurrentConsumers. See Section 3.1.16, “Listener Concurrency”. | ||||||
startConsumerMinInterval (min-start-interval) | The time in milliseconds which must elapse before each new consumer is started on demand. See Section 3.1.16, “Listener Concurrency”. Default 10000 (10 seconds). | ||||||
stopConsumerMinInterval (min-stop-interval) | The time in milliseconds which must elapse before a consumer is stopped, since the last consumer was stopped, when an idle consumer is detected. See Section 3.1.16, “Listener Concurrency”. Default 60000 (1 minute). | ||||||
consecutiveActiveTrigger (min-consecutive-active) | The minimum number of consecutive messages received by a consumer, without a receive timeout occurring, when considering starting a new consumer. Also impacted by txSize. See Section 3.1.16, “Listener Concurrency”. Default 10. | ||||||
consecutiveIdleTrigger (min-consecutive-idle) | The minimum number of receive timeouts a consumer must experience before considering stopping a consumer. Also impacted by txSize. See Section 3.1.16, “Listener Concurrency”. Default 10. | ||||||
connectionFactory (connection-factory) | A reference to the | ||||||
defaultRequeueRejected (requeue-rejected) | Determines whether messages that are rejected because the listener threw an exception should be requeued or not. Default true. | ||||||
recoveryInterval (recovery-interval) | Determines the time in milliseconds between attempts to start a consumer if it fails to start for non-fatal reasons.
Default 5000.
Mutually exclusive with | ||||||
recoveryBackOff (recovery-back-off) | Specifies the | ||||||
exclusive (exclusive) | Determines whether the single consumer in this container has exclusive access to the queue(s).
The concurrency of the container must be 1 when this is true.
If another consumer has exclusive access, the container will attempt to recover the consumer, according to the
| ||||||
rabbitAdmin (admin) | When a listener container listens to at least one auto-delete queue and it is found to be missing during startup, the container uses a | ||||||
missingQueuesFatal (missing-queues-fatal) | Starting with version 1.3.5, When set to This was not configurable in previous versions. When set to You can also use a properties bean to set the property globally for all containers, as follows: <util:properties id="spring.amqp.global.properties"> <prop key="smlc.missing.queues.fatal">false</prop> </util:properties> This global property will not be applied to any containers that have an explicit The default retry properties (3 retries at 5 second intervals) can be overridden using the properties below. | ||||||
mismatchedQueuesFatal (mismatched-queues-fatal) | This was added in version 1.6.
When the container starts, if this property is true (default: false), the container checks that all queues declared in
the context are compatible with queues already on the broker.
If mismatched properties (e.g. If the problem is detected during recovery (e.g. after a lost connection), the container will be stopped. There must be a single
| ||||||
autoDeclare (auto-declare) | Starting with version 1.4, When set to
| ||||||
declarationRetries (declaration-retries) | Starting with versions 1.4.3, 1.3.9, The number of retry attempts when passive queue declaration fails. Passive queue declaration occurs when the consumer starts or, when consuming from multiple queues, when not all queues were available during initialization. When none of the configured queues can be passively declared (for any reason) after the retries are exhausted, the container behavior is controlled by the 'missingQueuesFatal` property above. Default: 3 retries (4 attempts). | ||||||
failedDeclarationRetryInterval (failed-declaration-retry- interval) | Starting with versions 1.4.3, 1.3.9, The interval between passive queue declaration retry attempts. Passive queue declaration occurs when the consumer starts or, when consuming from multiple queues, when not all queues were available during initialization. Default: 5000 (5 seconds). | ||||||
retryDeclarationInterval (missing-queue-retry- interval) | Starting with versions 1.4.3, 1.3.9, If a subset of the configured queues are available during consumer initialization, the consumer starts consuming from those queues. The consumer will attempt to passively declare the missing queues using this interval. When this interval elapses, the declarationRetries and failedDeclarationRetryInterval will again be used. If there are still missing queues, the consumer will again wait for this interval before trying again. This process will continue indefinitely until all queues are available. Default: 60000 (1 minute). | ||||||
consumerTagStrategy (consumer-tag-strategy) | Starting with version 1.4.5, Previously, only broker-generated consumer tags can be used; while this is still the default, you can now provide an implementation of ConsumerTagStrategy, enabling the creation of a (unique) tag for each consumer. | ||||||
idleEventInterval (idle-event-integer) | Starting with version 1.6, |
By default, the listener container will start a single consumer which will receive messages from the queue(s).
When examining the table in the previous section, you will see a number of properties/attributes that control concurrency.
The simplest is concurrentConsumers
, which simply creates that (fixed) number of consumers which will concurrently process messages.
Prior to version 1.3.0, this was the only setting available and the container had to be stopped and started again to change the setting.
Since version 1.3.0, you can now dynamically adjust the concurrentConsumers
property.
If it is changed while the container is running, consumers will be added or removed as necessary to adjust to the new setting.
In addition, a new property maxConcurrentConsumers
has been added and the container will dynamically adjust the concurrency based on workload.
This works in conjunction with four additional properties: consecutiveActiveTrigger
, startConsumerMinInterval
, consecutiveIdleTrigger
, stopConsumerMinInterval
.
With the default settings, the algorithm to increase consumers works as follows:
If the maxConcurrentConsumers
has not been reached and an existing consumer is active for 10 consecutive cycles AND at least 10 seconds has elapsed since the last consumer was started, a new consumer is started.
A consumer is considered active if it received at least one message in txSize
* receiveTimeout
milliseconds.
With the default settings, the algorithm to decrease consumers works as follows:
If there are more than concurrentConsumers
running and a consumer detects 10 consecutive timeouts (idle) AND the last consumer was stopped at least 60 seconds ago, a consumer will be stopped.
The timeout depends on the receiveTimeout
and the txSize
properties.
A consumer is considered idle if it receives no messages in txSize
* receiveTimeout
milliseconds.
So, with the default timeout (1 second) and a txSize
of 4, stopping a consumer will be considered after 40 seconds of idle time (4 timeouts correspond to 1 idle detection).
Note | |
---|---|
Practically, consumers will only be stopped if the whole container is idle for some time. This is because the broker will share its work across all the active consumers. |
Also starting with version 1.3, the listener container can be configured with a single exclusive consumer; this prevents other containers from consuming from the queue(s) until the current consumer is cancelled. The concurrency of such a container must be 1.
When using exclusive consumers, other containers will attempt to consume from the queue(s) according to the recoveryInterval
property, and log a WARNing if the attempt fails.
version 1.3 introduced a number of improvements for handling multiple queues in a listener container.
The container must be configured to listen on at least one queue; this was the case previously too, but now queues can be added and removed at runtime.
The container will recycle (cancel and re-create) the consumers when any pre-fetched messages have been processed.
See methods addQueues
, addQueueNames
, removeQueues
and removeQueueNames
.
When removing queues, at least one queue must remain.
A consumer will now start if any of its queues are available - previously the container would stop if any queues were unavailable. Now, this is only the case if none of the queues are available. If not all queues are available, the container will attempt to passively declare (and consume from) the missing queue(s) every 60 seconds.
Also, if a consumer receives a cancel from the broker (for example if a queue is deleted) the consumer will attempt to recover and the recovered consumer will continue to process messages from any other configured queues. Previously a cancel on one queue cancelled the entire consumer and eventually the container would stop due to the missing queue.
If you wish to permanently remove a queue, you should update the container before or after deleting to queue, to avoid future attempts to consume from it.
Some of the key (and most popular) high-level features that Spring AMQP provides are to do with recovery and automatic re-connection in the event of a protocol error or broker failure. We have seen all the relevant components already in this guide, but it should help to bring them all together here and call out the features and recovery scenarios individually.
The primary reconnection features are enabled by the CachingConnectionFactory
itself.
It is also often beneficial to use the RabbitAdmin
auto-declaration features.
In addition, if you care about guaranteed delivery, you probably also need to use the channelTransacted
flag in RabbitTemplate
and SimpleMessageListenerContainer
and also the AcknowledgeMode.AUTO
(or manual if you do the acks yourself) in the SimpleMessageListenerContainer
.
The RabbitAdmin
component can declare exchanges, queues and bindings on startup.
It does this lazily, through a ConnectionListener
, so if the broker is not present on startup it doesn’t matter.
The first time a Connection
is used (e.g.
by sending a message) the listener will fire and the admin features will be applied.
A further benefit of doing the auto declarations in a listener is that if the connection is dropped for any reason (e.g.
broker death, network glitch, etc.) they will be applied again when the connection is re-established.
Note | |
---|---|
Queues declared this way must have fixed names; either explicitly declared, or generated by the framework for |
Important | |
---|---|
Automatic declaration is only performed when the |
See also the section called “RabbitMQ Automatic Connection/Topology recovery”.
If you lose your connection to the broker in a synchronous sequence using RabbitTemplate
(for instance), then Spring AMQP will throw an AmqpException
(usually but not always AmqpIOException
).
We don’t try to hide the fact that there was a problem, so you have to be able to catch and respond to the exception.
The easiest thing to do if you suspect that the connection was lost, and it wasn’t your fault, is to simply try the operation again.
You can do this manually, or you could look at using Spring Retry to handle the retry (imperatively or declaratively).
Spring Retry provides a couple of AOP interceptors and a great deal of flexibility to specify the parameters of the retry (number of attempts, exception types, backoff algorithm etc.).
Spring AMQP also provides some convenience factory beans for creating Spring Retry interceptors in a convenient form for AMQP use cases, with strongly typed callback interfaces for you to implement custom recovery logic.
See the Javadocs and properties of StatefulRetryOperationsInterceptor
and StatelessRetryOperationsInterceptor
for more detail.
Stateless retry is appropriate if there is no transaction or if a transaction is started inside the retry callback.
Note that stateless retry is simpler to configure and analyse than stateful retry, but it is not usually appropriate if there is an ongoing transaction which must be rolled back or definitely is going to roll back.
A dropped connection in the middle of a transaction should have the same effect as a rollback, so for reconnection where the transaction is started higher up the stack, stateful retry is usually the best choice.
Starting with version 1.3, a builder API is provided to aid in assembling these interceptors using Java (or in @Configuration
classes), for example:
@Bean public StatefulRetryOperationsInterceptor interceptor() { return RetryInterceptorBuilder.stateful() .maxAttempts(5) .backOffOptions(1000, 2.0, 10000) // initialInterval, multiplier, maxInterval .build(); }
Only a subset of retry capabilities can be configured this way; more advanced features would need the configuration of a RetryTemplate
as a Spring bean.
See the Spring Retry Javadocs for complete information about available policies and their configuration.
If a MessageListener
fails because of a business exception, the exception is handled by the message listener container and then it goes back to listening for another message.
If the failure is caused by a dropped connection (not a business exception), then the consumer that is collecting messages for the listener has to be cancelled and restarted.
The SimpleMessageListenerContainer
handles this seamlessly, and it leaves a log to say that the listener is being restarted.
In fact it loops endlessly trying to restart the consumer, and only if the consumer is very badly behaved indeed will it give up.
One side effect is that if the broker is down when the container starts, it will just keep trying until a connection can be established.
Business exception handling, as opposed to protocol errors and dropped connections, might need more thought and some custom configuration, especially if transactions and/or container acks are in use.
Prior to 2.8.x, RabbitMQ had no definition of dead letter behaviour, so by default a message that is rejected or rolled back because of a business exception can be redelivered ad infinitum.
To put a limit in the client on the number of re-deliveries, one choice is a StatefulRetryOperationsInterceptor
in the advice chain of the listener.
The interceptor can have a recovery callback that implements a custom dead letter action: whatever is appropriate for your particular environment.
Another alternative is to set the container’s rejectRequeued property to false. This causes all failed messages to be discarded. When using RabbitMQ 2.8.x or higher, this also facilitates delivering the message to a Dead Letter Exchange.
Or, you can throw a AmqpRejectAndDontRequeueException
; this prevents message requeuing, regardless of the setting of the defaultRequeueRejected
property.
Often, a combination of both techniques will be used.
Use a StatefulRetryOperationsInterceptor
in the advice chain, where it’s MessageRecover
throws an AmqpRejectAndDontRequeueException
.
The MessageRecover
is called when all retries have been exhausted.
The default MessageRecoverer
simply consumes the errant message and emits a WARN message.
In which case, the message is ACK’d and won’t be sent to the Dead Letter Exchange, if any.
Starting with version 1.3, a new RepublishMessageRecoverer
is provided, to allow publishing of failed messages after
retries are exhausted:
@Bean RetryOperationsInterceptor interceptor() { return RetryInterceptorBuilder.stateless() .maxAttempts(5) .recoverer(new RepublishMessageRecoverer(amqpTemplate(), "bar", "baz")) .build(); }
The RepublishMessageRecoverer
publishes the message with additional information in message headers, such as the
exception message, stack trace, original exchange and routing key.
Additional headers can be added by creating a subclass and overriding additionalHeaders()
.
Spring Retry has a great deal of flexibility for determining which exceptions can invoke retry.
The default configuration will retry for all exceptions.
Given that user exceptions will be wrapped in a ListenerExecutionFailedException
we need to ensure that the classification examines the exception causes.
The default classifier just looks at the top level exception.
Since Spring Retry 1.0.3, the BinaryExceptionClassifier
has a property traverseCauses
(default false
).
When true
it will traverse exception causes until it finds a match or there is no cause.
To use this classifier for retry, use a SimpleRetryPolicy
created with the constructor that takes the max attempts, the Map
of Exception
s and the boolean (traverseCauses), and inject this policy into the RetryTemplate
.
Spring AMQP provides extensive logging, especially at DEBUG
level.
If you wish to monitor the AMQP protocol between the application and broker, you could use a tool such as WireShark, which has a plugin to decode the protocol.
Alternatively the RabbitMQ java client comes with a very useful class Tracer
.
When run as a main
, by default, it listens on port 5673 and connects to port 5672 on localhost.
Simply run it, and change your connection factory configuration to connect to port 5673 on localhost.
It displays the decoded protocol on the console.
Refer to the Tracer
javadocs for more information.
The framework provides logging appenders for several popular logging subsystems:
The appenders are configured using the normal mechanisms for the logging subsystem, available properties are specified in the following sections.
The following properties are available with all appenders:
Table 3.4. Common Appender Properties
Property | Default | Description |
---|---|---|
exchangeName | logs | Name of the exchange to publish log events to. |
exchangeType | topic | Type of the exchange to publish log events to - only needed if the appender declares the exchange.
See |
routingKeyPattern | %c.%p | Logging subsystem pattern format to use to generate a routing key. |
applicationId | Application ID - added to the routing key if the pattern includes | |
senderPoolSize | 2 | The number of threads to use to publish log events. |
maxSenderRetries | 30 | How many times to retry sending a message if the broker is unavailable or there is some other error.
Retries are delayed like: |
addresses | A comma-delimited list of broker addresses: | |
host | localhost | RabbitMQ host to connect to. |
port | 5672 | RabbitMQ port to connect to. |
virtualHost | / | RabbitMQ virtual host to connect to. |
username | guest | RabbitMQ user to connect as. |
password | guest | RabbitMQ password for this user. |
contentType | text/plain |
|
contentEncoding |
| |
declareExchange | false | Whether or not to declare the configured exchange when this appender starts.
Also see |
durable | true | When |
autoDelete | false | When |
charset | null | Charset to use when converting String to byte[], default null (system default charset used). If the charset is unsupported on the current platform, we fall back to using the system charset. |
deliveryMode | PERSISTENT | PERSISTENT or NON_PERSISTENT to determine whether or not RabbitMQ should persist the messages. |
generateId | false | Used to determine whether the |
clientConnectionProperties | null | A comma-delimited list of |
Example log4j.properties Snippet.
log4j.appender.amqp.addresses=foo:5672,bar:5672 log4j.appender.amqp=org.springframework.amqp.rabbit.log4j.AmqpAppender log4j.appender.amqp.applicationId=myApplication log4j.appender.amqp.routingKeyPattern=%X{applicationId}.%c.%p log4j.appender.amqp.layout=org.apache.log4j.PatternLayout log4j.appender.amqp.layout.ConversionPattern=%d %p %t [%c] - <%m>%n log4j.appender.amqp.generateId=true log4j.appender.amqp.charset=UTF-8 log4j.appender.amqp.durable=false log4j.appender.amqp.deliveryMode=NON_PERSISTENT log4j.appender.amqp.declareExchange=true
Note | |
---|---|
This appender is deprecated and will be removed in version 2.0. |
Example log4j2.xml Snippet.
<Appenders> ... <RabbitMQ name="rabbitmq" addresses="foo:5672,bar:5672" user="guest" password="guest" virtualHost="/" exchange="log4j2" exchangeType="topic" declareExchange="true" durable="true" autoDelete="false" applicationId="myAppId" routingKeyPattern="%X{applicationId}.%c.%p" contentType="text/plain" contentEncoding="UTF-8" generateId="true" deliveryMode="NON_PERSISTENT" charset="UTF-8" senderPoolSize="3" maxSenderRetries="5"> </RabbitMQ> </Appenders>
Example logback.xml Snippet.
<appender name="AMQP" class="org.springframework.amqp.rabbit.logback.AmqpAppender"> <layout> <pattern><![CDATA[ %d %p %t [%c] - <%m>%n ]]></pattern> </layout> <addresses>foo:5672,bar:5672</addresses> <abbreviation>36</abbreviation> <applicationId>myApplication</applicationId> <routingKeyPattern>%property{applicationId}.%c.%p</routingKeyPattern> <generateId>true</generateId> <charset>UTF-8</charset> <durable>false</durable> <deliveryMode>NON_PERSISTENT</deliveryMode> <declareExchange>true</declareExchange> </appender>
Each of the appenders can be subclassed, allowing you to modify the messages before publishing.
Customizing the Log Messages.
public class MyEnhancedAppender extends AmqpAppender { @Override public Message postProcessMessageBeforeSend(Message message, Event event) { message.getMessageProperties().setHeader("foo", "bar"); return message; } }
Each appender supports adding client properties to the RabbitMQ connection.
log4j.
log4j.appender.amqp.clientConnectionProperties=foo:bar,baz:qux
logback.
<appender name="AMQP" ...> ... <clientConnectionProperties>foo:bar,baz:qux</clientConnectionProperties> ... </appender>
log4j2.
<Appenders> ... <RabbitMQ name="rabbitmq" ... clientConnectionProperties="foo:bar,baz:qux" ... </RabbitMQ> </Appenders>
The properties are a comma-delimited list of key:value
pairs; keys and values cannot contain commas or colons.
These properties appear on the RabbitMQ Admin UI when viewing the connection.
With the log4j and logback appenders, the appenders can be subclassed, allowing you to modify the client connection properties before the connection is established:
Customizing the Client Connection Properties.
public class MyEnhancedAppender extends AmqpAppender { private String foo; @Override protected void updateConnectionClientProperties(Map<String, Object> clientProperties) { clientProperties.put("foo", this.foo); } public void setFoo(String foo) { this.foo = foo; } }
For log4j2, add log4j.appender.amqp.foo=bar
to log4j.properties to set the property.
For logback, add <foo>bar</foo>
to logback.xml.
Of course, for simple String properties like this example, the previous technique can be used; subclasses allow
richer properties (such as adding a Map
or numeric property).
With log4j2, subclasses are not supported, due to the way log4j2 uses static factory methods.
The Spring AMQP Samples project includes two sample applications. The first is a simple "Hello World" example that demonstrates both synchronous and asynchronous message reception. It provides an excellent starting point for acquiring an understanding of the essential components. The second sample is based on a stock-trading use case to demonstrate the types of interaction that would be common in real world applications. In this chapter, we will provide a quick walk-through of each sample so that you can focus on the most important components. The samples are both Maven-based, so you should be able to import them directly into any Maven-aware IDE (such as SpringSource Tool Suite).
The Hello World sample demonstrates both synchronous and asynchronous message reception. You can import the spring-rabbit-helloworld sample into the IDE and then follow the discussion below.
Within the src/main/java directory, navigate to the org.springframework.amqp.helloworld package. Open the HelloWorldConfiguration class and notice that it contains the @Configuration annotation at class-level and some @Bean annotations at method-level. This is an example of Spring’s Java-based configuration. You can read more about that here.
@Bean public ConnectionFactory connectionFactory() { CachingConnectionFactory connectionFactory = new CachingConnectionFactory("localhost"); connectionFactory.setUsername("guest"); connectionFactory.setPassword("guest"); return connectionFactory; }
The configuration also contains an instance of RabbitAdmin
, which by default looks for any beans of type Exchange, Queue, or Binding and then declares them on the broker.
In fact, the "helloWorldQueue" bean that is generated in HelloWorldConfiguration is an example simply because it is an instance of Queue.
@Bean public Queue helloWorldQueue() { return new Queue(this.helloWorldQueueName); }
Looking back at the "rabbitTemplate" bean configuration, you will see that it has the helloWorldQueue’s name set as its "queue" property (for receiving Messages) and for its "routingKey" property (for sending Messages).
Now that we’ve explored the configuration, let’s look at the code that actually uses these components. First, open the Producer class from within the same package. It contains a main() method where the Spring ApplicationContext is created.
public static void main(String[] args) { ApplicationContext context = new AnnotationConfigApplicationContext(RabbitConfiguration.class); AmqpTemplate amqpTemplate = context.getBean(AmqpTemplate.class); amqpTemplate.convertAndSend("Hello World"); System.out.println("Sent: Hello World"); }
As you can see in the example above, the AmqpTemplate bean is retrieved and used for sending a Message. Since the client code should rely on interfaces whenever possible, the type is AmqpTemplate rather than RabbitTemplate. Even though the bean created in HelloWorldConfiguration is an instance of RabbitTemplate, relying on the interface means that this code is more portable (the configuration can be changed independently of the code). Since the convertAndSend() method is invoked, the template will be delegating to its MessageConverter instance. In this case, it’s using the default SimpleMessageConverter, but a different implementation could be provided to the "rabbitTemplate" bean as defined in HelloWorldConfiguration.
Now open the Consumer class. It actually shares the same configuration base class which means it will be sharing the "rabbitTemplate" bean. That’s why we configured that template with both a "routingKey" (for sending) and "queue" (for receiving). As you saw in Section 3.1.4, “AmqpTemplate”, you could instead pass the routingKey argument to the send method and the queue argument to the receive method. The Consumer code is basically a mirror image of the Producer, calling receiveAndConvert() rather than convertAndSend().
public static void main(String[] args) { ApplicationContext context = new AnnotationConfigApplicationContext(RabbitConfiguration.class); AmqpTemplate amqpTemplate = context.getBean(AmqpTemplate.class); System.out.println("Received: " + amqpTemplate.receiveAndConvert()); }
If you run the Producer, and then run the Consumer, you should see the message "Received: Hello World" in the console output.
Now that we’ve walked through the synchronous Hello World sample, it’s time to move on to a slightly more advanced but significantly more powerful option. With a few modifications, the Hello World sample can provide an example of asynchronous reception, a.k.a. Message-driven POJOs. In fact, there is a sub-package that provides exactly that: org.springframework.amqp.samples.helloworld.async.
Once again, we will start with the sending side. Open the ProducerConfiguration class and notice that it creates a "connectionFactory" and "rabbitTemplate" bean. This time, since the configuration is dedicated to the message sending side, we don’t even need any Queue definitions, and the RabbitTemplate only has the routingKey property set. Recall that messages are sent to an Exchange rather than being sent directly to a Queue. The AMQP default Exchange is a direct Exchange with no name. All Queues are bound to that default Exchange with their name as the routing key. That is why we only need to provide the routing key here.
public RabbitTemplate rabbitTemplate() { RabbitTemplate template = new RabbitTemplate(connectionFactory()); template.setRoutingKey(this.helloWorldQueueName); return template; }
Since this sample will be demonstrating asynchronous message reception, the producing side is designed to continuously send messages (if it were a message-per-execution model like the synchronous version, it would not be quite so obvious that it is in fact a message-driven consumer). The component responsible for sending messages continuously is defined as an inner class within the ProducerConfiguration. It is configured to execute every 3 seconds.
static class ScheduledProducer { @Autowired private volatile RabbitTemplate rabbitTemplate; private final AtomicInteger counter = new AtomicInteger(); @Scheduled(fixedRate = 3000) public void sendMessage() { rabbitTemplate.convertAndSend("Hello World " + counter.incrementAndGet()); } }
You don’t need to understand all of the details since the real focus should be on the receiving side (which we will cover momentarily). However, if you are not yet familiar with Spring 3.0 task scheduling support, you can learn more here. The short story is that the "postProcessor" bean in the ProducerConfiguration is registering the task with a scheduler.
Now, let’s turn to the receiving side. To emphasize the Message-driven POJO behavior will start with the component that is reacting to the messages. The class is called HelloWorldHandler.
public class HelloWorldHandler { public void handleMessage(String text) { System.out.println("Received: " + text); } }
Clearly, that is a POJO. It does not extend any base class, it doesn’t implement any interfaces, and it doesn’t even contain any imports. It is being "adapted" to the MessageListener interface by the Spring AMQP MessageListenerAdapter. That adapter can then be configured on a SimpleMessageListenerContainer. For this sample, the container is created in the ConsumerConfiguration class. You can see the POJO wrapped in the adapter there.
@Bean public SimpleMessageListenerContainer listenerContainer() { SimpleMessageListenerContainer container = new SimpleMessageListenerContainer(); container.setConnectionFactory(connectionFactory()); container.setQueueName(this.helloWorldQueueName); container.setMessageListener(new MessageListenerAdapter(new HelloWorldHandler())); return container; }
The SimpleMessageListenerContainer is a Spring lifecycle component and will start automatically by default. If you look in the Consumer class, you will see that its main() method consists of nothing more than a one-line bootstrap to create the ApplicationContext. The Producer’s main() method is also a one-line bootstrap, since the component whose method is annotated with @Scheduled will also start executing automatically. You can start the Producer and Consumer in any order, and you should see messages being sent and received every 3 seconds.
The Stock Trading sample demonstrates more advanced messaging scenarios than the Hello World sample. However, the configuration is very similar - just a bit more involved. Since we’ve walked through the Hello World configuration in detail, here we’ll focus on what makes this sample different. There is a server that pushes market data (stock quotes) to a Topic Exchange. Then, clients can subscribe to the market data feed by binding a Queue with a routing pattern (e.g. "app.stock.quotes.nasdaq.*"). The other main feature of this demo is a request-reply "stock trade" interaction that is initiated by the client and handled by the server. That involves a private "replyTo" Queue that is sent by the client within the order request Message itself.
The Server’s core configuration is in the RabbitServerConfiguration class within the org.springframework.amqp.rabbit.stocks.config.server package. It extends the AbstractStockAppRabbitConfiguration. That is where the resources common to the Server and Client(s) are defined, including the market data Topic Exchange (whose name is app.stock.marketdata) and the Queue that the Server exposes for stock trades (whose name is app.stock.request). In that common configuration file, you will also see that a JsonMessageConverter is configured on the RabbitTemplate.
The Server-specific configuration consists of 2 things. First, it configures the market data exchange on the RabbitTemplate so that it does not need to provide that exchange name with every call to send a Message. It does this within an abstract callback method defined in the base configuration class.
public void configureRabbitTemplate(RabbitTemplate rabbitTemplate) { rabbitTemplate.setExchange(MARKET_DATA_EXCHANGE_NAME); }
Secondly, the stock request queue is declared. It does not require any explicit bindings in this case, because it will be bound to the default no-name exchange with its own name as the routing key. As mentioned earlier, the AMQP specification defines that behavior.
@Bean public Queue stockRequestQueue() { return new Queue(STOCK_REQUEST_QUEUE_NAME); }
Now that you’ve seen the configuration of the Server’s AMQP resources, navigate to the org.springframework.amqp.rabbit.stocks package under the src/test/java directory. There you will see the actual Server class that provides a main() method. It creates an ApplicationContext based on the server-bootstrap.xml config file. In there you will see the scheduled task that publishes dummy market data. That configuration relies upon Spring 3.0’s "task" namespace support. The bootstrap config file also imports a few other files. The most interesting one is server-messaging.xml which is directly under src/main/resources. In there you will see the "messageListenerContainer" bean that is responsible for handling the stock trade requests. Finally have a look at the "serverHandler" bean that is defined in "server-handlers.xml" (also in src/main/resources). That bean is an instance of the ServerHandler class and is a good example of a Message-driven POJO that is also capable of sending reply Messages. Notice that it is not itself coupled to the framework or any of the AMQP concepts. It simply accepts a TradeRequest and returns a TradeResponse.
public TradeResponse handleMessage(TradeRequest tradeRequest) { ...
}
Now that we’ve seen the most important configuration and code for the Server, let’s turn to the Client. The best starting point is probably RabbitClientConfiguration within the org.springframework.amqp.rabbit.stocks.config.client package. Notice that it declares two queues without providing explicit names.
@Bean public Queue marketDataQueue() { return amqpAdmin().declareQueue(); } @Bean public Queue traderJoeQueue() { return amqpAdmin().declareQueue(); }
Those are private queues, and unique names will be generated automatically. The first generated queue is used by the Client to bind to the market data exchange that has been exposed by the Server. Recall that in AMQP, consumers interact with Queues while producers interact with Exchanges. The "binding" of Queues to Exchanges is what instructs the broker to deliver, or route, messages from a given Exchange to a Queue. Since the market data exchange is a Topic Exchange, the binding can be expressed with a routing pattern. The RabbitClientConfiguration declares that with a Binding object, and that object is generated with the BindingBuilder’s fluent API.
@Value("${stocks.quote.pattern}") private String marketDataRoutingKey; @Bean public Binding marketDataBinding() { return BindingBuilder.bind( marketDataQueue()).to(marketDataExchange()).with(marketDataRoutingKey); }
Notice that the actual value has been externalized in a properties file ("client.properties" under src/main/resources), and that we are using Spring’s @Value annotation to inject that value. This is generally a good idea, since otherwise the value would have been hardcoded in a class and unmodifiable without recompilation. In this case, it makes it much easier to run multiple versions of the Client while making changes to the routing pattern used for binding. Let’s try that now.
Start by running org.springframework.amqp.rabbit.stocks.Server and then org.springframework.amqp.rabbit.stocks.Client. You should see dummy quotes for NASDAQ stocks because the current value associated with the stocks.quote.pattern key in client.properties is app.stock.quotes.nasdaq.. Now, while keeping the existing Server and Client running, change that property value to app.stock.quotes.nyse. and start a second Client instance. You should see that the first client is still receiving NASDAQ quotes while the second client receives NYSE quotes. You could instead change the pattern to get all stocks or even an individual ticker.
The final feature we’ll explore is the request-reply interaction from the Client’s perspective. Recall that we have already seen the ServerHandler that is accepting TradeRequest objects and returning TradeResponse objects. The corresponding code on the Client side is RabbitStockServiceGateway in the org.springframework.amqp.rabbit.stocks.gateway package. It delegates to the RabbitTemplate in order to send Messages.
public void send(TradeRequest tradeRequest) { getRabbitTemplate().convertAndSend(tradeRequest, new MessagePostProcessor() { public Message postProcessMessage(Message message) throws AmqpException { message.getMessageProperties().setReplyTo(new Address(defaultReplyToQueue)); try { message.getMessageProperties().setCorrelationId( UUID.randomUUID().toString().getBytes("UTF-8")); } catch (UnsupportedEncodingException e) { throw new AmqpException(e); } return message; } }); }
Notice that prior to sending the message, it sets the "replyTo" address. It’s providing the queue that was generated by the "traderJoeQueue" bean definition shown above. Here’s the @Bean definition for the StockServiceGateway class itself.
@Bean public StockServiceGateway stockServiceGateway() { RabbitStockServiceGateway gateway = new RabbitStockServiceGateway(); gateway.setRabbitTemplate(rabbitTemplate()); gateway.setDefaultReplyToQueue(traderJoeQueue()); return gateway; }
If you are no longer running the Server and Client, start them now. Try sending a request with the format of 100 TCKR. After a brief artificial delay that simulates "processing" of the request, you should see a confirmation message appear on the Client.
Writing integration for asynchronous applications is necessarily more complex than testing simpler applications.
This is made more complex when abstractions such as the @RabbitListener
annotations come into the picture.
The question being how to verify that, after sending a message, the listener received the message as expected.
The framework itself has many unit and integration tests; some using mocks, others using integration testing with a live RabbitMQ broker. You can consult those tests for some ideas for testing scenarios.
Spring AMQP version 1.6 introduced the spring-rabbit-test
jar which provides support for testing some of these more
complex scenarios.
It is anticipated that this project will expand over time but we need community feedback to make suggestions for
features needed to help with testing.
Please use JIRA or
GitHub Issues to provide such feedback.
There are currently two Answer<?>
implementations to help with testing:
The first, LatchCountDownAndCallRealMethodAnswer
provides an Answer<Void>
that returns null
and counts down
a latch.
LatchCountDownAndCallRealMethodAnswer answer = new LatchCountDownAndCallRealMethodAnswer(2); doAnswer(answer) .when(listener).foo(anyString(), anyString()); ... assertTrue(answer.getLatch().await(10, TimeUnit.SECONDS));
The second, LambdaAnswer<T>
provides a mechanism to optionally call the real method and provides an opportunity
to return a custom result, based on the InvocationOnMock
and the result (if any).
public class Foo { public String foo(String foo) { return foo.toUpperCase(); } }
Foo foo = spy(new Foo()); doAnswer(new LambdaAnswer<String>(true, (i, r) -> r + r)) .when(foo).foo(anyString()); assertEquals("FOOFOO", foo.foo("foo")); doAnswer(new LambdaAnswer<String>(true, (i, r) -> r + i.getArguments()[0])) .when(foo).foo(anyString()); assertEquals("FOOfoo", foo.foo("foo")); doAnswer(new LambdaAnswer<String>(false, (i, r) -> "" + i.getArguments()[0] + i.getArguments()[0])).when(foo).foo(anyString()); assertEquals("foofoo", foo.foo("foo"));
When using Java 7 or earlier:
doAnswer(new LambdaAnswer<String>(true, new ValueToReturn<String>() { @Override public String apply(InvocationOnMock i, String r) { return r + r; } })).when(foo).foo(anyString());
Annotating one of your @Configuration
classes with @RabbitListenerTest
will cause the framework to replace the
standard RabbitListenerAnnotationBeanPostProcessor
with a subclass RabbitListenerTestHarness
(it will also enable
@RabbitListener
detection via @EnableRabbit
).
The RabbitListenerTestHarness
enhances the listener in two ways - it wraps it in a Mockito Spy
, enabling normal
Mockito
stubbing and verification operations.
It can also add an Advice
to the listener enabling access to the arguments, result and or exceptions thrown.
You can control which (or both) of these are enabled with attributes on the @RabbitListenerTest
.
The latter is provided for access to lower-level data about the invocation - it also supports blocking the test
thread until the async listener is called.
Important | |
---|---|
|
Let’s take a look at some examples.
Using spy:
@Configuration @RabbitListenerTest public class Config { @Bean public Listener listener() { return new Listener(); } ... } public class Listener { @RabbitListener(id="foo", queues="#{queue1.name}") public String foo(String foo) { return foo.toUpperCase(); } @RabbitListener(id="bar", queues="#{queue2.name}") public void foo(@Payload String foo, @Header("amqp_receivedRoutingKey") String rk) { ... } } public class MyTests { @Autowired private RabbitListenerTestHarness harness; @Test public void testTwoWay() throws Exception { assertEquals("FOO", this.rabbitTemplate.convertSendAndReceive(this.queue1.getName(), "foo")); Listener listener = this.harness.getSpy("foo"); assertNotNull(listener); verify(listener).foo("foo"); } @Test public void testOneWay() throws Exception { Listener listener = this.harness.getSpy("bar"); assertNotNull(listener); LatchCountDownAndCallRealMethodAnswer answer = new LatchCountDownAndCallRealMethodAnswer(2); doAnswer(answer).when(listener).foo(anyString(), anyString()); this.rabbitTemplate.convertAndSend(this.queue2.getName(), "bar"); this.rabbitTemplate.convertAndSend(this.queue2.getName(), "baz"); assertTrue(answer.getLatch().await(10, TimeUnit.SECONDS)); verify(listener).foo("bar", this.queue2.getName()); verify(listener).foo("baz", this.queue2.getName()); } }
Inject the harness into the test case so we can get access to the spy. | |
Get a reference to the spy so we can verify it was invoked as expected.
Since this is a send and receive operation, there is no need to suspend the test thread because it was already
suspended in the | |
In this case, we’re only using a send operation so we need a latch to wait for the asynchronous call to the listener on the container thread. We use one of the Answer<?> implementations to help with that. | |
Configure the spy to invoke the |
Using the capture advice:
@Configuration @ComponentScan @RabbitListenerTest(spy = false, capture = true) public class Config { } @Service public class Listener { private boolean failed; @RabbitListener(id="foo", queues="#{queue1.name}") public String foo(String foo) { return foo.toUpperCase(); } @RabbitListener(id="bar", queues="#{queue2.name}") public void foo(@Payload String foo, @Header("amqp_receivedRoutingKey") String rk) { if (!failed && foo.equals("ex")) { failed = true; throw new RuntimeException(foo); } failed = false; } } public class MyTests { @Autowired private RabbitListenerTestHarness harness; @Test public void testTwoWay() throws Exception { assertEquals("FOO", this.rabbitTemplate.convertSendAndReceive(this.queue1.getName(), "foo")); InvocationData invocationData = this.harness.getNextInvocationDataFor("foo", 0, TimeUnit.SECONDS); assertThat(invocationData.getArguments()[0], equalTo("foo")); assertThat((String) invocationData.getResult(), equalTo("FOO")); } @Test public void testOneWay() throws Exception { this.rabbitTemplate.convertAndSend(this.queue2.getName(), "bar"); this.rabbitTemplate.convertAndSend(this.queue2.getName(), "baz"); this.rabbitTemplate.convertAndSend(this.queue2.getName(), "ex"); InvocationData invocationData = this.harness.getNextInvocationDataFor("bar", 10, TimeUnit.SECONDS); Object[] args = invocationData.getArguments(); assertThat((String) args[0], equalTo("bar")); assertThat((String) args[1], equalTo(queue2.getName())); invocationData = this.harness.getNextInvocationDataFor("bar", 10, TimeUnit.SECONDS); args = invocationData.getArguments(); assertThat((String) args[0], equalTo("baz")); invocationData = this.harness.getNextInvocationDataFor("bar", 10, TimeUnit.SECONDS); args = invocationData.getArguments(); assertThat((String) args[0], equalTo("ex")); assertEquals("ex", invocationData.getThrowable().getMessage()); } }
Inject the harness into the test case so we can get access to the spy. | |
Use | |
We can then verify that the argument and result was as expected. | |
This time we need some time to wait for the data, since it’s an async operation on the container thread and we need to suspend the test thread. | |
When the listener throws an exception, it is available in the |
Spring AMQP version 1.7 provides an additional jar spring-rabbit-junit
; this jar contains a couple of utility @Rule
s for use when running JUnit tests.
BrokerRunning
provides a mechanism to allow tests to succeed when a broker is not running on localhost
.
It also has utility methods to delete queues and exchanges.
Usage:
@ClassRule public static BrokerRunning brokerRunning = BrokerRunning.isRunningWithEmptyQueues("foo", "bar"); @AfterClass public void tearDown() { brokerRunning.removeTestQueues("some.other.queue.too") // removes foo, bar as well }
Of course, there are times when you want tests to fail if there is no broker, such as a nightly CI build.
To disable the rule at runtime, set an environment variable RABBITMQ_SERVER_REQUIRED
to true
.
There are several isRunning...
static methods such as isBrokerAndManagementRunning()
which verifies the broker has the management plugin enabled.
LongRunningIntegrationTest
is a rule that disables long running tests; you might want to use this on a developer system but ensure that the rule is disabled on, for example, nightly CI builds.
Usage:
@Rule public LongRunningIntegrationTest longTests = new LongRunningIntegrationTest();
To disable the rule at runtime, set an environment variable RUN_LONG_INTEGRATION_TESTS
to true
.