Here is the definition of the Message interface:

public interface Message<T> {

    T getPayload();

    MessageHeaders getHeaders();

}

The Message is obviously a very important part of the API. By encapsulating the data in a generic wrapper, the messaging system can pass it around without any knowledge of the data’s type. As an application evolves to support new types, or when the types themselves are modified and/or extended, the messaging system will not be affected by such changes. On the other hand, when some component in the messaging system does require access to information about the Message, such metadata can typically be stored to and retrieved from the metadata in the Message Headers.

Just as Spring Integration allows any Object to be used as the payload of a Message, it also supports any Object types as header values. In fact, the MessageHeaders class implements the java.util.Map interface:

public final class MessageHeaders implements Map<String, Object>, Serializable {
  ...
}

Note

Even though the MessageHeaders implements Map, it is effectively a read-only implementation. Any attempt to put a value in the Map will result in an UnsupportedOperationException. The same applies for remove and clear. Since Messages may be passed to multiple consumers, the structure of the Map cannot be modified. Likewise, the Message’s payload Object can not be set after the initial creation. However, the mutability of the header values themselves (or the payload Object) is intentionally left as a decision for the framework user.

As an implementation of Map, the headers can obviously be retrieved by calling get(..) with the name of the header. Alternatively, you can provide the expected Class as an additional parameter. Even better, when retrieving one of the pre-defined values, convenient getters are available. Here is an example of each of these three options:

 Object someValue = message.getHeaders().get("someKey");

 CustomerId customerId = message.getHeaders().get("customerId", CustomerId.class);

 Long timestamp = message.getHeaders().getTimestamp();

The following Message headers are pre-defined:

MessageHeaders.ID

java.util.UUID

MessageHeaders.
    TIMESTAMP

java.lang.Long

MessageHeaders.
    REPLY_CHANNEL

java.lang.Object
(String or MessageChannel)

MessageHeaders.
    ERROR_CHANNEL

java.lang.Object
(String or MessageChannel)

Many inbound and outbound adapter implementations will also provide and/or expect certain headers, and additional user-defined headers can also be configured. Constants for these headers can be found in those modules where such headers exist, for example AmqpHeaders, JmsHeaders etc.

IntegrationMessageHeaderAccessor.
    CORRELATION_ID

java.lang.Object

IntegrationMessageHeaderAccessor.
    SEQUENCE_NUMBER

java.lang.Integer

IntegrationMessageHeaderAccessor.
    SEQUENCE_SIZE

java.lang.Integer

IntegrationMessageHeaderAccessor.
    EXPIRATION_DATE

java.lang.Long

IntegrationMessageHeaderAccessor.
    PRIORITY

java.lang.Integer

IntegrationMessageHeaderAccessor.
    DUPLICATE_MESSAGE

java.lang.Boolean

IntegrationMessageHeaderAccessor accessor = new IntegrationMessageHeaderAccessor(message);
int sequenceNumber = accessor.getSequenceNumber();
Object correlationId = accessor.getCorrelationId();
...

IntegrationMessageHeaderAccessor.
    SEQUENCE_DETAILS

java.util.List<
List<Object>>

IntegrationMessageHeaderAccessor.
    ROUTING_SLIP

java.util.Map<
List<Object>, Integer>

Message ID Generation

When a message transitions through an application, each time it is mutated (e.g. by a transformer) a new message id is assigned. The message id is a UUID. Beginning with Spring Integration 3.0, the default strategy used for id generation is more efficient than the previous java.util.UUID.randomUUID() implementation. It uses simple random numbers based on a secure random seed, instead of creating a secure random number each time.

A different UUID generation strategy can be selected by declaring a bean that implements org.springframework.util.IdGenerator in the application context.

Important

Only one UUID generation strategy can be used in a classloader. This means that if two or more application contexts are running in the same classloader, they will share the same strategy. If one of the contexts changes the strategy, it will be used by all contexts. If two or more contexts in the same classloader declare a bean of type org.springframework.util.IdGenerator, they must all be an instance of the same class, otherwise the context attempting to replace a custom strategy will fail to initialize. If the strategy is the same, but parameterized, the strategy in the first context to initialize will be used.

In addition to the default strategy, two additional IdGenerators are provided; org.springframework.util.JdkIdGenerator uses the previous UUID.randomUUID() mechanism; o.s.i.support.IdGenerators.SimpleIncrementingIdGenerator can be used in cases where a UUID is not really needed and a simple incrementing value is sufficient.

Header Propagation

When messages are processed (and modified) by message-producing endpoints (such as a service activator), in general, inbound headers are propagated to the outbound message. One exception to this is a transformer, when a complete message is returned to the framework; in that case, the user code is responsible for the entire outbound message. When a transformer just returns the payload; the inbound headers are propagated. Also, a header is only propagated if it does not already exist in the outbound message, allowing user code to change header values as needed.

Starting with version 4.3.10, you can configure message handlers (that modify messages and produce output) to suppress the propagation of specific headers. Call the setNotPropagatedHeaders() or addNotPropagatedHeaders() methods on the MessageProducingMessageHandler abstract class, to configure the header(s) you don’t want to be copied.

You can also globally suppress propagation of specific message headers by setting the readOnlyHeaders property in META-INF/spring.integration.properties to a comma-delimited list of headers.

Starting with version 5.0, the setNotPropagatedHeaders() implementation on the AbstractMessageProducingHandler applies the simple patterns (xxx*, *xxx, *xxx* or xxx*yyy) to allow filtering headers with a common suffix or prefix. See PatternMatchUtils JavaDocs for more information. When one of the patterns is * (asterisk), no headers are propagated; all other patterns are ignored. In this case the Service Activator behaves the same way as Transformer and any required headers must be supplied in the Message returned from the service method. The option notPropagatedHeaders() is available in the ConsumerEndpointSpec for Java DSL, as well as for XML configuration of the <service-activator> component as a not-propagated-headers attribute.

	Important
	Header propagation suppression does not apply to those endpoints that don’t modify the message, e.g. bridges and routers.

The base implementation of the Message interface is GenericMessage<T>, and it provides two constructors:

new GenericMessage<T>(T payload);

new GenericMessage<T>(T payload, Map<String, Object> headers)

When a Message is created, a random unique id will be generated. The constructor that accepts a Map of headers will copy the provided headers to the newly created Message.

There is also a convenient implementation of Message designed to communicate error conditions. This implementation takes Throwable object as its payload:

ErrorMessage message = new ErrorMessage(someThrowable);

Throwable t = message.getPayload();

Notice that this implementation takes advantage of the fact that the GenericMessage base class is parameterized. Therefore, as shown in both examples, no casting is necessary when retrieving the Message payload Object.

You may notice that the Message interface defines retrieval methods for its payload and headers but no setters. The reason for this is that a Message cannot be modified after its initial creation. Therefore, when a Message instance is sent to multiple consumers (e.g. through a Publish Subscribe Channel), if one of those consumers needs to send a reply with a different payload type, it will need to create a new Message. As a result, the other consumers are not affected by those changes. Keep in mind, that multiple consumers may access the same payload instance or header value, and whether such an instance is itself immutable is a decision left to the developer. In other words, the contract for Messages is similar to that of an unmodifiable Collection, and the MessageHeaders' map further exemplifies that; even though the MessageHeaders class implements java.util.Map, any attempt to invoke a put operation (or remove or clear) on the MessageHeaders will result in an UnsupportedOperationException.

Rather than requiring the creation and population of a Map to pass into the GenericMessage constructor, Spring Integration does provide a far more convenient way to construct Messages: MessageBuilder. The MessageBuilder provides two factory methods for creating Messages from either an existing Message or with a payload Object. When building from an existing Message, the headers and payload of that Message will be copied to the new Message:

Message<String> message1 = MessageBuilder.withPayload("test")
        .setHeader("foo", "bar")
        .build();

Message<String> message2 = MessageBuilder.fromMessage(message1).build();

assertEquals("test", message2.getPayload());
assertEquals("bar", message2.getHeaders().get("foo"));

If you need to create a Message with a new payload but still want to copy the headers from an existing Message, you can use one of the copy methods.

Message<String> message3 = MessageBuilder.withPayload("test3")
        .copyHeaders(message1.getHeaders())
        .build();

Message<String> message4 = MessageBuilder.withPayload("test4")
        .setHeader("foo", 123)
        .copyHeadersIfAbsent(message1.getHeaders())
        .build();

assertEquals("bar", message3.getHeaders().get("foo"));
assertEquals(123, message4.getHeaders().get("foo"));

Notice that the copyHeadersIfAbsent does not overwrite existing values. Also, in the second example above, you can see how to set any user-defined header with setHeader. Finally, there are set methods available for the predefined headers as well as a non-destructive method for setting any header (MessageHeaders also defines constants for the pre-defined header names).

Message<Integer> importantMessage = MessageBuilder.withPayload(99)
        .setPriority(5)
        .build();

assertEquals(5, importantMessage.getHeaders().getPriority());

Message<Integer> lessImportantMessage = MessageBuilder.fromMessage(importantMessage)
        .setHeaderIfAbsent(IntegrationMessageHeaderAccessor.PRIORITY, 2)
        .build();

assertEquals(2, lessImportantMessage.getHeaders().getPriority());

The priority header is only considered when using a PriorityChannel (as described in the next chapter). It is defined as java.lang.Integer.