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Message Mapping Rules and Conventions

Spring Integration implements a flexible facility to map messages to methods and their arguments without providing extra configuration, by relying on some default rules and defining certain conventions. The examples in the following sections articulate the rules.

Sample Scenarios

The following example shows a single un-annotated parameter (object or primitive) that is not a Map or a Properties object with a non-void return type:

public String doSomething(Object o);

The input parameter is a message payload. If the parameter type is not compatible with a message payload, an attempt is made to convert it by using a conversion service provided by Spring 3.0. The return value is incorporated as a payload of the returned message.

The following example shows a single un-annotated parameter (object or primitive)that is not a Map or a Properties with a Message return type:

public Message doSomething(Object o);

The input parameter is a message payload. If the parameter type is not compatible with a message payload, an attempt is made to convert it by using a conversion service provided by Spring 3.0. The return value is a newly constructed message that is sent to the next destination.

The following example shows a single parameter that is a message (or one of its subclasses) with an arbitrary object or primitive return type:

public int doSomething(Message msg);

The input parameter is itself a Message. The return value becomes a payload of the Message that is sent to the next destination.

The following example shows a single parameter that is a Message (or one of its subclasses) with a Message (or one of its subclasses) as the return type:

public Message doSomething(Message msg);

The input parameter is itself a Message. The return value is a newly constructed Message that is sent to the next destination.

The following example shows a single parameter of type Map or Properties with a Message as the return type:

public Message doSomething(Map m);

This one is a bit interesting. Although, at first, it might seem like an easy mapping straight to message headers, preference is always given to a Message payload. This means that if a Message payload is of type Map, this input argument represents a Message payload. However, if the Message payload is not of type Map, the conversion service does not try to convert the payload, and the input argument is mapped to message headers.

The following example shows two parameters, where one of them is an arbitrary type (an object or a primitive) that is not a Map or a Properties object and the other is of type Map or Properties type (regardless of the return):

public Message doSomething(Map h, <T> t);

This combination contains two input parameters where one of them is of type Map. The non-Map parameters (regardless of the order) are mapped to a Message payload and the Map or Properties (regardless of the order) is mapped to message headers, giving you a nice POJO way of interacting with Message structure.

The following example shows no parameters (regardless of the return):

public String doSomething();

This message handler method is invoked based on the Message sent to the input channel to which this handler is connected. However, no Message data is mapped, thus making the Message act as event or trigger to invoke the handler. The output is mapped according to the rules described earlier.

The following example shows no parameters and a void return:

public void soSomething();

This example is the same as the previous example, but it produces no output.

Annotation-based Mapping

Annotation-based mapping is the safest and least ambiguous approach to map messages to methods. The following example shows how to explicitly map a method to a header:

public String doSomething(@Payload String s, @Header("someheader") String b)

As you can see later on, without an annotation this signature would result in an ambiguous condition. However, by explicitly mapping the first argument to a Message payload and the second argument to a value of the someheader message header, we avoid any ambiguity.

The following example is nearly identical to the preceding example:

public String doSomething(@Payload String s, @RequestParam("something") String b)

@RequestMapping or any other non-Spring Integration mapping annotation is irrelevant and is therefore ignored, leaving the second parameter unmapped. Although the second parameter could easily be mapped to a payload, there can only be one payload. Therefore, the annotations keep this method from being ambiguous.

The following example shows another similar method that would be ambiguous were it not for annotations to clarify the intent:

public String foo(String s, @Header("foo") String b)

The only difference is that the first argument is implicitly mapped to the message payload.

The following example shows yet another signature that would definitely be treated as ambiguous without annotations, because it has more than two arguments:

public String soSomething(@Headers Map m, @Header("something") Map f, @Header("someotherthing") String bar)

This example would be especially problematic, because two of its arguments are Map instances. However, with annotation-based mapping, the ambiguity is easily avoided. In this example the first argument is mapped to all the message headers, while the second and third argument map to the values of the message headers named 'something' and 'someotherthing'. The payload is not being mapped to any argument.

Complex Scenarios

The following example uses multiple parameters:

Multiple parameters can create a lot of ambiguity in regards to determining the appropriate mappings. The general advice is to annotate your method parameters with @Payload, @Header, and @Headers. The examples in this section show ambiguous conditions that result in an exception being raised.

public String doSomething(String s, int i)

The two parameters are equal in weight. Therefore, there is no way to determine which one is a payload.

The following example shows a similar problem, only with three parameters:

public String foo(String s, Map m, String b)

Although the Map could be easily mapped to message headers, there is no way to determine what to do with the two String parameters.

The following example shows another ambiguous method:

public String foo(Map m, Map f)

Although one might argue that one Map could be mapped to the message payload and the other one to the message headers, we cannot rely on the order.

Any method signature with more than one method argument that is not (Map, <T>) and with unannotated parameters results in an ambiguous condition and triggers an exception.

The next set of examples each show multiple methods that result in ambiguity.

Message handlers with multiple methods are mapped based on the same rules that are described earlier (in the examples). However, some scenarios might still look confusing.

The following example shows multiple methods with legal (mappable and unambiguous) signatures:

public class Something {
    public String doSomething(String str, Map m);

    public String doSomething(Map m);
}

(Whether the methods have the same name or different names makes no difference). The Message could be mapped to either method. The first method would be invoked when the message payload could be mapped to str and the message headers could be mapped to m. The second method could also be a candidate by mapping only the message headers to m. To make matters worse, both methods have the same name. At first, that might look ambiguous because of the following configuration:

<int:service-activator input-channel="input" output-channel="output" method="doSomething">
    <bean class="org.things.Something"/>
</int:service-activator>

It works because mappings are based on the payload first and everything else next. In other words, the method whose first argument can be mapped to a payload takes precedence over all other methods.

Now consider an alternate example, which produces a truly ambiguous condition:

public class Something {
    public String doSomething(String str, Map m);

    public String doSomething(String str);
}

Both methods have signatures that could be mapped to a message payload. They also have the same name. Such handler methods will trigger an exception. However, if the method names were different, you could influence the mapping with a method attribute (shown in the next example). The following example shows the same example with two different method names:

public class Something {
    public String doSomething(String str, Map m);

    public String doSomethingElse(String str);
}

The following example shows how to use the method attribute to dictate the mapping:

<int:service-activator input-channel="input" output-channel="output" method="doSomethingElse">
    <bean class="org.bar.Foo"/>
</int:service-activator>

Because the configuration explicitly maps the doSomethingElse method, we have eliminated the ambiguity.