The interface for an annotation processor.
Annotation processing happens in a sequence of rounds. On each round, a processor may be asked to process a subset of the annotations found on the source and class files produced by a prior round. The inputs to the first round of processing are the initial inputs to a run of the tool; these initial inputs can be regarded as the output of a virtual zeroth round of processing. If a processor was asked to process on a given round, it will be asked to process on subsequent rounds, including the last round, even if there are no annotations for it to process. The tool infrastructure may also ask a processor to process files generated implicitly by the tool's operation.
Each implementation of a Processor
must provide a public no-argument constructor to be used by tools to instantiate the processor. The tool infrastructure will interact with classes implementing this interface as follows:
- If an existing
Processor
object is not being used, to create an instance of a processor the tool calls the no-arg constructor of the processor class.
- Next, the tool calls the
init
method with an appropriate ProcessingEnvironment
.
- Afterwards, the tool calls
getSupportedAnnotationTypes
, getSupportedOptions
, and getSupportedSourceVersion
. These methods are only called once per run, not on each round.
- As appropriate, the tool calls the
process
method on the Processor
object; a new Processor
object is not created for each round.
If a processor object is created and used without the above protocol being followed, then the processor's behavior is not defined by this interface specification.
The tool uses a discovery process to find annotation processors and decide whether or not they should be run. By configuring the tool, the set of potential processors can be controlled. For example, for a JavaCompiler
the list of candidate processors to run can be set directly or controlled by a search path used for a service-style lookup. Other tool implementations may have different configuration mechanisms, such as command line options; for details, refer to the particular tool's documentation. Which processors the tool asks to run is a function of the types of the annotations present on the root elements , what annotation types a processor supports , and whether or not a processor claims the annotation types it processes . A processor will be asked to process a subset of the annotation types it supports, possibly an empty set. For a given round, the tool computes the set of annotation types that are present on the elements enclosed within the root elements. If there is at least one annotation type present, then as processors claim annotation types, they are removed from the set of unmatched annotation types. When the set is empty or no more processors are available, the round has run to completion. If there are no annotation types present, annotation processing still occurs but only universal processors which support processing all annotation types, "*"
, can claim the (empty) set of annotation types.
An annotation type is considered present if there is at least one annotation of that type present on an element enclosed within the root elements of a round. For this purpose, a type parameter is considered to be enclosed by its generic element . For this purpose, a package element is not considered to enclose the top-level types within that package. (A root element representing a package is created when a package-info
file is processed.) Likewise, for this purpose, a module element is not considered to enclose the packages within that module. (A root element representing a module is created when a module-info
file is processed.) Annotations on type uses , as opposed to annotations on elements, are ignored when computing whether or not an annotation type is present.
An annotation is present if it meets the definition of being present given in AnnotatedConstruct
. In brief, an annotation is considered present for the purposes of discovery if it is directly present or present via inheritance. An annotation is not considered present by virtue of being wrapped by a container annotation. Operationally, this is equivalent to an annotation being present on an element if and only if it would be included in the results of Elements.getAllAnnotationMirrors(Element)
called on that element. Since annotations inside container annotations are not considered present, to properly process repeatable annotation types , processors are advised to include both the repeatable annotation type and its containing annotation type in the set of supported annotation types of a processor.
Note that if a processor supports "*"
and returns true
, all annotations are claimed. Therefore, a universal processor being used to, for example, implement additional validity checks should return false
so as to not prevent other such checkers from being able to run.
If a processor throws an uncaught exception, the tool may cease other active annotation processors. If a processor raises an error, the current round will run to completion and the subsequent round will indicate an error was raised . Since annotation processors are run in a cooperative environment, a processor should throw an uncaught exception only in situations where no error recovery or reporting is feasible.
The tool environment is not required to support annotation processors that access environmental resources, either per round or cross-round, in a multi-threaded fashion.
If the methods that return configuration information about the annotation processor return null
, return other invalid input, or throw an exception, the tool infrastructure must treat this as an error condition.
To be robust when running in different tool implementations, an annotation processor should have the following properties:
- The result of processing a given input is not a function of the presence or absence of other inputs (orthogonality).
- Processing the same input produces the same output (consistency).
- Processing input A followed by processing input B is equivalent to processing B then A (commutativity)
- Processing an input does not rely on the presence of the output of other annotation processors (independence)
The Filer
interface discusses restrictions on how processors can operate on files.