= Annotations [[annotations-inJava5]] == Annotations in Java 5 This section provides the essential information about annotations in Java 5 needed to understand how annotations are treated in AspectJ 5. For a full introduction to annotations in Java, please see the documentation for the Java 5 SDK. === Using Annotations Java 5 introduces _annotation types_ which can be used to express metadata relating to program members in the form of _annotations_. Annotations in Java 5 can be applied to package and type declarations (classes, interfaces, enums, and annotations), constructors, methods, fields, parameters, and variables. Annotations are specified in the program source by using the `@` symbol. For example, the following piece of code uses the `@Deprecated` annotation to indicate that the `obsoleteMethod()` has been deprecated: [source, java] .... @Deprecated public void obsoleteMethod() { ... } .... Annotations may be _marker annotations_, _single-valued annotations_, or _multi-valued annotations_. Annotation types with no members or that provide default values for all members may be used simply as marker annotations, as in the deprecation example above. Single-value annotation types have a single member, and the annotation may be written in one of two equivalent forms: [source, java] .... @SuppressWarnings({"unchecked"}) public void someMethod() {...} .... or [source, java] .... @SuppressWarnings(value={"unchecked"}) public void someMethod() {...} .... Multi-value annotations must use the `member-name=value ` syntax to specify annotation values. For example: [source, java] .... @Authenticated(role="supervisor",clearanceLevel=5) public void someMethod() {...} .... === Retention Policies Annotations can have one of three retention policies: Source-file retention:: Annotations with source-file retention are read by the compiler during the compilation process, but are not rendered in the generated `.class` files. Class-file retention:: This is the default retention policy. Annotations with class-file retention are read by the compiler and also retained in the generated `.class` files. Runtime retention:: Annotations with runtime retention are read by the compiler, retained in the generated `.class` files, and also made available at runtime. Local variable annotations are not retained in class files (or at runtime) regardless of the retention policy set on the annotation type. See JLS 9.6.1.2. === Accessing Annotations at Runtime Java 5 supports a new interface, `java.lang.reflect.AnnotatedElement`, that is implemented by the reflection classes in Java (`Class`, `Constructor`, `Field`, `Method`, and `Package`). This interface gives you access to annotations _that have runtime retention_ via the `getAnnotation`, `getAnnotations`, and `isAnnotationPresent`. Because annotation types are just regular Java classes, the annotations returned by these methods can be queried just like any regular Java object. === Annotation Inheritance It is important to understand the rules relating to inheritance of annotations, as these have a bearing on join point matching based on the presence or absence of annotations. By default annotations are _not_ inherited. Given the following program [source, java] .... @MyAnnotation class Super { @Oneway public void foo() {} } class Sub extends Super { public void foo() {} } .... Then `Sub` _does not_ have the `MyAnnotation` annotation, and `Sub.foo()` is not an `@Oneway` method, despite the fact that it overrides `Super.foo()` which is. If an annotation type has the meta-annotation `@Inherited` then an annotation of that type on a _class_ will cause the annotation to be inherited by sub-classes. So, in the example above, if the `MyAnnotation` type had the `@Inherited` attribute, then `Sub` would have the `MyAnnotation` annotation. `@Inherited` annotations are not inherited when used to annotate anything other than a type. A type that implements one or more interfaces never inherits any annotations from the interfaces it implements. [[annotations-aspectmembers]] == Annotating Aspects AspectJ 5 supports annotations on aspects, and on method, field, constructor, advice, and inter-type declarations within aspects. Method and advice parameters may also be annotated. Annotations are not permitted on pointcut declarations or on `declare` statements. The following example illustrates the use of annotations in aspects: [source, java] .... @AspectAnnotation public abstract aspect ObserverProtocol { @InterfaceAnnotation interface Observer {} @InterfaceAnnotation interface Subject {} @ITDFieldAnnotation private List Subject.observers; @ITDMethodAnnotation public void Subject.addObserver(Observer o) { observers.add(o); } @ITDMethodAnnotation public void Subject.removeObserver(Observer o) { observers.remove(o); } @MethodAnnotation private void notifyObservers(Subject subject) { for(Observer o : subject.observers) notifyObserver(o,subject); } /** * Delegate to concrete sub-aspect the actual form of * notification for a given type of Observer. */ @MethodAnnotation protected abstract void notifyObserver(Observer o, Subject s); /* no annotations on pointcuts */ protected abstract pointcut observedEvent(Subject subject); @AdviceAnnotation after(Subject subject) returning : observedEvent(subject) { notifyObservers(subject); } } .... An annotation on an aspect will be inherited by sub-aspects, iff it has the `@Inherited` meta-annotation. AspectJ 5 supports a new XLint warning, "the pointcut associated with this advice does not match any join points". The warning is enabled by default and will be emitted by the compiler if the pointcut expression associated with an advice statement can be statically determined to not match any join points. The warning can be suppressed for an individual advice statement by using the `@SuppressAjWarnings({"adviceDidNotMatch"})` annotation. This works in the same way as the Java 5 SuppressWarnings annotation (See JLS 9.6.1.5), but has class file retention. [source, java] .... import org.aspectj.lang.annotation.SuppressAjWarnings; public aspect AnAspect { pointcut anInterfaceOperation() : execution(* AnInterface.*(..)); @SuppressAjWarnings // may not match if there are no implementers of the interface... before() : anInterfaceOperation() { // do something... } @SuppressAjWarnings("adviceDidNotMatch") // alternate form after() returning : anInterfaceOperation() { // do something... } } .... [[annotations-pointcuts-and-advice]] == Join Point Matching based on Annotations This section discusses changes to type pattern and signature pattern matching in AspectJ 5 that support matching join points based on the presence or absence of annotations. We then discuss means of exposing annotation values within the body of advice. === Annotation Patterns For any kind of annotated element (type, method, constructor, package, etc.), an annotation pattern can be used to match against the set of annotations on the annotated element.An annotation pattern element has one of two basic forms: * `@`, for example, `@Foo`, or `@org.xyz.Foo`. * `@()`, for example, `@(org.xyz..*)`, or `@(Foo || Boo)` These simple elements may be negated using `!`, and combined by simple concatentation. The pattern `@Foo @Boo` matches an annotated element that has both an annotation of type `Foo` and an annotation of type `Boo`. Some examples of annotation patterns follow: `@Immutable`:: Matches any annotated element which has an annotation of type `Immutable`. `!@Persistent`:: Matches any annotated element which does not have an annotation of type `Persistent`. `@Foo @Goo`:: Matches any annotated element which has both an annotation of type `Foo` and an annotation of type `Goo`. `@(Foo || Goo)`:: Matches any annotated element which has either an annotation of a type matching the type pattern `(Foo || Goo)`. In other words, an annotated element with either an annotation of type `Foo` or an annotation of type `Goo` (or both). (The parenthesis are required in this example). `@(org.xyz..*)`:: Matches any annotated element which has either an annotation of a type matching the type pattern `(org.xyz..*)`. In other words, an annotated element with an annotation that is declared in the org.xyz package or a sub-package. (The parenthesis are required in this example). === Type Patterns AspectJ 1.5 extends type patterns to allow an optional `AnnotationPattern` prefix. [source, text] .... TypePattern := SimpleTypePattern | '!' TypePattern | '(' AnnotationPattern? TypePattern ')' TypePattern '&&' TypePattern | TypePattern '||' TypePattern SimpleTypePattern := DottedNamePattern '+'? '[]'* DottedNamePattern := FullyQualifiedName RestOfNamePattern? | '*' NotStarNamePattern? RestOfNamePattern := '..' DottedNamePattern | '*' NotStarNamePattern? NotStarNamePattern := FullyQualifiedName RestOfNamePattern? | '..' DottedNamePattern FullyQualifiedName := JavaIdentifierCharacter+ ('.' JavaIdentifierCharacter+)* .... Note that in most cases when annotations are used as part of a type pattern, the parenthesis are required (as in `(@Foo Hello+)`). In some cases (such as a type pattern used within a `within` or `handler` pointcut expression), the parenthesis are optional: [source, text] .... OptionalParensTypePattern := AnnotationPattern? TypePattern .... The following examples illustrate the use of annotations in type patterns: `(@Immutable *)`:: Matches any type with an `@Immutable` annotation. `(!@Immutable *)`:: Matches any type which does not have an `@Immutable` annotation. `(@Immutable (org.xyz.* || org.abc.*))`:: Matches any type in the `org.xyz` or `org.abc` packages with the `@Immutable` annotation. `((@Immutable Foo+) || Goo)`:: Matches a type `Foo` or any of its subtypes, which have the `@Immutable` annotation, or a type `Goo`. `((@(Immutable || NonPersistent) org.xyz..*)`:: Matches any type in a package beginning with the prefix `org.xyz`, which has either the `@Immutable` annotation or the `@NonPersistent` annotation. `(@Immutable @NonPersistent org.xyz..*)`:: Matches any type in a package beginning with the prefix `org.xyz`, which has both an `@Immutable` annotation and an `@NonPersistent` annotation. `(@(@Inherited *) org.xyz..*)`:: Matches any type in a package beginning with the prefix `org.xyz`, which has an inheritable annotation. The annotation pattern `@(@Inherited *)` matches any annotation of a type matching the type pattern `@Inherited *`, which in turn matches any type with the `@Inherited` annotation. [[signaturePatterns]] === Signature Patterns [[fieldPatterns]] ==== Field Patterns A `FieldPattern` can optionally specify an annotation-matching pattern as the first element: [source, text] .... FieldPattern := AnnotationPattern? FieldModifiersPattern? TypePattern (TypePattern DotOrDotDot)? SimpleNamePattern FieldModifiersPattern := '!'? FieldModifier FieldModifiersPattern* FieldModifier := 'public' | 'private' | 'protected' | 'static' | 'transient' | 'final' DotOrDotDot := '.' | '..' SimpleNamePattern := JavaIdentifierChar+ ('*' SimpleNamePattern)? .... If present, the `AnnotationPattern` restricts matches to fields with annotations that match the pattern. For example: `@SensitiveData * *`:: Matches a field of any type and any name, that has an annotation of type `@SensitiveData` `@SensitiveData List org.xyz..*.*`:: Matches a member field of a type in a package with prefix `org.xzy`, where the field is of type `List`, and has an annotation of type `@SensitiveData` `(@SensitiveData *) org.xyz..*.*`:: Matches a member field of a type in a package with prefix `org.xzy`, where the field is of a type which has a `@SensitiveData` annotation. `@Foo (@Goo *) (@Hoo *).*`:: Matches a field with an annotation `@Foo`, of a type with an annotation `@Goo`, declared in a type with annotation `@Hoo`. `@Persisted @Classified * *`:: Matches a field with an annotation `@Persisted` and an annotation `@Classified`. [[methodPatterns]] ==== Method and Constructor Patterns A `MethodPattern` can optionally specify an annotation-matching pattern as the first element. [source, text] .... MethodPattern := AnnotationPattern? MethodModifiersPattern? TypePattern (TypePattern DotOrDotDot)? SimpleNamePattern '(' FormalsPattern ')'ThrowsPattern? MethodModifiersPattern := '!'? MethodModifier MethodModifiersPattern* MethodModifier := 'public' | 'private' | 'protected' | 'static' | 'synchronized' | 'final' FormalsPattern := '..' (',' FormalsPatternAfterDotDot)* | OptionalParensTypePattern (',' FormalsPattern)* | TypePattern '...' FormalsPatternAfterDotDot := OptionalParensTypePattern (',' FormalsPatternAfterDotDot)* | TypePattern '...' ThrowsPattern := 'throws' TypePatternList TypePatternList := TypePattern (',' TypePattern)* .... A `ConstructorPattern` has the form [source, text] .... ConstructorPattern := AnnotationPattern? ConstructorModifiersPattern? (TypePattern DotOrDotDot)? 'new' '(' FormalsPattern ')' ThrowsPattern? ConstructorModifiersPattern := '!'? ConstructorModifier ConstructorModifiersPattern* ConstructorModifier := 'public' | 'private' | 'protected' .... The optional `AnnotationPattern` at the beginning of a method or constructor pattern restricts matches to methods/constructors with annotations that match the pattern. For example: `@Oneway * *(..)`:: Matches a method with any return type and any name, that has an annotation of type `@Oneway`. `@Transaction * (@Persistent org.xyz..*).*(..)`:: Matches a method with the `@Transaction` annotation, declared in a type with the `@Persistent` annotation, and in a package beginning with the `org.xyz` prefix. `* *.*(@Immutable *,..)`:: Matches any method taking at least one parameter, where the parameter type has an annotation `@Immutable`. === Example Pointcuts `within(@Secure *)`:: Matches any join point where the code executing is declared in a type with an `@Secure` annotation. The format of the `within` pointcut designator in AspectJ 5 is `'within' '(' OptionalParensTypePattern ')'`. `staticinitialization(@Persistent *)`:: Matches the staticinitialization join point of any type with the `@Persistent` annotation. The format of the `staticinitialization` pointcut designator in AspectJ 5 is `'staticinitialization' '(' OptionalParensTypePattern ')'`. `call(@Oneway * *(..))`:: Matches a call to a method with a `@Oneway` annotation. `execution(public (@Immutable *) org.xyz..*.*(..))`:: The execution of any public method in a package with prefix `org.xyz`, where the method returns an immutable result. `set(@Cachable * *)`:: Matches the set of any cachable field. `handler(!@Catastrophic *)`:: Matches the handler join point for the handling of any exception that is not `Catastrophic`. The format of the `handler` pointcut designator in AspectJ 5 is `'handler' '(' OptionalParensTypePattern ')'`. === Runtime type matching and context exposure AspectJ 5 supports a set of "@" pointcut designators which can be used both to match based on the presence of an annotation at runtime, and to expose the annotation value as context in a pointcut or advice definition. These designators are `@args, @this, @target, @within, @withincode`, and `@annotation` It is a compilation error to attempt to match on an annotation type that does not have runtime retention using `@this, @target` or `@args`. It is a compilation error to attempt to use any of these designators to expose an annotation value that does not have runtime retention. The `this()`, `target()`, and `args()` pointcut designators allow matching based on the runtime type of an object, as opposed to the statically declared type. In AspectJ 5, these designators are supplemented with three new designators : `@this()` (read, "this annotation"), `@target()`, and `@args()`. Like their counterparts, these pointcut designators can be used both for join point matching, and to expose context. The format of these new designators is: [source, text] .... AtThis := '@this' '(' AnnotationOrIdentifer ')' AtTarget := '@target' '(' AnnotationOrIdentifier ')' AnnotationOrIdentifier := FullyQualifiedName | Identifier AtArgs := '@args' '(' AnnotationsOrIdentifiersPattern ')' AnnotationsOrIdentifiersPattern := '..' (',' AnnotationsOrIdentifiersPatternAfterDotDot)? | AnnotationOrIdentifier (',' AnnotationsOrIdentifiersPattern)* | '*' (',' AnnotationsOrIdentifiersPattern)* AnnotationsOrIdentifiersPatternAfterDotDot := AnnotationOrIdentifier (',' AnnotationsOrIdentifiersPatternAfterDotDot)* | '*' (',' AnnotationsOrIdentifiersPatternAfterDotDot)* .... The forms of `@this()` and `@target()` that take a single annotation name are analogous to their counterparts that take a single type name. They match at join points where the object bound to `this` (or `target`, respectively) has an annotation of the specified type. For example: `@this(Foo)`:: Matches any join point where the object currently bound to 'this' has an annotation of type `Foo`. `call(* *(..)) && @target(Classified)`:: Matches a call to any object where the target of the call has a `@Classified` annotation. Annotations can be exposed as context in the body of advice by using the forms of `@this(), @target()` and `@args()` that use bound variables in the place of annotation names. For example: [source, java] .... pointcut callToClassifiedObject(Classified classificationInfo) : call(* *(..)) && @target(classificationInfo); pointcut txRequiredMethod(Tx transactionAnnotation) : execution(* *(..)) && @this(transactionAnnotation) && if(transactionAnnotation.policy() == TxPolicy.REQUIRED); .... The `@args` pointcut designator behaves as its `args` counterpart, matching join points based on number and position of arguments, and supporting the `*` wildcard and at most one `..` wildcard. An annotation at a given position in an `@args` expression indicates that the runtime type of the argument in that position at a join point must have an annotation of the indicated type. For example: [source, java] .... /** * matches any join point with at least one argument, and where the * type of the first argument has the @Classified annotation */ pointcut classifiedArgument() : @args(Classified,..); /** * matches any join point with three arguments, where the third * argument has an annotation of type @Untrusted. */ pointcut untrustedData(Untrusted untrustedDataSource) : @args(*,*,untrustedDataSource); .... In addition to accessing annotation information at runtime through context binding, access to `AnnotatedElement` information is also available reflectively with the body of advice through the `thisJoinPoint`, `thisJoinPointStaticPart`, and `thisEnclosingJoinPointStaticPart` variables. To access annotations on the arguments, or object bound to this or target at a join point you can use the following code fragments: [source, java] .... Annotation[] thisAnnotations = thisJoinPoint.getThis().getClass().getAnnotations(); Annotation[] targetAnnotations = thisJoinPoint.getTarget().getClass().getAnnotations(); Annotation[] firstParamAnnotations = thisJoinPoint.getArgs()[0].getClass().getAnnotations(); .... The `@within` and `@withincode` pointcut designators match any join point where the executing code is defined within a type (`@within`), or a method/constructor (`@withincode`) that has an annotation of the specified type. The form of these designators is: [source, text] .... AtWithin := '@within' '(' AnnotationOrIdentifier ')' AtWithinCode := '@withincode' '(' AnnotationOrIdentifier ')' .... Some examples of using these designators follow: `@within(Foo)`:: Matches any join point where the executing code is defined within a type which has an annotation of type `Foo`. `pointcut insideCriticalMethod(Critical c) : @withincode(c);`:: Matches any join point where the executing code is defined in a method or constructor which has an annotation of type `@Critical`, and exposes the value of the annotation in the parameter `c`. The `@annotation` pointcut designator matches any join point where the _subject_ of the join point has an annotation of the given type. Like the other @pcds, it can also be used for context exposure. [source, text] .... AtAnnotation := '@annotation' '(' AnnotationOrIdentifier ')' .... The subject of a join point is defined in the table in chapter one of this guide. Access to annotation information on members at a matched join point is also available through the `getSignature` method of the `JoinPoint` and `JoinPoint.StaticPart` interfaces. The `Signature` interfaces are extended with additional operations that provide access to the `java.lang.reflect` `Method, Field` and `Constructor` objects on which annnotations can be queried. The following fragment illustrates an example use of this interface to access annotation information. [source, java] .... Signature sig = thisJoinPointStaticPart.getSignature(); AnnotatedElement declaringTypeAnnotationInfo = sig.getDeclaringType(); if (sig instanceof MethodSignature) { // this must be a call or execution join point Method method = ((MethodSignature)sig).getMethod(); } .... _Note again that it would be nicer to add the method getAnnotationInfo directly to MemberSignature, but this would once more couple the runtime library to Java 5._ The `@this,@target` and `@args` pointcut designators can only be used to match against annotations that have runtime retention. The `@within, @withincode` and `@annotation` pointcut designators can only be used to match against annotations that have at least class-file retention, and if used in the binding form the annotation must have runtime retention. === Package and Parameter Annotations _Matching on package annotations is not supported in AspectJ. Support for this capability may be considered in a future release._ Parameter annotation matching is being added in AspectJ1.6. Initially only matching is supported but binding will be implemented at some point. Whether the annotation specified in a pointcut should be considered to be an annotation on the parameter type or an annotation on the parameter itself is determined through the use of parentheses around the parameter type. Consider the following: [source, java] .... @SomeAnnotation class AnnotatedType {} class C { public void foo(AnnotatedType a) {} public void goo(@SomeAnnotation String s) {} } .... The method foo has a parameter of an annotated type, and can be matched by this pointcut: [source, java] .... pointcut p(): execution(* *(@SomeAnnotation *)); .... When there is a single annotation specified like this, it is considered to be part of the type pattern in the match against the parameter: 'a parameter of any type that has the annotation @SomeAnnotation'. To match the parameter annotation case, the method goo, this is the pointcut: [source, java] .... pointcut p(): execution(* *(@SomeAnnotation (*))); .... The use of parentheses around the wildcard is effectively indicating that the annotation should be considered separately to the type pattern for the parameter type: 'a parameter of any type that has a parameter annotation of @SomeAnnotation'. To match when there is a parameter annotation and an annotation on the type as well: [source, java] .... pointcut p(): execution(* *(@SomeAnnotation (@SomeOtherAnnotation *))); .... The parentheses are grouping @SomeOtherAnnotation with the * to form the type pattern for the parameter, then the type @SomeAnnotation will be treated as a parameter annotation pattern. === Annotation Inheritance and pointcut matching According to the Java 5 specification, non-type annotations are not inherited, and annotations on types are only inherited if they have the `@Inherited` meta-annotation. Given the following program: [source, java] .... class C1 { @SomeAnnotation public void aMethod() {...} } class C2 extends C1 { public void aMethod() {...} } class Main { public static void main(String[] args) { C1 c1 = new C1(); C2 c2 = new C2(); c1.aMethod(); c2.aMethod(); } } aspect X { pointcut annotatedC2MethodCall() : call(@SomeAnnotation * C2.aMethod()); pointcut annotatedMethodCall() : call(@SomeAnnotation * aMethod()); } .... The pointcut `annotatedC2MethodCall` will not match anything since the definition of `aMethod` in `C2` does not have the annotation. The pointcut `annotatedMethodCall` matches `c1.aMethod()` but not `c2.aMethod()`. The call to `c2.aMethod` is not matched because join point matching for modifiers (the visibility modifiers, annotations, and throws clause) is based on the subject of the join point (the method actually being called). [[matchingOnAnnotationValues]] === Matching based on annotation values The `if` pointcut designator can be used to write pointcuts that match based on the values annotation members. For example: [source, java] .... pointcut txRequiredMethod(Tx transactionAnnotation) : execution(* *(..)) && @this(transactionAnnotation) && if(transactionAnnotation.policy() == TxPolicy.REQUIRED); .... [[annotations-decp]] == Using Annotations with declare statements === Declare error and declare warning Since pointcut expressions in AspectJ 5 support join point matching based on annotations, this facility can be exploited when writing `declare warning` and `declare error` statements. For example: [source, java] .... declare warning : withincode(@PerformanceCritical * *(..)) && call(@ExpensiveOperation * *(..)) : "Expensive operation called from within performance critical section"; .... [source, java] .... declare error : call(* org.xyz.model.*.*(..)) && !@within(Trusted) : "Untrusted code should not call the model classes directly"; .... === declare parents The general form of a `declare parents` statement is: [source, text] .... declare parents : TypePattern extends Type; declare parents : TypePattern implements TypeList; .... Since AspectJ 5 supports annotations as part of a type pattern specification, it is now possible to match types based on the presence of annotations _with either class-file or runtime retention_. For example: `declare parents : (@Secured *) implements SecuredObject;`:: All types with the `@Secured` annotation implement the `SecuredObject` inteface. `declare parents : (@Secured BankAccount+) implements SecuredObject;`:: The subset of types drawn from the `BankAccount` type and any subtype of `BankAccount`, where the `@Secured` annotation is present, implement the `SecuredObject` interface. An annotation type may not be used as the target of a declare parents statement. If an annotation type is named explicitly as the target of a declare parents statement, a compilation error will result. If an annotation type is matched by a non-explicit type pattern used in a declare parents statement it will be ignored (and an XLint warning issued). === declare precedence The general form of a declare precedence statement is: [source, java] .... declare precedence : TypePatList; .... AspectJ 5 allows the type patterns in the list to include annotation information as part of the pattern specification. For example: `declare precedence : (@Security *),*;`:: All aspects with the `@Security` annotation take precedence over any other aspects in the system. (Or, more informally, all security-related aspects take precedence). [[annotations-declare]] == Declare Annotation AspectJ 5 supports a new kind of declare statement, `declare annotation`. This takes different forms according to the recipient of the annotation: `declare @type` for types, `declare @method` for methods, `declare @constructor` for constructors, and `declare @field` for fields. `declare @package` may be supported in a future release. The general form is: [source, text] .... declare @ : ElementPattern : Annotation ; .... Where annotation is a regular annotation expression as defined in the Java 5 language. If the annotation has the `@Target` meta-annotation, then the elements matched by `ElementPattern` must be of the kind specified by the `@Target` annotation. `ElementPattern` is defined as follows: [source, text] .... ElementPattern := TypePattern | MethodPattern | ConstructorPattern | FieldPattern .... The following examples illustrate the use of `declare annotation`. `declare @type : org.xyz.model..* : @BusinessDomain ;`:: All types defined in a package with the prefix `org.xyz.model` have the `@BusinessDomain` annotation. declare @method : public * BankAccount+.*(..) : `@Secured(role="supervisor")`:: All public methods in `BankAccount` and its subtypes have the annotation `@Secured(role="supervisor")`. declare @constructor : BankAccount+.new(..) : `@Secured(role="supervisor")`:: All constructors in `BankAccount` and its subtypes have the annotation `@Secured(role="supervisor")`. `declare @field : * DAO+.* : @Persisted;`:: All fields defined in `DAO` or its subtypes have the `@Persisted` annotation. [[annotations-itds]] == Inter-type Declarations An annotation type may not be the target of an inter-type declaration.