[[jpsigs]] = Join Point Signatures Many of the extensions to the AspectJ language to address the new features of Java 5 are derived from a simple set of principles for join point matching. In this section, we outline these principles as a foundation for understanding the matching rules in the presence of annotations, generics, covariance, varargs, and autoboxing. == Join Point Matching AspectJ supports 11 different kinds of join points. These are the `method call, method execution, constructor call, constructor execution, field get, field set, pre-initialization, initialization, static initialization, handler,` and `advice execution` join points. The _kinded_ pointcut designators match based on the kind of a join point. These are the `call, execution, get, set, preinitialization, initialization, staticinitialization, handler,` and `adviceexecution` designators. A kinded pointcut is written using patterns, some of which match based on _signature_, and some of which match based on _modifiers_. For example, in the `call` pointcut designator: [source, text] .... call(ModifierPattern TypePattern TypePattern.IdPattern(TypePatternList) ThrowsPattern) .... the modifiers matching patterns are `ModifierPattern` and `ThrowsPattern`, and the signature matching patterns are `TypePattern TypePattern.IdPattern(TypePatternList)`. A join point has potentially multiple signatures, but only one set of modifiers. _A kinded primitive pointcut matches a particular join point if and only if_: [arabic] . They are of the same kind . The signature pattern (exactly) matches at least one signature of the join point . The modifiers pattern matches the modifiers of the subject of the join point These rules make it very easily to quickly determine whether a given pointcut matches a given join point. In the next two sections, we describe what the signature(s) of a join point are, and what the subjects of join points are. [[join-point-signatures]] == Join Point Signatures Call, execution, get, and set join points may potentially have multiple signatures. All other join points have exactly one signature. The following table summarizes the constituent parts of a join point signature for the different kinds of join point. [cols=",,,,,,",options="header",] |=== |Join Point Kind |Return Type |Declaring Type |Id |Parameter Types |Field Type |Exception Type |Method call |+ |+ |+ |+ | | |Method execution |+ |+ |+ |+ | | |Constructor call | |+ | |+ | | |Constructor execution | |+ | |+ | | |Field get | |+ |+ | |+ | |Field set | |+ |+ | |+ | |Pre-initialization | |+ | |+ | | |Initialization | |+ | |+ | | |Static initialization | |+ | | | | |Handler | | | | | |+ |Advice execution | |+ | |+ | | |=== Note that whilst an advice execution join point has a signature comprising the declaring type of the advice and the advice parameter types, the `adviceexecution` pointcut designator does not support matching based on this signature. The signatures for most of the join point kinds should be self-explanatory, except for field get and set, and method call and execution join points, which can have multiple signatures. Each signature of a method call or execution join point has the same id and parameter types, but the declaring type and return type (with covariance) may vary. Each signature of a field get or set join point has the same id and field type, but the declaring type may vary. The following sections examine signatures for these join points in more detail. === Method call join point signatures For a call join point where a call is made to a method `m(parameter_types)` on a target type `T` (where `T` is the static type of the target): [source, java] .... T t = new T(); t.m("hello"); // <= call join point occurs when this line is executed .... Then the signature `R(T) T.m(parameter_types)` is a signature of the call join point, where `R(T)` is the return type of `m` in `T`, and `parameter_types` are the parameter types of `m`. If `T` itself does not declare a definition of `m(parameter_types)`, then `R(T)` is the return type in the definition of `m` that `T` inherits. Given the call above, and the definition of `T.m`: [source, java] .... interface Q { R m(String s); } class P implements Q { R m(String s) {...} } class S extends P { R' m(String s) {...} } class T extends S {} .... Then `R' T.m(String)` is a signature of the call join point for `t.m("hello")`. For each ancestor (super-type) `A` of `T`, if `m(parameter_types)` is defined for that super-type, then `R(A) A.m(parameter_types)` is a signature of the call join point, where `R(A)` is the return type of ` m(parameter_types)` as defined in `A`, or as inherited by `A` if `A` itself does not provide a definition of `m(parameter_types)`. Continuing the example from above,we can deduce that [source, java] .... R' S.m(String) R P.m(String) R Q.m(String) .... are all additional signatures for the call join point arising from the call `t.m("hello")`. Thus this call join point has four signatures in total. Every signature has the same id and parameter types, and a different declaring type. === Method execution join point signatures Join point signatures for execution join points are defined in a similar manner to signatures for call join points. Given the hierarchy: [source, java] .... interface Q { R m(String s); } class P implements Q { R m(String s) {...} } class S extends P { R' m(String s) {...} } class T extends S { } class U extends T { R' m(String s) {...} } .... Then the execution join point signatures arising as a result of the call to `u.m("hello")` are: [source, java] .... R' U.m(String) R' S.m(String) R P.m(String) R Q.m(String) .... Each signature has the same id and parameter types, and a different declaring type. There is one signature for each type that provides its own declaration of the method. Hence in this example there is no signature `R' T.m(String)` as `T` does not provide its own declaration of the method. === Field get and set join point signatures For a field get join point where an access is made to a field `f` of type `F` on a object with declared type `T`, then `F T.f` is a signature of the get join point. If `T` does not directly declare a member `f`, then for each super type `S` of `T`, up to and including the most specific super type of `T` that does declare the member `f`, `F S.f` is a signature of the join point. For example, given the hierarchy: [source, java] .... class P { F f; } class S extends P { F f; } class T extends S { } .... Then the join point signatures for a field get join point of the field `f` on an object with declared type `T` are: [source, java] .... F S.f F T.f .... The signatures for a field set join point are derived in an identical manner. == Join Point Modifiers Every join point has a single set of modifiers - these include the standard Java modifiers such as `public, private, static, abstract` etc., any annotations, and the throws clauses of methods and constructors. These modifiers are the modifiers of the _subject_ of the join point. The following table defines the join point subject for each kind of join point. [cols=",",options="header",] |=== |Join Point Kind |Subject |Method call |The method picked out by Java as the static target of the method call. |Method execution |The method that is executing. |Constructor call |The constructor being called. |Constructor execution |The constructor executing. |Field get |The field being accessed. |Field set |The field being set. |Pre-initialization |The first constructor executing in this constructor chain. |Initialization |The first constructor executing in this constructor chain. |Static initialization |The type being initialized. |Handler |The declared type of the exception being handled. |Advice execution |The advice being executed. |=== For example, given the following types [source, java] .... public class X { @Foo protected void doIt() {...} } public class Y extends X { public void doIt() {...} } .... Then the modifiers for a call to `(Y y) y.doIt()` are simply `{ public }`. The modifiers for a call to `(X x) x.doIt()` are `{ @Foo, protected }`. [[join-point-matching-summary]] == Summary of Join Point Matching A join point has potentially multiple signatures, but only one set of modifiers. _A kinded primitive pointcut matches a particular join point if and only if_: [arabic] . They are of the same kind . The signature pattern (exactly) matches at least one signature of the join point . The modifiers pattern matches the modifiers of the subject of the join point Given the hierarchy [source, java] .... interface Q { R m(String s); } class P implements Q { @Foo public R m(String s) {...} } class S extends P { @Bar public R' m(String s) {...} } class T extends S {} .... and the program fragment: [source, java] .... P p = new P(); S s = new S(); T t = new T(); ... p.m("hello"); s.m("hello"); t.m("hello"); .... The the pointcut `call(@Foo R P.m(String))` matches the call `p.m("hello")` since both the signature and the modifiers match. It does not match the call `s.m("hello")` because even though the signature pattern matches one of the signatures of the join point, the modifiers pattern does not match the modifiers of the method m in S which is the static target of the call. The pointcut `call(R' m(String))` matches the calls `t.m("hello")` and `s.m("hello")`. It does not match the call `p.m("hello")` since the signature pattern does not match any signature for the call join point of m in P.