The AspectJ Language Introduction The previous chapter, , was a brief overview of the AspectJ language. You should read this chapter to understand AspectJ's syntax and semantics. It covers the same material as the previous chapter, but more completely and in much more detail. We will start out by looking at an example aspect that we'll build out of a pointcut, an introduction, and two pieces of advice. This example aspect will gives us something concrete to talk about. The Anatomy of an Aspect This lesson explains the parts of AspectJ's aspects. By reading this lesson you will have an overview of what's in an aspect and you will be exposed to the new terminology introduced by AspectJ. An Example Aspect Here's an example of an aspect definition in AspectJ: The FaultHandler consists of one inter-type field on Server (line 03), two methods (lines 05-07 and 09-11), one pointcut definition (line 13), and two pieces of advice (lines 15-17 and 19-22). This covers the basics of what aspects can contain. In general, aspects consist of an association of other program entities, ordinary variables and methods, pointcut definitions, inter-type declarations, and advice, where advice may be before, after or around advice. The remainder of this lesson focuses on those crosscut-related constructs. Pointcuts AspectJ's pointcut definitions give names to pointcuts. Pointcuts themselves pick out join points, i.e. interesting points in the execution of a program. These join points can be method or constructor invocations and executions, the handling of exceptions, field assignments and accesses, etc. Take, for example, the pointcut definition in line 13: This pointcut, named services, picks out those points in the execution of the program when Server objects have their public methods called. It also allows anyone using the services pointcut to access the Server object whose method is being called. The idea behind this pointcut in the FaultHandler aspect is that fault-handling-related behavior must be triggered on the calls to public methods. For example, the server may be unable to proceed with the request because of some fault. The calls of those methods are, therefore, interesting events for this aspect, in the sense that certain fault-related things will happen when these events occur. Part of the context in which the events occur is exposed by the formal parameters of the pointcut. In this case, that consists of objects of type Server. That formal parameter is then being used on the right hand side of the declaration in order to identify which events the pointcut refers to. In this case, a pointcut picking out join points where a Server is the target of some operation (target(s)) is being composed (, meaning and) with a pointcut picking out call join points (call(...)). The calls are identified by signatures that can include wild cards. In this case, there are wild cards in the return type position (first *), in the name position (second *) and in the argument list position (..); the only concrete information is given by the qualifier public. Pointcuts pick out arbitrarily large numbers of join points of a program. But they pick out only a small number of kinds of join points. Those kinds of join points correspond to some of the most important concepts in Java. Here is an incomplete list: method call, method execution, exception handling, instantiation, constructor execution, and field access. Each kind of join point can be picked out by its own specialized pointcut that you will learn about in other parts of this guide. Advice A piece of advice brings together a pointcut and a body of code to define aspect implementation that runs at join points picked out by the pointcut. For example, the advice in lines 15-17 specifies that the following piece of code is executed when instances of the Server class have their public methods called, as specified by the pointcut services. More specifically, it runs when those calls are made, just before the corresponding methods are executed. The advice in lines 19-22 defines another piece of implementation that is executed on the same pointcut: But this second method executes after those operations throw exception of type FaultException. There are two other variations of after advice: upon successful return and upon return, either successful or with an exception. There is also a third kind of advice called around. You will see those in other parts of this guide. Join Points and Pointcuts Consider the following Java class: In order to get an intuitive understanding of AspectJ's join points and pointcuts, let's go back to some of the basic principles of Java. Consider the following a method declaration in class Point: This piece of program says that that when method named setX with an int argument called on an object of type Point, then the method body { this.x = x; } is executed. Similarly, the constructor of the class states that when an object of type Point is instantiated through a constructor with two int arguments, then the constructor body { this.x = x; this.y = y; } is executed. One pattern that emerges from these descriptions is
When something happens, then something gets executed.
In object-oriented programs, there are several kinds of "things that happen" that are determined by the language. We call these the join points of Java. Join points consist of things like method calls, method executions, object instantiations, constructor executions, field references and handler executions. (See the for a complete listing.)
Pointcuts pick out these join points. For example, the pointcut picks out each call to setX(int) or setY(int) when called on an instance of Point. Here's another example: This pointcut picks out each the join point when exceptions of type IOException are handled inside the code defined by class MyClass. Pointcut definitions consist of a left-hand side and a right-hand side, separated by a colon. The left-hand side consists of the pointcut name and the pointcut parameters (i.e. the data available when the events happen). The right-hand side consists of the pointcut itself. Some Example Pointcuts Here are examples of pointcuts picking out when a particular method body executes execution(void Point.setX(int)) when a method is called call(void Point.setX(int)) when an exception handler executes handler(ArrayOutOfBoundsException) when the object currently executing (i.e. this) is of type SomeType this(SomeType) when the target object is of type SomeType target(SomeType) when the executing code belongs to class MyClass within(MyClass) when the join point is in the control flow of a call to a Test's no-argument main method cflow(call(void Test.main())) Pointcuts compose through the operations or ("||"), and ("") and not ("!"). It is possible to use wildcards. So execution(* *(..)) call(* set(..)) means (1) the execution of any method regardless of return or parameter types, and (2) the call to any method named set regardless of return or parameter types -- in case of overloading there may be more than one such set method; this pointcut picks out calls to all of them. You can select elements based on types. For example, execution(int *()) call(* setY(long)) call(* Point.setY(int)) call(*.new(int, int)) means (1) the execution of any method with no parameters that returns an int, (2) the call to any setY method that takes a long as an argument, regardless of return type or declaring type, (3) the call to any of Point's setY methods that take an int as an argument, regardless of return type, and (4) the call to any classes' constructor, so long as it takes exactly two ints as arguments. You can compose pointcuts. For example, target(Point) call(int *()) call(* *(..)) (within(Line) || within(Point)) within(*) execution(*.new(int)) !this(Point) call(int *(..)) means (1) any call to an int method with no arguments on an instance of Point, regardless of its name, (2) any call to any method where the call is made from the code in Point's or Line's type declaration, (3) the execution of any constructor taking exactly one int argument, regardless of where the call is made from, and (4) any method call to an int method when the executing object is any type except Point. You can select methods and constructors based on their modifiers and on negations of modifiers. For example, you can say: call(public * *(..)) execution(!static * *(..)) execution(public !static * *(..)) which means (1) any call to a public method, (2) any execution of a non-static method, and (3) any execution of a public, non-static method. Pointcuts can also deal with interfaces. For example, given the interface the pointcut call(* MyInterface.*(..)) picks out any call to a method in MyInterface's signature -- that is, any method defined by MyInterface or inherited by one of its a supertypes. call vs. execution When methods and constructors run, there are two interesting times associated with them. That is when they are called, and when they actually execute. AspectJ exposes these times as call and execution join points, respectively, and allows them to be picked out specifically by call and execution pointcuts. So what's the difference between these join points? Well, there are a number of differences: Firstly, the lexical pointcut declarations within and withincode match differently. At a call join point, the enclosing code is that of the call site. This means that call(void m()) withincode(void m()) will only capture directly recursive calls, for example. At an execution join point, however, the program is already executing the method, so the enclosing code is the method itself: execution(void m()) withincode(void m()) is the same as execution(void m()). Secondly, the call join point does not capture super calls to non-static methods. This is because such super calls are different in Java, since they don't behave via dynamic dispatch like other calls to non-static methods. The rule of thumb is that if you want to pick a join point that runs when an actual piece of code runs (as is often the case for tracing), use execution, but if you want to pick one that runs when a particular signature is called (as is often the case for production aspects), use call. Pointcut composition Pointcuts are put together with the operators and (spelled &&), or (spelled ||), and not (spelled !). This allows the creation of very powerful pointcuts from the simple building blocks of primitive pointcuts. This composition can be somewhat confusing when used with primitive pointcuts like cflow and cflowbelow. Here's an example: cflow(P) picks out each join point in the control flow of the join points picked out by P. So, pictorially: P --------------------- \ \ cflow of P \ What does cflow(P) && cflow(Q) pick out? Well, it picks out each join point that is in both the control flow of P and in the control flow of Q. So... P --------------------- \ \ cflow of P \ \ \ Q -------------\------- \ \ \ cflow of Q \ cflow(P) && cflow(Q) \ \ Note that P and Q might not have any join points in common... but their control flows might have join points in common. But what does cflow(P && Q) mean? Well, it means the control flow of those join points that are both picked out by P and picked out by Q. P && Q ------------------- \ \ cflow of (P && Q) \ and if there are no join points that are both picked by P and picked out by Q, then there's no chance that there are any join points in the control flow of (P && Q). Here's some code that expresses this. The !within(A) pointcut above is required to avoid the printPC pointcut applying to the System.out.println call in the advice body. If this was not present a recursive call would result as the pointcut would apply to its own advice. (See for more details.) Pointcut Parameters Consider again the first pointcut definition in this chapter: As we've seen, this pointcut picks out each call to setX(int) or setY(int) methods where the target is an instance of Point. The pointcut is given the name setters and no parameters on the left-hand side. An empty parameter list means that none of the context from the join points is published from this pointcut. But consider another version of version of this pointcut definition: This version picks out exactly the same join points. But in this version, the pointcut has one parameter of type Point. This means that any advice that uses this pointcut has access to a Point from each join point picked out by the pointcut. Inside the pointcut definition this Point is named p is available, and according to the right-hand side of the definition, that Point p comes from the target of each matched join point. Here's another example that illustrates the flexible mechanism for defining pointcut parameters: This pointcut also has a parameter of type Point. Similar to the setters pointcut, this means that anyone using this pointcut has access to a Point from each join point. But in this case, looking at the right-hand side we find that the object named in the parameters is not the target Point object that receives the call; it's the argument (also of type Point) passed to the equals method when some other Point is the target. If we wanted access to both Points, then the pointcut definition that would expose target Point p1 and argument Point p2 would be Let's look at another variation of the setters pointcut: In this case, a Point object and an int value are exposed by the named pointcut. Looking at the the right-hand side of the definition, we find that the Point object is the target object, and the int value is the called method's argument. The use of pointcut parameters is relatively flexible. The most important rule is that all the pointcut parameters must be bound at every join point picked out by the pointcut. So, for example, the following pointcut definition will result in a compilation error: because p1 is only bound when calling setX, and p2 is only bound when calling setY, but the pointcut picks out all of these join points and tries to bind both p1 and p2. Example: <literal>HandleLiveness</literal> The example below consists of two object classes (plus an exception class) and one aspect. Handle objects delegate their public, non-static operations to their Partner objects. The aspect HandleLiveness ensures that, before the delegations, the partner exists and is alive, or else it throws an exception.
Advice Advice defines pieces of aspect implementation that execute at well-defined points in the execution of the program. Those points can be given either by named pointcuts (like the ones you've seen above) or by anonymous pointcuts. Here is an example of an advice on a named pointcut: And here is exactly the same example, but using an anonymous pointcut: Here are examples of the different advice: This before advice runs just before the join points picked out by the (anonymous) pointcut: This after advice runs just after each join point picked out by the (anonymous) pointcut, regardless of whether it returns normally or throws an exception: This after returning advice runs just after each join point picked out by the (anonymous) pointcut, but only if it returns normally. The return value can be accessed, and is named x here. After the advice runs, the return value is returned: This after throwing advice runs just after each join point picked out by the (anonymous) pointcut, but only when it throws an exception of type Exception. Here the exception value can be accessed with the name e. The advice re-raises the exception after it's done: This around advice traps the execution of the join point; it runs instead of the join point. The original action associated with the join point can be invoked through the special proceed call: Inter-type declarations Aspects can declare members (fields, methods, and constructors) that are owned by other types. These are called inter-type members. Aspects can also declare that other types implement new interfaces or extend a new class. Here are examples of some such inter-type declarations: This declares that each Server has a boolean field named disabled, initialized to false: It is declared private, which means that it is private to the aspect: only code in the aspect can see the field. And even if Server has another private field named disabled (declared in Server or in another aspect) there won't be a name collision, since no reference to disabled will be ambiguous. This declares that each Point has an int method named getX with no arguments that returns whatever this.x is: Inside the body, this is the Point object currently executing. Because the method is publically declared any code can call it, but if there is some other Point.getX() declared there will be a compile-time conflict. This publically declares a two-argument constructor for Point: This publicly declares that each Point has an int field named x, initialized to zero: Because this is publically declared, it is an error if Point already has a field named x (defined by Point or by another aspect). This declares that the Point class implements the Comparable interface: Of course, this will be an error unless Point defines the methods required by Comparable. This declares that the Point class extends the GeometricObject class. An aspect can have several inter-type declarations. For example, the following declarations publicly declare that Point has both a String field name and a void method setName(String) (which refers to the name field declared by the aspect). An inter-type member can only have one target type, but often you may wish to declare the same member on more than one type. This can be done by using an inter-type member in combination with a private interface: This declares a marker interface HasName, and also declares that any type that is either Point, Line, or Square implements that interface. It also privately declares that all HasName object have a String field called name, and publically declares that all HasName objects have a String method getName() (which refers to the privately declared name field). As you can see from the above example, an aspect can declare that interfaces have fields and methods, even non-constant fields and methods with bodies. Inter-type Scope AspectJ allows private and package-protected (default) inter-type declarations in addition to public inter-type declarations. Private means private in relation to the aspect, not necessarily the target type. So, if an aspect makes a private inter-type declaration of a field Then code in the aspect can refer to Foo's x field, but nobody else can. Similarly, if an aspect makes a package-protected introduction, then everything in the aspect's package (which may or may not be Foo's package) can access x. Example: <literal>PointAssertions</literal> The example below consists of one class and one aspect. The aspect privately declares the assertion methods of Point, assertX and assertY. It also guards calls to setX and setY with calls to these assertion methods. The assertion methods are declared privately because other parts of the program (including the code in Point) have no business accessing the assert methods. Only the code inside of the aspect can call those methods. = 0); } private boolean Point.assertY(int y) { return (y <= 100 && y >= 0); } before(Point p, int x): target(p) && args(x) && call(void setX(int)) { if (!p.assertX(x)) { System.out.println("Illegal value for x"); return; } } before(Point p, int y): target(p) && args(y) && call(void setY(int)) { if (!p.assertY(y)) { System.out.println("Illegal value for y"); return; } } } ]]> thisJoinPoint AspectJ provides a special reference variable, thisJoinPoint, that contains reflective information about the current join point for the advice to use. The thisJoinPoint variable can only be used in the context of advice, just like this can only be used in the context of non-static methods and variable initializers. In advice, thisJoinPoint is an object of type org.aspectj.lang.JoinPoint. One way to use it is simply to print it out. Like all Java objects, thisJoinPoint has a toString() method that makes quick-and-dirty tracing easy: The type of thisJoinPoint includes a rich reflective class hierarchy of signatures, and can be used to access both static and dynamic information about join points such as the arguments of the join point: In addition, it holds an object consisting of all the static information about the join point such as corresponding line number and static signature: If you only need the static information about the join point, you may access the static part of the join point directly with the special variable thisJoinPointStaticPart. Using thisJoinPointStaticPart will avoid the run-time creation of the join point object that may be necessary when using thisJoinPoint directly. It is always the case that One more reflective variable is available: thisEnclosingJoinPointStaticPart. This, like thisJoinPointStaticPart, only holds the static part of a join point, but it is not the current but the enclosing join point. So, for example, it is possible to print out the calling source location (if available) with