The previous chapter described the Spring 2.0 and later version's support for AOP using @AspectJ and schema-based aspect definitions. In this chapter we discuss the lower-level Spring AOP APIs and the AOP support used in Spring 1.2 applications. For new applications, we recommend the use of the Spring 2.0 and later AOP support described in the previous chapter, but when working with existing applications, or when reading books and articles, you may come across Spring 1.2 style examples. Spring 3.0 is backwards compatible with Spring 1.2 and everything described in this chapter is fully supported in Spring 3.0.
Let's look at how Spring handles the crucial pointcut concept.
Spring's pointcut model enables pointcut reuse independent of advice types. It's possible to target different advice using the same pointcut.
The org.springframework.aop.Pointcut
interface
is the central interface, used to target advices to particular classes
and methods. The complete interface is shown below:
public interface Pointcut { ClassFilter getClassFilter(); MethodMatcher getMethodMatcher(); }
Splitting the Pointcut
interface
into two parts allows reuse of class and method matching parts, and
fine-grained composition operations (such as performing a "union" with
another method matcher).
The ClassFilter
interface is used
to restrict the pointcut to a given set of target classes. If the
matches()
method always returns true, all target
classes will be matched:
public interface ClassFilter { boolean matches(Class clazz); }
The MethodMatcher
interface is
normally more important. The complete interface is shown below:
public interface MethodMatcher { boolean matches(Method m, Class targetClass); boolean isRuntime(); boolean matches(Method m, Class targetClass, Object[] args); }
The matches(Method, Class)
method is used to
test whether this pointcut will ever match a given method on a target
class. This evaluation can be performed when an AOP proxy is created, to
avoid the need for a test on every method invocation. If the 2-argument
matches method returns true for a given method, and the
isRuntime()
method for the MethodMatcher returns
true, the 3-argument matches method will be invoked on every method
invocation. This enables a pointcut to look at the arguments passed to
the method invocation immediately before the target advice is to
execute.
Most MethodMatchers are static, meaning that their
isRuntime()
method returns false. In this case, the
3-argument matches method will never be invoked.
Tip | |
---|---|
If possible, try to make pointcuts static, allowing the AOP framework to cache the results of pointcut evaluation when an AOP proxy is created. |
Spring supports operations on pointcuts: notably, union and intersection.
Union means the methods that either pointcut matches.
Intersection means the methods that both pointcuts match.
Union is usually more useful.
Pointcuts can be composed using the static methods in the org.springframework.aop.support.Pointcuts class, or using the ComposablePointcut class in the same package. However, using AspectJ pointcut expressions is usually a simpler approach.
Since 2.0, the most important type of pointcut used by Spring is
org.springframework.aop.aspectj.AspectJExpressionPointcut
.
This is a pointcut that uses an AspectJ supplied library to parse an
AspectJ pointcut expression string.
See the previous chapter for a discussion of supported AspectJ pointcut primitives.
Spring provides several convenient pointcut implementations. Some can be used out of the box; others are intended to be subclassed in application-specific pointcuts.
Static pointcuts are based on method and target class, and cannot take into account the method's arguments. Static pointcuts are sufficient - and best - for most usages. It's possible for Spring to evaluate a static pointcut only once, when a method is first invoked: after that, there is no need to evaluate the pointcut again with each method invocation.
Let's consider some static pointcut implementations included with Spring.
One obvious way to specify static pointcuts is regular
expressions. Several AOP frameworks besides Spring make this
possible.
org.springframework.aop.support.JdkRegexpMethodPointcut
is a generic regular expression pointcut, using the regular
expression support in JDK 1.4+.
Using the JdkRegexpMethodPointcut
class,
you can provide a list of pattern Strings. If any of these is a
match, the pointcut will evaluate to true. (So the result is
effectively the union of these pointcuts.)
The usage is shown below:
<bean id="settersAndAbsquatulatePointcut" class="org.springframework.aop.support.JdkRegexpMethodPointcut"> <property name="patterns"> <list> <value>.*set.*</value> <value>.*absquatulate</value> </list> </property> </bean>
Spring provides a convenience class,
RegexpMethodPointcutAdvisor
, that allows us to
also reference an Advice (remember that an Advice can be an
interceptor, before advice, throws advice etc.). Behind the scenes,
Spring will use a JdkRegexpMethodPointcut
. Using
RegexpMethodPointcutAdvisor
simplifies wiring, as
the one bean encapsulates both pointcut and advice, as shown
below:
<bean id="settersAndAbsquatulateAdvisor" class="org.springframework.aop.support.RegexpMethodPointcutAdvisor"> <property name="advice"> <ref local="beanNameOfAopAllianceInterceptor"/> </property> <property name="patterns"> <list> <value>.*set.*</value> <value>.*absquatulate</value> </list> </property> </bean>
RegexpMethodPointcutAdvisor can be used with any Advice type.
Dynamic pointcuts are costlier to evaluate than static pointcuts. They take into account method arguments, as well as static information. This means that they must be evaluated with every method invocation; the result cannot be cached, as arguments will vary.
The main example is the control flow
pointcut.
Spring control flow pointcuts are conceptually similar to
AspectJ cflow pointcuts, although less
powerful. (There is currently no way to specify that a pointcut
executes below a join point matched by another pointcut.) A control
flow pointcut matches the current call stack. For example, it might
fire if the join point was invoked by a method in the
com.mycompany.web
package, or by the
SomeCaller
class. Control flow pointcuts are
specified using the
org.springframework.aop.support.ControlFlowPointcut
class.
Note | |
---|---|
Control flow pointcuts are significantly more expensive to evaluate at runtime than even other dynamic pointcuts. In Java 1.4, the cost is about 5 times that of other dynamic pointcuts. |
Spring provides useful pointcut superclasses to help you to implement your own pointcuts.
Because static pointcuts are most useful, you'll probably subclass StaticMethodMatcherPointcut, as shown below. This requires implementing just one abstract method (although it's possible to override other methods to customize behavior):
class TestStaticPointcut extends StaticMethodMatcherPointcut { public boolean matches(Method m, Class targetClass) { // return true if custom criteria match } }
There are also superclasses for dynamic pointcuts.
You can use custom pointcuts with any advice type in Spring 1.0 RC2 and above.
Because pointcuts in Spring AOP are Java classes, rather than language features (as in AspectJ) it's possible to declare custom pointcuts, whether static or dynamic. Custom pointcuts in Spring can be arbitrarily complex. However, using the AspectJ pointcut expression language is recommended if possible.
Note | |
---|---|
Later versions of Spring may offer support for "semantic pointcuts" as offered by JAC: for example, "all methods that change instance variables in the target object." |
Let's now look at how Spring AOP handles advice.
Each advice is a Spring bean. An advice instance can be shared across all advised objects, or unique to each advised object. This corresponds to per-class or per-instance advice.
Per-class advice is used most often. It is appropriate for generic advice such as transaction advisors. These do not depend on the state of the proxied object or add new state; they merely act on the method and arguments.
Per-instance advice is appropriate for introductions, to support mixins. In this case, the advice adds state to the proxied object.
It's possible to use a mix of shared and per-instance advice in the same AOP proxy.
Spring provides several advice types out of the box, and is extensible to support arbitrary advice types. Let us look at the basic concepts and standard advice types.
The most fundamental advice type in Spring is interception around advice.
Spring is compliant with the AOP Alliance interface for around advice using method interception. MethodInterceptors implementing around advice should implement the following interface:
public interface MethodInterceptor extends Interceptor { Object invoke(MethodInvocation invocation) throws Throwable; }
The MethodInvocation
argument to the
invoke()
method exposes the method being
invoked; the target join point; the AOP proxy; and the arguments to
the method. The invoke()
method should return
the invocation's result: the return value of the join point.
A simple MethodInterceptor
implementation
looks as follows:
public class DebugInterceptor implements MethodInterceptor { public Object invoke(MethodInvocation invocation) throws Throwable { System.out.println("Before: invocation=[" + invocation + "]"); Object rval = invocation.proceed(); System.out.println("Invocation returned"); return rval; } }
Note the call to the MethodInvocation's
proceed()
method. This proceeds down the
interceptor chain towards the join point. Most interceptors will
invoke this method, and return its return value. However, a
MethodInterceptor, like any around advice, can return a different
value or throw an exception rather than invoke the proceed method.
However, you don't want to do this without good reason!
Note | |
---|---|
MethodInterceptors offer interoperability with other AOP Alliance-compliant AOP implementations. The other advice types discussed in the remainder of this section implement common AOP concepts, but in a Spring-specific way. While there is an advantage in using the most specific advice type, stick with MethodInterceptor around advice if you are likely to want to run the aspect in another AOP framework. Note that pointcuts are not currently interoperable between frameworks, and the AOP Alliance does not currently define pointcut interfaces. |
A simpler advice type is a before
advice. This does not need a
MethodInvocation
object, since it will only be
called before entering the method.
The main advantage of a before advice is that there is no need
to invoke the proceed()
method, and therefore no
possibility of inadvertently failing to proceed down the interceptor
chain.
The MethodBeforeAdvice
interface is shown
below. (Spring's API design would allow for field before advice,
although the usual objects apply to field interception and it's
unlikely that Spring will ever implement it).
public interface MethodBeforeAdvice extends BeforeAdvice { void before(Method m, Object[] args, Object target) throws Throwable; }
Note the return type is void
. Before advice
can insert custom behavior before the join point executes, but cannot
change the return value. If a before advice throws an exception, this
will abort further execution of the interceptor chain. The exception
will propagate back up the interceptor chain. If it is unchecked, or
on the signature of the invoked method, it will be passed directly to
the client; otherwise it will be wrapped in an unchecked exception by
the AOP proxy.
An example of a before advice in Spring, which counts all method invocations:
public class CountingBeforeAdvice implements MethodBeforeAdvice { private int count; public void before(Method m, Object[] args, Object target) throws Throwable { ++count; } public int getCount() { return count; } }
Tip | |
---|---|
Before advice can be used with any pointcut. |
Throws advice is invoked after
the return of the join point if the join point threw an exception.
Spring offers typed throws advice. Note that this means that the
org.springframework.aop.ThrowsAdvice
interface does
not contain any methods: It is a tag interface identifying that the
given object implements one or more typed throws advice methods. These
should be in the form of:
afterThrowing([Method, args, target], subclassOfThrowable)
Only the last argument is required. The method signatures may have either one or four arguments, depending on whether the advice method is interested in the method and arguments. The following classes are examples of throws advice.
The advice below is invoked if a
RemoteException
is thrown (including
subclasses):
public class RemoteThrowsAdvice implements ThrowsAdvice { public void afterThrowing(RemoteException ex) throws Throwable { // Do something with remote exception } }
The following advice is invoked if a
ServletException
is thrown. Unlike the
above advice, it declares 4 arguments, so that it has access to the
invoked method, method arguments and target object:
public class ServletThrowsAdviceWithArguments implements ThrowsAdvice { public void afterThrowing(Method m, Object[] args, Object target, ServletException ex) { // Do something with all arguments } }
The final example illustrates how these two methods could be
used in a single class, which handles both
RemoteException
and
ServletException
. Any number of throws advice
methods can be combined in a single class.
public static class CombinedThrowsAdvice implements ThrowsAdvice { public void afterThrowing(RemoteException ex) throws Throwable { // Do something with remote exception } public void afterThrowing(Method m, Object[] args, Object target, ServletException ex) { // Do something with all arguments } }
Note: If a throws-advice method throws an exception itself, it will override the original exception (i.e. change the exception thrown to the user). The overriding exception will typically be a RuntimeException; this is compatible with any method signature. However, if a throws-advice method throws a checked exception, it will have to match the declared exceptions of the target method and is hence to some degree coupled to specific target method signatures. Do not throw an undeclared checked exception that is incompatible with the target method's signature!
Tip | |
---|---|
Throws advice can be used with any pointcut. |
An after returning advice in Spring must implement the org.springframework.aop.AfterReturningAdvice interface, shown below:
public interface AfterReturningAdvice extends Advice { void afterReturning(Object returnValue, Method m, Object[] args, Object target) throws Throwable; }
An after returning advice has access to the return value (which it cannot modify), invoked method, methods arguments and target.
The following after returning advice counts all successful method invocations that have not thrown exceptions:
public class CountingAfterReturningAdvice implements AfterReturningAdvice { private int count; public void afterReturning(Object returnValue, Method m, Object[] args, Object target) throws Throwable { ++count; } public int getCount() { return count; } }
This advice doesn't change the execution path. If it throws an exception, this will be thrown up the interceptor chain instead of the return value.
Tip | |
---|---|
After returning advice can be used with any pointcut. |
Spring treats introduction advice as a special kind of interception advice.
Introduction requires an IntroductionAdvisor
,
and an IntroductionInterceptor
, implementing the
following interface:
public interface IntroductionInterceptor extends MethodInterceptor { boolean implementsInterface(Class intf); }
The invoke()
method inherited from the AOP
Alliance MethodInterceptor
interface must implement
the introduction: that is, if the invoked method is on an introduced
interface, the introduction interceptor is responsible for handling
the method call - it cannot invoke
proceed()
.
Introduction advice cannot be used with any pointcut, as it
applies only at class, rather than method, level. You can only use
introduction advice with the IntroductionAdvisor
,
which has the following methods:
public interface IntroductionAdvisor extends Advisor, IntroductionInfo { ClassFilter getClassFilter(); void validateInterfaces() throws IllegalArgumentException; } public interface IntroductionInfo { Class[] getInterfaces(); }
There is no MethodMatcher
, and
hence no Pointcut
, associated with
introduction advice. Only class filtering is logical.
The getInterfaces()
method returns the
interfaces introduced by this advisor.
The validateInterfaces()
method is used internally to
see whether or not the introduced interfaces can be implemented by the configured
IntroductionInterceptor
.
Let's look at a simple example from the Spring test suite. Let's suppose we want to introduce the following interface to one or more objects:
public interface Lockable { void lock(); void unlock(); boolean locked(); }
This illustrates a mixin. We
want to be able to cast advised objects to Lockable, whatever their
type, and call lock and unlock methods. If we call the lock() method,
we want all setter methods to throw a
LockedException
. Thus we can add an aspect that
provides the ability to make objects immutable, without them having
any knowledge of it: a good example of AOP.
Firstly, we'll need an
IntroductionInterceptor
that does the heavy
lifting. In this case, we extend the
org.springframework.aop.support.DelegatingIntroductionInterceptor
convenience class. We could implement IntroductionInterceptor
directly, but using
DelegatingIntroductionInterceptor
is best for most
cases.
The DelegatingIntroductionInterceptor
is
designed to delegate an introduction to an actual implementation of
the introduced interface(s), concealing the use of interception to do
so. The delegate can be set to any object using a constructor
argument; the default delegate (when the no-arg constructor is used)
is this. Thus in the example below, the delegate is the
LockMixin
subclass of
DelegatingIntroductionInterceptor
. Given a delegate
(by default itself), a
DelegatingIntroductionInterceptor
instance looks
for all interfaces implemented by the delegate (other than
IntroductionInterceptor), and will support introductions against any
of them. It's possible for subclasses such as
LockMixin
to call the
suppressInterface(Class intf)
method to suppress
interfaces that should not be exposed. However, no matter how many
interfaces an IntroductionInterceptor
is prepared
to support, the IntroductionAdvisor
used will
control which interfaces are actually exposed. An introduced interface
will conceal any implementation of the same interface by the
target.
Thus LockMixin subclasses
DelegatingIntroductionInterceptor
and implements
Lockable itself. The superclass automatically picks up that Lockable
can be supported for introduction, so we don't need to specify that.
We could introduce any number of interfaces in this way.
Note the use of the locked
instance variable.
This effectively adds additional state to that held in the target
object.
public class LockMixin extends DelegatingIntroductionInterceptor implements Lockable { private boolean locked; public void lock() { this.locked = true; } public void unlock() { this.locked = false; } public boolean locked() { return this.locked; } public Object invoke(MethodInvocation invocation) throws Throwable { if (locked() && invocation.getMethod().getName().indexOf("set") == 0) throw new LockedException(); return super.invoke(invocation); } }
Often it isn't necessary to override the invoke()
method: the
DelegatingIntroductionInterceptor
implementation -
which calls the delegate method if the method is introduced, otherwise
proceeds towards the join point - is usually sufficient. In the
present case, we need to add a check: no setter method can be invoked
if in locked mode.
The introduction advisor required is simple. All it needs to do
is hold a distinct LockMixin
instance, and specify
the introduced interfaces - in this case, just
Lockable
. A more complex example might take a
reference to the introduction interceptor (which would be defined as a
prototype): in this case, there's no configuration relevant for a
LockMixin
, so we simply create it using
new
.
public class LockMixinAdvisor extends DefaultIntroductionAdvisor { public LockMixinAdvisor() { super(new LockMixin(), Lockable.class); } }
We can apply this advisor very simply: it requires no
configuration. (However, it is necessary: It's
impossible to use an IntroductionInterceptor
without an IntroductionAdvisor.) As usual with
introductions, the advisor must be per-instance, as it is stateful. We
need a different instance of LockMixinAdvisor
, and
hence LockMixin
, for each advised object. The
advisor comprises part of the advised object's state.
We can apply this advisor programmatically, using the
Advised.addAdvisor()
method, or (the recommended
way) in XML configuration, like any other advisor. All proxy creation
choices discussed below, including "auto proxy creators," correctly
handle introductions and stateful mixins.
In Spring, an Advisor is an aspect that contains just a single advice object associated with a pointcut expression.
Apart from the special case of introductions, any advisor can be
used with any advice.
org.springframework.aop.support.DefaultPointcutAdvisor
is the most commonly used advisor class. For example, it can be used with
a MethodInterceptor
, BeforeAdvice
or
ThrowsAdvice
.
It is possible to mix advisor and advice types in Spring in the same AOP proxy. For example, you could use a interception around advice, throws advice and before advice in one proxy configuration: Spring will automatically create the necessary interceptor chain.
If you're using the Spring IoC container (an ApplicationContext or BeanFactory) for your business objects - and you should be! - you will want to use one of Spring's AOP FactoryBeans. (Remember that a factory bean introduces a layer of indirection, enabling it to create objects of a different type.)
Note | |
---|---|
The Spring 2.0 AOP support also uses factory beans under the covers. |
The basic way to create an AOP proxy in Spring is to use the org.springframework.aop.framework.ProxyFactoryBean. This gives complete control over the pointcuts and advice that will apply, and their ordering. However, there are simpler options that are preferable if you don't need such control.
The ProxyFactoryBean
, like other Spring
FactoryBean
implementations, introduces a level of
indirection. If you define a ProxyFactoryBean
with
name foo
, what objects referencing
foo
see is not the
ProxyFactoryBean
instance itself, but an object
created by the ProxyFactoryBean
's implementation of
the getObject()
method. This method will create an
AOP proxy wrapping a target object.
One of the most important benefits of using a
ProxyFactoryBean
or another IoC-aware class to create
AOP proxies, is that it means that advices and pointcuts can also be
managed by IoC. This is a powerful feature, enabling certain approaches
that are hard to achieve with other AOP frameworks. For example, an
advice may itself reference application objects (besides the target,
which should be available in any AOP framework), benefiting from all the
pluggability provided by Dependency Injection.
In common with most FactoryBean
implementations provided with Spring, the
ProxyFactoryBean
class is itself a JavaBean. Its
properties are used to:
Specify the target you want to proxy.
Specify whether to use CGLIB (see below and also Section 10.5.3, “JDK- and CGLIB-based proxies”).
Some key properties are inherited from
org.springframework.aop.framework.ProxyConfig
(the superclass for all AOP proxy factories in Spring). These key
properties include:
proxyTargetClass
: true
if the target class is to be proxied, rather than the target class'
interfaces. If this property value is set to
true
, then CGLIB proxies will be created (but see
also Section 10.5.3, “JDK- and CGLIB-based proxies”).
optimize
: controls whether or not
aggressive optimizations are applied to proxies created
via CGLIB. One should not blithely use this setting
unless one fully understands how the relevant AOP proxy handles
optimization. This is currently used only for CGLIB proxies; it has
no effect with JDK dynamic proxies.
frozen
: if a proxy configuration is
frozen
, then changes to the configuration are no
longer allowed. This is useful both as a slight optimization and for
those cases when you don't want callers to be able to manipulate the
proxy (via the Advised
interface)
after the proxy has been created. The default value of this property
is false
, so changes such as adding additional
advice are allowed.
exposeProxy
: determines whether or not the
current proxy should be exposed in a
ThreadLocal
so that it can be accessed by the
target. If a target needs to obtain the proxy and the
exposeProxy
property is set to
true
, the target can use the
AopContext.currentProxy()
method.
Other properties specific to
ProxyFactoryBean
include:
proxyInterfaces
: array of String interface
names. If this isn't supplied, a CGLIB proxy for the target class
will be used (but see also Section 10.5.3, “JDK- and CGLIB-based proxies”).
interceptorNames
: String array of
Advisor
, interceptor or other advice
names to apply. Ordering is significant, on a first come-first
served basis. That is to say that the first interceptor in the list
will be the first to be able to intercept the invocation.
The names are bean names in the current factory, including
bean names from ancestor factories. You can't mention bean
references here since doing so would result in the
ProxyFactoryBean
ignoring the singleton
setting of the advice.
You can append an interceptor name with an asterisk
(*
). This will result in the application of all
advisor beans with names starting with the part before the asterisk
to be applied. An example of using this feature can be found in
Section 10.5.6, “Using 'global' advisors”.
singleton: whether or not the factory should return a single
object, no matter how often the getObject()
method is called. Several FactoryBean
implementations offer such a method. The default value is
true
. If you want to use stateful advice - for
example, for stateful mixins - use prototype advices along with a
singleton value of false
.
This section serves as the definitive documentation on how the
ProxyFactoryBean
chooses to create one of either
a JDK- and CGLIB-based proxy for a particular target object (that is to
be proxied).
Note | |
---|---|
The behavior of the |
If the class of a target object that is to be proxied (hereafter
simply referred to as the target class) doesn't implement any
interfaces, then a CGLIB-based proxy will be created. This is the
easiest scenario, because JDK proxies are interface based, and no
interfaces means JDK proxying isn't even possible. One simply plugs in
the target bean, and specifies the list of interceptors via the
interceptorNames
property. Note that a CGLIB-based
proxy will be created even if the proxyTargetClass
property of the ProxyFactoryBean
has been set to
false
. (Obviously this makes no sense, and is best
removed from the bean definition because it is at best redundant, and at
worst confusing.)
If the target class implements one (or more) interfaces, then the
type of proxy that is created depends on the configuration of the
ProxyFactoryBean
.
If the proxyTargetClass
property of the
ProxyFactoryBean
has been set to
true
, then a CGLIB-based proxy will be created. This
makes sense, and is in keeping with the principle of least surprise.
Even if the proxyInterfaces
property of the
ProxyFactoryBean
has been set to one or more
fully qualified interface names, the fact that the
proxyTargetClass
property is set to
true
will cause CGLIB-based
proxying to be in effect.
If the proxyInterfaces
property of the
ProxyFactoryBean
has been set to one or more
fully qualified interface names, then a JDK-based proxy will be created.
The created proxy will implement all of the interfaces that were
specified in the proxyInterfaces
property; if the
target class happens to implement a whole lot more interfaces than those
specified in the proxyInterfaces
property, that is
all well and good but those additional interfaces will not be
implemented by the returned proxy.
If the proxyInterfaces
property of the
ProxyFactoryBean
has not
been set, but the target class does implement one (or
more) interfaces, then the
ProxyFactoryBean
will auto-detect the fact that
the target class does actually implement at least one interface, and a
JDK-based proxy will be created. The interfaces that are actually
proxied will be all of the interfaces that the
target class implements; in effect, this is the same as simply supplying
a list of each and every interface that the target class implements to
the proxyInterfaces
property. However, it is
significantly less work, and less prone to typos.
Let's look at a simple example of
ProxyFactoryBean
in action. This example
involves:
A target bean that will be proxied. This is the "personTarget" bean definition in the example below.
An Advisor and an Interceptor used to provide advice.
An AOP proxy bean definition specifying the target object (the personTarget bean) and the interfaces to proxy, along with the advices to apply.
<bean id="personTarget" class="com.mycompany.PersonImpl"> <property name="name" value="Tony"/> <property name="age" value="51"/> </bean> <bean id="myAdvisor" class="com.mycompany.MyAdvisor"> <property name="someProperty" value="Custom string property value"/> </bean> <bean id="debugInterceptor" class="org.springframework.aop.interceptor.DebugInterceptor"> </bean> <bean id="person" class="org.springframework.aop.framework.ProxyFactoryBean"> <property name="proxyInterfaces" value="com.mycompany.Person"/> <property name="target" ref="personTarget"/> <property name="interceptorNames"> <list> <value>myAdvisor</value> <value>debugInterceptor</value> </list> </property> </bean>
Note that the interceptorNames
property takes a
list of String: the bean names of the interceptor or advisors in the
current factory. Advisors, interceptors, before, after returning and
throws advice objects can be used. The ordering of advisors is
significant.
Note | |
---|---|
You might be wondering why the list doesn't hold bean references. The reason for this is that if the ProxyFactoryBean's singleton property is set to false, it must be able to return independent proxy instances. If any of the advisors is itself a prototype, an independent instance would need to be returned, so it's necessary to be able to obtain an instance of the prototype from the factory; holding a reference isn't sufficient. |
The "person" bean definition above can be used in place of a Person implementation, as follows:
Person person = (Person) factory.getBean("person");
Other beans in the same IoC context can express a strongly typed dependency on it, as with an ordinary Java object:
<bean id="personUser" class="com.mycompany.PersonUser"> <property name="person"><ref local="person"/></property> </bean>
The PersonUser
class in this example would
expose a property of type Person. As far as it's concerned, the AOP
proxy can be used transparently in place of a "real" person
implementation. However, its class would be a dynamic proxy class. It
would be possible to cast it to the Advised
interface
(discussed below).
It's possible to conceal the distinction between target and proxy
using an anonymous inner bean, as follows. Only the
ProxyFactoryBean
definition is different; the advice
is included only for completeness:
<bean id="myAdvisor" class="com.mycompany.MyAdvisor"> <property name="someProperty" value="Custom string property value"/> </bean> <bean id="debugInterceptor" class="org.springframework.aop.interceptor.DebugInterceptor"/> <bean id="person" class="org.springframework.aop.framework.ProxyFactoryBean"> <property name="proxyInterfaces" value="com.mycompany.Person"/> <!-- Use inner bean, not local reference to target --> <property name="target"> <bean class="com.mycompany.PersonImpl"> <property name="name" value="Tony"/> <property name="age" value="51"/> </bean> </property> <property name="interceptorNames"> <list> <value>myAdvisor</value> <value>debugInterceptor</value> </list> </property> </bean>
This has the advantage that there's only one object of type
Person
: useful if we want to prevent users of the
application context from obtaining a reference to the un-advised object,
or need to avoid any ambiguity with Spring IoC
autowiring. There's also arguably an advantage in
that the ProxyFactoryBean definition is self-contained. However, there
are times when being able to obtain the un-advised target from the
factory might actually be an advantage: for
example, in certain test scenarios.
What if you need to proxy a class, rather than one or more interfaces?
Imagine that in our example above, there was no
Person
interface: we needed to advise a class called
Person
that didn't implement any business interface.
In this case, you can configure Spring to use CGLIB proxying, rather
than dynamic proxies. Simply set the proxyTargetClass
property on the ProxyFactoryBean above to true. While it's best to
program to interfaces, rather than classes, the ability to advise
classes that don't implement interfaces can be useful when working with
legacy code. (In general, Spring isn't prescriptive. While it makes it
easy to apply good practices, it avoids forcing a particular
approach.)
If you want to, you can force the use of CGLIB in any case, even if you do have interfaces.
CGLIB proxying works by generating a subclass of the target class at runtime. Spring configures this generated subclass to delegate method calls to the original target: the subclass is used to implement the Decorator pattern, weaving in the advice.
CGLIB proxying should generally be transparent to users. However, there are some issues to consider:
Final
methods can't be advised, as they
can't be overridden.
There is no need to add CGLIB to your classpath. As of Spring 3.2, CGLIB is repackaged and included in the spring-core JAR. In other words, CGLIB-based AOP will work "out of the box" just as do JDK dynamic proxies.
There's little performance difference between CGLIB proxying and dynamic proxies. As of Spring 1.0, dynamic proxies are slightly faster. However, this may change in the future. Performance should not be a decisive consideration in this case.
By appending an asterisk to an interceptor name, all advisors with bean names matching the part before the asterisk, will be added to the advisor chain. This can come in handy if you need to add a standard set of 'global' advisors:
<bean id="proxy" class="org.springframework.aop.framework.ProxyFactoryBean"> <property name="target" ref="service"/> <property name="interceptorNames"> <list> <value>global*</value> </list> </property> </bean> <bean id="global_debug" class="org.springframework.aop.interceptor.DebugInterceptor"/> <bean id="global_performance" class="org.springframework.aop.interceptor.PerformanceMonitorInterceptor"/>
Especially when defining transactional proxies, you may end up with many similar proxy definitions. The use of parent and child bean definitions, along with inner bean definitions, can result in much cleaner and more concise proxy definitions.
First a parent, template, bean definition is created for the proxy:
<bean id="txProxyTemplate" abstract="true" class="org.springframework.transaction.interceptor.TransactionProxyFactoryBean"> <property name="transactionManager" ref="transactionManager"/> <property name="transactionAttributes"> <props> <prop key="*">PROPAGATION_REQUIRED</prop> </props> </property> </bean>
This will never be instantiated itself, so may actually be incomplete. Then each proxy which needs to be created is just a child bean definition, which wraps the target of the proxy as an inner bean definition, since the target will never be used on its own anyway.
<bean id="myService" parent="txProxyTemplate"> <property name="target"> <bean class="org.springframework.samples.MyServiceImpl"> </bean> </property> </bean>
It is of course possible to override properties from the parent template, such as in this case, the transaction propagation settings:
<bean id="mySpecialService" parent="txProxyTemplate"> <property name="target"> <bean class="org.springframework.samples.MySpecialServiceImpl"> </bean> </property> <property name="transactionAttributes"> <props> <prop key="get*">PROPAGATION_REQUIRED,readOnly</prop> <prop key="find*">PROPAGATION_REQUIRED,readOnly</prop> <prop key="load*">PROPAGATION_REQUIRED,readOnly</prop> <prop key="store*">PROPAGATION_REQUIRED</prop> </props> </property> </bean>
Note that in the example above, we have explicitly marked the parent bean definition as abstract by using the abstract attribute, as described previously, so that it may not actually ever be instantiated. Application contexts (but not simple bean factories) will by default pre-instantiate all singletons. It is therefore important (at least for singleton beans) that if you have a (parent) bean definition which you intend to use only as a template, and this definition specifies a class, you must make sure to set the abstract attribute to true, otherwise the application context will actually try to pre-instantiate it.
It's easy to create AOP proxies programmatically using Spring. This enables you to use Spring AOP without dependency on Spring IoC.
The following listing shows creation of a proxy for a target object, with one interceptor and one advisor. The interfaces implemented by the target object will automatically be proxied:
ProxyFactory factory = new ProxyFactory(myBusinessInterfaceImpl);
factory.addAdvice(myMethodInterceptor);
factory.addAdvisor(myAdvisor);
MyBusinessInterface tb = (MyBusinessInterface) factory.getProxy();
The first step is to construct an object of type
org.springframework.aop.framework.ProxyFactory
. You can
create this with a target object, as in the above example, or specify the
interfaces to be proxied in an alternate constructor.
You can add advices (with interceptors as a specialized kind of advice) and/or advisors, and manipulate them for the life of the ProxyFactory. If you add an IntroductionInterceptionAroundAdvisor, you can cause the proxy to implement additional interfaces.
There are also convenience methods on ProxyFactory (inherited from
AdvisedSupport
) which allow you to add other advice
types such as before and throws advice. AdvisedSupport is the superclass
of both ProxyFactory and ProxyFactoryBean.
Tip | |
---|---|
Integrating AOP proxy creation with the IoC framework is best practice in most applications. We recommend that you externalize configuration from Java code with AOP, as in general. |
However you create AOP proxies, you can manipulate them using the
org.springframework.aop.framework.Advised
interface.
Any AOP proxy can be cast to this interface, whichever other interfaces it
implements. This interface includes the following methods:
Advisor[] getAdvisors(); void addAdvice(Advice advice) throws AopConfigException; void addAdvice(int pos, Advice advice) throws AopConfigException; void addAdvisor(Advisor advisor) throws AopConfigException; void addAdvisor(int pos, Advisor advisor) throws AopConfigException; int indexOf(Advisor advisor); boolean removeAdvisor(Advisor advisor) throws AopConfigException; void removeAdvisor(int index) throws AopConfigException; boolean replaceAdvisor(Advisor a, Advisor b) throws AopConfigException; boolean isFrozen();
The getAdvisors()
method will return an Advisor
for every advisor, interceptor or other advice type that has been added to
the factory. If you added an Advisor, the returned advisor at this index
will be the object that you added. If you added an interceptor or other
advice type, Spring will have wrapped this in an advisor with a pointcut
that always returns true. Thus if you added a
MethodInterceptor
, the advisor returned for this index
will be an DefaultPointcutAdvisor
returning your
MethodInterceptor
and a pointcut that matches all
classes and methods.
The addAdvisor()
methods can be used to add any
Advisor. Usually the advisor holding pointcut and advice will be the
generic DefaultPointcutAdvisor
, which can be used with
any advice or pointcut (but not for introductions).
By default, it's possible to add or remove advisors or interceptors even once a proxy has been created. The only restriction is that it's impossible to add or remove an introduction advisor, as existing proxies from the factory will not show the interface change. (You can obtain a new proxy from the factory to avoid this problem.)
A simple example of casting an AOP proxy to the
Advised
interface and examining and manipulating its
advice:
Advised advised = (Advised) myObject; Advisor[] advisors = advised.getAdvisors(); int oldAdvisorCount = advisors.length; System.out.println(oldAdvisorCount + " advisors"); // Add an advice like an interceptor without a pointcut // Will match all proxied methods // Can use for interceptors, before, after returning or throws advice advised.addAdvice(new DebugInterceptor()); // Add selective advice using a pointcut advised.addAdvisor(new DefaultPointcutAdvisor(mySpecialPointcut, myAdvice)); assertEquals("Added two advisors", oldAdvisorCount + 2, advised.getAdvisors().length);
Note | |
---|---|
It's questionable whether it's advisable (no pun intended) to modify advice on a business object in production, although there are no doubt legitimate usage cases. However, it can be very useful in development: for example, in tests. I have sometimes found it very useful to be able to add test code in the form of an interceptor or other advice, getting inside a method invocation I want to test. (For example, the advice can get inside a transaction created for that method: for example, to run SQL to check that a database was correctly updated, before marking the transaction for roll back.) |
Depending on how you created the proxy, you can usually set a
frozen
flag, in which case the
Advised
isFrozen()
method will
return true, and any attempts to modify advice through addition or removal
will result in an AopConfigException
. The ability to
freeze the state of an advised object is useful in some cases, for
example, to prevent calling code removing a security interceptor. It may
also be used in Spring 1.1 to allow aggressive optimization if runtime
advice modification is known not to be required.
So far we've considered explicit creation of AOP proxies using a
ProxyFactoryBean
or similar factory bean.
Spring also allows us to use "autoproxy" bean definitions, which can automatically proxy selected bean definitions. This is built on Spring "bean post processor" infrastructure, which enables modification of any bean definition as the container loads.
In this model, you set up some special bean definitions in your XML
bean definition file to configure the auto proxy infrastructure. This
allows you just to declare the targets eligible for autoproxying: you
don't need to use ProxyFactoryBean
.
There are two ways to do this:
Using an autoproxy creator that refers to specific beans in the current context.
A special case of autoproxy creation that deserves to be considered separately; autoproxy creation driven by source-level metadata attributes.
The org.springframework.aop.framework.autoproxy
package provides the following standard autoproxy creators.
The BeanNameAutoProxyCreator
class is a
BeanPostProcessor
that automatically creates AOP
proxies for beans with names matching literal values or
wildcards.
<bean class="org.springframework.aop.framework.autoproxy.BeanNameAutoProxyCreator"> <property name="beanNames" value="jdk*,onlyJdk"/> <property name="interceptorNames"> <list> <value>myInterceptor</value> </list> </property> </bean>
As with ProxyFactoryBean
, there is an
interceptorNames
property rather than a list of
interceptors, to allow correct behavior for prototype advisors. Named
"interceptors" can be advisors or any advice type.
As with auto proxying in general, the main point of using
BeanNameAutoProxyCreator
is to apply the same
configuration consistently to multiple objects, with minimal volume of
configuration. It is a popular choice for applying declarative
transactions to multiple objects.
Bean definitions whose names match, such as "jdkMyBean" and
"onlyJdk" in the above example, are plain old bean definitions with
the target class. An AOP proxy will be created automatically by the
BeanNameAutoProxyCreator
. The same advice will be
applied to all matching beans. Note that if advisors are used (rather
than the interceptor in the above example), the pointcuts may apply
differently to different beans.
A more general and extremely powerful auto proxy creator is
DefaultAdvisorAutoProxyCreator
. This will
automagically apply eligible advisors in the current context, without
the need to include specific bean names in the autoproxy advisor's
bean definition. It offers the same merit of consistent configuration
and avoidance of duplication as
BeanNameAutoProxyCreator
.
Using this mechanism involves:
Specifying a
DefaultAdvisorAutoProxyCreator
bean
definition.
Specifying any number of Advisors in the same or related contexts. Note that these must be Advisors, not just interceptors or other advices. This is necessary because there must be a pointcut to evaluate, to check the eligibility of each advice to candidate bean definitions.
The DefaultAdvisorAutoProxyCreator
will
automatically evaluate the pointcut contained in each advisor, to see
what (if any) advice it should apply to each business object (such as
"businessObject1" and "businessObject2" in the example).
This means that any number of advisors can be applied automatically to each business object. If no pointcut in any of the advisors matches any method in a business object, the object will not be proxied. As bean definitions are added for new business objects, they will automatically be proxied if necessary.
Autoproxying in general has the advantage of making it impossible for callers or dependencies to obtain an un-advised object. Calling getBean("businessObject1") on this ApplicationContext will return an AOP proxy, not the target business object. (The "inner bean" idiom shown earlier also offers this benefit.)
<bean class="org.springframework.aop.framework.autoproxy.DefaultAdvisorAutoProxyCreator"/> <bean class="org.springframework.transaction.interceptor.TransactionAttributeSourceAdvisor"> <property name="transactionInterceptor" ref="transactionInterceptor"/> </bean> <bean id="customAdvisor" class="com.mycompany.MyAdvisor"/> <bean id="businessObject1" class="com.mycompany.BusinessObject1"> <!-- Properties omitted --> </bean> <bean id="businessObject2" class="com.mycompany.BusinessObject2"/>
The DefaultAdvisorAutoProxyCreator
is very
useful if you want to apply the same advice consistently to many
business objects. Once the infrastructure definitions are in place,
you can simply add new business objects without including specific
proxy configuration. You can also drop in additional aspects very
easily - for example, tracing or performance monitoring aspects - with
minimal change to configuration.
The DefaultAdvisorAutoProxyCreator offers support for filtering
(using a naming convention so that only certain advisors are
evaluated, allowing use of multiple, differently configured,
AdvisorAutoProxyCreators in the same factory) and ordering. Advisors
can implement the org.springframework.core.Ordered
interface to ensure correct ordering if this is an issue. The
TransactionAttributeSourceAdvisor used in the above example has a
configurable order value; the default setting is unordered.
This is the superclass of DefaultAdvisorAutoProxyCreator. You
can create your own autoproxy creators by subclassing this class, in
the unlikely event that advisor definitions offer insufficient
customization to the behavior of the framework
DefaultAdvisorAutoProxyCreator
.
A particularly important type of autoproxying is driven by
metadata. This produces a similar programming model to .NET
ServicedComponents
. Instead of using XML deployment
descriptors as in EJB, configuration for transaction management and
other enterprise services is held in source-level attributes.
In this case, you use the
DefaultAdvisorAutoProxyCreator
, in combination with
Advisors that understand metadata attributes. The metadata specifics are
held in the pointcut part of the candidate advisors, rather than in the
autoproxy creation class itself.
This is really a special case of the
DefaultAdvisorAutoProxyCreator
, but deserves
consideration on its own. (The metadata-aware code is in the pointcuts
contained in the advisors, not the AOP framework itself.)
The /attributes
directory of the JPetStore
sample application shows the use of attribute-driven autoproxying. In
this case, there's no need to use the
TransactionProxyFactoryBean
. Simply defining
transactional attributes on business objects is sufficient, because of
the use of metadata-aware pointcuts. The bean definitions include the
following code, in /WEB-INF/declarativeServices.xml
.
Note that this is generic, and can be used outside the JPetStore:
<bean class="org.springframework.aop.framework.autoproxy.DefaultAdvisorAutoProxyCreator"/> <bean class="org.springframework.transaction.interceptor.TransactionAttributeSourceAdvisor"> <property name="transactionInterceptor" ref="transactionInterceptor"/> </bean> <bean id="transactionInterceptor" class="org.springframework.transaction.interceptor.TransactionInterceptor"> <property name="transactionManager" ref="transactionManager"/> <property name="transactionAttributeSource"> <bean class="org.springframework.transaction.interceptor.AttributesTransactionAttributeSource"> <property name="attributes" ref="attributes"/> </bean> </property> </bean> <bean id="attributes" class="org.springframework.metadata.commons.CommonsAttributes"/>
The DefaultAdvisorAutoProxyCreator
bean
definition (the name is not significant, hence it can even be omitted)
will pick up all eligible pointcuts in the current application context.
In this case, the "transactionAdvisor" bean definition, of type
TransactionAttributeSourceAdvisor
, will apply to
classes or methods carrying a transaction attribute. The
TransactionAttributeSourceAdvisor depends on a TransactionInterceptor,
via constructor dependency. The example resolves this via autowiring.
The AttributesTransactionAttributeSource
depends on
an implementation of the
org.springframework.metadata.Attributes
interface. In
this fragment, the "attributes" bean satisfies this, using the Jakarta
Commons Attributes API to obtain attribute information. (The application
code must have been compiled using the Commons Attributes compilation
task.)
The /annotation
directory of the JPetStore
sample application contains an analogous example for auto-proxying
driven by JDK 1.5+ annotations. The following configuration enables
automatic detection of Spring's Transactional
annotation, leading to implicit proxies for beans containing that
annotation:
<bean class="org.springframework.aop.framework.autoproxy.DefaultAdvisorAutoProxyCreator"/> <bean class="org.springframework.transaction.interceptor.TransactionAttributeSourceAdvisor"> <property name="transactionInterceptor" ref="transactionInterceptor"/> </bean> <bean id="transactionInterceptor" class="org.springframework.transaction.interceptor.TransactionInterceptor"> <property name="transactionManager" ref="transactionManager"/> <property name="transactionAttributeSource"> <bean class="org.springframework.transaction.annotation.AnnotationTransactionAttributeSource"/> </property> </bean>
The TransactionInterceptor
defined here depends
on a PlatformTransactionManager
definition, which is
not included in this generic file (although it could be) because it will
be specific to the application's transaction requirements (typically
JTA, as in this example, or Hibernate, JDO or JDBC):
<bean id="transactionManager" class="org.springframework.transaction.jta.JtaTransactionManager"/>
Tip | |
---|---|
If you require only declarative transaction management, using these generic XML definitions will result in Spring automatically proxying all classes or methods with transaction attributes. You won't need to work directly with AOP, and the programming model is similar to that of .NET ServicedComponents. |
This mechanism is extensible. It's possible to do autoproxying based on custom attributes. You need to:
Define your custom attribute.
Specify an Advisor with the necessary advice, including a pointcut that is triggered by the presence of the custom attribute on a class or method. You may be able to use an existing advice, merely implementing a static pointcut that picks up the custom attribute.
It's possible for such advisors to be unique to each advised class
(for example, mixins): they simply need to be defined as prototype,
rather than singleton, bean definitions. For example, the
LockMixin
introduction interceptor from the Spring
test suite, shown above, could be used in conjunction with an
attribute-driven pointcut to target a mixin, as shown here. We use the
generic DefaultPointcutAdvisor
, configured using
JavaBean properties:
<bean id="lockMixin" class="org.springframework.aop.LockMixin" scope="prototype"/> <bean id="lockableAdvisor" class="org.springframework.aop.support.DefaultPointcutAdvisor" scope="prototype"> <property name="pointcut" ref="myAttributeAwarePointcut"/> <property name="advice" ref="lockMixin"/> </bean> <bean id="anyBean" class="anyclass" ...
If the attribute aware pointcut matches any methods in the
anyBean
or other bean definitions, the mixin will be
applied. Note that both lockMixin
and
lockableAdvisor
definitions are prototypes. The
myAttributeAwarePointcut
pointcut can be a singleton
definition, as it doesn't hold state for individual advised
objects.
Spring offers the concept of a TargetSource,
expressed in the org.springframework.aop.TargetSource
interface. This interface is responsible for returning the "target object"
implementing the join point. The TargetSource
implementation is asked for a target instance each time the AOP proxy
handles a method invocation.
Developers using Spring AOP don't normally need to work directly with TargetSources, but this provides a powerful means of supporting pooling, hot swappable and other sophisticated targets. For example, a pooling TargetSource can return a different target instance for each invocation, using a pool to manage instances.
If you do not specify a TargetSource, a default implementation is used that wraps a local object. The same target is returned for each invocation (as you would expect).
Let's look at the standard target sources provided with Spring, and how you can use them.
Tip | |
---|---|
When using a custom target source, your target will usually need to be a prototype rather than a singleton bean definition. This allows Spring to create a new target instance when required. |
The
org.springframework.aop.target.HotSwappableTargetSource
exists to allow the target of an AOP proxy to be switched while allowing
callers to keep their references to it.
Changing the target source's target takes effect immediately. The
HotSwappableTargetSource
is threadsafe.
You can change the target via the swap()
method
on HotSwappableTargetSource as follows:
HotSwappableTargetSource swapper =
(HotSwappableTargetSource) beanFactory.getBean("swapper");
Object oldTarget = swapper.swap(newTarget);
The XML definitions required look as follows:
<bean id="initialTarget" class="mycompany.OldTarget"/> <bean id="swapper" class="org.springframework.aop.target.HotSwappableTargetSource"> <constructor-arg ref="initialTarget"/> </bean> <bean id="swappable" class="org.springframework.aop.framework.ProxyFactoryBean"> <property name="targetSource" ref="swapper"/> </bean>
The above swap()
call changes the target of the
swappable bean. Clients who hold a reference to that bean will be
unaware of the change, but will immediately start hitting the new
target.
Although this example doesn't add any advice - and it's not
necessary to add advice to use a TargetSource
- of
course any TargetSource
can be used in conjunction
with arbitrary advice.
Using a pooling target source provides a similar programming model to stateless session EJBs, in which a pool of identical instances is maintained, with method invocations going to free objects in the pool.
A crucial difference between Spring pooling and SLSB pooling is that Spring pooling can be applied to any POJO. As with Spring in general, this service can be applied in a non-invasive way.
Spring provides out-of-the-box support for Jakarta Commons Pool
1.3, which provides a fairly efficient pooling implementation. You'll
need the commons-pool Jar on your application's classpath to use this
feature. It's also possible to subclass
org.springframework.aop.target.AbstractPoolingTargetSource
to support any other pooling API.
Sample configuration is shown below:
<bean id="businessObjectTarget" class="com.mycompany.MyBusinessObject" scope="prototype"> ... properties omitted </bean> <bean id="poolTargetSource" class="org.springframework.aop.target.CommonsPoolTargetSource"> <property name="targetBeanName" value="businessObjectTarget"/> <property name="maxSize" value="25"/> </bean> <bean id="businessObject" class="org.springframework.aop.framework.ProxyFactoryBean"> <property name="targetSource" ref="poolTargetSource"/> <property name="interceptorNames" value="myInterceptor"/> </bean>
Note that the target object - "businessObjectTarget" in the
example - must be a prototype. This allows the
PoolingTargetSource
implementation to create new
instances of the target to grow the pool as necessary. See the javadoc
for AbstractPoolingTargetSource
and the concrete
subclass you wish to use for information about its properties: "maxSize"
is the most basic, and always guaranteed to be present.
In this case, "myInterceptor" is the name of an interceptor that would need to be defined in the same IoC context. However, it isn't necessary to specify interceptors to use pooling. If you want only pooling, and no other advice, don't set the interceptorNames property at all.
It's possible to configure Spring so as to be able to cast any
pooled object to the
org.springframework.aop.target.PoolingConfig
interface, which exposes information about the configuration and current
size of the pool through an introduction. You'll need to define an
advisor like this:
<bean id="poolConfigAdvisor" class="org.springframework.beans.factory.config.MethodInvokingFactoryBean"> <property name="targetObject" ref="poolTargetSource"/> <property name="targetMethod" value="getPoolingConfigMixin"/> </bean>
This advisor is obtained by calling a convenience method on the
AbstractPoolingTargetSource
class, hence the use of
MethodInvokingFactoryBean. This advisor's name ("poolConfigAdvisor"
here) must be in the list of interceptors names in the ProxyFactoryBean
exposing the pooled object.
The cast will look as follows:
PoolingConfig conf = (PoolingConfig) beanFactory.getBean("businessObject"); System.out.println("Max pool size is " + conf.getMaxSize());
Note | |
---|---|
Pooling stateless service objects is not usually necessary. We don't believe it should be the default choice, as most stateless objects are naturally thread safe, and instance pooling is problematic if resources are cached. |
Simpler pooling is available using autoproxying. It's possible to set the TargetSources used by any autoproxy creator.
Setting up a "prototype" target source is similar to a pooling TargetSource. In this case, a new instance of the target will be created on every method invocation. Although the cost of creating a new object isn't high in a modern JVM, the cost of wiring up the new object (satisfying its IoC dependencies) may be more expensive. Thus you shouldn't use this approach without very good reason.
To do this, you could modify the
poolTargetSource
definition shown above as follows.
(I've also changed the name, for clarity.)
<bean id="prototypeTargetSource" class="org.springframework.aop.target.PrototypeTargetSource"> <property name="targetBeanName" ref="businessObjectTarget"/> </bean>
There's only one property: the name of the target bean. Inheritance is used in the TargetSource implementations to ensure consistent naming. As with the pooling target source, the target bean must be a prototype bean definition.
ThreadLocal
target sources are useful if
you need an object to be created for each incoming request (per thread
that is). The concept of a ThreadLocal
provide a
JDK-wide facility to transparently store resource alongside a thread.
Setting up a ThreadLocalTargetSource
is pretty
much the same as was explained for the other types of target
source:
<bean id="threadlocalTargetSource" class="org.springframework.aop.target.ThreadLocalTargetSource"> <property name="targetBeanName" value="businessObjectTarget"/> </bean>
Note | |
---|---|
ThreadLocals come with serious issues (potentially resulting in
memory leaks) when incorrectly using them in a multi-threaded and
multi-classloader environments. One should always consider wrapping a
threadlocal in some other class and never directly use the
|
Spring AOP is designed to be extensible. While the interception implementation strategy is presently used internally, it is possible to support arbitrary advice types in addition to the out-of-the-box interception around advice, before, throws advice and after returning advice.
The org.springframework.aop.framework.adapter
package is an SPI package allowing support for new custom advice types to
be added without changing the core framework. The only constraint on a
custom Advice
type is that it must
implement the org.aopalliance.aop.Advice
tag interface.
Please refer to the
org.springframework.aop.framework.adapter
package's
Javadocs for further information.
Please refer to the Spring sample applications for further examples of Spring AOP:
The JPetStore's default configuration illustrates the use of the
TransactionProxyFactoryBean
for declarative
transaction management.
The /attributes
directory of the JPetStore
illustrates the use of attribute-driven declarative transaction
management.