Java dynamic proxy is a runtime generation proxy class to implement method interception, which is implemented through Proxy and InvocationHandler; 1. It can only proxy interfaces; 2. Performance is general under high concurrency; 3. It cannot proxy final methods or classes; Spring AOP uses dynamic proxy or CGLIB to insert surface logic into target method calls to implement logs, transactions and other functions; when using it, you need to pay attention to the proxy type, internal calls not taking effect, avoid abuse and performance problems.
Java Dynamic Proxy and AOP are concepts that many Java developers will come into contact with when using Spring or other frameworks. Many people know that they can do things like "method enhancement" or "logging", but it may not be clear how to implement it and how the underlying operation is. This article mainly talks about the basic principles of Java dynamic proxy and how it is related to AOP.
What is a Java dynamic proxy?
Java dynamic proxy, as the name suggests, is to dynamically generate a proxy class at runtime to proxy the implementation of a certain interface. Its core is java.lang.reflect.Proxy class and InvocationHandler interface.
To give a simple example: you have an interface Service , which has a method doSomething() . You don't want to call it directly, but want to add some logic before and after the call, such as recording time, printing logs, etc. This is the time to implement it with dynamic proxy.
Service proxy = (Service) Proxy.newProxyInstance(
classLoader,
new Class[]{Service.class},
new InvocationHandler() {
@Override
public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
// Do something before the method is executed System.out.println("Before method call");
Object result = method.invoke(realService, args);
// Do something after the method is executed System.out.println("After method call");
return result;
}
}
); In this example, proxy is a dynamically generated proxy object. Every time its method is called, it will go into the invoke method, thereby achieving interception and enhancement of the original method.
Limitations of Dynamic Proxy
While dynamic proxying is good, it also has obvious limitations:
- Only proxy interfaces : If your class does not implement any interface, then
Proxy.newProxyInstancecannot be used. - The performance of JDK proxy is average : In high concurrency scenarios, the performance of dynamic proxy may not be as good as some underlying solutions, such as CGLIB.
- Unable to proxy final methods or classes : Because dynamic proxying depends on generating subclasses or implementing interfaces, final classes or methods cannot be inherited or overwritten.
These limitations lead to the use of JDK dynamic proxy and CGLIB in real development, for example in Spring frameworks, to support a wider range of scenarios.
The relationship between dynamic proxy and AOP
The core idea of AOP (sectional programming) is to separate "horizontal concerns", such as logs, transactions, security and other logic, which should not be intruded into business code. Dynamic proxy is a basic mechanism for implementing AOP.
In Spring AOP, when you use @Aspect to define a tangent and define notifications through @Around , @Before , etc., the underlying Spring layer creates proxy objects through dynamic proxy (or CGLIB), thereby inserting the tangent logic before and after method calls.
for example:
@Around("execution(* com.example.service.*.*(..))")
public Object logExecutionTime(ProceedingJoinPoint joinPoint) throws Throwable {
long start = System.currentTimeMillis();
Object result = joinPoint.proceed(); // Execute the original method long executionTime = System.currentTimeMillis() - start;
System.out.println("Method takes time: " executionTime "ms");
return result;
}This section is essentially inserted into the call chain of the target method through a dynamic proxy mechanism. You can understand it as: Spring helps you create an "enhanced" object at runtime. When calling the method of this object, it will automatically trigger the tangent logic you defined.
Some points to pay attention to in actual development
- Type of proxy object : When you inject a proxy bean using
@Autowire, its type is actually a proxy class, not a primitive class. This can cause problems in some reflection operations. - Method calls must go through proxy : only methods called through proxy objects will be intercepted. If you call your own method directly inside the class, AOP will not be triggered.
- Avoid overuse of AOP : Although AOP is powerful, abuse can lead to a decrease in code readability and difficult to debug. It is recommended to only be used for general logic such as logs, permissions, transactions, etc.
- Pay attention to performance impact : AOP does bring certain performance overhead, especially when
@Aroundis used heavily. A performance evaluation of critical paths can be considered.
In general, Java dynamic proxy is a mechanism to implement AOP. Although it has some limitations, it can meet most development needs after combining frameworks such as Spring. Understanding its principles will help you better use AOP and can also locate the cause faster when encountering problems such as proxy failure and type conversion exceptions.
Basically that's it.
The above is the detailed content of Understanding Java Dynamic Proxies and AOP. For more information, please follow other related articles on the PHP Chinese website!
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