The Java Language Specification speaks of the mechanism of loading, unloading, and reloading of classes in great details.
Loading refers to the process of finding the binary form of a
interface type with a particular name, perhaps by computing it on the fly, but more typically by retrieving a binary representation previously computed from source code by a compiler, and constructing, from that binary form, a
Class object to represent the class or interface.
The precise semantics of loading are given in chapter 5 of The Java Virtual Machine Specification (whenever we refer to the Java virtual machine specification in this book, we mean the second edition, as amended by JSR 924). Here we present an overview of the process from the viewpoint of the Java programming language.
The binary format of a class or interface is normally the class file format described in The Java Virtual Machine Specification cited above, but other formats are possible, provided they meet the requirements specified in §13.1. The method
class ClassLoader may be used to construct
Class objects from binary representations in the class file format.
Under certain circumstances, it is possible to unload classes and interfaces, which may cause an unpreventable reload.
An implementation of the Java programming language may unload classes. A class or interface may be unloaded if and only if its defining class loader may be reclaimed by the garbage collector as discussed in §12.6. Classes and interfaces loaded by the bootstrap loader may not be unloaded.
Class unloading is an optimization that helps reduce memory use. Obviously, the semantics of a program should not depend on whether and how a system chooses to implement an optimization such as class unloading. To do otherwise would compromise the portability of programs. Consequently, whether a class or interface has been unloaded or not should be transparent to a program.
However, if a class or interface C was unloaded while its defining loader was potentially reachable, then C might be reloaded. One could never ensure that this would not happen.
In fact, it went to address your specific concerns:
Reloading may not be transparent if, for example, the class has:
- Static variables (whose state would be lost).
- Static initializers (which may have side effects).
- Native methods (which may retain static state).
Furthermore the hash value of the Class object is dependent on its identity. Therefore it is, in general, impossible to reload a class or interface in a completely transparent manner.
Since we can never guarantee that unloading a class or interface whose loader is potentially reachable will not cause reloading, and reloading is never transparent, but unloading must be transparent, it follows that one must not unload a class or interface while its loader is potentially reachable. A similar line of reasoning can be used to deduce that classes and interfaces loaded by the bootstrap loader can never be unloaded.
One must also argue why it is safe to unload a class C if its defining class loader can be reclaimed. If the defining loader can be reclaimed, then there can never be any live references to it (this includes references that are not live, but might be resurrected by finalizers). This, in turn, can only be true if there are can never be any live references to any of the classes defined by that loader, including C, either from their instances or from code.
Class unloading is an optimization that is only significant for applications that load large numbers of classes and that stop using most of those classes after some time. A prime example of such an application is a web browser, but there are others. A characteristic of such applications is that they manage classes through explicit use of class loaders. As a result, the policy outlined above works well for them.
Strictly speaking, it is not essential that the issue of class unloading be discussed by this specification, as class unloading is merely an optimization. However, the issue is very subtle, and so it is mentioned here by way of clarification.