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Typically, I've seen people use the class literal like this:

Class<Foo> cls = Foo.class;

But what if the type is generic, e.g. List? This works fine, but has a warning since List should be parameterized:

Class<List> cls = List.class

So why not add a <?>? Well, this causes a type mismatch error:

Class<List<?>> cls = List.class

I figured something like this would work, but this is just a plain ol' a syntax error:

Class<List<Foo>> cls = List<Foo>.class

How can I get a Class<List<Foo>> statically, e.g. using the class literal?

I could use @SuppressWarnings("unchecked") to get rid of the warnings caused by the non-parameterized use of List in the first example, Class<List> cls = List.class, but I'd rather not.

Any suggestions?


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4 Answers 4

up vote 51 down vote accepted

You can't due to type erasure.

Java generics are little more than syntactic sugar for Object casts. To demonstrate:

List<Integer> list1 = new ArrayList<Integer>();
List<String> list2 = (List<String>)list1;
list2.add("foo"); // perfectly legal

The only instance where generic type information is retained at runtime is with Field.getGenericType() if interrogating a class's members via reflection.

All of this is why Object.getClass() has this signature:

public final native Class<?> getClass();

The important part being Class<?>.

To put it another way, from the Java Generics FAQ:

Why is there no class literal for concrete parameterized types?

Because parameterized type has no exact runtime type representation.

A class literal denotes a Class object that represents a given type. For instance, the class literal String.class denotes the Class object that represents the type String and is identical to the Class object that is returned when method getClass is invoked on a String object. A class literal can be used for runtime type checks and for reflection.

Parameterized types lose their type arguments when they are translated to byte code during compilation in a process called type erasure . As a side effect of type erasure, all instantiations of a generic type share the same runtime representation, namely that of the corresponding raw type . In other words, parameterized types do not have type representation of their own. Consequently, there is no point in forming class literals such as List<String>.class , List<Long>.class and List<?>.class , since no such Class objects exist. Only the raw type List has a Class object that represents its runtime type. It is referred to as List.class.

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Aha! This makes more sense. I figured that the class literal on a generic wouldn't even make much sense, but I had no idea that it was due to this. Thanks! –  Tom Mar 5 '10 at 23:48

There are no Class literals for parameterized types, however there are Type objects that correctly define these types.

See java.lang.reflect.ParameterizedType - http://java.sun.com/j2se/1.5.0/docs/api/java/lang/reflect/ParameterizedType.html

Google's Gson library defines a TypeToken class that allows to simply generate parameterized types and uses it to spec json objects with complex parameterized types in a generic friendly way. In your example you would use:

Type typeOfListOfFoo = new TypeToken<List<Foo>>(){}.getType()

I intended to post links to the TypeToken and Gson classes javadoc but Stack Overflow won't let me post more than one link since I'm a new user, you can easily find them using Google search

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To expound on cletus' answer, at runtime all record of the generic types is removed. Generics are processed only in the compiler and are used to provide additional type safety. They are really just shorthand that allows the compiler to insert typecasts at the appropriate places. For example, previously you'd have to do the following:

List x = new ArrayList();
x.add(new SomeClass());
Iterator i = x.iterator();
SomeClass z = (SomeClass) i.next();


List<SomeClass> x = new ArrayList<SomeClass>();
x.add(new SomeClass());
Iterator<SomeClass> i = x.iterator();
SomeClass z = i.next();

This allows the compiler to check your code at compile-time, but at runtime it still looks like the first example.

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Thanks for the additional explanation--my understanding of generics is so much clearer now that I realize they're not a runtime mechanism. :) –  Tom Mar 5 '10 at 23:49
In my opinion, this just means that generic were implemented in a mediocre manner by Sun, hopefully Oracle fixes this some day. C#'s implementation of generic is much much much better (Anders is godlike) –  Marcel Valdez Orozco Aug 25 '13 at 21:38
@MarcelValdezOrozco AFAIK, in Java they implemented it that way because they wanted old code (pre-1.5) to work on new JVMs without any issues. Seems it's a very smart design decision which cares about compatibility. I don't think there's anything mediocre in that. –  peter.petrov Feb 11 at 21:41

Due to the exposed fact that Class literals doesn't have generic type information, I think you should assume that it will be impossible to get rid of all the warnings. In a way, using Class<Something> is the same as using a collection without specifying the generic type. The best I could come out with was:

private <C extends A<C>> List<C> getList(Class<C> cls) {
    List<C> res = new ArrayList<C>();
    // "snip"... some stuff happening in here, using cls
    return res;

public <C extends A<C>> List<A<C>> getList() {
    return getList(A.class);
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