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Double brace initialisation (anonymous inner class) with diamond operator

In Java 7 and later, diamond can be used to infer types on normally like so without an issue:

List<String> list = new ArrayList<>();

However, it can't for anonymous inner classes like this:

List<String> st = new List<>() { //Doesn't compile

    //Implementation here

}

Why is this? Logically in this scenario, I can definitely infer the type as String. Is there a logical reason for this decision where the type cannot actually be inferred on anonymous inner classes, or was it omitted for other reasons?

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marked as duplicate by Philipp, durron597, Alessandro Minoccheri, VMAtm, Ragunath Jawahar Dec 12 '12 at 8:24

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

1  
@Philipp I disagree - that question is asking why a certain piece of code doesn't compile (indeed the answer is just that you can't use diamond with anonymous inner classes), this one is asking the technical / logical reason for why the Java devs chose to put that particular restriction in place. Related, but hardly the same thing. – berry120 Dec 11 '12 at 16:09
up vote 9 down vote accepted

In the JSR-334:

Using diamond with anonymous inner classes is not supported since doing so in general would require extensions to the class file signature attribute to represent non-denotable types, a de facto JVM change.

What I guess is that as everybody knows, anonymous class leads to a generation of its own class file.

I imagine that generic type doesn't exist within these files and rather replaced by the effective (static) type (thus declared by the explicit type like <String> at declaration object time).

Indeed, file corresponding to an inner class is never shared across multiple different instantiations of it, so why bother with generics into it?! :).

It would be more hardly achievable (and surely useless) for compiler to force an extension (by adding a special attribute for generics) to theses kind of class files.

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google yields, after skipping posts from stackoverflow, http://mail.openjdk.java.net/pipermail/coin-dev/2011-June/003283.html

I'm guessing it's like this, usually an anonymous class is a concrete subclass of the apparent type

    interface Foo<N extends Number>
    {
        void foo(N n);
    }

    Foo<Integer> foo = new Foo<Integer>(){ ... }

is implemented by

    class AnonFoo_1 implements Foo<Integer>{ ... }

    Foo<Integer> foo = new AnonFoo_1();

Suppose we allow diamond inference on anonymous classes, there can be complicated case like

    Foo<? extends Runnable> foo = new Foo<>(){ ... }

The inference rules yield N=Number&Runnable; following the prev implementation trick, we need

    class AnonFoo_2 implements Foo<Number&Runnable>{ ... }

That is currently not allowed; the type arg to super type Foo must be a "normal" type.


However, the rationale is not very strong. We can invent other implementation tricks to make it work

    class AnonFoo<N extends Number&Runnable> implements Foo<N>
    {
        @Override public void foo(N n)
        {
            n.intValue();
            n.run();
        }
    }

    Foo<? extends Runnable> foo = new AnonFoo<>();

the compiler ought to be able to do the same trick.

In any case, at least the compiler should allow the majority of use cases that do not involve "undenotable types", like Foo<Integer> foo = new Foo<>(){...} It's a pity that these common/simple cases are unnecessarily forbidden too.

share|improve this answer
    
Your example is strictly applicable with a simple (non-anonymous) concrete class. What is the specific feature corresponding to anonymous class in your sample? Indeed, if your theory were true, does never diamond could be applicable whatever the case. – Mik378 Dec 11 '12 at 16:17
    
on bytecode level, I don't think there's anything special about anonymous classes. – irreputable Dec 11 '12 at 16:20
    
So your sample would behave in exactly the same manner if instead of having an interface Foo you have: class Foo<N extends Number> { void foo(N n){} } Foo<Integer> foo = new Foo<Integer>(); – Mik378 Dec 11 '12 at 16:23
    
What I want to say is that even this line (with a simple concrete class instantiation) never compiles: Foo<? extends Runnable> foo = new Foo<???What I put in there???>(); => Number unrelated to Runnable. So the "HARD WORK" you're showing (declaring interface with multiple extending class) need obviously to be achieve for non-anonymous concrete classes also. – Mik378 Dec 11 '12 at 16:33
    
if you put nothing there, it'll compile:) – irreputable Dec 11 '12 at 16:36

Interesting questions. The solution can be found here http://docs.oracle.com/javase/specs/jls/se7/html/jls-15.html#jls-15.9 or here Double brace initialisation (anonymous inner class) with diamond operator

At least I learned something. Thanks for the question. ;)

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In short, the <> does little to infer types, it turns off the warning you would get without it.

EDIT: As @Natix points out it does some checking.

List<Integer> ints = new ArrayList<>();
List<String> copy = new ArrayList<>(ints);

produces a compilation error

Error:Error:line (42)error: incompatible types
required: List<String>
found:    ArrayList<Integer>

As you can see the <> is taking the type of the argument, not inferring the type from the type of copy

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3  
Not exactly, diamond still performs a type check. It may not be obvious for simple collection initializations, but take for example using a copy constructor: List<String> copy = new ArrayList<>(original); This ensures that the original list is also a list of strings (or more precisely a Collection<? extends String>). – Natix Dec 11 '12 at 15:02
    
While this is true, it is not inferring the type from how it is used. It is taking the type from an argument. – Peter Lawrey Dec 11 '12 at 15:17

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