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Why Bar.go for f2 is OK but for f1 is not?

public class HelloWorld {
    public static void main(String[] args) {
        Foo<Foo<?>> f1 = new Foo<Foo<?>>();
        Foo<Foo<String>> f2 = new Foo<Foo<String>>();
        Bar.go(f1);     // not OK
        Bar.go(f2);     // OK

    public static void p(Object o) {

class Foo<E> {

class Bar {
    public static <T> void go(Foo<Foo<T>> f) {

Shouldn't the compiler automatically infer type T as capture of ? in both cases?

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Foo<Foo<?>> f1 = new Foo<Foo<?>>();

This implies that the type is unknown and objects of any type can be added to Foo<Foo<?>> that are heterogeneous and compiler cannot guarantee that all object in Foo<Foo<?>> are of same type. Hence it cannot be passed to Bar.go that takes a bounded type as parameter.

You can instead declare that as Foo<Foo<Object>> f1 = new Foo<Foo<Object>>(); to pass it to Bar.go where you explicitly mention everything is of type Object.

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actually, assuming Foo is like a collection, it is your suggested type that is the heterogeneous one. Foo<Foo<?>> means a Foo containing Foos containing some specific, homogeneous element type that is not specified. – Judge Mental Sep 23 '12 at 5:28
The idea was to drive the point that Foo<Foo<?>> works on unbounded type and so the compiler can't match it with a bounded counterpart. And yes, I agree the terminology was more assuming that Foo is a container which it need not be, but the point stil holds. – Vikdor Sep 23 '12 at 5:30
@JudgeMental: No, Foo<Foo<?>> is heterogenous and can contain Foo<Bar> and Foo<Baz> at the same time. – newacct Sep 24 '12 at 20:19

A Nice Read What do multi-level wildcards mean?


Collection< Pair<String,Long> >        c1 = new ArrayList<Pair<String,Long>>();

Collection< Pair<String,Long> >        c2 = c1;  // fine
Collection< Pair<String,?> >           c3 = c1;  // error
Collection< ? extends Pair<String,?> > c4 = c1; // fine  

Of course, we can assign a Collection<Pair<String,Long>> to a Collection<Pair<String,Long>>. There is nothing surprising here.

But we can not assign a Collection<Pair<String,Long>> to a Collection<Pair<String,?>>. The parameterized type Collection<Pair<String,Long>> is a homogenous collection of pairs of a String and a Long ; the parameterized type Collection<Pair<String,?>> is a heterogenous collection of pairs of a String and something of unknown type. The heterogenous Collection<Pair<String,?>> could for instance contain a Pair<String,Date> and that clearly does not belong into a Collection<Pair<String,Long>>. For this reason the assignment is not permitted.

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I will prove that if the compiler allows Bar.go(f1);, the type system(safety) would be broken:

Java grammar allows you to use T as a type to declare variables in go(). Something like: T t = <something>.

Now, let's use ArrayList instead of Foo,

Then we have:

class HW {
 public static void main(String[] args) {
        ArrayList<ArrayList<?>> f1 = new ArrayList<ArrayList<?>>();
        go(f1);     // not OK

    public static <T> void go(ArrayList<ArrayList<T>> f) {

ArrayList<?> is supertype of ArrayList<String>, it is also supertype of ArrayList<Integer>, meaning that you can do the following in main:

ArrayList<?> s = new ArrayList<String>();

ArrayList<?> i = new ArrayList<Integer>();

Now, let's assume that the compiler allows you to call go() with f1 as argument. The option to infer T are:

  1. T = Object, but ArrayList<ArrayList<Object>> is not ArrayList<ArrayList<?>> because ArrayList<Object> is not the same type as ArrayList<?> So that is not allowed option.

  2. T = ?, then we would be able to do:

    public static <T> void go(ArrayList<ArrayList<T>> f) {
         ArrayList<T> alt1 = f.get(0); // ArrayList<String>
         T str = alt1.get(0);
         ArrayList<T> alt2 = f.get(1); // ArrayList<Integer>
         alt2.add(str); // We have added String to List<Integer>
        // ... type system broken

go() to work in both cases you have to do:

public static void go(ArrayList<? extends ArrayList<?>> f) {
share|improve this answer
Your proof seems broken. Why should alt.add(new Integer(1)) (I assume you mean add) work? The subtyping between T and Integer being unknown, it would be rejected. A working proof would be: f.get(1).add(f.get(0).get(0)), effectively adding a String to a list of Integers. – Ben Schulz Sep 23 '12 at 15:41
@Ben Schulz Thank you for discovering my mistake. Fixed. – Op De Cirkel Sep 23 '12 at 16:48

Great question!

(In the following comments, w.r.t. a class generic in E like Foo< E >, define "covariant method" as a method that returns an E without having any parameters using E, and a "contravariant method" as the opposite: one which takes a formal parameter of type E but doesn't return a type involving E. [The real definition of these terms is more complicated, but never mind that for now.])

It seems that the compiler is trying to bind T to Object in the case of f1, because if you do

class Bar0 {
    public static < T > void go( Foo< Foo< ? extends T > > f ) {
        // can pass a Foo< T > to a contravariant method of f;
        // can use any result r of any covariant method of f,
        // but can't pass T to any contravariant method of r

then the go(f1) works, but now go(f2) doesn't, because even though Foo< String > <: Foo< ? extends String >, that does not imply that Foo< Foo< String > > <: Foo< Foo< ? extends String > >.

Here are a few modifications that compile for both f1 and f2:

class Bar1 {
    public static < T > void go( Foo< ? super Foo< T > > f ) {
        // can't properly type the results of any covariant method of f,
        // but we can pass a Foo< T > to any contravariant method of f

class Bar2 {
    public static < T > void go( Foo< ? extends Foo< ? extends T > > f ) {
        // can't pass a Foo< T > to a contravariant method of f;
        // can use result r of any covariant method of f;
        // can't pass a T to a contravariant method of r;
        // can use result of covariant method of r
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