This question already has an answer here:

I want to know how generics work in this kind of situation and why Set<? extends Foo<?>> set3 = set1; is allowed but Set<Foo<?>> set2 = set1; is not?

import java.util.HashSet;
import java.util.Set;

public class TestGenerics {
    public static <T> void test() {
        Set<T> set1 = new HashSet<>();
        Set<?> set2 = set1;             // OK

    public static <T> void test2() {
        Set<Foo<T>> set1 = new HashSet<>();
        Set<Foo<?>> set2 = set1;           // COMPILATION ERROR
        Set<? extends Foo<?>> set3 = set1; // OK

class Foo<T> {}

marked as duplicate by Lino, aminography, Andy Turner java Jan 9 at 13:50

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.

  • An interesting reading about this "issue": stackoverflow.com/a/4343547/7709086 – kagmole Jan 9 at 9:07
  • 2
    @Lino: This question is similar to and related to "What is PECS", but not exactly the same. This question is about PECS, but specifically applied to the case when the type arguments themselves are types which have type parameters. That makes this a particularly tricky special case, which warrants its own question. (But I'd be surprised if there is no other exactly duplicate question some where.) – Lii Jan 9 at 11:11

Simply said, this is because Set<? extends Foo<?>> is covariant (with the extends keyword). Covariant types are read-only and the compiler will refuse any write action, like Set.add(..).

Set<Foo<?>> is not covariant. It does not block write or read actions.


Set<Foo<String>> set1 = new HashSet<>();
Set<Foo<?>> set2 = set1; // KO by compiler

... is illegal because otherwise I could for example put a Foo<Integer> into set1 via set2.

set2.add(new Foo<Integer>()); // Whoopsie


Set<Foo<String>> set1 = new HashSet<>();
Set<? extends Foo<?>> set3 = set1; // OK

... is covariant (extends keyword), so it is legal. For example, the compiler will refuse a write operation like set3.add(new Foo<Integer>()), but accept a read operation like set3.iterator().

Iterator<Foo<String>> fooIterator = set3.iterator(); // OK
set3.add(new Foo<String>()); // KO by compiler

See these posts for a better explanation:

  • 3
    Did you mean Foo<Integer> foo; set2.add(foo); because set2.add(42) 42 isn't a Foo<?>. – matt Jan 9 at 10:10
  • Oops thank you @matt, I fixed my answer. – kagmole Jan 9 at 10:39

Perhaps the issue becomes clearer if you leave the generic parameter of Foo out of the equation.


final Set<Foo> set1 = new HashSet<>();
Set<Object> set2 = set1;

This makes the compile error more obvious. If this was valid, it would be possible to insert an object into set2, thus into set1 violating the type constraint.

Set<? extends Foo> set3 = set1;

This is perfectly valid because set1 would also accept types derived from Foo.

  • 1
    why did you transform Set<Foo<?>> to Set<Object> after type erasure? I guess wildcard will be replaced by Object since it is closest bound? – Sergey Prokofiev Jan 9 at 9:15
  • 1
    Foo<?> is not Object, it is Foo "of something". What allows the assignment to set3 is the covariance. – kagmole Jan 9 at 9:41
  • 2
    Also you answer implies that set3 is writable, which is not the case. See more about covariance and contravariance here : stackoverflow.com/a/4343547/7709086 – kagmole Jan 9 at 9:48

Additionally to the answers given already I'll add some formal explanation.

Given by 4.10.2 (emp. mine)

Given a generic type declaration C (n > 0), the direct supertypes of the parameterized type C, where Ti (1 ≤ i ≤ n) is a type, are all of the following:

D < U1 θ,...,Uk θ>, where D is a generic type which is a direct supertype of the generic type C and θ is the substitution [F1:=T1,...,Fn:=Tn].

C < S1,...,Sn> , where Si contains Ti (1 ≤ i ≤ n) (§4.5.1).

The type Object, if C is a generic interface type with no direct superinterfaces.

The raw type C.

Rule for contains are specified at 4.5.1:

A type argument T1 is said to contain another type argument T2, written T2 <= T1, if the set of types denoted by T2 is provably a subset of the set of types denoted by T1 under the reflexive and transitive closure of the following rules (where <: denotes subtyping (§4.10)):

? extends T <= ? extends S if T <: S

? extends T <= ?

? super T <= ? super S if S <: T

? super T <= ?

? super T <= ? extends Object

T <= T

T <= ? extends T

T <= ? super T

Since T <= ? super T <= ? extends Object = ? so applying 4.10.2 Foo<T> <: Foo<?> we have ? extends Foo<T> <= ? extends Foo<?>. But Foo<T> <= ? extends Foo<T> so we have Foo<T> <= ? extends Foo<?>.

Applying 4.10.2 we have that Set<? extends Foo<?>> is a direct supertype of Set<Foo<T>>.

The formal answer to why your first example does not compile may be got by assuming a contradiction. Percisely:

If Set<Foo<T>> <: Set<Foo<?>> we have that Foo<T> <= Foo<?> which is not possible to prove applying reflexive or transitive relations to rules from 4.5.1.


I think simply because the Set element Datatype is different while it must be the same except for Generic Datatype.
the first set Set<Foo<T>> datatype is Foo<T>,
then second set Set<Foo<?>> is Foo<?>,
As I can see the element datatype is different Foo<T> != Foo<?> and not generic type because it use Foo, so then would cause compilation error.
It is same as below invalid different datatype example :

Set<List<T>> set3 = new HashSet<>();
Set<List<?>> set4 = set3;   // compilation error due to different element datatype List<T> != List<?>

Set<? extends Foo<?>> set3 = set1; can because it have ? datatype which is generic and have purpose can accept any datatype.
ex :

Set<List<T>> set4 = new HashSet<>();
Set<?> set5 = set4;  // would be Ok

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