Why is Predicate<? super SomeClass> not applicable to Object?

Question

Assume we have a predicate declared as Predicate<? super SomeClass>. I would naively expect it to be applicable to any superclass of SomeClass up the hierarchy, including Object.

However this predicate is not applicable to Object. I get the following error:

The method test(capture#3-of ? super SomeClass) in the type Predicate is not applicable for the arguments (Object)

Demo.

Why is Predicate<? super SomeClass> not applicable to an instance of Object?

The code:

import java.util.*;
import java.lang.*;
import java.io.*;
import java.net.URL;
import java.util.function.Predicate;


/* Name of the class has to be "Main" only if the class is public. */
class Ideone
{
    public static void main (String[] args) throws java.lang.Exception
    {
        Predicate<? super URL> p = u -> u.getFile().isEmpty();
        p.test(new Object());
    }
}

Answer 1

For a Predicate<? super SomeClass> variable, you can assign a Predicate<SomeClass> instance, or a Predicate<Object> instance.

However, you can't pass an Object to the test() method of a Predicate<SomeClass>. You can only pass a SomeClass instance.

Therefore you can't pass an Object to the test() method of a Predicate<? super SomeClass>

Consider the following:

Predicate<URL> p1 = u -> u.getFile().isEmpty();
Predicate<? super URL> p2 = p1;

p2 is referring to a Predicate<URL>, so you can't pass a new Object() to its test() method.

In other words, in order for p.test(new Object()) to be accepted by the compiler, it must be valid for any Predicate that can be assigned to the Predicate<? super URL> p variable. Since the Predicate<URL> Predicate can be assigned to that variable, and its test() method cannot accept an Object, p.test(new Object()) cannot be accepted by the compiler.

BTW, in your specific example, you are creating a Predicate<URL>, and URL is a final class. Therefore, you should simply declare it as:

Predicate<URL> p = u -> u.getFile().isEmpty();

There's no reason for ? super or ? extends.

Answer 2

Consider the broader example:

Predicate<? super Integer> p;

In this situation, any of the following assignments is valid, right?

p = (Predicate<Integer>) i -> true; // but, only Integer can be applied
p = (Predicate<Number>)  n -> true; // Number and its sub-classes (Integer, Double...)
p = (Predicate<Object>)  o -> true; // any type

So, if in the end it is:

Predicate<? super Integer> p  = (Predicate<Integer>) i -> true;

Then, certainly, neither Number nor Object could not be applied to the predicate.

To guarantee type safety, a compiler allows only those types, which are valid for any of the possible assignments to the Predicate<? super Integer> - so, only Integer in this particular example.

Changing the lower bound from Integer to Number extends the boundaries respectively:

Predicate<? super Number> p  = (Predicate<Number>) n -> true;

Now, the predicate can be applied to the Number and any of its sub-classes : Integer, Double etc.

Summarizing

The only types which can be applied to the Predicate<? super SomeClass> without breaking a type safety guarantees: the lower bound itself and its sub-classes.

Answer 3

The Predicate already has a type. The type the predicate accepts can't be decided at the point when you try and call it. It has a type, and that type is some superclass of X; it's just unknown.

If I have a Predicate<Collection>, that could be referenced as a Predicate<? super List>. But that doesn't mean that it will accept any Object. The ? extends X generic type doesn't mean it will accept anything matching the given constraints. It means it is a predicate for some kind of unknown type that matches the given constraints.

Predicate<? super List> predicate = Collection::isEmpty;
predicate.test(new Object()); // Should this be valid? Clearly not

Answer 4

The java tutorial pages provides some good information about upper / lower bounded wildcards when using generics.

It also provides some guidelines for using wildcards which can help decide which wildcard you should use:

An "In" Variable An "in" variable serves up data to the code. Imagine a copy method with two arguments: copy(src, dest). The src argument provides the data to be copied, so it is the "in" parameter. An "Out" Variable An "out" variable holds data for use elsewhere. In the copy example, copy(src, dest), the dest argument accepts data, so it is the "out" parameter.

Of course, some variables are used both for "in" and "out" purposes — this scenario is also addressed in the guidelines.

You can use the "in" and "out" principle when deciding whether to use a wildcard and what type of wildcard is appropriate. The following list provides the guidelines to follow: Wildcard Guidelines:

An "in" variable is defined with an upper bounded wildcard, using the extends keyword.
An "out" variable is defined with a lower bounded wildcard, using the super keyword.
In the case where the "in" variable can be accessed using methods defined in the Object class, use an unbounded wildcard.
In the case where the code needs to access the variable as both an "in" and an "out" variable, do not use a wildcard.

These guidelines do not apply to a method's return type. Using a wildcard as a return type should be avoided because it forces programmers using the code to deal with wildcards.

Answer 5

This is quite a complex subject. These ? extends T and ? super T declarations are rather supposed to create a "matching" between classes.

If a class defines a method taking a Consumer, say something like Iterable<T>.foreach(), it defines this consumer to accept everything which can take a T. Thus, it defines it as forEach(Consumer<? super T> action). Why? Because an Iterator<Integer>'s foreach() can be called with a Consumer<Number> or even a Consumer<Object>. This is something which wouldn't be possible without the ? super T.

OTOH, if a class defines a method taking a Supplier, say something like addFrom, it defines this supplier to supply everything which is a T. Thus, it defines it as addFrom(Supplier<? extends T> supplier). Why? Because a ThisClass<Number>'s addFrom() can be called with a Supplier<Integer> or a Supplier<Double>. This is something which wouldn't be possible without the ? extends T.

Maybe a better example for the latter: List<E>.addAll() which takes a Collection<? extends E>. This makes it possible to add the elements of a List<Integer> to a List<Number>, but not vice versa.