74

I understand that <? super T> represents any super class of T (parent class of T of any level). But I really struggle to imagine any real life example for this generic bound wildcard.

I understand what <? super T> means and I have seen this method:

public class Collections {
  public static <T> void copy(List<? super T> dest, List<? extends T> src) {
      for (int i = 0; i < src.size(); i++)
        dest.set(i, src.get(i));
  }
}

I am looking for an example of real life use case where this construction can be used and not for an explanation of what it is.

  • 18
    this is NOT a duplicate, a very valid question – Eugene Sep 5 '18 at 13:12
  • 6
    i also dont think its a duplicate, he is asking for concrete situations, not the principle behind – ItFreak Sep 5 '18 at 13:28
  • 2
    This is the start of the answer that I was about to write when this one was closed: I agree to some extent with the close-voters: The answer could be derived, with some diligence, from stackoverflow.com/questions/2723397/… . However, this question (as well as the answers here) focus on the technical principle. A simple, realistic example of where it makes sense to use ? super T could be helpful. – Marco13 Sep 5 '18 at 14:49
  • 4
    Don't think this should have been closed as a duplicate, since the author is asking for real-world models of OOP, rather than in-depth explanations of how inheritance works in Java. – John Stark Sep 5 '18 at 14:49
  • 3
    Isn't this example here a real life use case? – user253751 Sep 6 '18 at 1:21
46

The easiest example I can think of is:

public static <T extends Comparable<? super T>> void sort(List<T> list) {
    list.sort(null);
}

taken from the same Collections. This way a Dog can implement Comparable<Animal> and if Animal already implements that, Dog does not have to do anything.

EDIT for a real example:

After some email ping-pongs, I am allowed to present a real example from my work-place (yay!).

We have an interface called Sink (it does not matter what it does), the idea is that is accumulates things. The declaration is pretty trivial (simplified):

interface Sink<T> {
    void accumulate(T t);
}

Obviously there is a helper method that takes a List and drains it's elements to a Sink (it's a bit more complicated, but to make it simple):

public static <T> void drainToSink(List<T> collection, Sink<T> sink) {
    collection.forEach(sink::accumulate);
}

This is simple right? Well...

I can have a List<String>, but I want to drain it to a Sink<Object> - this is a fairly common thing to do for us; but this will fail:

Sink<Object> sink = null;
List<String> strings = List.of("abc");
drainToSink(strings, sink);

For this to work we need to change the declaration to:

public static <T> void drainToSink(List<T> collection, Sink<? super T> sink) {
    ....
}
  • Kotlin tutorial uses Source as example... which is basically the dual of your Sink example. – Bakuriu Sep 5 '18 at 17:16
  • 2
    Surely you could define it in the opposite way by making the list ? extends T? – Weckar E. Sep 5 '18 at 17:46
  • @WeckarE. Not if the method is on the list itself. – Reinstate Monica Sep 6 '18 at 1:35
  • 1
    @WeckarE. I could yes, but this would change the semantics a bit now I can't add anything to that list, it becomes a producer only; as said this is a simplified example... – Eugene Sep 10 '18 at 9:14
15

Suppose you have this class hierarchy: Cat inherits from Mammal, which in turn inherits from Animal.

List<Animal> animals = new ArrayList<>();
List<Mammal> mammals = new ArrayList<>();
List<Cat> cats = ...

These calls are valid:

Collections.copy(animals, mammals); // all mammals are animals
Collections.copy(mammals, cats);    // all cats are mammals
Collections.copy(animals, cats);    // all cats are animals
Collections.copy(cats, cats);       // all cats are cats 

But these calls are not valid:

Collections.copy(mammals, animals); // not all animals are mammals
Collections.copy(cats, mammals);    // not all mammals are cats
Collections.copy(cats, animals);    // mot all animals are cats

So the method signature simply insures that you copy from a more specific (lower in the inheritance hierarchy) class to a more generic class (upper in the inheritance hierarchy), and not the other way round.

  • 1
    The super keyword isn't necessary for this to work, though. This signature would also have exposed identical behavior: public static <T> void copy(List<T> dest, List<? extends T> src) { – Nick Sep 6 '18 at 11:41
  • 1
    @Nick Good catch. Why this signature then ? This question should be raised to Java language designers. So far the only reason I found is that you can write code like: Collections.<Mammal>copy(animals, cats); - but I don't know why someone would/should write code like this... – Benoit Sep 6 '18 at 13:14
6

For example, look into the Collections.addAll method implmenetation:

public static <T> boolean addAll(Collection<? super T> c, T... elements) {
    boolean result = false;
    for (T element : elements)
        result |= c.add(element);
    return result;
}

Here, the elements can be inserted into any collection whose element type is a supertype of the type T of the element.

Without a lower bounded wildcard:

public static <T> boolean addAll(Collection<T> c, T... elements) { ... }

the following would have been invalid:

List<Number> nums = new ArrayList<>();
Collections.<Integer>addAll(nums , 1, 2, 3);

because the term Collection<T> is more restrictive than Collection<? super T>.


Another example:

Predicate<T> interface in Java, that uses a <? super T> wildcard in the following methods:

default Predicate<T> and(Predicate<? super T> other);

default Predicate<T>  or(Predicate<? super T> other);

<? super T> allows to chain a wider range of different predicates, for example:

Predicate<String> p1 = s -> s.equals("P");
Predicate<Object> p2 = o -> o.equals("P");

p1.and(p2).test("P"); // which wouldn't be possible with a Predicate<T> as a parameter
  • I don't think this example is particularly compelling. If you leave out the explicit instantiation of the type variable, you're just as able to write Collections.addAll(nums, 1, 2, 3) with either method signature. – Nick Sep 7 '18 at 1:55
2

Suppose you have a method:

passToConsumer(Consumer<? super SubType> consumer)

then you call this method with any Consumer which can consume SubType:

passToConsumer(Consumer<SuperType> superTypeConsumer)
passToConsumer(Consumer<SubType> subTypeConsumer)
passToConsumer(Consumer<Object> rootConsumer)

For exmaple:

class Animal{}

class Dog extends Animal{

    void putInto(List<? super Dog> list) {
        list.add(this);
    }
}

So I can put the Dog into List<Animal> or List<Dog>:

List<Animal> animals = new ArrayList<>();
List<Dog> dogs = new ArrayList<>();

Dog dog = new Dog();
dog.putInto(dogs);  // OK
dog.putInto(animals);   // OK

If you change putInto(List<? super Dog> list) method to putInto(List<Animal> list):

Dog dog = new Dog();

List<Dog> dogs = new ArrayList<>();
dog.putInto(dogs);  // compile error, List<Dog> is not sub type of List<Animal>

or putInto(List<Dog> list):

Dog dog = new Dog();

List<Animal> animals = new ArrayList<>();
dog.putInto(animals); // compile error, List<Animal> is not sub type of List<Dog>
  • 1
    whenever you say Consumer or consume this automatically falls into the PECS category, not saying this is bad though, good examples – Eugene Sep 5 '18 at 14:57
1

I wrote a webradio, so I had the class MetaInformationObject, which was the superclass for PLS and M3U playlists. I had a selection dialogue, so I had:

public class SelectMultipleStreamDialog <T extends MetaInformationObject>
public class M3UInfo extends MetaInformationObject
public class PLSInfo extends MetaInformationObject

This class had a method public T getSelectedStream().
So the caller received a T which was of the concrete type (PLS or M3U), but needed to work on the superclass, so there was a list: List<T super MetaInformationObject>. where the result was added.
Thats how a generic dialogue could handle the concrete implementations and the rest of the code could work on the superclass.
Hope that makes it a little more clearer.

1

Consider this simple example:

List<Number> nums = Arrays.asList(3, 1.2, 4L);
Comparator<Object> numbersByDouble = Comparator.comparing(Object::toString);
nums.sort(numbersByDouble);

Hopefully this is a somewhat compelling case: You could imagine wanting to sort the numbers for display purposes (for which the toString is a reasonable ordering), but Number is not itself Comparable.

This compiles because integers::sort takes a Comparator<? super E>. If it took just a Comparator<E> (where E in this case is Number), then the code would fail to compile because Comparator<Object> is not a subtype of Comparator<Number> (due to reasons that your question indicates you already understand, so I won't go into).

1

Collections serve as a good example here.

As stated in 1, List<? super T> lets you create List that will hold elements of type, that are less derived than T, so it can hold elements that inherit from T, that are type of T and that T inherits from.

On the other hand, List<? extends T> lets you define a List that can hold only elements that inherit from T (in some cases not even of type T).

This is a good example:

public class Collections {
  public static <T> void copy(List<? super T> dest, List<? extends T> src) {
      for (int i = 0; i < src.size(); i++)
        dest.set(i, src.get(i));
  }
}

Here you want to project List of less derived type to List of less derived type. Here List<? super T> assures us that all elements from src will be valid in the new collection.

1 : Difference between <? super T> and <? extends T> in Java

0

Say you have:

class T {}
class Decoder<T>
class Encoder<T>

byte[] encode(T object, Encoder<? super T> encoder);    // encode objects of type T
T decode(byte[] stream, Decoder<? extends T> decoder);  // decode a byte stream into a type T

And then:

class U extends T {}
Decoder<U> decoderOfU;
decode(stream, decoderOfU);     // you need something that can decode into T, I give you a decoder of U, you'll get U instances back

Encoder<Object> encoderOfObject;
encode(stream, encoderOfObject);// you need something that can encode T, I give you something that can encode all the way to java.lang.Object
0

A few real life examples come to mind for this. The first one I like to bring up, is the idea of a real-world object being used for 'improvised' functionality. Imagine that you have a socket wrench:

public class SocketWrench <T extends Wrench>

The obvious purpose of a socket wrench it so be used as a Wrench. However, if you consider that a wrench could be used in a pinch to pound in a nail, you could have an inheritance hierarchy that looks like this:

public class SocketWrench <T extends Wrench>
public class Wrench extends Hammer

In this scenario, you would be able to call socketWrench.pound(Nail nail = new FinishingNail()), even though that would be considered an atypical use for a SocketWrench.

While all along, the SocketWrench would have access to be able to call methods like applyTorque(100).withRotation("clockwise").withSocketSize(14) if it's being used as a SocketWrench instead of just a Wrench, instead of a Hammer.

  • I don't find this very compelling: why would SocketWrench be a generic? – Max Sep 5 '18 at 15:11
  • You can have all sorts socket wrench types: 1/4” drive, 1/2” drive, adjustable handle angle socket wrenches, torque wrenches, differing ratchet teeth counts, etc. But if you just needed a wrench that ratchets, you could use a generic SocketWrench instead of a specific 3/4” drive 32-tooth angled handle socket wrench. – John Stark Sep 5 '18 at 15:23

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.