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I'm a bit confused about how Java generics handle inheritance / polymorphism.

Assume the following hierarchy -

Animal (Parent)

Dog - Cat (Children)

So suppose I have a method doSomething(List<Animal> animals). By all the rules of inheritance and polymorphism, I would assume that a List<Dog> is a List<Animal> and a List<Cat> is a List<Animal> - and so either one could be passed to this method. Not so. If I want to achieve this behavior, I have to explicitly tell the method to accept a list of any subset of Animal by saying doSomething(List<? extends Animal> animals).

I understand that this is Java's behavior. My question is why? Why is polymorphism generally implicit, but when it comes to generics it must be specified?

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1  
And a totally unrelated grammar question that's bothering me now - should my title be "why aren't Java's generics" or "why isn't Java's generics"?? Is "generics" plural because of the s or singular because it's one entity? –  froadie Apr 30 '10 at 14:44
6  
generics as done in Java are a very poor form of parametric polymorphism. Don't put too much into faith into them (like I used to), because one day you'll hit hard their pathetic limitations: Surgeon extends Handable<Scalpel>, Handable<Sponge> KABOOM! Does not compute [TM]. There's your Java generics limitation. Any OOA/OOD can be translated fine into Java (and MI can be done very nicely using Java interfaces) but generics just don't cut it. They're fine for "collections" and procedural programming that said (which is what most Java programmers do anyway so...). –  SyntaxT3rr0r Apr 30 '10 at 15:43
1  
Super class of List<Dog> is not List<Animal> but List<?> (i.e list of unknown type) . Generics erases type information in compiled code. This is done so that code which is using generics(java 5 & above) is compatible with earlier versions of java without generics. –  rai.skumar Dec 4 '12 at 11:15

7 Answers 7

up vote 236 down vote accepted

No, a List<Dog> is not a List<Animal>. Consider what you can do with a List<Animal> - you can add any animal to it... including a cat. Now, can you logically add a cat to a litter of puppies? Absolutely not.

// Illegal code - because otherwise life would be Bad
List<Dog> dogs = new List<Dog>();
List<Animal> animals = dogs; // Awooga awooga
animals.add(new Cat());
Dog dog = dogs.get(0); // This should be safe, right?

Suddenly you have a very confused cat.

Now, you can't add a Cat to a List<? extends Animal> because you don't know it's a List<Cat>. You can retrieve a value and know that it will be an Animal, but you can't add arbitrary animals. The reverse is true for List<? super Animal> - in that case you can add an Animal to it safely, but you don't know anything about what might be retrieved from it, because it could be a List<Object>.

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3  
Interestingly, every list of dogs is indeed a list of animals, just like intuition tells us. The point is, that not every list of animals is a list of dogs, hence mutattion of the list by adding a cat is the problem. –  Ingo Jan 28 '13 at 19:29
4  
@Ingo: No, not really: you can add a cat to a list of animals, but you can't add a cat to a list of dogs. A list of dogs is only a list of animals if you consider it in a read-only sense. –  Jon Skeet Jan 28 '13 at 19:33
3  
@JonSkeet - Of course, but who is mandating that making a new list from a cat and a list of dogs actually changes the list of dogs? This is an arbitrary implementation decision in Java. One that goes counter to logic and intuition. –  Ingo Jan 28 '13 at 19:41
4  
@ruakh: The problem is that you're then punting to execution time something which can be blocked at compile-time. And I'd argue that array covariance was a design mistake to start with. –  Jon Skeet Jul 3 '13 at 17:22
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10 points for use of Awooga –  orbfish Jul 30 at 19:47

What you are looking for is called covariant type parameters. The problem is that they are not type-safe in the general case, specifically for mutable lists. Suppose you have a List<Dog>, and it is allowed to function as a List<Animal>. What happens when you try to add a Cat to this List<Animal> which is really a List<Dog>? Automatically allowing type parameters to be covariant therefore breaks the type system.

It would be useful to add syntax to allow type parameters to be specified as covariant, which avoids the ? extends Foo in method declarations, but that does add additional complexity.

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Or use: List<Object> –  moin Aug 29 '12 at 11:35

The reason a List<Dog> is not a List<Animal>, is that, for example, you can insert a Cat into a List<Animal>, but not into a List<Dog>... you can use wildcards to make generics more extensible where possible; for example, reading from a List<Dog> is the similar to reading from a List<Animal> -- but not writing.

The Generics in the Java Language and the Section on Generics from the Java Tutorials have a very good, in-depth explanation as to why some things are or are not polymorphic or permitted with generics.

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9  
I would vote this excellent explanation up, except that it didn't contain the comment "Awooga Awooga". –  DJClayworth Mar 28 '11 at 14:47
2  
This is actually the best answer here. I am tempted to edit it, just to add the awoogas. –  David Wallace Nov 18 '13 at 4:07

I would say the whole point of Generics is that it doesn't allow that. Consider the situation with arrays, which do allow that type of covariance:

  Object[] objects = new String[10];
  object[0] = Boolean.FALSE;

That code compiles fine, but throws a runtime error. It is not typesafe. The point of Generics is to add the compile time type safety, otherwise you could just stick with a plain class without generics.

Now there are times where you need to be more flexible and that is what the ? super Class and ? extends Class are for. The former is when you need to insert into a type Collection (for example), and the latter is for when you need to read from it, in a type safe manner. But the only way to do both at the same time is to have a specific type.

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8  
Arguably, array covariance is a language design bug. Note that due to type erasure, the same behaviour is technically impossible for generic collection. –  Michael Borgwardt Apr 30 '10 at 14:55
    
FYI: I mentioned your answer in stackoverflow.com/a/26551453/295802 –  Mark Bennett Oct 24 at 17:16

The basis logic for such behavior is that Generics follow a mechanism of type erasure. So at run time you have no way if identifying the type of collection unlike arrays where there is no such erasure process. So coming back to your question...

So suppose there is a method as given below:

add(List<Animal>){//You can add List<Dog or List<Cat> and this will compile as per rules of polymorphism}

Now if java allows caller to add List of type Animal to this method then you might add wrong thing into collection and at run time too it will run due to type erasure. While in case of arrays you will get a run time exception for such scenarios...

Thus in essence this behavior is implemented so that one cannot add wrong thing into collection. Now I believe type erasure exists so as to give compatibility with legacy java without generics....

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A point I think should be added to what other answers mention is that while

List<Dog> isn't-a List<Animal> in Java

it is also true that

A list of dogs is-a list of animals in English

The way the OP's intuition works - which is completely valid of course - is the latter sentence. However, if we apply this intuition we get a language that is not Java-esque in its type system: Suppose our language does allow adding a cat to our list of dogs. What would that mean? It would mean that the list ceases to be a list of dogs, and remains merely a list of animals. And a list of mammals, and a list of quadrapeds.

More generally, OP's intuition lends itself towards a language in which operations on objects can change their type, or rather, an object's type(s) is a (dynamic) function of its value.

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The answer http://stackoverflow.com/a/2745301/4350148 as well as other answers are correct. I am going to add to those answers with a solution that I think will be helpful. I think this comes up often in programming. One thing to note, is that for Collections(Lists,Sets, etc) the main issue is adding to the Collection. That is where things break down. Even removing is OK. In most cases we can use Collection<? extends T> rather then Collection<T> and that should be the first choice. However, I am finding cases where it is not easy to do that. It is up for debate as to whether that is always the best thing to do. I am presenting here a class DownCastCollection that can take convert a Collection<? extends T> to a Collection<T> (we can define similar classes for List, Set, NavigableSet,..) to be used when using the standard approach is very inconvenient. Below is an example of how to use it (we could also use Collection<? extends Object> in this case, but I am keeping it simple to illustrate using DownCastCollection.

/**Could use Collection<? extends Object> and that is the better choice. 
* But I am doing this to illustrate how to use DownCastCollection. **/

public static void print(Collection<Object> col){  
    for(Object obj : col){
    System.out.println(obj);
    }
}
public static void main(String[] args){
  ArrayList<String> list = new ArrayList<>();
  list.addAll(Arrays.asList("a","b","c"));
  print(new DownCastCollection<Object>(list));
}

Now the class:

import java.util.AbstractCollection;
import java.util.Collection;
import java.util.Iterator;
import java.util.NoSuchElementException;

public class DownCastCollection<E> extends AbstractCollection<E> implements Collection<E> {
private Collection<? extends E> delegate;

public DownCastCollection(Collection<? extends E> delegate) {
    super();
    this.delegate = delegate;
}

@Override
public int size() {
    return delegate ==null ? 0 : delegate.size();
}

@Override
public boolean isEmpty() {
    return delegate==null || delegate.isEmpty();
}

@Override
public boolean contains(Object o) {
    if(isEmpty()) return false;
    return delegate.contains(o);
}
private class MyIterator implements Iterator<E>{
    Iterator<? extends E> delegateIterator;

    protected MyIterator() {
        super();
        this.delegateIterator = delegate == null ? null :delegate.iterator();
    }

    @Override
    public boolean hasNext() {
        return delegateIterator != null && delegateIterator.hasNext();
    }

    @Override
    public  E next() {
        if(!hasNext()) throw new NoSuchElementException("The iterator is empty");
        return delegateIterator.next();
    }

    @Override
    public void remove() {
        delegateIterator.remove();

    }

}
@Override
public Iterator<E> iterator() {
    return new MyIterator();
}



@Override
public boolean add(E e) {
    throw new UnsupportedOperationException();
}

@Override
public boolean remove(Object o) {
    if(delegate == null) return false;
    return delegate.remove(o);
}

@Override
public boolean containsAll(Collection<?> c) {
    if(delegate==null) return false;
    return delegate.containsAll(c);
}

@Override
public boolean addAll(Collection<? extends E> c) {
    throw new UnsupportedOperationException();
}

@Override
public boolean removeAll(Collection<?> c) {
    if(delegate == null) return false;
    return delegate.removeAll(c);
}

@Override
public boolean retainAll(Collection<?> c) {
    if(delegate == null) return false;
    return delegate.retainAll(c);
}

@Override
public void clear() {
    if(delegate == null) return;
        delegate.clear();

}

}

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