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In case of arrays we can say Animal[] animals = new Cat[10];

But, using generic syntax we can't say List<Animal> is a ArrayList<Cat>.

List<Animal> can refer to any polymorphic base collection of only Animal and nothing else for the sake of type safety.

public void foo() {
    Cat[] cats = {new Cat(), new Cat()};

public void addAnimal(Animal[] animals) {
    animals[0] = new Dog(); // No compile time error. But ArrayStoreException
                            // at runtime as the JVM knows the type of animals.

Had generics been implicitly polymorphic, in the worst case, even if we add some wrong element into a collection and do some stuff similar to the one as in the above code, at most we will get a ClassCastException (or some other exception) which also stops program flow like ArrayStoreException right?

I have read that in case of generics, because of type erasure, the JVM doesn't know anything about the type of the collection and hence it can't throw an exception like ArrayStoreException.

My question is why this much compile time protection in case of typed collections? Why so many picky rules with generics? Please provide a correct understanding.

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Is your Animal an Abstract Class or an interface? –  OrhanC1 Apr 8 '14 at 11:22
Because, well, type-safety improves robustness, and Java is a type-safe language. You can use JavaScript, Groovy, or whatever other dynamic language if you prefer less type-safe languages. In Java, we prefer not having dogs in a List<Cat>. –  JB Nizet Apr 8 '14 at 11:22
Because it is better to catch bugs in compile time rather than let it through to runtime. –  anonymous Apr 8 '14 at 11:24
"at most we will get a ClassCastException (or some other exception) which also stops program flow like ArrayStoreException" It is not hard to argue that covariance of arrays is the feature Java got wrong. –  Radiodef Apr 8 '14 at 11:51

2 Answers 2

up vote 1 down vote accepted

It is a common misconception that generics was introduced as an extension to the existing Java polymorphism. This is not true. Java generics was introduced to allow for Compile time type checking.

interface Species {


class Animal implements Species {


class Cat extends Animal {


class Dog extends Animal {


class Plant implements Species {


class Tree extends Plant {


public void test() {
    List<Animal> animals = new ArrayList<>();
    animals.add(new Cat());
    animals.add(new Dog());
    // Not allowed.
    //animals.add(new Tree());

    // The old way.
    List beasts = new ArrayList();
    beasts.add(new Cat());
    beasts.add(new Dog());
    // Allowed - only caught at run time and difficult to find.
    beasts.add(new Tree());

    // The interface way.
    List<Species> living = new ArrayList();
    living.add(new Cat());
    living.add(new Dog());
    // Allowed.
    living.add(new Tree());


The aim of generics was to make it easy to specify exactly what class the object can handle and have that checked at compile time.

Generics also made the use of interfaces much neater.

share|improve this answer

The idea is generics are intended to be type safe. If List<Cat> was a subclass of List<Animal> - it would violate it:

List<Cat> cats = new ArrayList<Cat>();
List<Animal> animals = cats;
animals.add(new Dog());

The above would compile just fine - but what would happen now when you try to access cats? it will have an element which is not a Cat, and for instance:

for (Cat c : cats) { ...} 

would fail.

share|improve this answer
I think you meant animals.add(new Dog());? –  anonymous Apr 8 '14 at 11:25
@anonymous Thank you. Of course I did. –  amit Apr 8 '14 at 11:27
@amit Are you sure List<Animal> animals = cats; will compile? –  user3034861 Apr 8 '14 at 11:30
@Phoenix It would have compiled if List<Cat> was extending List<Animal>. Luckily - it is not, so it does not compile. –  amit Apr 8 '14 at 11:31
@amit Thank you. –  user3034861 Apr 8 '14 at 11:40

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