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Generally, Java can be considered as a type-safe language. I know that there are some flaws with generics, but I recently came across a Problem I never had before. To break it down:

Object[] objects = new Integer[10];
objects[0] = "Hello World";

will NOT result in a compile-time error as expected. I would assume that the declaration of an Array of Object will disallow to point to to an array of something else. In Generics I'm not allowed to make such weird things like:

ArrayList<Object> objs = new ArrayList<Integer>

and if I try to kind of trick Java into doing something with

ArrayList<? extends Object> objects = new ArrayList<Integer>

I'm allowed to declare it, but I can only add Objects of type null.

Why doesn't Java prevent the declaration of such weired arrays?

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5 Answers

up vote 7 down vote accepted

I don't think there's an answer to this besides "legacy design". (Which I admit is a fancy way of saying "because".) You pretty much need to be able to do an equivalent of the last assignment you show somehow. (Otherwise you're stuck to making lots and lots of copies with manual up/down casts, assuming language features of Java pre 1.4)

In Java 1 when type semantics for arrays were basically set in stone, generics weren't available, or even up for consideration for a long while yet. So there was no mechanism available to express the higher-order type constraints needed to make this construct type-safe – and Gosling (IIRC a fan of simplicity) felt resolving this edge case of compile-time type safety wasn't worth complicated the language with whichever solutions were available. Or wasn't bothered by doing the check at runtime enough to even look for a solution. (At the end of the day language design decisions are arbitrary to at least some degree, and there's only one person that could answer this with any certainty.)

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Firstly, I should point out that this is type-safe.

Object[] objects = new Integer[10];
objects[0] = "Hello World";

because an exception will be thrown. (It is not statically type-safe ... but that is a different statement entirely.)

The reason that Java allows this is historical. Until Java 5, Java did not support any form of generics. Gosling has said that if they had had the time to figure out and incorporate generics into Java 1.0, they would have done so.

Unfortunately, they didn't. But they still wanted to be able write things like a general purpose sort method with the following signature:

    void sort(Object[] array, Comparator comp) ...

To make this method work for any kind of object array (without generics), it was necessary to make arrays covariant; i.e. to make it legal to pass a String[] or Integer[] as an argument where the formal type is Object[]. If they hadn't done that you would have had to copy the String[] to an Object[], sort it, and then copy it back.

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1  
I disagree strongly with the first sentence. “type safe” isn’t an absolute, although it’s often erroneously used that way. It’s a sliding scale, and OP’s code is pretty low on that scale. You can get lower in languages which don’t provide runtime type safety but a compile-time check would be much preferred. That’s what you said with “statically type safe”. –  Konrad Rudolph Dec 3 '12 at 15:39
    
I understand your answer, but I have a problem with " But they still wanted to be able write things like a general purpose sort method with the following signature: ..." What sense has it to Compare Objects (maybe Apples or Cars) with a Comparator which is designed to compare GameCards? What result does one expect from it? –  Rafael T Dec 3 '12 at 17:01
2  
@RafaelT: The point is that you shouldn't have to create a separate void sort(Apple[] array, AppleComparator comp), void sort(Car[] array, CarComparator comp), etc., that all have identical source-code except for the signature. This doesn't mean that all comparators are compatible with all arrays, only that the type-checking has to happen at run-time. (With the advent of generics, we can write <T> void sort(T[] array, Comparator<T> comp) and get compile-time type-checking as well, but the language didn't offer that till Java 5.) –  ruakh Dec 3 '12 at 19:56
    
@KonradRudolph - while "type-safe" is not an absolute in general (i.e. its meaning depends on the language), ignoring runtime type-safety in Java is just plain wrong. Remember we are talking about Java here ... and in this context type-safety is an absolute. –  Stephen C Dec 4 '12 at 7:24
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"Because it has to".

To elaborate a bit, consider the following example:

Object[] objects = null;
if (something) {
    objects = new Integer[10];
} else {
    objects = new String[10];
}

Now, how would the Java compiler know which assignments to allow and which to refuse? It can't. The compile-time type is Object so the compiler will let you put any Object in your array, simply because it doesn't have any knowledge of the runtime type of your array.

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If the compiler would take the same approach as with generics, it would disallow both assignments to objects in your code example. Only a new Object[10] would be allowed. –  Janoz Dec 3 '12 at 14:40
4  
-1: "Now, how would the Java compiler know which assignments to allow and which to refuse?" - the whole idea of static type checking is teaching the compiler which assignments to allow and refuse. This isn't an answer, it's a restatement of the question. –  millimoose Dec 3 '12 at 15:06
1  
@Eraser No, the static type is "array of Objects" – this is a completely distinct type from Object, even in Java's type system. (For example, array types override clone() to make it public and return the type of the array itself.) It is perfectly permissible to disallow an assignment of Integer[] to Object[] while allowing Integer to Object, and it in fact would make sense to do so because it's not type safe. The question goes over all this. –  millimoose Dec 3 '12 at 15:19
1  
To get formal: Arrays in Java are covariant, which allows type errors which can't be detected at compile time (as you noted). However, your answer (silently) assumes that they must be covariant -- this is not the case, the designers could have made them nonvariant (as others have pointed out, generics already are nonvariant). If they are nonvariant, the type errors are prevented. –  delnan Dec 3 '12 at 15:29
2  
That interpretation conflicts with these sentences from the question: "I would assume that the declaration of an Array of Object will disallow to point to to an array of something else." and "Why doesn't Java prevent the declaration of such weired arrays?" (emphasis mine) –  delnan Dec 3 '12 at 15:43
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actually in case of arrays you get a exception at run time called ArrayStoreException when you add wrong type of element In this case a String. In case of generics there is no such exception. its for the very same reason you are not allowed to add anything but object, as you might just add a wrong type into the list.

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There's Discussion that I found while I google it

I Found:

Firstly, arrays do not break type safety. If they did, then upcasting an array wouldn't fail at runtime. They make it impossible for the compiler to prove the program type-safe, so the checking is deferred until runtime.

I think confusion occurs here because one the one hand, since a String is-a Object an array of Strings is-obviously-an array of Objects, and on the other it clearly isn't. The answer is in the mutability of an array.

If the array is immutable, then it safe to treat a String[] as an Object[], because an immutable String[] is always exactly like an immutable Object[].

On the other hand, if the array is mutable, then it is not usually safe to treat a String[] as an Object[].

The "wildcards" technique described in the above link is exactly what CommonLisp has been doing for years.

(deftype StringArray? () (array String)) ; This is the type of arrays of String 
(deftype ObjectArray? () (array Object)) ; This is the type of arrays of Object 
(subtypep StringArray? ObjectArray?)      ; Is StringArray? a subtype of ObjectArray?? false, true                               ; No, it isn't. (false: it isn't, true: I'm ure) 
(deftype AnyArray? () (array *))         ; This is the type of arrays of anything (subtypep StringArray? AnyArray?)         ; Is StringArray? a subtype of AnyArray??   true, true                                ; Yes, it is. (true: it is, true: I'm sure)
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