We are learning about the Collection Interface and I was wondering if you all have any good advice for it's general use? What can you do with an Collection that you cannot do with an array? What can you do with an array that you cannot do with a Collection(besides allowing duplicates)?

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    Collections allows duplicate. – Rudy May 23 '11 at 16:31
  • Collections can (sometimes) contain duplicates based on their type. Sets can't, but lists can for example. It all depends on the (more specific) collection type. – Michael Berry May 23 '11 at 16:32
  • @kreeSeeker: by "array" I take you mean a primitive array, like an int[] (seen that, say, an ArrayList is itself extending Collection at one point in its monstrously huge inheritance hierarchy). Well, what you can do with, say, an int[], that you cannot do with an List{Integer} is get the most out of your hardware which is important for people doing, for example, number crunching (and, yes, Java can and is used to crunch numbers, just not with the default collection). People don't realize that amount of waste that goes in Map{Integer,Integer}... Besides those using Trove ;) – SyntaxT3rr0r May 23 '11 at 16:33
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    @Marcelo Hernández Rishmawy: "Google is your friend" is not the kind of answer/comment welcome on SO. And hiding it behind a tinyurl is lame. SO is a place to find answers, not links to search engines. – SyntaxT3rr0r May 23 '11 at 16:34
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    @Rudy, @Berry120, @SyntaxT3rr0r, even answers to extremely simple questions should be answers and not comments. – Kirk Woll May 23 '11 at 16:35

It's easy if you think of it like this: Collections are better than object arrays in basically every way imaginable.

You should prefer List<Foo> over Foo[] whenever possible. Consider:

  • A collection can be mutable or immutable. A nonempty array must always be mutable.
  • A collection can be thread-safe; even concurrent. An array is never safe to publish to multiple threads.
  • A collection can allow or disallow null elements. An array must always permit null elements.
  • A collection is type-safe; an array is not. Because arrays "fake" covariance, ArrayStoreException can result at runtime.
  • A collection can hold a non-reifiable type (e.g. List<Class<? extends E>> or List<Optional<T>>). With an array you get compilation warnings and confusing runtime exceptions.
  • A collection has a fully fleshed-out API; an array has only set-at-index, get-at-index and length.
  • A collection can have views (unmodifiable, subList, filter...). No such luck for an array.
  • A list or set's equals, hashCode and toString methods do what users expect; those methods on an array do anything but what you expect -- a common source of bugs.
  • Because of all the reasons above, third-party libraries like Guava won't bother adding much additional support for arrays, focusing only on collections, so there is a network effect.

Object arrays will never be first-class citizens in Java.

A few of the reasons above are covered in much greater detail in Effective Java, Second Edition, starting at page 119.

So, why would you ever use object arrays?

  • You have to interact with an API that uses them, and you can't fix that API
    • so convert to/from a List as close to that API as you can
  • You have a reliable benchmark that shows you're actually getting better performance with them
    • but benchmarks can lie, and often do
  • I can't think of any other reasons
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    From what I understand, arrays are inherently threadsafe without locking in the scenario where different threads are accessing disjoint parts of the array. Most collections are either not threadsafe at all for any operations concurrent with any writes, even when the regions being acted upon are disjoint, or else they impose substantial threading-related overhead even when all threads happen to access disjoint regions. In .net arrays can offer thread-safety even when threads use shared elements, via Interlocked.CompareExchange but I don't think that's available on Java array elements. – supercat Sep 22 '12 at 17:37
  • Maybe with com.sun.Unsafe, which will be public in JDK9. – Kr0e May 1 '15 at 11:35

It's basically a question of the desired level of abstraction.

Most collections can be implemented in terms of arrays, but they provide many more methods on top of it for your convenience. Most collection implementations I know of for instance, can grow and shrink according to demand, or perform other "high-level" operations which basic arrays can't.

Suppose for instance that you're loading strings from a file. You don't know how many new-line characters the file contains, thus you don't know what size to use when allocating the array. Therefore an ArrayList is a better choice.

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    while that is true for some of the collection classes, it's not true for all of them! Look at some of the implementations of BlockingQueues (in java.util.concurrent) which don't expand necessarily -- as for shrinking apart from LinkedList I am not aware of any that does that -- which ones are you refering to? – Liv May 23 '11 at 16:38
  • Ah, thanks for letting me know :-) Updated the answer! – aioobe May 23 '11 at 16:40
  • that's ok -- it might help occasionally if you include the names of some of the classes you are referring to (e.g. the ones which grow and the ones which shrink -- in fact I'm vary curious about that one as I only know of LinkedList to do so!). – Liv May 23 '11 at 16:42
  • obviously depends on how you define shrink. An ArrayLists size can shrink, while an arrays .length stays fixed, right? – aioobe May 23 '11 at 16:44
  • oh right, i'm with you! Obviously .size() can go up and down but the size of the array used internally never goes down -- I think that's the point I was trying to make. But I take your point! – Liv May 23 '11 at 17:00

The details are in the sub interfaces of Collection, like Set, List, and Map. Each of those types has semantics. A Set typically cannot contain duplicates, and has no notion of order (although some implementations do), following the mathematical concept of a Set. A List is closest to an Array. A Map has specific behavior for push and get. You push an object by its key, and you retrieve with the same key.

There are even more details in the implementations of each collection type. For example, any of the hash based collections (e.g. HashSet, HasMap) are based on the hashcode() method that exists on any Java object.

You could simulate the semantics of any collection type based of an array, but you would have to write a lot of code to do it. For example, to back a Map with an array, you would need to write a method that puts any object entered into your Map into a specific bucket in the array. You would need to handle duplicates. For an array simulating a Set, you would need to write code to not allow duplicates.

  • What about for example: ArrayList a {1,2,3,4,5,6,7,8,9,0} – kreeSeeker May 23 '11 at 16:40
  • And ArrayList b {1,3,5,7,9,0}? – kreeSeeker May 23 '11 at 16:41
  • and a.addAll(b); Wont it remove duplicates? – kreeSeeker May 23 '11 at 16:42
  • ArrayList's can grow and shrink. Arrays can't. That's one of the main differences between arrays and ArrayLists. (See my answer for details.) – aioobe May 23 '11 at 16:43
  • Ok I think I see it now. So what if the ArrayLists I mentioned were instead primitive Arrays? What would the above code do? – kreeSeeker May 23 '11 at 16:45

The Collection interface is just a base interface for specialised collections -- I am not aware yet of a class that simply just implements Collection; instead classes implement specialized interfaces which extend Collection. These specialized interfaces and abstract classes provide functionality for working with sets (unique objects), growing arrays (e.g. ArrayList), key-value maps etc -- all of which you cannot do out of the box with an array. However, iterating through an array and setting/reading items from an array remains one of the fastest methods of dealing with data in Java.


One advantage is the Iterator interface. That is all Collections implement an Iterator. An Iterator is an object that knows how to iterate over the given collection and present the programmer with a uniformed interface regardless of the underlying implementation. That is, a linked list is traversed differently from a binary tree, but the iterator hides these differences from the programmer making it easier for the programmer to use one or the other collection.

This also leads to the ability to use various implementations of Collections interchangeably if the client code targets the Collection interface iteself.

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