Update 2011-Jan-06:

Believe it or not, I went ahead and incorporated this interface into an open source library I've started, Tao.NET. I wrote a blog post explaining this library's IArray<T> interface, which not only addresses the issues I originally raised in this question (a year ago?!) but also provides a covariant indexed interface, something that's sorely lacking (in my opinion) in the BCL.

Question (in short):

I asked why .NET has IList<T>, which implements ICollection<T> and therefore provides methods to modify the list (Add, Remove, etc.), but doesn't offer any in-between interface such as IArray<T> to provide random access by index without any list modification.

EDIT 2010-Jan-21 2:22 PM EST:

In a comment to Jon Skeet's original answer (in which he questioned how often one would have any need for a contract such as IArray<T>), I mentioned that the Keys and Values properties of the SortedList<TKey, TValues> class are IList<TKey> and IList<Value>, respectively, to which Jon replied:

But in this case it's declared to be IList and you know to just use the indexers. . . . It's not hugely elegant, I agree - but it doesn't actually cause me any pain.

This is reasonable, but I would respond by saying that it doesn't cause you any pain because you just know you can't do it. But the reason you know isn't that it's clear from the code; it's that you have experience with the SortedList<TKey, TValue> class.

Visual Studio isn't going to give me any warnings if I do this:

SortedList<string, int> mySortedList = new SortedList<string, int>();

// ...

IList<string> keys = mySortedList.Keys;

It's legal, according to IList<string>. But we all know, it's going to cause an exception.

Guillaume made an apt point as well:

Well, the interfaces aren't perfect but a dev can check the IsReadOnly property before calling Add/Remove/Set...

Again, this is reasonable, BUT: does this not strike you as a bit circuitous?

Suppose I defined an interface as follows:

public interface ICanWalkAndRun {
    bool IsCapableOfRunning { get; }

    void Walk();
    void Run();

Now, suppose as well that I made it a common practice to implement this interface, but only for its Walk method; in many cases, I would opt to set IsCapableOfRunning to false and throw a NotSupportedException on Run...

Then I might have some code that looked like this:

var walkerRunners = new Dictionary<string, ICanWalkAndRun>();

// ...

ICanWalkAndRun walkerRunner = walkerRunners["somekey"];

if (walkerRunner.IsCapableOfRunning) {
} else {

Am I crazy, or is this kind of defeating the purpose of an interface called ICanWalkAndRun?

Original Post

I find it very peculiar that in .NET, when I am designing a class with a collection property that provides random access by index (or a method that returns an indexed collection, etc.), but should not or cannot be modified by adding/removing items, and if I want to "do the right thing" OOP-wise and provide an interface so that I can change the internal implementation without breaking the API, I have to go with IList<T>.

The standard approach, it seems, is to go with some implementation of IList<T> that explicitly defines the methods Add, Insert, etc. -- typically by doing something like:

private List<T> _items;
public IList<T> Items {
    get { return _items.AsReadOnly(); }

But I kind of hate this. If another developer is using my class, and my class has a property of type IList<T>, and the whole idea of an interface is: "these are some available properties and methods", why should I throw a NotSupportedException (or whatever the case may be) when he/she tries to do something that, according to the interface, should be completely legal?

I feel like implementing an interface and explicitly defining some of its members is like opening a restaurant and putting some items on the menu -- perhaps in some obscure, easy-to-miss part of the menu, but on the menu nonetheless -- that are simply never available.

It seems there ought to be something like an IArray<T> interface that provides very basic random access by index, but no adding/removing, like the following:

public interface IArray<T> {
    int Length { get; }
    T this[int index] { get; }

And then IList<T> could implement ICollection<T> and IArray<T> and add its IndexOf, Insert and RemoveAt methods.

Of course, I could always just write this interface and use it myself, but that doesn't help with all the pre-existing .NET classes that don't implement it. (And yes, I know I could write a wrapper that takes any IList<T> and spits out an IArray<T>, but ... seriously?)

Does anyone have any insight into why the interfaces in System.Collections.Generic were designed this way? Am I missing something? Is there a compelling argument against what I'm saying about my issues with the approach of explicitly defining members of IList<T>?

I'm not trying to sound cocky, as if I know better than the people who designed the .NET classes and interfaces; it just doesn't make sense to me. But I'm ready to acknowledge there's plenty I probably haven't taken into consideration.

  • 3
    Good question. Since I do a lot of programming work in C++, I can immediately see the benefit this would have (cue random access iterator). – Konrad Rudolph Jan 21 '10 at 19:40
  • Can you link to the original post? – Amy Jan 21 '10 at 19:45
  • @yodaj007: This is the original post. I just added a lot to the beginning. – Dan Tao Jan 21 '10 at 19:47
  • I don't see "Jon Skeet's original answer". That's why I asked. – Amy Jan 21 '10 at 22:48
  • 2
    It's a notable update that something almost identical to your IArray<T> exists in .NET 4.5 as IReadOnlyList<T> (and readonly Collection and Dictionary interfaces). – Tim S. Sep 26 '13 at 14:55

Design questions are not always black and white.

One side is exact interfaces for each situation, which makes the whole process of actually implementing interfaces a real pain.

The other is few(er) multi-purpose interfaces which aren't always fully supported by the implementor but make many things easier, such as passing instances around which are similar but would not get the same interfaces assigned in the "exact interface" design.

So the BCL designers chose to go the second way. Sometimes I also wish that interfaces were a little less multi-purpose, especially for the collections and with the C#4 interface co-/contravariance features (which cannot be applied to most collection interfaces escept for IEnumerable<> because they contain both co- as well as contravariant parts).

Also, it's a shame that the base classes such as string and the primitive types do not support some interfaces such as ICharStream (for strings, which could be used for regex etc. to allow using other sources than string instances for pattern matching) or IArithmetic for numeric primitives, so that generic math would be possible. But I guess that all frameworks have some weak points.

  • Just going back through some past questions to make sure I've accepted answers that deserved to be accepted. This one was definitely thoughtful and provided some much-appreciated insight. – Dan Tao Mar 10 '10 at 3:57
  • If IList were defined as inheriting IIndexable, which in turn inherited IReadableByIndex, which in turn inherited IEnumerable, how would that add any grief to implementers? Simply type "Inherits IList" and all the necessary routines would be filled in, and would only have to be defined once each. – supercat Dec 17 '10 at 19:49
  • It would be confusing to need to know 100 different interfaces and the detailed differences between them; not to mention the fact that interface inheritance doesn't work quite as orthogonally as you might wish; e.g. adding a property setter in a sub-interface or inheriting the same method from two base interfaces. Google's Go has the better solution here; but that's water under the bridge for .NET. – Eamon Nerbonne Jan 6 '11 at 15:59
  • Having lots of interfaces wouldn't be a problem with the language system as it is, since if interface X derives from Y which contains function foo(), an implementation of X.foo will automatically be regarded as an implementation of Y.foo. Interfaces like IList<T> may have been designed before that was known, however. IMHO, at minimum the covariant, contravariant, and type-independent aspects of each interface, should be split out in likely combinations. The biggest tricky bit would be something like IList.Contains method, which should in some sense be type-independent: ... – supercat Jul 18 '11 at 23:12
  • If an IReadableList<Giraffe> is passed to some code that expects an IReadableList<Animal> and that code wants to know if it contains a particular Zebra, the IReadableList<Giraffe> shouldn't reject the request because it's not a Giraffe; it should simply answer "No". – supercat Jul 18 '11 at 23:14

Well, the interfaces aren't perfect but a dev can check the IsReadOnly property before calling Add/Remove/Set...

  • 1
    IsReadOnly is pretty much broken … because it doesn’t differentiate between the list itself and its elements (“does not allow … modification of elements”). Hence, most classes which do not allow Add/Remove still are not read-only in the sense of IsReadOnly. Yeah, this sucks. – Konrad Rudolph Jan 21 '10 at 19:38
  • 1
    IList (non generic) contains a IsFixedSize property. – Guillaume Jan 22 '10 at 10:13
  • yes but IList<T> doesn’t inherit from IList – you’d need to implement both. Sucks. – Konrad Rudolph Jan 25 '10 at 21:37
  • @KonradRudolph: If T is a reference type, an IList<T> serves to identify a number of T instances (as being the first, second, third, etc.) Since the IList<T> serves to identify, rather than contain, instances of T, none of the properties of those instances for any part of the IList<T>'s state; there's no "ambiguity" as to whether a "read-only" list of a mutable class type T restricts mutations to its members. It CAN'T, so it doesn't. The real problem is the lack of a property to say whether an IList<T> is immutable (immutable implies read-only, but not vice versa). – supercat Nov 19 '12 at 18:58
  • @supercat Not sure I understand this. If I remember correctly, what I said was that there are IList implementations which forbid Add and Remove, yet IsReadOnly returns false because they provide an element setter. This was based off of some other discussion here which I cannot now find. (Or maybe it was the other way round; the point is that implementations can distinguish, based on the existence of a setter for the this[] property, whether its elements are re-assignable or not; this is not adequately covered by the IsReadOnly property.) – Konrad Rudolph Nov 19 '12 at 19:02

The closest you can get is to return IEnumerable< T > and then the client (a.k.a. caller) can call .ToArray() themselves.

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