I wonder why IEnumerable<int> can't be assigned to a IEnumerable<object>. After all IEnumerable is one of the few interfaces that supports covariance...

  • The subtype relation and covariance stuff works with reference types
  • int seems to be a proper subtype of object

The combination of both features doesn't work however...

class A

class B : A

class Program
    static void Main(string[] args)
        bool b;
        b = typeof(IEnumerable<A>).IsAssignableFrom(typeof(List<B>));
        Console.WriteLine("ienumerable of ref types is covariant: " + b); //true

        b = typeof(IEnumerable<object>).IsAssignableFrom(typeof(List<int>));
        Console.WriteLine("ienumerable of value tpyes is covariant: " + b); //false

        b = typeof(object).IsAssignableFrom(typeof(int));
        Console.WriteLine("int is a subtype of object: " + b); //true

thanks for your help! sebastian

up vote 8 down vote accepted

Value types aren't LSP-subtypes of object until they're boxed.

Variance doesn't work with value types. At all.

Demonstration that int is not a proper subtype (subtype in the LSP sense) of object:


object x = new object();
lock (x) { ... }

Does not work (substitutability violated):

int y = new int();
lock (y) { ... }

Returns true:

object x = new object();
object a = x;
object b = x;
return ReferenceEquals(a, b);

Returns false (substitutability violated):

int y = new int();
object a = y;
object b = y;
return ReferenceEquals(a, b);

Of course, the topic of the question (interface variance) is a third demonstration.

  • 1
    I wouldn't go as far as your first sentence. How is int not a subtype of object? It overrides the virtual methods GetHashCode and ToString and inherits GetType... and can be passed to any method that accepts an object parameter... – Dan Tao Mar 24 '11 at 1:51
  • 1
    @Chris: MSDN doesn't show System.Object as a base type even of types that inherit from it directly, so that doesn't prove much. – Ben Voigt Mar 24 '11 at 2:06
  • 1
    @Ben: I don't dispute your description of the underlying mechanisms, but there's no getting away from the fact that an int, boxed or unboxed, derives from object. That's the whole point of having a "unified type system", isn't it? – LukeH Mar 24 '11 at 2:41
  • 2
    @Ben Voigt: Where are you getting this notion that "In order to access certain members of X, type Y must be boxed" somehow means "Y is therefore not a subtype of X"? Also, what fields of object? There are none. – Dan Tao Mar 24 '11 at 2:44
  • 2
    @Ben, @LukeH: I must say, I think we are all (Ben and I especially) just talking past each other. No one is saying anything the others didn't already know. We're just operating on different definitions of what it means to be a subtype. Personally, I favor Luke's and my position because it agrees with the definition utilized by the spec. Ben is basically disagreeing with the spec based on a different way of defining the term. So, Ben, I dislike your definition; but at least I understand what you're saying (and I think you understand what I'm saying). – Dan Tao Mar 24 '11 at 3:12

The problem is that object is a reference type, not a value type. The only reason you can assign an int to a variable of type object is boxing.

In order to assign List<int> to IEnumerable<object> you'd have to box each element of the list. You can't do that just by assigning the reference to the list and calling it a different type.

  • thanks for that easy explanation. so we have object and int variables that can have the runtime type int32. however i think there is some design flaw in c#, when implicit boxing is done in one case and not in the other... one time int behaves like a subtype, next time it doesn't. so it is no subtype. thanks... – Sebastian Gregor Mar 24 '11 at 15:23
  • @SebastianGregor: The simplest way to think of things is to recognize that System.Int32 describes a heap object type which derives from ValueType which in turn derives from Object, and also describes a storage location type which is implicitly convertible to the heap-object type, and explicitly convertible from it. – supercat Dec 19 '12 at 3:05

The simplistic answer is that this is just one of the quirks in the way that variance is implemented in C# and the CLR.

From "Covariance and Contravariance in Generics":

Variance applies only to reference types; if you specify a value type for a variant type parameter, that type parameter is invariant for the resulting constructed type.

  • Would you happen to know why? – Jordão Sep 8 '12 at 15:11

Every value type in .net has a corresponding ("boxed") object type. Non-boxed value types are effectively outside the object type hierarchy, but the compiler will perform a widening from the value type to the boxed class type. It would be helpful to have a "class" Boxed<T> which would support a widening conversions to and from T, but which would be a class type. Internally, I think that's what the compiler's doing implicitly, but I don't know any way to do it explicitly. For any particular type like "integer", there would be no difficulty defining a class which would behave as a Boxed<Integer> should, but I don't know any way of doing such a thing in generic fashion.

  • yes. i also think that such a type would help a lot. int i = 4; object x = i; Console.WriteLine(x.GetType()); should then return Boxed<int>... – Sebastian Gregor Mar 24 '11 at 15:15
  • @Sebastian Gregor: I'm not sure the best semantics for GetType, but there have been some occasions when I've found myself creating a class holding a single value type when it would have been more convenient to have a Boxed type that could have been used implicitly as the value type. For one's own types, it's sometimes useful to declare ISelf<T> with a read-only Self property that returns T. Note that if T is a value type, an ISelf<T> will be a boxed version. A function with a generic parameter that's constrained to ISelf<Foo> will accept... – supercat Mar 24 '11 at 17:45
  • ...either a boxed or unboxed Foo as a parameter. Curiously, it's possible to access explicit interface members of a struct without boxing or other heap allocations, but I can't figure any really clean way. – supercat Mar 24 '11 at 19:00

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