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I'll start with several postulates to better explain the context of my question:

Array Covariance

Postulate 1.1

An array of a value type is not covariant. int[] cannot pass for object[].

Postulate 1.2

An array of a reference type is covariant with a valid IEnumerable. string[] can pass for IEnumerable<object>).

Postulate 1.3

An array of a reference type is covariant with a valid covariant array. string[] can pass for object[].

List Covariance

Postulate 2.1 (same as 1.1)

A list of a value type is not covariant. List<int> cannot pass for List<object>.

Postulate 2.2 (same as 1.2)

A list of a reference type is covariant with a valid IEnumerable. List<string> can pass for IEnumerable<object>).

Postulate 2.3 (different from 1.3)

A list of a reference type is not covariant with a valid covariant List. List<string> cannot pass for List<object>).

My question concerns postulates 1.3, 2.2 and 2.3. Specifically:

  1. Why can string[] pass for object[], but List<string> not for List<object>?
  2. Why can List<string> pass for IEnumerable<object> but not for List<object>?
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Because a list is mutable and an array or IEnumerable<T> not. Only immutable collection classes should be covariant. – Tim Schmelter Jun 12 '13 at 9:25
@TimSchmelter: While true, that argument applies to postulate 1.3 as well and as such doesn't explain why 1.3 is valid. ReSharper correctly warns in scenarios of 1.3 – Daniel Hilgarth Jun 12 '13 at 9:30

2 Answers 2

up vote 13 down vote accepted

List covariance is unsafe:

List<string> strings = new List<string> { "a", "b", "c" };
List<object> objects = strings;
objects.Add(1);              //

Array covariance is also unsafe for the same reason:

string[] strings = new[] { "a", "b", "c" };
object[] objects = strings;
objects[0] = 1;              //throws ArrayTypeMismatchException

array covariance in C# is recognised as a mistake, and has been present since version 1.

Since the collection cannot be modified through the IEnumerable<T> interface, it is safe to type a List<string> as an IEnumerable<object>.

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Yes, it's most irksome that they allowed array covariance. They should not have. – Matthew Watson Jun 12 '13 at 9:32
@MatthewWatson: Array covariance and contravariance could have been a good thing if the system included a types for "readable array reference" (covariant), "writable array reference" (contravariant), "item-swappable array reference" (type-independent), and "sortable array reference" (covariant combination of readable and item-swappable). A general-purpose Sort routine could accept the latter type. The lack of such specific types, however, does not eliminate the fact that a general-purpose sort routine needs a covariant sortable type. Thus, System.Array was made covariant and sortable. – supercat Jun 12 '13 at 17:15
@supercat Well the language designers do say "this particular kind of covariance is broken" - did you look at the link Lee posted? – Matthew Watson Jun 12 '13 at 17:16
@MatthewWatson: Writing an efficient general-purpose array-sort routine requires that the framework either support array covariance or generic types. The designers of .NET had a choice between (1) having a framework where it was impossible to write an efficient general-purpose sort routine in user code, (2) not releasing a framework until generic support was complete, (3) including a variety of array-reference types, or (4) allowing array covariance as a kludge to make it possible for user code to write efficient general-purpose sorting routines. – supercat Jun 12 '13 at 17:39
@supercat Or, in this case, it might be from reading a blog by one of the people who worked on the language design. :) – Matthew Watson Jun 12 '13 at 18:47

Arrays are covariant, but a System.Int32[] does not hold references to things which are derived from System.Object. Within the .NET runtime, each value-type definition actually defines two kinds of things: a heap object type and a value (storage location) type. The heap object type is derived from System.Object; the storage location type is implicitly convertible to the heap object type (which in turn derives from System.Object) but does not itself actually derive from System.Object nor anything else. Although all arrays, including System.Int32[] are heap-object types, the individual elements of a System.Int32[] are instances of the storage location type.

The reason that a String[] can be passed to code expecting an Object[] is that the former contains "references to heap-object instances of type derived from type String", and the latter likewise for type Object. Since String derives from Object, a reference to a heap-object of a type derived from String will also be a reference to a heap object which derives from Object, and a String[] will contain references to heap objects which derive from Object--exactly what code would expect to read from an Object[]. By contrast, because an int[] [i.e. System.Int32[]] does not contain references to heap-object instances of type Int32, its contents will not conform to the expectations of code which is expecting Object[].

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