# List, array and IEnumerable covariance

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

List covariance is unsafe:

``````List<string> strings = new List<string> { "a", "b", "c" };
List<object> objects = strings;
``````

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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