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Assume I have interface and class:

public interface ITree {}
public class Tree : ITree {}

As IEnumerable<T> is covariant, the code line below is compiled successfully:

IEnumerable<ITree> trees = new List<Tree>();

But when I put it into generic method:

public void Do<T>() where T : ITree
     IEnumerable<ITree> trees = new List<T>();

I get compiled error from compiler:

Error 1 Cannot implicitly convert type 'System.Collections.Generic.List' to 'System.Collections.Generic.IEnumerable'. An explicit conversion exists (are you missing a cast?) D:\lab\Lab.General\Lab.General\Program.cs 83 40 Lab.General

Why covariance does not work in this case?

share|improve this question
possible duplicate of Is this a covariance bug in C# 4? – nawfal Jul 7 '14 at 7:01
up vote 18 down vote accepted

That is because variance only works with reference types (classes, interfaces & delegates). Add a class constraint and it compiles just fine:

public static void Do<T>() where T : class, ITree
share|improve this answer
Thank, I mislead that when doing constraint T : ITree it is implicit that T is reference type, but it actually is not – Cuong Le Oct 5 '12 at 11:19
If ITree is an interface type, a storage location of type ITree will always hold either null or a reference to a heap object that implements ITree, but a storage location of a generic type constrained to ITree may hold a reference or it may hold an actual instance of a value type which implements ITree. Personally, I dislike the way that structs which implement interfaces are implicitly converted to heap references which implement those interfaces without the structs having any say in the matter. Value-type semantics differ from rerefence semantics in USEFUL ways, but... – supercat Oct 19 '12 at 22:53
...the "unified type system" model assumes (wrongly) that they will behave identically. A variable of type List<string>.Enumerator implements IEnumerable<string>, but holds something whose behavior is very different from that of a variable of type IEnumerable<string> which holds a reference to a List<string>.Enumerator. – supercat Oct 19 '12 at 23:00
@supercat I guess you mean IEnumerator<string>, not IEnumerable. It is true that value types get boxed when you store them in a variable of interface type. The good thing about generics is that we don't get boxing there. So if you say Do<MyStruct>() where MyStruct is a struct implementing the interface, then you get a specific "version" of the method for MyStruct. So if inside the method it says T localT = default(T); then the code produces a value of MyStruct and makes no boxing which is cool. But with ITree localT = default(T); of course you get a boxed value. – Jeppe Stig Nielsen Nov 25 '12 at 13:55
@JeppeStigNielsen: You are correct. The problem is that a struct which implements a mutating interface will have struct semantics, but if cast to that interface it will become (and behave as) a reference type with a broken Equals method. While it's useful to have a concept of interfaces that can be implemented by value types, I'm not sure it's useful to say that a boxed structure implicitly implements the interfaces of the original; it might be more useful to allow structures to define casts to interfaces (where the cast would yield a new object which does implement the interface). – supercat Nov 25 '12 at 17:20

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