Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

From C# 4.0 Spec section 6.1.6:

The implicit reference conversions are:

[...]

From any reference-type to an interface or delegate type T if it has an implicit identity or reference conversion to an interface or delegate type T0 and T0 is varience-convertible (13.1.3.2) to T.

Vladimir Reshetnikov tells us that there is an implicit reference conversion from List<string> to IEnumerable<object>. But, how can I apply this to a user defined type (is it even possible)?

I tried an implicit operator, custom derived types and a few varitions there-of...but I cannot reproduce the scenerio. I have:

class Program
{
    static void Main(string[] args)
    {
        IEnumerable<object> specialClassConversion = new List<string>();
        IEnumerable<A> userdefinedTypeConversion = new List<B>();
        A implicitConversion = new B();//varience-convertible
        IC<A> explicitConversion = (IC<A>)new D<B>();//OK, varience-convertible
        IC<A> implicitConversion2 = new D<B>();//does not compile
    }
}

class A { }

class B : A { }

interface IC<T> { }    

class D<T> 
{
    //public static implicit operator IC(D<T> m)//Error: user-defined conversions to or from an interface are not allowed
    //{
    //    return null;
    //}
}
share|improve this question
    
"implicit conversion" in the excerpt you quote doesn't mean "an implicit conversion operator exists", it just means "a conversion that doesn't need an explicit cast" – millimoose Feb 8 '13 at 22:05
    
IC<A> explicitConversion = (IC<A>)new D<B>(); isn't okay either, the cast should fail at runtime. Not without the interface being declared as either interface IC<in T> or interface<out T>. (I don't remember exactly which is which and what that means for subtype relationships between generic instantiations.) If they were variance-convertible, the line after that would compile. – millimoose Feb 8 '13 at 22:07
2  
@millimoose Actually "an implicit conversion operator exists" is exactly what it means. Note that language provides an implicit conversion from a type to all of its base types as well as to any interfaces it implements, so it's not just user or language defined conversion operators. – Servy Feb 8 '13 at 22:10
    
@Servy Under operator I meant specifically the special methods C# lets you implement - I don't think of the language provided conversions as "operators". I guess I should have phrased that comment better. A better version would've been: "implicit conversion" doesn't only mean that you've defined an implicit conversion operator method, but any conversion that doesn't require an explicit cast (user-defined or language-defined.) – millimoose Feb 8 '13 at 22:16
    
Well, List<T> and IEnumerable<T> are both a user-defined types, so it must be possible somehow. – Eric Lippert Feb 8 '13 at 23:16
up vote 3 down vote accepted

If you want a user-defined class or struct to be implicitly convertible to an interface, let your class/struct implement that interface.

(Edit)

And if you want IC<B> to be implicitly convertible to IC<A>, make the IC<T> interface covariant in T by specifying the out keyword, interface IC<out T> { }. The quote from the spec you gave tells that the "composition" of these two implicit conversion is also an implicit conversion.

Source:

interface IC<out T> {  }

class D<T> : IC<T>  { }

(End edit)

Regarding the List<string> class, it implements IEnumerable<string> which in turn is convertible (implicitly) to IEnumerable<object> because IEnumerable<out T> is covariant (out) in T.

(One reason why they didn't allow you to make a public static implicit operator which converts to/from the interface, is that somone could write a derived class which inherited from your class and implemented the interface. That would give a "natural" conversion between their class and the interface, but the public static implicit operator would also apply, leading to two conversions (one "natural" and one "user-defined") between the types, which would be confusing and ambiguous.)

share|improve this answer
    
Can you demostrate how this works with the code in the OP? I tried implementing the interface and ran into various other implementation problems...one is noted in the comments in the OP. – P.Brian.Mackey Feb 8 '13 at 22:14
    
@P.Brian.Mackey If you mean to make your interface covariant like IEnumerable<>, write interface IC<out T> { } (note the out). Be sure to have D implement the interface: class D<T> : IC<T> { } The "variance-convertible" stuff of the quote from the spec, is about covariance and contravariance, and in your code sample, use covariance. – Jeppe Stig Nielsen Feb 8 '13 at 22:24
2  
The only way to make a conversion that involves an interface type is to make a conversion in class C<T> from C<T> to T, and then construct C<IFoo>. The code to deal with that situation in the compiler get my vote for the most arcane and difficult code in the compiler, and the specification is very difficult to read. Getting Roslyn to match some semblance of both the specification and the previous compiler was one of the toughest challenges in the Roslyn semantic analysis effort. – Eric Lippert Feb 8 '13 at 23:19
    
@EricLippert I tried it out with the Visual C# 5.0 compiler. It looks like in that case the conversion to IFoo is never considered. In the "Related" column on the right I found this question about it: C# compiler bug? Why doesn't this implicit user-defined conversion compile? – Jeppe Stig Nielsen Feb 9 '13 at 16:14
    
@EricLippert 's post helped me understand a subtle covarient issue that I missed in this case: blogs.msdn.com/b/ericlippert/archive/2009/11/30/… – P.Brian.Mackey Feb 9 '13 at 16:48

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.