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I'm implementing a fluent builder pattern that requires accepting enumerables in a static extension method and iterating through its contents, while applying a functor to the enumerable's contents. As in (not the actual code, just an illustration):

public static IValidator<IEnumerable<T>> Each<T>(
    this IValidator<IEnumerable<T>> enumerable, 
    Func<T, bool> action)
{
    foreach (T value in enumerable)
        action(value);

    return validator;
}

This works pretty well for enumerables but fails for inherited types/interfaces. Let's say:

IValidator<IEnumerable<Guid>> validator = ...;

IEnumerable<Guid> guids = ...;
validator.Each(guids, guid => guid != Guid.Empty);   // ok

IList<Guid> guids = ...;
validator.Each(guids, guid => guid != Guid.Empty);   // doesn't compile (see below)

The exception is:

IValidator<IList<Guid>> does not contain a definition for 'Each' and no extension method 'Each' accepting a first argument of type IValidator<IList<Guid>> could be found (are you missing a using directive or an assembly reference?

My question is about the inheritance chain of IValidator<T> and, more specifically, its generic type arguments T. Why is type IValidator<IEnumerable<T>> not assignable from IValidator<IList<T>>? There's no circumstance I can think of on which IList<T> is not an IEnumerable<T> (given the same T).

Constraining the generic argument to T : IEnumerable<R> does work but that requires two type arguments (T and R) which I'd like to avoid, if possible.

Any thoughts? Better solutions? Thanks.

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3  
I think this could be a covariance and contravariance issue. Let me see if I can get some sample code to see if this the case. –  Jason Evans Aug 31 '12 at 13:39
1  
Even if you solve your current problem, what's the point of the method? You aren't using the boolean result of the functor passed in, so unless the functor mutates the object the net result is nothing changes, and if it does mutate it then...well...it shouldn't, as Linq is designed for queries, not mutation, of sequences. –  Servy Aug 31 '12 at 13:41
    
@Servy - that's just a sample to illustrate my intentions, not the actual code. I left it as Func<T, bool> because it requires less code than Action<T> to write the calling lambdas in the example that follows. I was being a little lazy. :-) –  lsoliveira Aug 31 '12 at 13:48
    
IEnumerable (with .Net 4+) is covariant but IList is not because the later takes both input and output parameters. –  Jim Wooley Aug 31 '12 at 13:50
1  
OK, I haven't got time to write some code. My suggestion is when you're using IValidator<T> try IValidator<out T> or IValidator<in T>, I forget which one. You could also just use var guids = validator.Each..... which could help, though it won't remove your design issue. –  Jason Evans Aug 31 '12 at 13:53
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2 Answers

up vote 5 down vote accepted

This is due to the definition of your IValidator<T> interface. I'm betting it's something along the lines of:

public interface IValidator<T>

What you really want is:

public interface IValidator<out T>

This will make your interface covariant, meaning that you can assign an implementation of IValidator<T2> to IValidator<T>, assuming that T2 derives from T.

In this case, IList<T> derives from IEnumerable<T>, so you should be able to declare T as covariant. However, this depends on the methods on IValidator<T> and how they are exposed.

Namely, if you have methods on IValidator<T> that take instances of T in as a parameter to any methods on the interface, then you won't be able to declare the interface as covariant.

If this is the case, then you should be able to get away with this definition of Each:

public static IValidator<T> Each<T, TValue>(
    this IValidator<T> enumerable, 
    Func<TValue, bool> action) where T : IEnumerable<TValue>
{
    foreach (TValue value in enumerable)
        action(value);

    return validator;
}

This will indicate that T should derive from IEnumerable<TValue>.

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After @JasonEvans comment above I remembered I had completely forgotten about co/contravariance. You're right on the mark. Making the interface covariant solved the issue. Thanks for the input. –  lsoliveira Aug 31 '12 at 14:08
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Two answers:

  1. It is perfectly legal to say where T: IEnumerable<T> which may solve your problem and doesn't require a second generic type.

  2. IValidator<IEnumerable<T>> is not assignable from IValidator<IList<T>> because your interface is not variant. As of v4, C# does support interface variance, but you have to ask for it explicitly in your interface definition. To do so, see the out Generic Modifier

Covariance is what allows you to substitute a more-derived type for a generic parameter that expects a less-derived type when doing assignments, etc.

Note that it's up to you to make sure your interface really is variant-safe. This is why it wasn't possible before C# 4, because it's not always true that it works; some interfaces are safely covariant, some are safely contravariant (you can only substitute less derived types for the expected type). It all depends on what you're doing.

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