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So I have the following simple wrapper class:

interface IReference<out T> where T : myAbstractBase {
    T Value { get; }
}
public class Reference<T> : IReference<T> where T : myAbstractBase
{
    private T _value = null;
    public T Value {  get { return _value; } }
}

Throughout my application, I want to have collections of these IReference<someClass> objects (where someClass implements myAbstractBase)

private List<Reference<shapes>> shapeList = new Collection<Reference<shapes>>();

But I want to be able to add all kinds of different shapes to this collection. (Especially since shape is also abstract). Of course, this yields an error:

shapeList.Add( new Reference<circle>(){ radius = 2; } );

The value "Reference[circle]" is not of type "Reference[shape]" and cannot be used in this generic collection.

Is there any way I can design my Reference<T> class such that so long as A is of type B, Reference<A> will be considered of type Reference<B>?

Seems to me like people would run into the same sort of problem trying to use lists of Nullable, etc.

I've tried implementing implicit operators for converting between Reference and T, but I haven't thought of any practical use for them...

public class Reference<T> ... {
    ...

    public static implicit operator Reference<T>(T value)
    {
        return new Reference<T> { _value = value, };
    }
    public static implicit operator T(Reference<T> value)
    {
        return value.Value;
    }
}

To anyone curious about my intentions, this is all part of an (ill-fated) attempt to implement lazy loading for a set of classes without having to without having to add anything more to those classes.

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You would have to use <in T>, and that wouldn't work for your interface. –  It'sNotALie. May 28 '13 at 23:13
    
@newStackExchangeInstance You know, I'm not sure why that interface is that way. It came from this question earlier today: stackoverflow.com/questions/16795750/…, but the interface seems to do it's job even with T defined as invariant. –  Alain May 28 '13 at 23:25
    
Wikipedia (en.wikipedia.org/wiki/…) says the the IList<T> type constructor is invariant so no two lists are a subtype of the other. Does this mean this is a lost cause with lists? –  Alain May 28 '13 at 23:27
    
Does using a list of IReferences instead of References work for you: List<IReference<Shape>> shapeList = new List<IReference<Shape>>(); –  Steven Wexler May 28 '13 at 23:36
    
@steaks, That doesn't work because unlike my Reference<T> implicit converters, I can't define implicit converters for the Interface class, so I wouldn't be able to go List<IReference<circle>> circleList.Add( new circle() ) like I can now (because it automatically converts circle to Reference<Circle>) –  Alain May 28 '13 at 23:53

4 Answers 4

Your problem is that you can't chain user defined implicit casts. At first glance it seems like you should be able go from Reference<Circle> -> Reference<Shape> via Reference<Circle> -> Circle -> Shape -> Reference<Shape>. However, you'd be using two user defined implicit casts. First you'd go from Reference<Circle> -> Circle via operator T(Reference<T> value). Then you'd go from Shape -> Reference<Shape> via operator Reference<T>(T value). You can get around this by creating an overload of the Add method by extending List. This will free you to use one of the user defined cast operators explicitly in Reference.Add. Now, you won't have to chain user defined implicit cast operators.

See the spec on user defined implicit casts: http://msdn.microsoft.com/en-us/library/aa691302(v=vs.71).aspx

//You can get around your inability to chain user defined implicit casts
//by creating a ReferenceList<T> that extends List<IReference<T>>
//and overloads the List.Add method
public class ReferenceList<T> : List<IReference<T>> where T : MyAbstractBase
{
    //With this overload you can accept a T.  Then explicity cast to Reference<T>
    //by using operator Reference<T>(T value)
    public void Add(T item)
    {
        base.Add((Reference<T>)item);
    }
}
List<Reference<Shape>> shapeList = new List<Reference<Shape>>();
ReferenceList<Shape> shapeList2 = new ReferenceList<Shape>();
List<IReference<Shape>> shapeList3 = new List<IReference<Shape>>();

//Interesting cases that should work with the OP

//Works for obvious reasons
shapeList.Add(new Reference<Shape>());
//Works because you're using one user defined implicit cast 
//where the cast is operator Reference<T>(T value).
//Shape -> Reference<Shape>
shapeList.Add(new Shape());
//Works because you're using one non user defined implicit cast and one user defined 
//implicit cast where the user defined implicit cast is operator Reference<T>(T value)
//Circle -> Shape -> Wrapper<Shape>
shapeList.Add(new Circle());
//Does not work because you need to chain two user defined implicit casts
//where the implicit casts are operator T(Reference<T> value) and operator Reference<T>(T value)
//Reference<Circle> -> Circle -> Shape -> Reference<Shape>
//Theoretically this could work, but the C# specs state that chaining user defined
//implicit casts is not allowed in C# (See link below)
shapeList.Add(new Reference<Circle>());
//This case works for similiar reasons that shapeList.Add(new Circle()).  It uses
//only one user defined implicit cast because you're calling operator T(Reference<T> value)
//explicitely  
shapeList.Add(new (Circle)Reference<Circle>());

//Interesting cases for ReferenceList

//Works because this calls List.Add which accepts a Reference<T>
shapeList2.Add(new Reference<Shape>());
//Works because this calls ReferenceList.Add wich accepts a T
shapeList2.Add(new Circle());
//Works because this calls ReferenceList.Add wich accepts a T.
//and Reference<Circle> can be implicitly cast to a Circle via
//operator T(Reference<T> value).
//Reference<Circle> -> Circle -> Shape -> Reference<Shape> where
//the last cast is done explicitely in the ReferenceList.Add method
//via operator Reference<T>(T value)
shapeList2.Add(new Reference<Circle>());

//Interesting cases for List<IReference<Shape>>


//Works for obvious reasons
shapeList3.Add(new Reference<Shape>());
//Works because IReference is covariant.  In C# interfaces can be
//covariant.  Classes cannot be covariant.
shapeList3.Add(new Reference<Circle>());
//Does not work because C# does not support user defined implicit
//casts to interface.  In other words, you implicitly cast Shape -> Reference<Shape>
shapeList3.Add(new Shape());
//Doesn't work for similiar reasons to why shapeList3.Add(new Shape()) doesn't work
shapeList3.Add(new Circle());
share|improve this answer

Okay, here's a shot in the dark that should at least make your implicit operator compile. I don't have anything setup that I can test it with right off hand. Still, it should work. Add this to the Reference class.

public static implicit operator Reference<myAbstractBase>(Reference<T> i)
{
    return i;
}

Note there's a lack of type checking going on here, so if T isn't derived from myAbstractBase you could be hosed.

share|improve this answer
    
I tried to define implicit converters from Reference<T> to Reference<myAbstractBase>, Reference<T> to Reference<shape>, Reference<T> to Reference<circle>, but when trying to put a Reference<circle> into a List<Reference<shape>> it still complains about not being able to convert Reference<circle> to Reference<shape> :/ –  Alain May 29 '13 at 0:11
    
What happens when you make the converters explicit and/or add them to a list with an explicit conversion? –  Jacob Proffitt May 29 '13 at 5:26

I've started down the path of defining a custom collection that is exactly a List<Reference<T>> inside, but it seems to be doing the trick:

public class ReferenceCollection<T> : ICollection<T> where T : myAbstractBase 
{
    private List<Reference<T>> collection = new List<Reference<T>>();

    public IEnumerable<T> toIEnumerable()
    {
        return (IEnumerable<T>) collection.Select(r => r.Value);
    }

    public IEnumerator<T> GetEnumerator()
    {
        return toIEnumerable().GetEnumerator(); ;
    }

    #region ICollection<T> Members
    public void Add(T item)
    {
        collection.Add(item);
    }
    ...
}

Now I can make the folling call (which I couldn't do before):

ReferenceCollection<shape> test = new ReferenceCollection<shape>();
test.Add(new circle());

Why is it working this way but not the other? Am I really doing anything all that different? Perhaps the conversion is actually now happening in the opposite order (circle gets cast to shape, and then shape gets implicitly converted to Resource<shape> as it's added to the internal collection.)

I can't see any downfalls to this method yet. I could even define implicit converters to turn a ReferenceCollection<T> directly into a List<T> or List<Reference<T>> without so much as iterating over it. Still, I wonder if there's a way to define the original class such that the cast is similarly happening before the implicit conversion to avoid the un-castable wrapped type.

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You posted that shapeList.Add( new Reference<circle>(){ radius = 2; } ) didn't work in your original problem. Are you sure that shapeList.Add( new circle(){ radius = 2; } ) didn't work? –  Steven Wexler May 29 '13 at 0:51
    
@steaks Yes it fails because shapeList is a List<IReference<Shape>>(), not a List<Shape>(). It was first converting the added circle instanec to an IReference<Circle> and then understandably failing to convert that into an IReference<Shape>. –  Alain May 29 '13 at 1:24
    
This ended up being no good - I can no longer deserialize Reference<circle> objects into the class because the enumerator now exposes it as a collection of shape objects. circle can be cast to shape and shape can be cast to Reference<shape> but Reference<circle> cannot be cast to Reference<shape> so the deserializer crashes. Same problem, just reversed now. –  Alain May 29 '13 at 2:53
up vote 0 down vote accepted

I rephrased the question and got an answer in another thread: How to cast a Generic<T> to a Generic<R> where T is a subclass of R?

The trick was to create a covariant interface IReference<out T> and always use the interface wherever the type is used. So declaring List<IReference<myAbstractBase>> rather than List<Reference<myAbstractBase>>. Details as to why this works at Covariance and Contravariance in Generics

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