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While we can inherit from base class/interface, why can't we declare a List<> using same class/interface?

interface A
{ }

class B : A
{ }

class C : B
{ }

class Test
{
    static void Main(string[] args)
    {
        A a = new C(); // OK
        List<A> listOfA = new List<C>(); // compiler Error
    }
}

Is there a way around?

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up vote 105 down vote accepted

The way to make this work is to iterate over the list and cast the elements. This can be done using ConvertAll:

List<A> listOfA = new List<C>().ConvertAll(x => (A)x);

You could also use Linq:

List<A> listOfA = new List<C>().Cast<A>().ToList();
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1  
another option: List<A> listOfA = listOfC.ConvertAll(x => (A)x); – ahaliav fox Jul 16 '14 at 7:56
3  
Which one is faster? ConvertAll or Cast? – modiX Sep 3 '14 at 10:21
    
This will create a copy of the list. If you add or remove something in the new list, this won't be reflected in the original list. And secondly, there is a big performance and memory penalty since it creates a new list with the existing objects. See my answer below for a solution without these problems. – Bigjim Jun 5 '15 at 9:07

First of all, stop using impossible-to-understand class names like A, B, C. Use Animal, Mammal, Giraffe, or Food, Fruit, Orange or something where the relationships are clear.

Your question then is "why can I not assign a list of giraffes to a variable of type list of animal, since I can assign a giraffe to a variable of type animal?"

The answer is: suppose you could. What could then go wrong?

Well, you can add a Tiger to a list of animals. Suppose we allow you to put a list of giraffes in a variable that holds a list of animals. Then you try to add a tiger to that list. What happens? Do you want the list of giraffes to contain a tiger? Do you want a crash? or do you want the compiler to protect you from the crash by making the assignment illegal in the first place?

We choose the latter.

This kind of conversion is called a "covariant" conversion. In C# 4 we will allow you to make covariant conversions on interfaces and delegates when the conversion is known to be always safe. See my blog articles on covariance and contravariance for details. (There will be a fresh one on this topic on both Monday and Thursday of this week.)

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1  
Thanks mate for correction and suggestions, will take care next time. – Asad Butt Nov 30 '09 at 1:04
    
Thanks for the simple and clear explanation. – DeeStackOverflow Jul 1 '11 at 14:51
3  
Would there be anything unsafe about an IList<T> or ICollection<T> implementing non-generic IList, but implementing having the non-generic Ilist/ICollection return True for IsReadOnly, and throw NotSupportedException for any methods or properties that would modify it? – supercat Jul 28 '11 at 15:40
    
Whilst this answer contains quite acceptable reasoning it is not really "true". The simple answer is that C# doesn't support this. The idea of having a list of animals that contains giraffes and tigers is perfectly valid. The only issue comes when you want to access the higher level classes. In reality this is no different to passing a parent class as a parameter to a function and then trying to cast it to a different sibling class. There may be technical issues with implementing the cast but the explanation above does not provide any reason why it would be a bad idea. – Paul Coldrey Jan 29 at 5:55

As far as why it doesn't work, it might be helpful to understand covariance and contravariance.

Just to show why this shouldn't work, here is a change to the code you provided:

void DoesThisWork()
{
     List<C> DerivedList = new List<C>();
     List<A> BaseList = DerivedList;
     BaseList.Add(new B());

     C FirstItem = DerivedList.First();
}

Should this work? The First item in the list is of Type "B", but the type of the DerivedList item is C.

Now, assume that we really just want to make a generic function that operates on a list of some type which implements A, but we don't care what type that is:

void ThisWorks<T>(List<T> GenericList) where T:A
{

}

void Test()
{
     ThisWorks(new List<B>());
     ThisWorks(new List<C>());
}
share|improve this answer
    
"Should this work?" - I would yes and no. I see no reason why you shouldn't be able to write the code and have it fail at compile time since it is actually doing an invalid conversion at the time you access FirstItem as type 'C'. There are many analogous ways to blow up C# that are supported. IF you actually want to achieve this functionality for a good reason (and there are many) then bigjim's answer below is awesome. – Paul Coldrey Jan 29 at 6:19

If you use IEnumerable instead, it will work (at least in C# 4.0, I have not tried previous versions). This is just a cast, of course, it will still be a list.

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How to use the IEnumerable in that case exactly? – Vladius Dec 14 '15 at 12:12
    
Instead of List<A> listOfA = new List<C>(); // compiler Error in the original code of the question, enter IEnumerable<A> listOfA = new List<C>(); // compiler error - no more! :) – PhistucK Dec 14 '15 at 16:39
    
The method taking the IEnumerable<BaseClass> as a parameter will allow for the inherited class to be passed in as a List. So there's very little to do but change the parameter type. – beauXjames Dec 15 '15 at 17:00

To quote the great explanation of Eric

What happens? Do you want the list of giraffes to contain a tiger? Do you want a crash? or do you want the compiler to protect you from the crash by making the assignment illegal in the first place? We choose the latter.

But what if you want to choose for a runtime crash instead of a compile error? You would normally use Cast<> or ConvertAll<> but then you will have 2 problems: It will create a copy of the list. If you add or remove something in the new list, this won't be reflected in the original list. And secondly, there is a big performance and memory penalty since it creates a new list with the existing objects.

I had the same problem and therefore I created a wrapper class that can cast a generic list without creating an entirely new list.

In the original question you could then use:

class Test
{
    static void Main(string[] args)
    {
        A a = new C(); // OK
        IList<A> listOfA = new List<C>().CastList<C,A>(); // now ok!
    }
}

and here the wrapper class (+ an extention method CastList for easy use)

public class CastedList<TTo, TFrom> : IList<TTo>
{
    public IList<TFrom> BaseList;

    public CastedList(IList<TFrom> baseList)
    {
        BaseList = baseList;
    }

    // IEnumerable
    IEnumerator IEnumerable.GetEnumerator() { return BaseList.GetEnumerator(); }

    // IEnumerable<>
    public IEnumerator<TTo> GetEnumerator() { return new CastedEnumerator<TTo, TFrom>(BaseList.GetEnumerator()); }

    // ICollection
    public int Count { get { return BaseList.Count; } }
    public bool IsReadOnly { get { return BaseList.IsReadOnly; } }
    public void Add(TTo item) { BaseList.Add((TFrom)(object)item); }
    public void Clear() { BaseList.Clear(); }
    public bool Contains(TTo item) { return BaseList.Contains((TFrom)(object)item); }
    public void CopyTo(TTo[] array, int arrayIndex) { BaseList.CopyTo((TFrom[])(object)array, arrayIndex); }
    public bool Remove(TTo item) { return BaseList.Remove((TFrom)(object)item); }

    // IList
    public TTo this[int index]
    {
        get { return (TTo)(object)BaseList[index]; }
        set { BaseList[index] = (TFrom)(object)value; }
    }

    public int IndexOf(TTo item) { return BaseList.IndexOf((TFrom)(object)item); }
    public void Insert(int index, TTo item) { BaseList.Insert(index, (TFrom)(object)item); }
    public void RemoveAt(int index) { BaseList.RemoveAt(index); }
}

public class CastedEnumerator<TTo, TFrom> : IEnumerator<TTo>
{
    public IEnumerator<TFrom> BaseEnumerator;

    public CastedEnumerator(IEnumerator<TFrom> baseEnumerator)
    {
        BaseEnumerator = baseEnumerator;
    }

    // IDisposable
    public void Dispose() { BaseEnumerator.Dispose(); }

    // IEnumerator
    object IEnumerator.Current { get { return BaseEnumerator.Current; } }
    public bool MoveNext() { return BaseEnumerator.MoveNext(); }
    public void Reset() { BaseEnumerator.Reset(); }

    // IEnumerator<>
    public TTo Current { get { return (TTo)(object)BaseEnumerator.Current; } }
}

public static class ListExtensions
{
    public static IList<TTo> CastList<TFrom, TTo>(this IList<TFrom> list)
    {
        return new CastedList<TTo, TFrom>(list);
    }
}
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Now this is a BRILLIANT answer - I cannot understand which this doesn't have all the votes! – Paul Coldrey Jan 29 at 6:12

Because C# doesn't allow that type of inheritance conversion at the moment.

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6  
First, this is a question of convertibility, not of inheritance. Second, covariance of generic types will not work on class types, only on interface and delegate types. – Eric Lippert Nov 30 '09 at 0:40
5  
Well, I can hardly argue with you. – Noon Silk Nov 30 '09 at 0:51

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