34

I'm trying to pass A list of DerivedClass to a function that takes a list of BaseClass, but I get the error:

cannot convert from 
'System.Collections.Generic.List<ConsoleApplication1.DerivedClass>' 
to 
'System.Collections.Generic.List<ConsoleApplication1.BaseClass>'

Now I could cast my List<DerivedClass> to a List<BaseClass>, but I don't feel comfortable doing that unless I understand why the compiler doesn't allow this.

Explanations that I have found have simply said that it violates type safety somehow, but I'm not seeing it. Can anyone help me out?

What is the risk of the compiler allowing conversion from List<DerivedClass> to List<BaseClass>?


Here's my SSCCE:

class Program
{
    public static void Main()
    {
        BaseClass bc = new DerivedClass(); // works fine
        List<BaseClass> bcl = new List<DerivedClass>(); // this line has an error

        doSomething(new List<DerivedClass>()); // this line has an error
    }

    public void doSomething(List<BaseClass> bc)
    {
        // do something with bc
    }
}

class BaseClass
{
}

class DerivedClass : BaseClass
{
}
  • The class derives from its base but not the List<Derived> derives from List<Base>. – Tim Schmelter Jun 6 '13 at 16:10
  • @TimSchmelter Does that mean that this sort of inheritance could potentially be made a feature where Generic<Derived> can be considered to derive from Generic<Base>? or would such a feature cause problems? – Sam I am says Reinstate Monica Jun 6 '13 at 16:11
  • 1
    It's just not implemented that way. marcgravell.blogspot.fr/2009/02/… – Tim Schmelter Jun 6 '13 at 16:13
  • @TimSchmelter: No; it's just impossible that way. – SLaks Jun 6 '13 at 16:17
  • 1
    @SamIam: You should just instantiate it as a List<Base> to begin with. – voithos Jun 6 '13 at 16:30
50

It is because List<T> is in-variant, not co-variant, so you should change to IEnumerable<T> which supports co-variant, it should work:

IEnumerable<BaseClass> bcl = new List<DerivedClass>();
public void doSomething(IEnumerable<BaseClass> bc)
{
    // do something with bc
}

Information about co-variant in generic

  • Starting from .Net 4.5, there is also IReadOnlyList<T> that can be used if the method needs random access to the collection element. – tia Jun 6 '13 at 16:21
45

Explanations that I have found have simply said that it violates type safety somehow, but I'm not seeing it. What is the risk of the compiler allowing conversion from List<DerivedClass> to List<BaseClass>?

This question is asked almost every day.

A List<Mammal> cannot be converted to a List<Animal> because you can put a lizard into a list of animals. A List<Mammal> cannot be converted to a List<Giraffe> because there might be a tiger in the list already.

Therefore List<T> has to be invariant in T.

However, List<Mammal> can be converted to IEnumerable<Animal> (as of C# 4.0) because there is no method on IEnumerable<Animal> that adds a lizard. IEnumerable<T> is covariant in T.

  • 5
    +1 A simple zoological explanation that explains it all. (there is no method on IEnumerable<Animal> that adds a lizard --> I'll check just in case ;)) – vc 74 Jun 6 '13 at 16:32
  • 3
    I feel dumb... the giraffe one seems obvious, but why shouldn't you be able to pass mammals to something that can handle animals, just because it can handle non-mammals too? – MGOwen Sep 24 '16 at 6:29
  • 4
    @MGOwen: You have a list of mammals. You decide to treat it as a list of animals. You put a lizard into the list of animals. But it is really a list of mammals. Now you have a list of mammals with a lizard in it, violating the expectation that a list of mammals has only mammals in it. The conclusion is a violation of the type system, so one of those steps must be illegal. It is the first one: you cannot treat a list of mammals as a list of animals. – Eric Lippert Sep 24 '16 at 12:30
13

The behavior you're describing is called covariance – if A is B, then List<A> is List<B>.

However, for mutable types like List<T>, that is fundamentally unsafe.

Had this been possible, the method would be able to add a new OtherDerivedClass() to a list that can actually only hold DerivedClass.

Covariance is safe on immutable types, although .Net only supports it in interfaces and delegates.
If you change the List<T> parameter to IEnumerable<T>, that will work

  • @SamIam: No; you're trying to pass a List<Derived>. Passing a List<Base> that contains Deriveds would work fine. – SLaks Jun 6 '13 at 16:15
  • So if I cast or convert my List<Derived> to List<Base> before passing it in would that be okay? – Sam I am says Reinstate Monica Jun 6 '13 at 16:16
  • 1
    @SamIam: No. The whole point is that it is fundamentally unsafe to cast List<Derived> to List<Base>. If you create a List<Base> to begin with, it will work. – SLaks Jun 6 '13 at 16:17
  • @SamIam: SLaks explained it well: if you could cast a List<Derived> to a List<Base>, then you could theoretically add an instance of OtherDerived to it (because the list is mutable). But it was instantiated as a List<Derived>, and if you tried to manually cast it back to List<Derived>, you'd get a List<Derived> with an OtherDerived in it. – voithos Jun 6 '13 at 16:28
2

When you have a class derived from a base class, any containers of those classes are not automatically derived. So you cannot just cast a List<Derived> to a List<Base>.

Use .Cast<T>() to create a new list where each object is cast back to the base class:

List<MyDerived> list1 = new List<MyDerived>();
List<MyBase> list2 = list1.Cast<MyBase>().ToList();

Note that this is a new list, not a cast version of your original list, so operations on this new list will not reflect on the original list. Operations on the contained objects will reflect, however.

  • 2
    List<MyBase> list2 = new List<MyBase>(list1); strikes me as cleaner than using Cast. – Brian Jun 6 '13 at 17:43
1

If you could write

List<BaseClass> bcl = new List<DerivedClass>(); 

you could call

var instance = new AnotherClassInheritingFromBaseClass();
bc1.Add(instance);

Adding an instance which is not a DerivedClass to the list.

0

A solution i used was to create an extension class:

public static class myExtensionClass 
{
    public void doSomething<T>(List<BaseClass> bc) where T: BaseClass
    {
        // do something with bc
    }
}

It uses generic, but when you call it you don't have to especify the class since you already 'told' the compiler the type is the same of extended class.

You would call it this way:

List<DerivedClass> lst = new List<DerivedClass>();
lst.doSomething();

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