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There's IsAssignableFrom method returns a boolean value indicates if one type is assignable from another type.

How can we not only test if they are assignable from or to each other, but also know the minimum covariant type for best fit?

Consider the following example(C# 4.0)

  • Code

    Action<char[]> x=default(Action<char[]>);
    Action<int[]> y=default(Action<int[]>);
    
    Action<Array> f=default(Action<Array>);
    Action<IList> g=default(Action<IList>);
    
    x=g;
    y=g;
    
    // following two are okay, but Array is abstract
    // neither char[] is int[] nor int[] is char[]
    x=f;
    y=f;
    
    f=g;
    g=f; // won't compile
    
    x=y; // won't compile
    y=x; // won't compile
    

In the example above, what to find is the type between char[] and int[].

share|improve this question
    
@DWright: Please let me know if it was still not fine, thank you very much. – Ken Kin Jan 23 '13 at 4:37
1  
Better. But what does "most possible" mean? The largest number of combinations? – DWright Jan 23 '13 at 4:53
2  
Now I'm understanding better. I'm wondering if the title could reflect that better. Perhaps: "What all the ways of assigning types to each other?", but that doesn't cover everything you are talking about. But a title like that conveys better what you are investigating. – DWright Jan 23 '13 at 5:34
up vote 24 down vote accepted

Important: Edits to correct grammar(both Q&A) would be greatly appreciated!

Thank to the feature of partial class, I can separate the methods to public and nonpublic.

  • Code

    using System; 
    
    partial class TypeExtensions {
        static readonly Type[] EmptyArray=new Type[] { };
    
        static T[] Subtract<T>(this T[] ax, T[] ay) {
            return Array.FindAll(ax, x => false==Array.Exists(ay, y => y.Equals(x)));
        }
    
        static T[] Intersect<T>(this T[] ax, T[] ay) {
            return Array.FindAll(ax, x => Array.Exists(ay, y => y.Equals(x)));
        }
    
        static int GetOccurrenceCount(this Type[] ax, Type ty) {
            return Array.FindAll(ax, x => Array.Exists(x.GetInterfaces(), tx => tx.Equals(ty))).Length;
        }
    
        static int GetOverlappedCount<T>(this T[] ax, T[] ay) {
            return ay.Intersect(ax).Length;
        }
    
        static Comparison<Type> CoverageComparison(this Type[] az) {
            return
                (tx, ty) => {
                    var ay=ty.GetInterfaces();
                    var ax=tx.GetInterfaces();
                    var overlapped=az.GetOverlappedCount(ax).CompareTo(az.GetOverlappedCount(ay));
    
                    if(0!=overlapped)
                        return overlapped;
                    else {
                        var occurrence=az.GetOccurrenceCount(tx).CompareTo(az.GetOccurrenceCount(ty));
    
                        if(0!=occurrence)
                            return occurrence;
                        else
                            return 0;
                    }
                };
        }
    }
    
    public static partial class TypeExtensions {
        public static Type[] GetTypesArray(this Type node) {
            if(null==node)
                return EmptyArray;
            else {
                var baseArray=TypeExtensions.GetTypesArray(node.BaseType);
                var interfaces=null==node?EmptyArray:node.GetInterfaces().Subtract(baseArray);
                var index=interfaces.Length+baseArray.Length;
                var typeArray=new Type[1+index];
                typeArray[index]=node;
                Array.Sort(interfaces, interfaces.CoverageComparison());
                Array.Copy(interfaces, 0, typeArray, index-interfaces.Length, interfaces.Length);
                Array.Copy(baseArray, typeArray, baseArray.Length);
                return typeArray;
            }
        }
    
        public static Type FindInterfaceWith(this Type type1, Type type2) {
            var array=type2.GetTypesArray().Intersect(type1.GetTypesArray());
            var typeCurrent=default(Type);
    
            for(var i=array.Length; i-->0; )
                if((null==(typeCurrent=array[i])||null==typeCurrent.BaseType)?i>0:false) {
                    var typeNext=array[i-1];
    
                    if(typeNext.FindInterfaceWith(typeCurrent)!=typeNext)
                        return default(Type);
                    else
                        break;
                }
    
            return typeof(object)!=typeCurrent?typeCurrent:default(Type);
        }
    
        public static Type FindBaseClassWith(this Type type1, Type type2) {
            if(null==type1)
                return type2;
    
            if(null==type2)
                return type1;
    
            for(var currentType2=type2; null!=currentType2; currentType2=currentType2.BaseType)
                for(var currentType1=type1; null!=currentType1; currentType1=currentType1.BaseType)
                    if(currentType2==currentType1)
                        return currentType2;
    
            return default(Type);
        }
    
        public static Type FindEqualTypeWith(this Type type1, Type type2) {
            var baseClass=type2.FindBaseClassWith(type1);
            var interfaCe=type2.FindInterfaceWith(type1);
    
            if(null==interfaCe)
                return baseClass;
            else {
                if(null==baseClass||typeof(object)==baseClass||baseClass.IsAbstract)
                    return interfaCe;
                else
                    return baseClass;
            }
        }
    }
    

The code can totally be more simple with Linq; but in my scenario, I should reduce the requirment of references and namespaces as possible.

There're two recursive methods, one is FindInterfaceWith, another is an important new defined method GetTypesArray which I meant it has the same length of name with GetInterfaces; for one another reason, there is already a method named GetTypeArray of class Type with a different of use.

It works like the method Akim provided GetClassHierarchy; but in this version, it builds an array like:

  • Output of hierarchy

    a[8]=System.String
    a[7]=System.Collections.Generic.IEnumerable`1[System.Char]
    a[6]=System.Collections.IEnumerable
    a[5]=System.ICloneable
    a[4]=System.IComparable
    a[3]=System.IConvertible
    a[2]=System.IEquatable`1[System.String]
    a[1]=System.IComparable`1[System.String]
    a[0]=System.Object
    

Here we are aware that it is in a particular order, that is how it makes things work. The array GetTypesArray built is in fact a flatten tree, that's why it given the parameter named node. The array is actually in the model of following:

  • Diagram

    hP9xR.jpg

    Note the implementing relation of interfaces such as IList<int> implements ICollection<int>, are not drawn with lines in this diagram, but we should keep the fact in mind.

The interfaces in the returned array is sorted, with the delegate of comparison returned by the method CoverageComparison which is used by Array.Sort.

Here are something to mention, for example, ability of multiple interfaces implementation been mentioned not only once by some answers(like [this]); and I have defined the way to solve, those are:

  • Note

    1. The GetInterfaces method does not return interfaces in a particular order, such as alphabetical or declaration order. Your code must not depend on the order in which interfaces are returned, because that order varies.

    2. Because of recursion, base classes are always ordered.

    3. If two interfaces of the top have the same coverage, is nothing different from there's none.

      Suppose we have these interfaces defined(either classes are just fine):

      public interface IDelta {
      }
      
      public interface ICharlie {
      }
      
      public interface IBravo: IDelta, ICharlie {
      }
      
      public interface IAlpha: IDelta, ICharlie {
      }
      

      Then which one is better for assignment between IAlpha and IBravo?

      I would say none!

      Isn't it simple and clear? In this case, FindInterfaceWith just returns null.

In the question [ How to find the best fit of common type between two types? ], I stated:

  • Wrong deduction

    If this supposition was correct, then the FindInterfaceWith becomes a redundant method; because of the only difference between FindInterfaceWith and FindEqualTypeWith is:

    FindInterfaceWith returns null if there was a best choice of class; while FindEqualTypeWith returns the exact class directly.

However, now we can look at the method FindEqualTypeWith, it's true of the method is based on the original assumption, to call other two methods. The paradoxical bug just disappeared magically.


Well, I've typed a lot of words. But there's something more, about the method FindBaseClassWith. What it returns is different from the original assumption of any parameter is null then it returns null. It actually returns another type argument passed.

This is related to the question [ Should BaseType of System.Object be the same as interfaces? ] and [ What should the method `FindBaseClassWith` return? ], the latter question is about chained calling the method FindBaseClassWith. In the current implementation, we can call it like:

  • Chained calling

    var type=
        typeof(int[])
            .FindBaseClassWith(null)
            .FindBaseClassWith(null)
            .FindBaseClassWith(typeof(char[]));
    

    It will return typeof(Array); thank to this feature, we can even call

    var type=
        typeof(String)
            .FindEqualTypeWith(null)
            .FindEqualTypeWith(null)
            .FindEqualTypeWith(typeof(String));
    

    Although it looks strange, but doesn't null been contravariant of any class? Nevertheless, one thing we might not able to do with the code is call FindInterfaceWith like above, because of the possibility of relations like IAlpha and IBravo.

I've had the code tested with the situation I can imagine, some samples by calling FindEqualTypeWith shows:

  • Output of assignable types

    (Dictionary`2, Dictionary`2) = Dictionary`2
    (List`1, List`1) = IList
    (Dictionary`2, KeyValuePair`2) = Object
    (IAlpha, IBravo) = <null>
    (IBravo, IAlpha) = <null>
    (ICollection, IList) = ICollection
    (IList, ICollection) = ICollection
    (Char[], Int32[]) = IList
    (Int32[], Char[]) = IList
    (IEnumerable`1, IEnumerable`1) = IEnumerable
    (String, Array) = Object
    (Array, String) = Object
    (Char[], Int32[]) = IList
    (Form, SplitContainer) = ContainerControl
    (SplitContainer, Form) = ContainerControl
    

    The List'1 test appears IList is because I tested typeof(List<int>) with typeof(List<String>); and the Dictionary'2 are both Dictionary<String, String>. Sorry about that I did not do the work to present exact type names.

I found that I omitted to describe the coverage comparison rule of ordering interfaces. In the delegate CoverageComparison, I use:

  • Dual rules

    1. compare two interfaces in a source interfaces array, with each covering how many others in the source, by calling GetOverlappedCount

    2. if the rule 1 does not distinguish them (returns 0), the secondary ordering is which has been inherited more times by others, by calling GetOccurrenceCount and then comparing

      Compound of these two rules are equivalent to the Linq query of

      interfaces=(
          from it in interfaces
          let order1=it.GetInterfaces().Intersect(interfaces).Count()
          let order2=(
              from x in interfaces
              where x.GetInterfaces().Contains(it)
              select x
              ).Count()
          orderby order1, order2
          select it
          ).ToArray();
      

      FindInterfaceWith will then perform the possibly recursive call, to figure out:

      Is this interface sufficient to recognized as the most common interface?

      Or just another relation like IAlpha and IBravo?

share|improve this answer
    
You: ... (List`1, List`1) = IList ... Sorry about that I did not do the work to present exact type names. If you have a System.Type like t = typeof(List<int>), you get only "List`1" if you use t.Name. If instead you use t.ToString(), you get more information: "System.Collections.Generic.List`1[System.Int32]" – Jeppe Stig Nielsen Mar 19 '13 at 20:47
    
@JeppeStigNielsen: Ah, thank you for that. My test code was written in Linq(since many cases), but the return value of Find X^9 With methods are possible to return null. I did not write a extension method to do the work. And actually, to make the name(with actual T) shown without the name of namespace, there're some little more to do. – Ken Kin Mar 19 '13 at 21:47

If you look at base classes only, the problem is trivial and a solution is given by Impworks's answer ("iterating over one object's parents and checking them for being assignable with the other type").

But if you want to include also interfaces, there's no unique solution to the problem, as you note yourself with your IDelta and ICharlie example. Two or more interfaces can easily be equally "good", so there's no single best solution. One can easily construct arbitrarily complex diagrams (graphs) of interface inheritances, and it's easy to see from such diagrams that there's no well-defined "FindEqualTypeWith".

You use the words covariance and contravariance in a non-standard way. In C#, these terms are used for variance kinds of generic types. Let me give an example. Supose we have

type1: System.Func<string>
type2: System.Func<Tuple<int>>

then of course with base classes, the "FindEqualTypeWith" could be

solutionA: System.MulticastDelegate

But the type Func<out T> is also covariant (out) in its type parameter T. Therefore, the type

solutionB: System.Func<System.Object>

is also a solution in the sense that it IsAssignableFrom the two given types type1 and type2. But the same could be said of

solutionC: System.Func<System.IComparable>

which works because both string and Tuple<> are IComparable.

So in the general case, there's no unique solution. So unless you specify precise rules describing what you want, we can't come up with an algorithm that finds your solution.

share|improve this answer
    
@KenKin Covariance is what makes a Func<object> "assignable from" a Func<string> even if Func<object> is not a base class of Func<string>. Contravariance is similar, but goes the other way, for example an IComparer<string> is "assignable from" an IComparer<object>. Read What's the difference between covariance and assignment compatibility? for more info on this terminology. Also see MSDN help. – Jeppe Stig Nielsen Mar 19 '13 at 23:17
    
Thank you, I've revised. – Ken Kin Mar 21 '13 at 15:32

The simplest case would be iterating over the base types of one object and checking them for being assignable with the other type, like this:

  • Code

    public Type GetClosestType(Type a, Type b) {
        var t=a;
    
        while(a!=null) {
            if(a.IsAssignableFrom(b))
                return a;
    
            a=a.BaseType;
        }
    
        return null;
    }
    

This will produce System.Object for two types which are unrelated, if they are both classes. I'm not sure if this behaviour met your requirement.

For more advanced cases, I'm using a custom extension method called IsExtendablyAssignableFrom.

It can handle different numeric types, generics, interfaces, generic parameters, implicit conversions, nullable, boxing/unboxing, and pretty much all the types I have come across with when implementing my own compiler.

I've uploaded the code into a separate github repository [here], so you could use it in your project.

share|improve this answer
    
The code is pretty huge, especially the numeric-related part. I believe the repository on GitHub is virtually eternal :) – Impworks Mar 19 '13 at 18:44
    
I've read up the code, and thought IsExtendablyAssignableFrom may not meet the requirement, but MostWideType seems closely. – Ken Kin Mar 19 '13 at 18:51
    
@KenKin, it does not resolve the closest type by itself. I believe you can use MostWideType for numerics and the snippet from my original post with IsExtendablyAssignableFrom instead of IsAssignableFrom for reference types. – Impworks Mar 19 '13 at 21:17

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