Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Suppose I have an interface IFoo with implementation classes VideoFoo, AudioFoo, and TextFoo. Suppose further that I cannot modify any of that code. Suppose that I would then like to write a function that acts differently based on the runtime type of IFoo, such as

Public Class Bar
    Public Shared Sub Fix(ByVal Foo as IFoo)
        If TypeOf Foo Is VideoFoo Then DoBar1()
        If TypeOf Foo Is AudioFoo Then DoBar2()
        If TypeOf Foo Is TextFoo Then DoBar3()

    End Sub
End Class

I would like to refactor this to use overloaded methods:

Sub DoBar(ByVal foo as VideoFoo)
Sub DoBar(ByVal foo as AudioFoo)
Sub DoBar(ByVal foo as TextFoo)

But the only way I see to do something like that would be to write

Sub DoBar(ByVal foo as IFoo)

Then I have to do my "If TypeOf ... Is" again. How can I refactor this to take advantage of the polymorphism of the implementations of IFoo without manually checking the types?

(in VB.NET, though my question applies to C# too)

share|improve this question
    
Why not have overloads for Fix? –  Blorgbeard Mar 24 '11 at 20:42
    
Because I have an instance of type IFoo; If I just add other overloads to Class Bar, my code will always call Fix(IFoo) rather than the specific Fix(...) that I want. –  Patrick Szalapski Mar 24 '11 at 20:47
    
Oh, right - I see. –  Blorgbeard Mar 24 '11 at 20:49
add comment

3 Answers 3

up vote 2 down vote accepted

Well, one option is to simply overload the Fix() method so that you have one overload for each type implementing IFoo. But I suspect you want to accept the interface directly, rather than it's implementing types.

What you're actually looking for is multiple dispatch. Normally, C#/VB use the types of the argument(s) to perform overload resolution at compile time, and dynamic dispatch of the call based on the runtime type of the instance on which the method is called. What you want is to perform overload resolution at runtime based on the runtime types of the arguments - a feature that neither VB.NET or C# directly support.

In the past, I've generally solved this kind of problem using a dictionary of delegates indexed by System.Type:

private readonly Dictionary<Type,Action<IFoo>> _dispatchDictionary;

static Bar()
{
    _dispatchDictionary.Add( typeof(TextFoo),  DoBarTextFoo );
    _dispatchDictionary.Add( typeof(AudioFoo), DoBarAudioFoo );
    _dispatchDictionary.Add( typeof(VideoFoo), DoBarVideoFoo );        
}

public void Fix( IFoo foo )
{
   Action<IFoo> barAction;
   if( _dispatchDictionary.TryGetValue( foo.GetType(), out barAction ) )
   {
      barAction( foo );
   }
   throw new NotSupportedException("No Bar exists for type" + foo.GetType());
}

private void DoBarTextFoo( IFoo foo ) { TextFoo textFoo = (TextFoo)foo; ... }
private void DoBarAudioFoo( IFoo foo ) { AudioFoo textFoo = (AudioFoo)foo; ... }
private void DoBarVideoFoo( IFoo foo ) { VideoFoo textFoo = (VideoFoo)foo; ... }

However, as of C# 4, we can now use the dynamic keyword in C# do essentially do the same thing (VB.NET does not have this feature as of yet):

public void Fix( IFoo foo )
{
    dynamic dynFoo = foo;
    dynamic thisBar = this;

    thisBar.DoBar( dynFoo ); // performs runtime resolution, may throw
}

private void Dobar( TextFoo foo ) { ... /* no casts needed here */ }
private void Dobar( AudioFoo foo ) { ... }
private void Dobar( VideoFoo foo ) { ... }

Note that using the dynamic keyword this way has a price - it requires that the call site be processed at runtime. It essentially spins up a version of the C# compiler at runtime, processes the metadata captured by the compiler, performs runtime analysis of the types, and spits out C# code. Fortunately, the the DLR can typicall cache such call sites effectively after their first use.

As a general rule, I find both of these pattern to be confusing, and overkill for most situations. If the number of subtypes is small and they are all known ahead of time, a simple if/else block can bemuch simpler and clearer.

share|improve this answer
    
I don't think multiple dispatch is the answer to this question. Patrick only seems to be switching based on one type, not two. –  Daniel T. Mar 25 '11 at 13:17
    
In fact VB.Net has had runtime resolution from the very first version, provided you use Option Strict Off. Most people recommend limiting Option Strict Off to as few source files as possible, because there's no direct equivalent to dynamic - you can't limit dynamic resolution and implicit casting to specific variables, it applies to an entire source file. –  MarkJ Mar 25 '11 at 15:00
    
... Requests for an exact equivalent keyword to dynamic in VB.Net are not meeting with much support from Microsoft :( –  MarkJ Mar 25 '11 at 15:06
    
I give you an answer with REAL multiple dispatch BEFORE this guy's answer (which has immitation dispatch and a blatant copy of my anw –  Martin Doms Mar 30 '11 at 0:20
add comment

What you're asking about is Multiple Dispatch, or a language feature that allows method overload resolution at runtime instead of compile time.

Unfortunately C# and VB.NET are both single-dispatch languages, which means the method overload is chosen at compile time. This means that the overload for an IFoo object will always be chosen for IFoo, regardless of its implementing type.

There are ways around this however. One way is to use the Visitor design pattern to implement double-dispatch, which would work. In C# you can also use the new dynamic keyword to force the run-time environment to resolve the overload at run-time. I wrote a blog entry about how to perform collision handling using this technique, but it's certainly applicable to what you're doing too.

I'm not terribly familiar with VB.NET, but I believe the language exhibits some dynamic behaviours by default, if the objects are cast to Object. Someone please correct me if this is wrong.

share|improve this answer
    
Yes, I'd like to avoid dynamic behavior, so my question is the same for C# and VB.NET. –  Patrick Szalapski Mar 24 '11 at 20:55
    
Fair enough :-) –  Martin Doms Mar 24 '11 at 21:22
    
VB.Net can be used dynamically if you use Option Strict Off. I recommend using Option Strict On in the majority of your code, and limiting Option Strict Off to source files where it's specifically needed for something like this. –  MarkJ Mar 25 '11 at 14:56
add comment

If you can't change the interface, nor any of the classes, then it stands to reason that no previously written code can take advantage of this new Fix function you want to add.

I don't know VB.net, but I can't help but wonder why you don't simply sub-class off of each of the current classes (and the interface,) and put your new Fix method in the sub-classes. All of your new code that wants to send the Fix message should accept an IFixFoo instead of an IFoo.

If you want to call Fix on IFoo objects that you didn't create, then you need a method that can create a correct IFixFoo. Using the above, you only have one place where you have to do the If TypeOf ... Is (when you actually convert an IFoo to an IFixFoo.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.