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Below a Compose function. If f and g are unary functions which return values, then Compose(f,g) returns a function which when called on x performs the equivalent to f(g(x)).

static Func<X, Z> Compose<Z, Y, X>(Func<Y, Z> f,Func<X, Y> g) 
{ return x => f(g(x)); }

Here's a couple of simple Func values which can be composed:

Func<int, bool> is_zero = x => { return x == 0; };

Func<int, int> mod_by_2 = x => { return x % 2; };

E.g. this works:

Console.WriteLine(Compose(is_zero, mod_by_2)(4));

However, if I instead have these equivalent static methods:

static bool IsZero(int n) { return n == 0; }

static int ModBy2(int n) { return n % 2; }

the same example doesn't work with those. I.e. this produces a compile time error:

Console.WriteLine(Compose(IsZero, ModBy2)(4));

Explicitly passing types to Compose fixes the issue:

Console.WriteLine(Compose<bool, int, int>(IsZero, ModBy2)(4));

Is there anyway to write Compose such that it works on the static methods without the explicit types?

Is this a good approach to take to implementing Compose? Can anyone make improvements to this?

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C#'s rigidity in its treatment of function/delegate types is one thing that's always frustrated me when compared to duck-typed languages like JavaScript. –  Will Vousden Jan 3 '12 at 23:17
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1 Answer

up vote 10 down vote accepted

The problem here is not the use of static methods but the use of method groups. When you use a function name as an expression without invoking it then it's a method group and must go through method group conversion. You would have the exact same problem with instance methods.

The problem you're running into is that C# can't do return type inference on method groups. Using Compose(IsZero, ModBy2)) requires the return type to be inferred for both IsZero and ModBy2 and hence this operation fails.

This is a known limitation in the inference capabilities of the C# compiler. Eric Lippert wrote an extensive blog article on this particular subject which covers this problem in detail

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I note that the article is slightly out of date. In this particular case it is correct; you cannot do inference on the method groups because we have a chicken-and-egg problem; we cannot determine what the delegate types are until we know what method is chosen from the method group, and we cannot do overload resolution on a method group until we know the delegate formal parameter types. If, by contrast, the delegate return types were being inferred but the formal parameter types were all somehow known then return type inference would work on method groups. –  Eric Lippert Jan 4 '12 at 0:21
    
Thank you Jared! –  dharmatech Jan 4 '12 at 1:01
    
When you use a function name as an expression without invoking it then it's a method group and must go through method group conversion. OK. So the name IsZero refers to a method group. But in this case, there is clearly only one method in the group, and thus no ambiguity about the return type. Obviously the compiler team decided against taking advantage of these cases (single method groups). Would it have been unsound to do otherwise? (Let me know if I should open a separate question for this... :-)) –  dharmatech Jan 4 '12 at 4:48
    
Of course, another unambiguous case would be method groups where all methods in the group have the same return type. –  dharmatech Jan 4 '12 at 4:50
4  
@dharmatech: of course there is a good justification. It would be bizarre if we had one overload resolution algorithm for the case where there was only one method in the method group and a completely different algorithm if there were two. That would mean, for instance, that adding a new unambiguous overload to your program could cause it to fail to compile. More generally, making a languages that requires that its compiler reasons about all possible logical inferences is not our goal; making a language that has clear and consistent rules is a goal. –  Eric Lippert Jan 4 '12 at 16:43
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