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In the latest version of C#, can I do something like this?

I feel like linq is the closest but that's chaining, not function composition, right?

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FYI, you can use the + operator to combine delegates (functions and actions) so they run in sequence. You can even use - to remove a delegate that has been added. It works like event += and -= (unless add and remove have been explicitly defined). This isn't function composition, but it's good to know about. –  Joey Adams Feb 20 at 15:58

7 Answers 7

up vote 8 down vote accepted

I did not let the compiler check this, but this should be possible:

Func<T3,T1> my_chain(Func<T2,T1> f1, Func<T3,T2> f2)
    return (x=> f2(f1(x)));
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+1 Now this is a generally useful implementation. I'd swap the types to stay in order though: Func<T1, T3> compose(Func<T2, T3> f, Func<T1, T2> g) { return (x => f(g(x))) }. –  delnan Mar 10 '11 at 18:41
@pst Sadly I'm quite sure more than half of the "standard" methods of .NET have more than one parameter. Those bad persons at Microsoft created a truly hellish framework! They should have learned for Haskell! One parameter is enough for everybody!! :-) –  xanatos Mar 10 '11 at 18:49
@delnan And if there is a controversy if Scala fits as a "functional language" ... C# sure doesn't ;-) –  user166390 Mar 10 '11 at 18:50
@Joan: Basically, f x y z = (x + y) * z becomes f x = (\y -> (\z -> )). So for each parameter you apply, you get a closure that's one step/parameter closer to the actual result, but will wait for the remaining arguments before calculating the result. Also goes by the term "partial application". You can do it yourself in every language that supports closures, but it's only practical with language assistance. –  delnan Mar 10 '11 at 19:11
@Joan Venge a Closure is a [often anonymous] function that binds over a free variable: var limit = 100; elms.Where(x => x > limit); <-- the lambda x => x > limit is a closure here as it "binds" to limit from the enclosing scope. I think the "old" inline delegate syntax could also create closures, but I'm not sure as I've never been restricted to C#2 ;-) –  user166390 Mar 10 '11 at 20:16

More than Linq, it's delegates, and lambda expressions/statements that are similar to chaining.

Func<int, string> a = p => p.ToString();
Func<string, string> b = p => "|" + p + "|";

Func<int, string> c = p => b(a(p));

The definition given in the link is:

Function composition is the act of pipelining the result of one function, to the input of another, creating an entirely new function.

And c is clearly a new function that chain call a and b.

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-1 Might be a valueable comment, but doesn't even touch the actual question. Edit: Okay, now you added a hand-rolled composition. So your answer is "No, you have to compose yourself"? –  delnan Mar 10 '11 at 18:32
@delnan Pink fairies don't compose functions in the link given. In the link it's desort = (reverse . sort), in C# it's desort = p => reverse(sort(p)). I can't see the difference (other than the fact that in the example the types are automatically discovered) –  xanatos Mar 10 '11 at 18:35
The Haskell equivalent to your code is (\p -> reverse (sort p)). It's obvious C#, as any other language that has lambdas, allows you to write an equivalent lambda by hand. The beauty of (.) in Haskell etc. is that you don't have do that, you just write the two functions you want to compose. –  delnan Mar 10 '11 at 18:37
@delnan: What is the actual question? I don't understand it if this answer doesn't touch it. –  Gabe Mar 10 '11 at 18:38
I had pressed the wrong key and the response was sent... I was still editing it. –  xanatos Mar 10 '11 at 18:39

C# doesn't have first class support but it's not particularly hard to implement. You just have to write a lot of overloads.

public static class Composition
    public static Func<T2> Compose<T1, T2>(Func<T1> f1, Func<T1, T2> f2)
        return () => f2(f1());

    public static Func<T1, T3> Compose<T1, T2, T3>(Func<T1, T2> f1, Func<T2, T3> f2)
        return v => f2(f1(v));
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Thanks but this generic version is supposed to support any type to any type? Because you said you have to write lots of overloads? –  Joan Venge Mar 10 '11 at 19:05
@Joan - As you can see in my update I mean the different signature combinations. –  ChaosPandion Mar 10 '11 at 19:14
I see what you mean now. –  Joan Venge Mar 10 '11 at 19:22
public static class Extensions
    public static Func<T, TReturn2> Compose<T, TReturn1, TReturn2>(this Func<TReturn1, TReturn2> func1, Func<T, TReturn1> func2)
        return x => func1(func2(x));


Func<int, int> makeDouble = x => x * 2;
Func<int, int> makeTriple = x => x * 3;
Func<int, string> toString = x => x.ToString();
Func<int, string> makeTimesSixString = toString.Compose(makeDouble).Compose(makeTriple);

//Prints "true"
Console.WriteLine(makeTimesSixString (3) == toString(makeDouble(makeTriple(3))));
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There is no specific operator / "syntax sugar" for that in C# (however, in F# you would use the >> operator).

There is a great blog post on this subject from Matthew Podwysocki. He suggests this kind of construct in C#:

public static class FuncExtensions
    public static Func<TSource, TResult> ForwardCompose<TSource, TIntermediate, TResult>(
        this Func<TSource, TIntermediate> func1, Func<TIntermediate, TResult> func2)
        return source => func2(func1(source));

Func<Func<int, int>, IEnumerable<int>, IEnumerable<int>> map = (f, i) => i.Select(f);
Func<Func<int, bool>, IEnumerable<int>, IEnumerable<int>> filter = (f, i) => i.Where(f);
Func<int, Func<int, int, int>, IEnumerable<int>, int> fold = (s, f, i) => i.Aggregate(s, f);

// Compose together
var mapFilterFold = map.Apply(x => x * x * x)
    .ForwardCompose(filter.Apply(x => x % 3 == 0))
    .ForwardCompose(fold.Apply(1, (acc, x) => acc * x));
Console.WriteLine(mapFilterFold(Enumerable.Range(1, 10)));
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It's not nearly as pretty, but you could do:

Func<IEnumerable<T>, IEnumerable<T>> desort = l => l.OrderBy(i => i).Reverse();

Or, if you want something more composit-y (that acts on the array in place):

Action<int[]> desort = a => Array.Reverse(Array.Sort(a));

Assuming those methods existed...but the syntax should be about right.

You could then use it in the following way (assuming you went with the first method above):

var arr = { 2,8,7,10,1,9,5,3,4,6 };
var desortedArr = desort(arr);
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That's one possible application of function composition hand-rolled as lambda... –  delnan Mar 10 '11 at 18:35
@delnan - That's correct, but this is definitely the way composition is typically handled in C# (since it's not built in to the language). –  Justin Niessner Mar 10 '11 at 18:37
Sort isn't chainable for Lists (it's void), but OrderBy(p => p) is (it's a small detail), the idea/example are correct –  xanatos Mar 10 '11 at 18:41

No, not short of defining your own generic Compose<T, U...>() functions. C# has no built-in functionality to help you out with this. (It doesn't do partial application, either.)

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