# What is a function composition algorithm that will work for multiple arguments, such as h(x,y) . f(x) . g(x) = h(f(x),g(x))?

For example, suppose we had the functions `double(x) = 2 * x`, `square(x) = x ^ 2` and `sum(x,y) = x + y`. What is a function `compose` such as `compose(compose(sum, square), double) = x^2 + 2*x`? Notice that I'm asking a function that can be used for functions of any arity. For example, you could compose `f(x,y,z)` with `g(x)`, `h(x)`, `i(x)` into `f(g(x), h(x), i(x))`.

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Is this for a particular language? –  Hodapp Nov 18 '12 at 6:54
@Hodapp no, any will do –  Viclib Nov 18 '12 at 14:23
You just defined the function you're asking for, so I don't know what you need here. –  Hodapp Nov 18 '12 at 15:05
I'm asking for a high-order function that does what I did here (manually) to any functions (automatically). –  Viclib Nov 18 '12 at 18:23

This is a common Haskell idiom, applicative functors:

``````composed = f <\$> g1 <*> g2 <*> ... <*> gn
``````

(A nicer introduction can be found here).

This looks very clean because of automatic partial application, and works like this:

``````(<*>) f g x = f x (g x)
(<\$>) f g x = f (g x) -- same as (.)
``````

For example,

``````f <\$> g <*> h <*> i ==>
(\x -> f (g x)) <*> h <*> i ==>
(\y -> (\x -> f (g x)) y (h y)) <*> i ==>
(\y -> f (g y) (h y)) <*> i ==>
(\z -> (\y -> f (g y) (h y)) z (i z)) ==>
(\z -> f (g z) (h z) (i z)).
``````

Applicative functors are more general, though. They are not an "algorithm", but a concept. You could also do the same on a tree, for example (if properly defined):

``````(+) <\$> (Node (Leaf 1) (Leaf 2)) <*> (Node (Leaf 3) (Leaf 4)) ==>
Node (Leaf 4) (Leaf 6)
``````

But I doubt that applicatives are really usable in most other languages, due to the lack of easy partial application.

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Haskell is really awesome. I upvoted but will need some time to understand what's going on there. Thanks you! –  Viclib Nov 18 '12 at 18:22
@Dokkat great to hear that. Just ask if I should clarify on something. –  phg Nov 19 '12 at 13:27