Part of some computation I am doing in Haskell results in a list of functions that map `Float` to `Float`. I'd like to apply a single argument to all these functions, like so:

``````-- x :: Float
-- functions :: [Float -> Float]
map (\f -> f x) functions
``````

Is there a way to do this without making use of a throw-away lambda function? I've searched Hoogle for what I think the signature should be (`[a -> b] -> a -> [b]`) with no luck.

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– Matvey Aksenov Oct 30 '12 at 8:13
Just a heads-up, there is a program called `pointfree` (`cabal install pointfree`) that can do these sort of reductions automagically. e.g. `map (\f -> f x) fs` becomes `map (\$ x) fs` as desired. – huon Oct 30 '12 at 9:35

You can use the `\$` operator, which is just function application:

``````map (\$ x) functions
``````

(This presupposes that `x` is in scope for the expression.)

Hoogle can only find functions, not arbitrary expressions. Since you're using `map`, you wanted to search for a function like `(a -> b) -> a -> b` rather than anything involving lists. Given a normal function, passing it to `map` makes it act on lists.

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Yeah, I think I was getting a bit confused with the signature. Thanks! I understand how `\$` defines precedence, but how does it work in this case? – Daniel Buckmaster Oct 30 '12 at 8:12
The operator is defined very simply: `f \$ x = f x`. So it really is just function application, as an operator. When you partially apply it, you get something equivalent to `\ f -> f \$ x`; using the above definition, this works out to `\ f -> f x`, which is exactly what you had. – Tikhon Jelvis Oct 30 '12 at 8:14
As I understand it, `map f xs` sort of does `f x` for each `x` in `xs`. So it looks to me like `\$ f x`, hence my confusion! – Daniel Buckmaster Oct 30 '12 at 8:19
Your understanding of `map` is correct. However, you may be a little confused by operator sections. In Haskell, you can partially apply operators by passing in an argument to either side. So you could write `(1 +)`, which is the function `\ x -> 1 + x`, but you could also write `(+ 1)` which is the function `\ x -> x + 1`. In this case, I'm doing exactly that except with the `\$` operator. – Tikhon Jelvis Oct 30 '12 at 8:24
Sorry, in my comment above I meant it looks like `\$ x f`. Which passes the argument `x` from the left? – Daniel Buckmaster Oct 30 '12 at 8:29

`functions <*> pure x` should do it. Import `Control.Applicative` module first.

Also consider this:

``````Prelude Control.Applicative> [(1+),(2+)] <*> pure 4
[5,6]
Prelude Control.Applicative> [(1+),(2+)] <*> [4]
[5,6]
Prelude Control.Applicative> [(1+),(2+)] <*> [4,5]
[5,6,6,7]
Prelude Control.Applicative> [(+)] <*> [1,2] <*> [4,5]
[5,6,6,7]
Prelude Control.Applicative> (+) <\$> [1,2] <*> [4,5]
[5,6,6,7]
Prelude Control.Applicative> getZipList \$ ZipList [(1+),(2+)] <*> ZipList [4,5]
[5,7]
Prelude Control.Applicative> getZipList \$ ZipList [(1+),(2+)] <*> pure 4
[5,6]
``````

`<\$>` is just a synonym for `fmap`. `<*>` applies what's "carried" in the applicative functor on the left, to what's on the right, according to a certain semantics. For naked lists, the semantics is the same as list monad - make all possible combinations - apply each function from the left to each object on the right, and `pure x = [x]`. For lists tagged (i.e. `newtype`d) as `ZipList`s, the semantics is "zippery" application - i.e. one-on-one, and `pure x = ZipList \$ repeat x`.

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Okay, time for me to learn some monads? Thanks! – Daniel Buckmaster Oct 30 '12 at 8:19
not monads, applicative functors. :) – Will Ness Oct 30 '12 at 8:23
These functions are actually defined for applicative functors rather than monads. Applicatives are more general--all monads are also applicatives, but not vice versa. – Tikhon Jelvis Oct 30 '12 at 8:23
Haha, I'm still at the stage where I assume weird things in Haskell are monads! I will do some research - thanks for the tip. – Daniel Buckmaster Oct 30 '12 at 8:29