I couldn't find anything on Hoogle, but is there a standard function or operator with a signature like:

```
func :: (a -> b -> c) -> (a -> b) -> a -> c
```

I.e. given two functions `f`

and `g`

and an element `x`

as arguments it computes `f x (g x)`

?

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I couldn't find anything on Hoogle, but is there a standard function or operator with a signature like:

```
func :: (a -> b -> c) -> (a -> b) -> a -> c
```

I.e. given two functions `f`

and `g`

and an element `x`

as arguments it computes `f x (g x)`

?

`f <*> g`

⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀⠀

The function you’re looking for is `(<*>)`

. Why? Well, it’s true that `(<*>)`

has a more general type:

```
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
```

But consider that we can specialize `f`

to `(->) r`

, which has an `Applicative`

instance:

```
(<*>) :: (->) r (a -> b) -> (->) r a -> (->) r b
```

…then we can rearrange the type so `->`

is infix instead of prefix, as it normally is:

```
(<*>) :: (r -> a -> b) -> (r -> a) -> (r -> b)
```

…which is the same as your signature modulo alpha renaming.

This works because the function type, `(->)`

, has instances of `Functor`

, `Applicative`

, and `Monad`

, which are idiomatically called “reader”. These instances thread an extra argument around to all their arguments, which is exactly what your function does.

Yes, this is a special case of `ap :: Monad m => m (a -> b) -> m a -> m b`

Here you should see the monad `m`

as `(->) r`

, so a function with a parameter. Now `ap`

is defined as [source]:

```
ap m1 m2 = do
x1 <- m1
x2 <- m2
return (x1 x2)
```

Which is thus syntactical sugar for:

```
ap m1 m2 = m1 >>= (\x1 -> m2 >>= return . x1)
```

The bind function `>>=`

is defined for a `(->) r`

instance as [source]:

```
instance Monad ((->) r) where
f >>= k = \ r -> k (f r) r
return = const
```

(`return`

is by default equal to `pure`

, which is defined as `const`

).

So that means that:

```
ap f g = f >>= (\x1 -> g >>= const . x1)
= f >>= (\x1 -> (\r -> (const . x1) (g r) r))
= \x -> (\x1 -> (\r -> (const . x1) (g r) r)) (f x) x
```

now we can perform a *beta* reduction (`x1`

is `(f x)`

):

```
ap f g = \x -> (\r -> (const . (f x)) (g r) r) x
```

and another *beta* reduction (`r`

is `x`

):

```
ap f g = \x -> (const . (f x)) (g x) x
```

We can unwrap the `const`

as `\c _ -> c`

, and `(.)`

as `f . g`

to `\z -> f (g z):

```
ap f g = \x -> ((\c _ -> c) . (f x)) (g x) x
= \x -> (\z -> (\c _ -> c) ((f x) z)) (g x) x
```

Now we can again perform a beta reductions (`z`

is `(g x)`

, and `c`

is `((f x) (g x))`

):

```
ap f g = \x -> ((\c _ -> c) ((f x) (g x))) x
= \x -> (\_ -> ((f x) (g x))) x
```

finally we perform a beta-reduction (`_`

is `x`

):

```
ap f g = \x -> ((f x) (g x))
```

We now move `x`

to the head of the function:

```
ap f g x = (f x) (g x)
```

and in Haskell `f x y`

is short for `(f x) y`

, so that means that:

```
ap f g x = (f x) (g x)
= f x (g x)
```

which is the requested function.

`(<*>)`

in Haskell. – chi Dec 12 '17 at 19:25