First, look at the definition of `f . g`

:

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

Then we can expand the definition of `compute`

as follows:

```
compute f g x y = (f . g) x y
= (\z -> f (g z)) x y
= (f (g x)) y
= (5 + (g x)) y
```

`g x : Int -> Int`

, for which there is no `Num`

instance, so you can't add it to 5.

The problem is that you want `g`

applied to both `x`

*and* `y`

before its result is passed to `f`

. To do that, you need something more than simple composition. The simplest way to write this is directly:

```
compute f g x y = f (g x y)
```

If you are aiming for something more point-free, you need to get fancy with the composition:

```
compute f g = \x -> \y -> f (g x y)
-- application is left-associative
= \x -> \y -> f ((g x) y)
-- def'n of (.)
= \x -> f . (g x)
-- eta abstraction
= \x -> (\z -> f . z) (g x)
-- def'n of an operator section
= \x -> (f .) (g x)
-- def'n of (.)
= (f .) . g
```

If you want to be *completely* point-free, you can write

```
compute = (.) . (.)
```

You compose the composition operator with itself.

exactlyone argument. – chepner Dec 6 at 18:54`compute f g x y = f (g x y)`

. – Willem Van Onsem Dec 6 at 18:55`seq`

to a function (don't do that!) things get more subtle. – dfeuer Dec 6 at 19:03