Let's tackle this using "hole-driven development" a la Agda. We want to define `method`

which is, at the highest level, a function. We create functions using lambdas so we can start there and leave ourselves some holes.

```
method = \f -> #{1}
```

where we know that `f :: (a -> (a -> b))`

and our hole, `#{1} :: (a -> b)`

. We need to somehow use `f`

to create something of the type of `#{1}`

. Since we now *want* another function, `#{1}`

, let's use another lambda

```
method = \f -> \a -> #{2}
```

Now `a :: a`

and `#{2} :: b`

. We need to generate a `b`

using `f`

and `a`

of types `f :: (a -> (a -> b))`

and `a :: a`

. Hopefully this is becoming clear, but lets keep breaking it down.

Type notation has the convention that function arrows `(->)`

are right associative, so whenever we see `a -> (b -> c)`

we can think of it as `a -> b -> c`

. Furthermore, we have an equivalence between two argument functions like `a -> b -> c`

and functions of pairs `(a, b) -> c`

. This equivalence is exactly `curry`

/`uncurry`

, but it's useful in our case.

Let's rewrite `f`

to be the equivalent function `f' :: (a, a) -> b`

by having `f' (a, b) = f a b`

. Given that we can always use the "diagonal" function `diag :: a -> (a,a)`

to create homogenous pairs, we're done. We can use `f'`

to create a `b`

from any `(a,a)`

and we can use `diag`

to create a `(a, a)`

from any `a`

. We want a `b`

and we have an `a`

.

```
method = \f -> \a -> f' (diag a)
where
f' (a, b) = f a b
diag a = (a, a)
```

or

```
method f a = f a a
```

So you might see `method`

as *shrinking* a certain more general function to a more specific one acting only on the `diagonals`

. A type signature that makes that even more clear uses our `f'`

trick:

```
method :: ((a, a) -> b) -> (a -> b)
method f' a = f' (a, a)
```