The `Lens`

type:

```
type Lens s t a b = forall f. Functor f => (a -> f b) -> s -> f t
```

For our illustrative purposes, we can stick to the less general simple lens type, `Lens'`

. The right side then becomes:

```
forall f. Functor f => (a -> f a) -> s -> f s
```

Intuitively, `(a -> f a)`

is an operation on a part of a structure of type `s`

, which is promoted to an operation on the whole structure, `(s -> f s)`

. (The functor type constructor `f`

is part of the trickery which allows lenses to generalize getters, setters and lots of other things. We do not need to worry about it for now.) In other words:

- From the user point of view, a lens allows to, given a whole, focus on a part of it.
- Implementation-wise, a lens is a function which takes a function of the part and results in a function of the whole.

(Note how, in the descriptions I just made, "part" and "whole" appear in different orders.)

Now, a lens is a function, and functions can be composed. As we know, `(.)`

has type:

```
(.) :: (y -> z) -> (x -> y) -> (x -> z)
```

Let us make the involved types simple lenses (For the sake of clarity, I will drop the constraint and the `forall`

). `x`

becomes `a -> f a`

, `y`

becomes `s -> f s`

and `z`

becomes `t -> f t`

. The specialized type of `(.)`

would then be:

```
((s -> f s) -> t -> f t) -> ((a -> f a) -> s -> f s) -> ((a -> f a) -> t -> f t)
```

The lens we get as result has type `(a -> f a) -> (t -> f t)`

. So, a composed lens `firstLens . secondLens`

takes an operation on the part focused by `secondLens`

and makes it an operation on the whole structure `firstLens`

aims at. That just happens to match the order in which OO-style field references are composed, which is opposite to the order in which vanilla Haskell record accessors are composed.