The important thing to understand here is that OCaml performs type inference in a compositional manner, i.e., it will first infer type of `struct ... end`

and only then it will match the inferred types against `sig ... end`

to verify that the structure really does implement the signature.

For example, if you write

```
module Monkey : sig val f : int -> int end =
struct
let f x = x
end
```

then OCaml will be happy, as it will see that `f`

has a polymorphic type `'a -> 'a`

which can be specialized to the required type `int -> int`

. Because the `sig ... end`

makes `Monkey`

opaque, i.e., the signature hides the implementation, it will tell you that `f`

has type `int -> int`

, even though the actual implementation has a polymorphic type.

In your particular case OCaml first infers that `g`

has type `'a -> 'a`

, and then that the type of `h`

is `'a -> 'a`

as well. So it concludes that the structure has the type

```
sig val g : 'a -> 'a val h : 'a -> 'a end
```

Next, the signature is matched against the given one. Because a function of type `'a -> 'a`

can be specialized to `int -> int`

as well as `string -> string`

OCaml concludes that all is well. Of course, the whole point of using `sig ... end`

is to make the structure opaque (the implementation is hidden), which is why the toplevel does *not* expose the polymorphic type of `g`

and `h`

.

Here is another example which shows how OCaml works:

```
module Cow =
struct
let f x = x
let g x = f [x]
let a = f "hi"
end
module Bull : sig
val f : int -> int
val g : 'b * 'c -> ('b * 'c) list
val a : string
end = Cow
```

The response is

```
module Cow :
sig
val f : 'a -> 'a
val g : 'a -> 'a list
val a : string
end
module Bull :
sig
val f : int -> int
val g : 'a * 'b -> ('a * 'b) list
val a : string end
end
```