I am experimenting with the module language of OCaml (3.12.1), defining functors and signatures for modules and so on, mostly following the examples from Chapter 2 of the OCaml manual and I've stumbled, by accident, on a situation where apparently my mental model of how functors and module signatures work is flawed. I tried to narrow the situation I encountered to the shortest amount of code possible so don't ask what I am trying to accomplish, this is a totally contrived example to demonstrate the OCaml feature in question.

So, we have a functor that simply provides an identity function 'f' and is parametrized by a module supplying the type of that function's input parameter. Totally contrived example like I said.

```
module type SOMETYPE = sig type t end ;;
module Identity = functor (Type: SOMETYPE) -> struct let f (x: Type.t) = x end ;;
```

Given the above, we proceed to define a module to supply the int type:

```
module IntType = struct type t = int end ;;
```

.. and then we use the functor to generate a module for the int identity function:

```
module IdentityInt = Identity(IntType) ;;
```

Sure enough the generated module and its f function behave as expected:

```
#IdentityInt.f(3) + 10 ;;
- : int = 13
```

The mental model of functors being functions that take modules as inputs and return modules seems to be serving us right so far. The `Identity`

functor expects as input parameter a module of signature (module type) SOMETYPE, and indeed the module we supplied (`IntType`

) has the correct signature and so a valid output module is produced (`IdentityInt`

) whose `f`

function behaves as expected.

Now comes the un-intuitive part. What if we would like to make it explicit that the supplied module `IntType`

is indeed a SOMETYPE type of module. As in:

```
module IntType : SOMETYPE = struct type t = int end ;;
```

and then generate the functor's output module the same way as before:

```
module IdentityInt = Identity(IntType) ;;
```

... let's try to use the `f`

function of the newly generated module:

```
IdentityInt.f 0 ;;
```

Whereupon the REPL complains with:

```
"Error: This expression [the value 0] has type int but an expression was expected of type IntType.t."
```

How can providing redundant but correct type information break the code? Even in case A the functor module Identity had to treat the `IntType`

module as `SOMETYPE`

type. So how come explicitly declaring `IntType`

to be `SOMETYPE`

type yields a different outcome ?

`module IntType`

is missing the`= int`

part? – Ptival Mar 19 '12 at 22:39`module IntType : SOMETYPE = struct type t = int end`

and you get exactly the same results that I describe above. I'll edit the post too to avoid any misunderstandings. – Marcus Junius Brutus Mar 20 '12 at 7:41