If you come from an OOP universe, then it probably helps to think of a module as analogous to a static class. Similar to .NET static classes, OCaml module have constructors; unlike .NET, OCaml modules can accept parameters in their constructors. A functor is a scary sounding name for the object you pass into the module constructor.

So using the canonical example of a binary tree, we'd normally write it in F# like this:

```
type 'a tree =
| Nil
| Node of 'a tree * 'a * 'a tree
module Tree =
let rec insert v = function
| Nil -> Node(Nil, v, Nil)
| Node(l, x, r) ->
if v < x then Node(insert v l, x, r)
elif v > x then Node(l, x, insert v r)
else Node(l, x, r)
```

Fine and dandy. But how does F# know how to compare two objects of type `'a`

using the `<`

and `>`

operators?

Behind the scenes, its doing something like this:

```
> let gt x y = x > y;;
val gt : 'a -> 'a -> bool when 'a : comparison
```

Alright, well what if you have an object of type `Person`

which doesn't implement that particular interface? What if you wanted to define the sorting function on the fly? One approach is just to pass in the comparer as follows:

```
let rec insert comparer v = function
| Nil -> Node(Nil, v, Nil)
| Node(l, x, r) ->
if comparer v x = 1 then Node(insert v l, x, r)
elif comparer v x = -1 then Node(l, x, insert v r)
else Node(l, x, r)
```

It *works*, but if you're writing a module for tree operations with insert, lookup, removal, etc, you require clients to pass in an ordering function everytime they call anything.

If F# supported functors, its hypothetical syntax might look like this:

```
type 'a Comparer =
abstract Gt : 'a -> 'a -> bool
abstract Lt : 'a -> 'a -> bool
abstract Eq : 'a -> 'a -> bool
module Tree (comparer : 'a Comparer) =
let rec insert v = function
| Nil -> Node(Nil, v, Nil)
| Node(l, x, r) ->
if comparer.Lt v x then Node(insert v l, x, r)
elif comparer.Gt v x then Node(l, x, insert v r)
else Node(l, x, r)
```

Still in the hypothetical syntax, you'd create your module as such:

```
module PersonTree = Tree (new Comparer<Person>
{
member this.Lt x y = x.LastName < y.LastName
member this.Gt x y = x.LastName > y.LastName
member this.Eq x y = x.LastName = y.LastName
})
let people = PersonTree.insert 1 Nil
```

Unfortunately, F# doesn't support functors, so you have to fall back on some messy workarounds. For the scenario above, I would almost always store the "functor" in my data structure with some auxillary helper functions to make sure it gets copied around correctly:

```
type 'a Tree =
| Nil of 'a -> 'a -> int
| Node of 'a -> 'a -> int * 'a tree * 'a * 'a tree
module Tree =
let comparer = function
| Nil(f) -> f
| Node(f, _, _, _) -> f
let empty f = Nil(f)
let make (l, x, r) =
let f = comparer l
Node(f, l, x, r)
let rec insert v = function
| Nil(_) -> make(Nil, v, Nil)
| Node(f, l, x, r) ->
if f v x = -1 then make(insert v l, x, r)
elif f v x = 1 then make(l, x, insert v r)
else make(l, x, r)
let people = Tree.empty (function x y -> x.LastName.CompareTo(y.LastName))
```