Almost a direct translation of the python code linked.

First we need to define a `gcd`

function using recursion as "looping construct" instead of the python while (FP is more "recursion oriented")

```
let rec gcd = function
| x, 0 -> x
| x, y -> gcd (y, x % y)
```

That just leaves the `coprime`

function to define which can be easily done in *pointfree style* by composing the previous `gcd`

function with the partial application of equality with 1

```
let coprime = gcd >> (=) 1
```

which is functionaly the same as :

```
let coprime (x, y) = gcd (x, y) = 1
```

Aside from that we can make with a few tweaks the code more general (regarding numeric types) though I'm not sure it's worth it

(as one could prefer to use `BigInteger.GreatestCommonDivisor`

when manipulating bigint for example)

```
open LanguagePrimitives
let inline gcd (x, y) =
// we need an helper because inline and rec don't mix well
let rec aux (x, y) =
if y = GenericZero
then x
else aux (y, x % y)
aux (x, y)
// no pointfree style, only function can be inlined not values
let inline coprime (x, y) = gcd (x, y) = GenericOne
```

From @Henrik Hansen's answer here is an updated version figuring an active pattern to ease readability and extract common behaviour

```
let (|LT|EQ|GT|) (x, y) =
if x < y then LT
elif x = y then EQ
else GT
let areCoPrimes x y =
let rec aux (x, y) =
match x, y with
| 0, _ | _, 0 -> false
| LT -> aux (x, y - x)
| EQ -> x = 1
| GT -> aux (x - y, y)
aux (abs x, abs y)
```