Similar to Sam Westrick's definition, "number of times you can subtract `n2`

from `n1`

without going negative", you could also do integer division with addition and greater-than using the definition, "number of times you can add `n2`

to itself before it is greater than `n1`

."

```
datatype nat = Z | S of nat
fun gt (S x, S y) = gt (x, y)
| gt (S _, Z) = true
| gt (Z, _) = false
fun add (x, Z) = x
| add (x, S y) = add (S x, y)
fun divide (_, Z) = raise Domain
| divide (x, y) = (* ... *)
```

Addition might seem like a conceptually simpler thing than subtraction. But greater-than is a more expensive operator than determining when a number is negative, since the case is incurred by induction, so Sam's suggestion would be more efficient.

You might test your solution with the following tests:

```
fun int2nat 0 = Z
| int2nat n = S (int2nat (n-1))
fun nat2int Z = 0
| nat2int (S n) = 1 + nat2int n
fun range (x, y) f = List.tabulate (y - x + 1, fn i => f (i + x))
fun divide_test () =
let fun showFailure (x, y, expected, actual) =
Int.toString x ^ " div " ^ Int.toString y ^ " = " ^
Int.toString expected ^ ", but divide returns " ^
Int.toString actual
in List.mapPartial (Option.map showFailure) (
List.concat (
range (0, 100) (fn x =>
range (1, 100) (fn y =>
let val expected = x div y
val actual = nat2int (divide (int2nat x, int2nat y))
in if expected <> actual
then SOME (x, y, expected, actual)
else NONE
end))))
end
```