Exactly what Andreas said. Now, the obvious way to get around this is to use a wrapper function:

```
fun f n =
let
fun f' 0 = []
| f' num = num mod 2 :: f' (num div 2)
in
rev (f' n)
end
```

This works, but has the disadvantage of first building up the list, and then traversing it (the `rev`

call). It also isn't tail-recursive. We can do better!

Instead of using reverse, we flip things around and use an accumulator:

```
fun g n =
let
fun g' 0 acc = acc
| g' num acc = g' (num div 2) (num mod 2 :: acc)
in
g' n []
end
```

To understand the difference, let's see what happens if we run each of these on the number 4.

```
f 4 -> rev (f' 4)
-> rev (4 mod 2 :: f' (4 div 2))
-> rev (0 :: f' 2)
-> rev (0 :: 2 mod 2 :: f' (2 div 2))
-> rev (0 :: 0 :: f' 1)
-> rev (0 :: 0 :: 1 mod 2 :: f' (1 div 2))
-> rev (0 :: 0 :: 1 :: f' 0)
-> rev (0 :: 0 :: 1 :: [])
-> [1, 0, 0]
g 4 -> g' 4 []
-> g' (4 div 2) (4 mod 2 :: [])
-> g' 2 (0 :: [])
-> g' (2 div 2) (2 mod 2 :: 0 :: [])
-> g' 1 (0 :: 0 :: [])
-> g' (1 div 2) (1 mod 2 :: 0 :: 0 :: [])
-> g' 0 (1 :: 0 :: 0 :: [])
-> [1, 0, 0]
```