This is just a variant of @ony's, but how I'd write it:

```
import Data.List (unfoldr)
digits :: (Integral a) => a -> [a]
digits = unfoldr step . abs
where step n = if n==0 then Nothing else let (q,r)=n`divMod`10 in Just (r,q)
```

This will product the digits from low to high, which while unnatural for reading, is generally what you want for mathematical problems involving the digits of a number. (Project Euler anyone?) Also note that `0`

produces `[]`

, and negative numbers are accepted, but produce the digits of the absolute value. (I don't want partial functions!)

If, on the other hand, I need the digits of a number as they are commonly written, then I would use @newacct's method, since the problem *is* one of essentially orthography, not math:

```
import Data.Char (digitToInt)
writtenDigits :: (Integral a) => a -> [a]
writtenDigits = map (fromIntegral.digitToInt) . show . abs
```

Compare output:

```
> digits 123
[3,2,1]
> writtenDigits 123
[1,2,3]
> digits 12300
[0,0,3,2,1]
> writtenDigits 12300
[1,2,3,0,0]
> digits 0
[]
> writtenDigits 0
[0]
```

In doing Project Euler, I've actually found that some problems call for one, and some call for the other.

## About `.`

and "point-free" style

To make this clear for those not familiar with Haskell's `.`

operator, and "point-free" style, these could be rewritten as:

```
import Data.Char (digitToInt)
import Data.List (unfoldr)
digits :: (Integral a) => a -> [a]
digits i = unfoldr step (abs i)
where step n = if n==0 then Nothing else let (q,r)=n`divMod`10 in Just (r,q)
writtenDigits :: (Integral a) => a -> [a]
writtenDigits i = map (fromIntegral.digitToInt) (show (abs i))
```

These are exactly the same as the above. You should learn that these are the same:

```
f . g
(\a -> f (g a))
```

And "point-free" means that these are the same:

```
foo a = bar a
foo = bar
```

Combining these ideas, these are the same:

```
foo a = bar (baz a)
foo a = (bar . baz) a
foo = bar . baz
```

The laster is idiomatic Haskell, since once you get used to reading it, you can see that it is very concise.

`fac n = product [1..n]`

. Explicit recursion is unfashionable in Haskell circles. – C. A. McCann May 15 '10 at 4:15