Another possible solution is the following

```
import Data.List
removeDups :: Eq a => [a] -> [a]
removeDups = map head . filter ((== 1) . length) . group
```

written in Haskell and using the library functions `group`

, `length`

, `(==)`

, `filter`

, `head`

, and `map`

.

Since the above might not be overly readable, I'll step through the definition piecewise

First a textual description of the individual parts that constitute the above definition

- First
*group* the list into sublists containing equal elements.
- For each of those, check whether it is of length exactly 1. If so keep it, otherwise throw it away.
- From the resulting list of lists (of which we know that every element has length exactly 1) we actually just need the singleton elements, which correspond to the
*heads* of the individual list.

Now for some code. A function that groups elements of a list together as long as they are equal can be defined as follows (sorry I'm using Haskell syntax because I'm not very familiar with scheme, but it should be easy to translate):

```
group :: Eq a -> [a] -> [[a]]
group [] = []
group (x:xs) = (x:ys) : group zs
where (ys, zs) = span (== x) xs
```

where `span`

is another library function that, given some predicate `p`

, splits its input list into an initial segment of elements *all* satisfying `p`

and the remainder of the list. For completeness, it could be defined as follows

```
span :: (a -> Bool) -> [a] -> ([a], [a])
span _ [] = ([], [])
span p xs@(x:xs')
| p x = let (ys, zs) = span p xs' in (x:ys, zs)
| otherwise = ([], xs)
```

`map`

, `filter`

, and `head`

are even more standard then those and I'm sure they are part of schemes library (as might be `group`

).

I guess my main point is that the solution is easy once you split the problem into small chunks of subproblems (using some predefined functions) and combine the results.