Edit: `julia`

: Inevitably, what looks to be the same answer, from `hammar`

appeared while writing, but maybe there is some helpful difference.

`julia`

, as `larsmans`

says, one problem is that you are not capitalizing the names of types and their constructors. The definition of Bool is:

```
data Bool = True | False
```

the words on both sides are capitalized; `Bool`

is the name of the type, `True`

and `False`

are the constructors we match on when dividing cases. By contrast, if the new terms we define are functions and other values, we use lower case. Suppose I want to define `not :: Bool -> Bool`

, well there are two cases:

```
not True = False
not False = True
```

with `or :: Bool -> Bool -> Bool`

there are four cases, but we can shorten things.

```
or False False = False
or _ _ = True
```

So here, `not`

and `or`

are both introduced with in lower case. Now to get to your problem, the first thing to note is that the type signature and the first two cases,

```
commonElt :: (Eq a) => [a] -> [a] -> Bool
commonElt [] _ = True
commonElt _ [] = False
```

don't really correspond to your specification, which is to find the common elements. That would have the signature

```
commonElts :: (Eq a) => [a] -> [a] -> [a]
```

If we repair the first two lines to match that ambition we get

```
commonElts [] _ = []
commonElts _ [] = []
```

then, following the idea of your third case we can spare ourselves the use of `head`

and `tail`

if we note that in the case in question neither term will be constructed as `[]`

but rather with `:`

, so the case is, say:

```
commonElts (s:ss) (t:ts)
```

Your idea was to check whether `s`

was in the second list, and then include it in a list that is built up by using `commonElts`

on the remaining bit, `ss`

. There are several ways of going about this, I will use `if`

, following your example. Note that Haskell's `if...then..`

is always `if ... then --- else ---`

; the first blank is the boolean test, the other two blanks can be of any type as long as it is the same, thus we usually line them up:

```
commonElts (s:ss) (t:ts) =
if elem s (t:ts) == True then s : commonElts ss (t:ts)
else commonElts ss (t:ts)
```

Note. though, that `elem s (t:ts)`

is already a Bool, True or False, so we don't need to add `== True`

. Furthermore, we don't actually use the division of the second list into `t`

and `ts`

, so we can just call it `ts`

or `s2`

as you did. Thus the complete definition is:

```
commonElts [] _ = []
commonElts _ [] = []
commonElts (s:s1) s2 =
if elem s s2 then s : commonElts s1 s2
else commonElts s1 s2
```

If an element appears more than once in the first list, it will appear more than once in the 'common element' list; we could resolve this with a further distinction of cases.

Edit: note that a very similar function can be defined with a 'list comprehension':

```
common xs ys = [ x | x <- xs , y <- ys, x == y]
```