The simplest way to neaten your implementation is to use guards. Instead of `pattern = value`

, you can write write `pattern | boolean = value`

; this will only match when `boolean`

is true. Thus, we can get

```
filter1 :: (a -> Bool) -> [a] -> [a]
filter1 p (x:xs) | p x = x : filter1 p xs
| otherwise = filter1 p xs
filter1 _ [] = []
```

(Note that `otherwise`

is just a synonym for `True`

.) Now, we have `filter p xs`

in two places, so we can move it out into a `where`

clause; these are shared by everything which shares a common pattern, even if it has a different guard:

```
filter2 :: (a -> Bool) -> [a] -> [a]
filter2 p (x:xs) | p x = x : xs'
| otherwise = xs'
where xs' = filter2 p xs
filter2 _ [] = []
```

(This implementation is the one used by GHCs Prelude.)

Now, neither of these are tail-recursive. This can be disadvantageous, but it does make the function lazy. If we want a tail-recursive version, we could write

```
filter3 :: (a -> Bool) -> [a] -> [a]
filter3 p xs = let filter3' p (x:xs) ys | p x = next $! x:ys
| otherwise = next $! ys
where next = filter3' p xs
filter3' _ [] ys = reverse ys
in filter3' p xs []
```

Note, however, that this would fail on infinite lists (though all the other implementations will work), thanks to the `reverse`

, so we make it strict with `$!`

. (I think I did this right—I could have forced the wrong variable. I think I got this one right, though.)

Those implementations all look like yours. There are, of course, others. One is based on `foldr`

:

```
filter4 :: (a -> Bool) -> [a] -> [a]
filter4 p = let check x | p x = (x :)
| otherwise = id
in foldr check []
```

We take advantage of point-free style here; since `xs`

would be the last argument to both `filter4`

and `foldr check []`

, we can elide it, and similarly with the last argument of `check`

.

You could also take advantage of the list monad:

```
import Control.Monad
filter5 :: MonadPlus m => (a -> Bool) -> m a -> m a
filter5 p xs = do x <- xs
guard $ p x
return x
```

The list monad represents nondeterminism. You pick an element `x`

from `xs`

, make sure that it satisfies `p`

, and then return it if it does. All of these results are then collected together. But note that this is now more general; this works for any `MonadPlus`

(a monad which is also a monoid; that is, which has an associative binary operation `mplus`

—`++`

for lists—and an identity element `mzero`

—`[]`

for lists), such as `[]`

or `Maybe`

. For instance, `filter5 even $ Just 1 == Nothing`

, and `filter5 even $ Just 2 == Just 2`

.

We can also adapt the `foldr`

-based version to get a different generic type signature:

```
import Control.Monad
import qualified Data.Foldable as F
import qualified Data.Monoid as M
filter6 :: (F.Foldable f, MonadPlus m, M.Monoid (m a))
=> (a -> Bool) -> f a -> m a
filter6 p = let check x | p x = return x
| otherwise = mzero
in F.foldMap check
```

The Data.Foldable module provides the `Foldable`

type class, which represents any structure which can be `fold`

ed like a list (placing the result in a generic `Monoid`

instead.) Our `filter`

requires a `MonadPlus`

constraint on the result as well so that we can write `return x`

. The `foldMap`

function requires a function which converts everything to elements of a `Monoid`

, and then concatenates all of them together. The mismatch between the `f a`

on the left and the `m a`

on the right means you could, for instance, `filter6`

a `Maybe`

and get back a list.

I'm sure that there are (many!) other implementations of `filter`

, but these are the 6 that I could think of relatively quickly. Now, which of these do I actually like best? It's a tossup between the straightforward `filter2`

and the `foldr`

-based `filter4`

. And `filter5`

is nice for its generic type signature. (I don't think I've ever needed a type signature like `filter6`

's.) The fact that `filter2`

is used by GHC is a plus, but GHC also uses some funky rewrite rules, so it's not obvious to me that it's superior without those. Personally, I would *probably* go with `filter4`

(or `filter5`

if I needed the genericity), but `filter2`

is definitely fine.