As a first step we observe that your definition

```
outputList x y = concat . map ($ y) $ map ($ x) [getRow,getColumn,getBlock]
```

can be rewritten using the function composition operator `(.)`

instead of the function application operator `($)`

as follows.

```
outputList x y = (concat . map ($ y) . map ($ x)) [getRow,getColumn,getBlock]
```

Next we notice that `map`

is another name for `fmap`

on lists and satisfies the `fmap`

laws, therefore, in particular, we have `map (f . g) == map f . map g`

. We apply this law to define a version using a single application of `map`

.

```
outputList x y = (concat . map (($ y) . ($ x))) [getRow,getColumn,getBlock]
```

As a final step we can replace the composition of `concat`

and `map`

by `concatMap`

.

```
outputList x y = concatMap (($ y) . ($ x)) [getRow,getColumn,getBlock]
```

Finally, in my opinion, although Haskell programmers tend to use many fancy operators, it is not a shame to define the function by

```
outputList x y = concatMap (\f -> f x y) [getRow,getColumn,getBlock]
```

as it clearly expresses, what the function does. However, using type class abstractions (as demonstrated in the other answer) can be a good thing as you might observe that your problem has a certain abstract structure and gain new insights.