I have a list of functions and their 'apply priority'.

It looks like this. Length of it is `33`

```
listOfAllFunctions = [ (f1, 1)
, (f2, 2)
, ...
, ...
, (f33, 33)
]
```

What I want to do is generate a list of permutations of the above list with no duplicates and I only want 8 unique elements in the inner list.

Which I'm implementing like this

```
prioratizedFunctions :: [[(MyDataType -> MyDataType, Int)]]
prioratizedFunctions = nubBy removeDuplicates
$ sortBy (comparing snd)
<$> take 8
<$> permutations listOfAllFunctions
```

where `removeDuplicates`

is defined like

```
removeDuplicates a b = map snd a == map snd b
```

Lastly I'm turning the sublists which'd be `[(MyDataType -> MyDataType, Int)]`

to a composition of functions and a `[Int]`

with this function

```
compFunc :: [(MyDataType -> MyDataType, Int)] -> MyDataType -> (MyDataType, [Int])
compFunc listOfDataAndInts target = (foldr ((.) . fst) id listOfDataAndInts target
, map snd listOfDataAndInts)
```

Applying the above function like this `(flip compFunc) target <$> prioratizedFunctions`

All of the above is a simplified version of the actual code but it should provide the gist it.

The problem is that this code takes practically forever to execute. From some prototyping I think the blame of it falls on my implementation of `permutations`

function inside `prioratizedFunctions`

.

So I was wondering, is there a better way of doing what I want (basically generating permutation of `listOfAllFunctions`

where each list only contains 8 elements, every list of elements sorted by their priority with `snd`

and containing no duplicate list)

or is the problem inherently a long process?

`choose 0 xs = [[]]`

`choose n [] = []`

`choose n (x:xs) = map (x:) (choose (n-1) xs) ++ choose n xs`

. Will it have the same effect as the function I used in my question? – atis Jan 11 at 15:08