So, several questions, lets take them one by one :

**First** : How to generate something else than integers with the functions from System.Random (which is a slow generator, but for your application, performance isn't vital).
There is several approaches, with your list, you would have to write a function intToColor :

```
intToColor :: Int -> String
intToColor n = head . filter (\p -> snd p == n) $ [("Black",1),("Green",2),("Purple",3),("Red",4),("White",5),("Yellow",6)]
```

Not really nice. Though you could do better if you wrote the pair in the (key, value) order instead since there's a little bit of support for "association list" in Data.List with the lookup function :

```
intToColor n = fromJust . lookup n $ [(1,"Black"),(2,"Green"),(3,"Purple"),(4,"Red"),(5,"White"),(6,"Yellow")]
```

Or of course you could just forget this business of Int key from 1 to 6 in a list since lists are *already* indexed by Int :

```
intToColor n = ["Black","Green","Purple","Red","White","Yellow"] !! n
```

(note that this function is a bit different since intToColor 0 is "Black" now rather than intToColor 1, but this is not really important given your objective, if it really shock you, you can write "!! (n-1)" instead)

But since your colors are not really Strings and more like symbols, you should probably create a Color type :

```
data Color = Black | Green | Purple | Red | White | Yellow deriving (Eq, Ord, Show, Read, Enum)
```

So now Black is a value of type Color, you can use it anywhere in your program (and GHC will protest if you write Blak) and thanks to the magic of automatic derivation, you can compare Color values, or show them, or use toEnum to convert an Int into a Color !

So now you can write :

```
randColorIO :: IO Color
randColorIO = do
n <- randomRIO (0,5)
return (toEnum n)
```

**Second**, you want to store dice values (colors) in a data structure and give the option to keep identical throws. So first you should stock the results of several throws, given the maximum number of simultaneous throws (5) and the complexity of your data, a simple list is plenty and given the number of functions to handle lists in Haskell, it is the good choice.

So you want to throws several dices :

```
nThrows :: Int -> IO [Color]
nThrows 0 = return []
nThrows n = do
c <- randColorIO
rest <- nThrows (n-1)
return (c : rest)
```

That's a good first approach, that's what you do, more or less, except you use if instead of pattern matching and you have an explicit accumulator argument (were you going for a tail recursion ?), not really better except for strict accumulator (Int rather than lists).

Of course, Haskell promotes higher-order functions rather than direct recursion, so let's see the combinators, searching "Int -> IO a -> IO [a]" with Hoogle gives you :

```
replicateM :: Monad m => Int -> m a -> m [a]
```

Which does exactly what you want :

```
nThrows n = replicateM n randColorIO
```

(I'm not sure I would even write this as a function since I find the explicit expression clearer and almost as short)

Once you have the results of the throws, you should check which are identical, I propose you look at sort, group, map and length to achieve this objective (transforming your list of results in a list of list of identical results, not the most efficient of data structure but at this scale, the most appropriate choice). Then keeping the colors you got several time is just a matter of using filter.

Then you should write some more functions to handle interaction and scoring :

```
type Score = Int
yahtzee :: IO Score
yahtzeeStep :: Int -> [[Color]] -> IO [[Color]] -- recursive
scoring :: [[Color]] -> Score
```

So I recommend to keep and transmit a [[Color]] to keeps track of what was put aside. This should be enough for your needs.