# Remove duplicates from list

I have datatype:

``````data SidesType = Sides Int Int Int deriving (Show)
``````

And I need a function which get a list of SidesType and remove duplicates from it.

``````*Main> let a = [Sides 3 4 5,Sides 3 4 5,Sides 5 12 13,Sides 6 8 10,Sides 6 8 10,Sides 8 15 17,Sides 9 12 15,Sides 5 12 13,Sides 9 12 15,Sides 12 16 20,Sides 8 15 17,Sides 15 20 25,Sides 12 16 20,Sides 15 20 25]
*Main> removeDuplicateFromList [] a
[Sides 3 4 5,Sides 5 12 13,Sides 6 8 10,Sides 6 8 10,Sides 8 15 17,Sides 9 12 15,Sides 5 12 13,Sides 9 12 15,Sides 12 16 20,Sides 8 15 17,Sides 15 20 25,Sides 12 16 20,Sides 15 20 25]
``````

Here is my solution:

``````removeElementFromList :: [SidesType] -> SidesType -> [SidesType]
removeElementFromList lst element  =
let (Sides a b c) = element
in [(Sides x y z) | (Sides x y z) <- lst, (x /= a) || (y /= b)]

removeDuplicateFromList :: [SidesType] -> [SidesType] -> [SidesType]
removeDuplicateFromList inlist outlist
| (length outlist) == 0 = inlist
| otherwise =
b = tail outlist
filtered = removeElementFromList b element
in removeDuplicateFromList (inlist ++ [element]) filtered
``````

I am just wondering if there is any other way to write this code in more haskell-way ?

-
`(length outlist) == 0` -> `null outlist` – Thomas Eding Dec 3 '10 at 8:31

As usual there is "By" function which adds flexibility:

``````nubBy :: (a -> a -> Bool) -> [a] -> [a]
``````

PS Although it's O(n^2)

-

You're already deriving `Show` for your datatype. If you also derive `Eq`, you can use `nub` from `module Data.List`.

-

Use Data.List.nub

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I don't find how to use it with custom datatype. And I check only 2 of three members of type: (x /= a) || (y /= b) – demas Dec 3 '10 at 8:13
Then nubBy :: (a -> a -> Bool) -> [a] -> [a] – Ed'ka Dec 3 '10 at 8:28
Or wrap in a newtype! So much more elegant than using nubBy ;) – Thomas Eding Dec 3 '10 at 8:30
@Ed'ka can you create an answer so I accept it? – demas Dec 3 '10 at 8:33
This is really a comment, not an answer to the question. Please use "add comment" to leave feedback for the author. – The Lion Aug 18 '12 at 8:55

First derive the order class also:

``````data XYZ = XYZ .... deriving (Show, Eq, Ord)
``````

Or write your on Eq instance:

``````instance Eq XYZ where
a == b = ...
``````

Then be intelligent and use a Tree! [Computer Science Trees grow from top to bottom!][1]

``````import qualified Data.Map.Strict as Map

removeDuplicates ::[a] -> [a]
removeDuplicates list = map fst \$ Map.toList \$ Map.fromList \$ map (\a -> (a,a)) list
``````

Complexity (from right to left) for list with length N:

1. map of the list: O(N)
2. Map.fromList: O(N*log N)
3. Map.toList: O(log N)
4. map over list with list length smaller or equal to N: O(N)

They are called consecutively, this means, there are pluses between the complexities of the parts => O(2 * N + N * log N + log N) = O(N * log N)

This is way better than traversing N^2 times over the list! See: wolframAlpha plots. I included 2*N also for comparison reasons.

[1]: Search wikipedia for Computer Science Tree

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I'd hesitate to give a type like `XYZ` an `Ord` instance, just to speed up this algorithm – any such instance should also make sense conceptually! You can achieve the same complexity by staying with lists and using `map head . group . sortBy adHocOrd` instead of `nub`, with an "inline definition" of your proposed `Ord` instance. Or, if you really care about performance, define a `Hashable` instance instead: with a hashmap, you can get this down to O (n)! – leftaroundabout Mar 12 '14 at 0:04
well, yeah the Hashtable makes sense of course. I didn't know about that package before...(well I actually I didn't know about the primitive package, which are needed by arrays and such). But what's so bad about the Ord instance? At least if it is a type that does have some partial ordering defined, that shouldn't be any problem. Or am I wrong? Btw: Thanks for the reply. – Schnecki Mar 12 '14 at 22:49
There are quite a few types where you could define a partial ordering, but not a canonical one, in the sense that there would be an obvious mathematical unambiguous interpretation of it. Typical examples are the complex numbers, as well as any vector type (where any `Ord` instance would need to exploit some particular basis, but often there are multiple different ones that might be reasonable). And what the OP has looks quite vector-like indeed. – leftaroundabout Mar 13 '14 at 10:53