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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 = 
                          let element = head outlist
                              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 ?

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2  
(length outlist) == 0 -> null outlist –  Thomas Eding Dec 3 '10 at 8:31

4 Answers 4

up vote 6 down vote accepted

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

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

PS Although it's O(n^2)

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

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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
1  
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.

2+3: http://hackage.haskell.org/package/containers-0.5.4.0/docs/Data-Map-Strict.html

[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

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