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I've been trying to solve this, but I just can't figure it out. So, I've a list with tuples, for example:

[("Mary", 10), ("John", 45), ("Bradley", 30), ("Mary", 15), ("John", 10)]

and what I want to get is a list with also tuples where, if the name is the same, the numbers of those tuples should be added and, if not, that tuple must be part of the final list too, exemplifying:

[("Mary",25), ("John", 55), ("Bradley", 30)]

I don't know if I explained myself really well, but I think you'll probably understand with the examples.

I've tried this, but it doesn't work:

test ((a,b):[]) = [(a,b)]
test ((a,b):(c,d):xs) | a == c = (a,b+d):test((a,b):xs)
                      | otherwise = (c,d):test((a,b):xs)
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Does this question help you at all? –  Useless Dec 30 '12 at 22:52
    
What have you tried so far? –  Marcin Dec 30 '12 at 22:52
    
Can you solve it by hand using a bunch of cards with names and numbers on them? –  n.m. Dec 30 '12 at 23:02

4 Answers 4

up vote 1 down vote accepted

Here's another way using lists:

import Data.List

answer :: [(String, Int)] -> [(String, Int)]
answer = map (foo . unzip) . groupBy (\x y -> fst x == fst y) . sort            
   where foo (names, vals) = (head names, sum vals)

It's a fairly straightforward approach. First, the dot (.) represents function composition which allows us to pass values from one function to the next, that is, the output of one becomes the input of the next, and so on. We start by applying sort which will automatically move the names next to one another in the list. Next we use groupBy to put each pair with similar names into a single list. We end up with a list of lists, each containing pairs with similar names:

[[("Bradley",30)], [("John",10),("John",45)], [("Mary",10),("Mary", 15)]]

Given such a list, how would you handle each sublist? That is, how would you handle a list containing all the same names?

Obviously we wish to shrink them down into a single pair, which contains the name and the sum of the values. To accomplish this, I chose the function (foo . unzip), but there are many other ways to go about it. unzip takes a list of pairs and creates a single pair. The pair contains 2 lists, the first with all the names, the second with all the values. This pair is then passed to foo by way of function composition, as discussed earlier. foo picks it apart using a pattern, and then applies head to the names, returning only a single name (they're all the same), and applying sum to the list of values. sum is another standard list function that sums the values in a list, naturally.

However, this (foo . unzip) only applies to a single list of pairs, yet we have a list of lists. This is where map comes in. map will apply our (foo . unzip) function to each list in the list, or more generally, each element in the list. We end up with a list containing the results of applying (foo . unzip) to each sublist.

I would recommend looking at all the list functions used in Data.List.

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@Raphm I added more to the answer above. Hopefully that helps. –  user1891025 Dec 31 '12 at 1:38
    
@Raphm Sorry, I should've attempted an explanation the first time. –  user1891025 Dec 31 '12 at 2:24
    
For sake of didactics: can I ask what's not straight and simple about using Data.Map? –  Rhymoid Dec 31 '12 at 11:55
    
@Tinctorius Nothing, however it was evident he desired a solution restricted to lists. I took him simply as a student tasked with understanding common list functions, making the use of Data.Map, albeit a clever solution, somewhat inconsequential. –  user1891025 Dec 31 '12 at 14:28

Here are my two cents. Using just the Haskell Prelude.

test tup = sumAll
  where
    collect ys [] = ys
    collect ys (x:xs) =
        if (fst x) `notElem` ys
        then collect (fst x : ys) xs
        else collect ys xs
    collectAllNames = collect [] tup

    sumOne [] n x = (x, n)
    sumOne (y:ys) n x =
        if fst y == x
        then sumOne ys (n + snd y) x
        else sumOne ys n x

    sumAll = map (sumOne tup 0) collectAllNames

This method traverses the original list several times. Collect builds a temporary list holding just the names, skipping name repetitions. sumOne takes a name, checks what names in the list matches, and adds their numbers. It returns the name as well as the sum.

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Doing this sort of thing is always awkward with lists, because of their sequential nature--they don't really lend themselves to operations like "find matching items" or "compute a new list by combining specific combinations of list elements" or other things that are by nature non-sequential.

If you step back for a moment, what you really want to do here is, for each distinct String in the list, find all the numbers associated to it and add them up. This sounds more suited to a key-value style data structure, for which the most standard in Haskell is found in Data.Map, which gives you a key-value map for any value type and any ordered key type (that is, an instance of Ord).

So, to build a Map from your list, you can use the fromList function in Data.Map... which, conveniently, expects input in the form of a list of key-value tuples. So you could do this...

import qualified Data.Map as M

nameMap = M.fromList [("Mary", 10), ("John", 45), ("Bradley", 30), ("Mary", 15), ("John", 10)]

...but that's no good, because inserting them directly will overwrite the numbers instead of adding them. You can use M.fromListWith to specify how to combine values when inserting a duplicate key--in the general case, it's common to use this to build a list of values for each key, or similar things.

But in your case we can skip straight to the desired result:

nameMap = M.fromListWith (+) [("Mary", 10), ("John", 45), ("Bradley", 30), ("Mary", 15), ("John", 10)]

This will insert directly if it finds a new name, otherwise it will add the values (the numbers) on a duplicate. You can turn it back into a list of tuples if you like, using M.toList:

namesList = M.toList $ M.fromListWith (+) [("Mary", 10), ("John", 45), ("Bradley", 30), ("Mary", 15), ("John", 10)]

Which gives us a final result of [("Bradley",30),("John",55),("Mary",25)].

But if you want to do more stuff with the collection of names/numbers, it might make more sense to keep it as a Map until you're done.

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Beat me to the punch. Glad to see I was writing the same solution :) –  Rhymoid Dec 30 '12 at 23:12
    
@Tinctorius: Yeah, you'd be hard-pressed to find a more direct case of "just use this thing in the standard library"! I was going to just link to Data.Map in a comment, but figured that using fromListWith needed a bit more clarification. –  C. A. McCann Dec 30 '12 at 23:15
    
What does import qualified do? –  Marcin Dec 30 '12 at 23:23
1  
@Marcin: Imports the names qualified--notice that I wrote the functions like M.fromListWith and such. You generally want to import Data.Map qualified because it defines a bunch of functions that have the same name as Prelude functions--with just import Data.Map you'll get all kinds of ambiguous name errors. Actually, if you look at the documentation page for Data.Map it explicitly recommends importing qualified for that reason. –  C. A. McCann Dec 30 '12 at 23:25
1  
@Raphm You can get a not-too-complicated implementation using only lists if you sort the list first, then pairs with the same String component are adjacent. Then you can do something similar to your attempt. –  Daniel Fischer Dec 31 '12 at 0:19

I think the reason your potential solution did not work, is that it will only group elements together if they occur sequentially with the same key in the list. So instead, I'm going to use a map (often called a dictionary if you've used other languages) to remember which keys we've seen and keep the totals. First we need to import the functions we need.

import Data.Map hiding (foldl, foldl', foldr)
import Data.List (foldl')

Now we can just fold along the list, and for each key value pair update our map accordingly.

sumGroups :: (Ord k, Num n) => [(k, n)] -> Map k n
sumGroups list = foldl' (\m (k, n) -> alter (Just . maybe n (+ n)) k m) empty list

So, foldl' walks along the list with a function. It calls the function with each element (here the pair (k, n)), and another argument, the accumulator. This is our map, which starts out as empty. For each element, we alter the map, using a function from Maybe n -> Maybe n. This reflects the fact the map may not already have anything in it under the key k - so we deal with both cases. If there's no previous value, we just return n, otherwise we add n to the previous value. This gives us a map at the end which should contain the sums of the groups. Calling the toList function on the result should give you the list you want.

Testing this in ghci gives:

 $ ghci
GHCi, version 7.6.1: http://www.haskell.org/ghc/  :? for help
Loading package ghc-prim ... linking ... done.
Loading package integer-gmp ... linking ... done.
Loading package base ... linking ... done.
Prelude> import Data.Map hiding (foldl, foldl', foldr)
Prelude Data.Map> import Data.List (foldl')
Prelude Data.Map Data.List> let sumGroups list = foldl' (\m (k, n) -> alter (Just . maybe n (+ n)) k m) empty list
Loading package array-0.4.0.1 ... linking ... done.
Loading package deepseq-1.3.0.1 ... linking ... done.
Loading package containers-0.5.0.0 ... linking ... done.
Prelude Data.Map Data.List> toList $ sumGroups $ [("Mary", 10), ("John", 45), ("Bradley", 30), ("Mary", 15), ("John", 10)]
[("Bradley",30),("John",55),("Mary",25)]
Prelude Data.Map Data.List> 

The groups come out in sorted order as a bonus, because internally map uses a form of binary tree, and so it's relatively trivial to traverse in order and output a sorted (well, sorted by key anyway) list.

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I'm sure it would be possible without Data.Map, but I'm inclined to think not using Data.Map is only going to make it more complicated really. Your original approach would work if you sort the list first, but I'd be inclined to say that your original approach is more complicated, and you end up dealing with tricky cases all the time. Plus, although they have the same big O complexity, collecting them in this way means the list may be generated lazily, which could be an advantage in memory usage for a long list with many identical keys. –  DarkOtter Dec 31 '12 at 14:24

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