There are several ways to solve this and Adam has already given you an efficient way based on maps. However, I think a solution using only lists and recursion would also be instructive, especially when learning Haskell. Since you've already gotten an answer I hope I can write a solution here without spoiling anything.

The way I approached this is to think of how we can reduce the input list to the output list. We start with

```
[('A',3), ('B',2), ('C',2), ('A',5), ('C',3), ('C',2)]
```

The goal is to end up with a result list where each tuple starts with a **unique** character. Building such a result list can be done incrementally: Start with an empty list, and then insert tuples into the list, making sure not to duplicate the characters. The type would be

```
insertInResult :: (Char, Integer) -> [(Char, Integer)] -> [(Char, Integer)]
```

It takes the pair, like `('A',3)`

and inserts it into an existing list of unique pairs. The result is a new list of unique pairs. This can be done like this:

```
insertInResult (c, n) [] = [(c, n)]
insertInResult (c, n) ((c', n'):results)
| c == c' = (c, n + n') : results
| otherwise = (c', n') : (insertInResult (c, n) results)
```

Explanation: inserting a tuple into an empty result list is easy, just insert it. If the result list is not empty, then we get hold of the first result `(c', n')`

with pattern matching. We check if the characters match with the guard, and add the numbers if so. Otherwise we just copy the result tuple and insert the `(c, n)`

tuple into the remaining results.

We can now do

```
*Main> insertInResult ('A',3) []
[('A',3)]
*Main> insertInResult ('B',2) [('A',3)]
[('A',3),('B',2)]
```

Next step is to use `insertInResult`

repeatedly on the input list so that we build up a result list. I called this function `sumPairs'`

since I called the top-level function `sumPairs`

:

```
sumPairs' :: [(Char, Integer)] -> [(Char, Integer)] -> [(Char, Integer)]
sumPairs' [] results = results
sumPairs' (p:pairs) results = sumPairs' pairs (insertInResult p results)
```

It's a simple function that just iterates on the first argument and inserts each pair into the result list. The final step is to call this helper function with an empty result list:

```
sumPairs :: [(Char, Integer)] -> [(Char, Integer)]
sumPairs pairs = sumPairs' pairs []
```

It works! :-)

```
*Main> sumPairs [('A',3), ('B',2), ('C',2), ('A',5), ('C',3), ('C',2)]
[('A',8),('B',2),('C',7)]
```

The complexity of this solution is not as good as the one based on `Data.Map`

. For a list with *n* pairs, we call `insertInResult`

*n* times from `sumPairs'`

. Each call to `insertInResult`

may iterate up to *n* times until it finds a matching result tuple, or reaches the end of the results. This gives a time complexity of O(*n*²). The solution based on `Data.Map`

will have O(*n* log *n*) time complexity since it uses log *n* time to insert and update each of the *n* elements.

Note that this is the same complexity you would have gotten if you had sorted the input list and then scanned it once to add up adjacent tuples with the same character:

```
sumPairs pairs = sumSorted (sort pairs) []
sumSorted [] result = result
sumSorted (p:pairs) [] = sumSorted pairs [p]
sumSorted ((c,n) : pairs) ((c',n') : results)
| c == c' = sumSorted pairs ((c,n + n') : results)
| otherwise = sumSorted pairs ((c,n) : (c',n') : results)
```