Suppose 2 Maps

```
import qualified Data.Map as M
sparse1, sparse2 :: M.Map Int Float
sparse1 = M.fromList [(1,2.0),(10,3),(12,5),(100,7),(102,11)]
sparse2 = M.fromList [(2,13.0),(11,17),(12,19),(101,23),(102,29)]
```

How do you define an elegant function

```
combi :: M.Map Int Float -> M.Map Int Float -> Float
```

such that combi sparse1 sparse2 returns 414.0 (= 5 * 19 + 11 * 29) because 12 and 102 are the only common keys of the two maps ? There is an elegant (simple and efficient) function with lists since those would be strictly ordered:

```
combiList xs ys = cL xs ys 0
cL [] _ acc = acc
cL _ [] acc = acc
cL (x@(k,r):xs) (y@(k',r'):ys) acc
| k < k' = cL xs (y:ys) acc
| k == k' = cL xs ys (acc+r*r')
| k > k' = cL (x:xs) ys acc
```

But is

```
combi m1 m2 = combiList (M.toList m1) (M.toList m2)
```

a good idea knowing the lists are no more used in the rest of the code ? And if not, how would you efficiently write combi without toList ?