# Why does Data.Set require elements to be an instance of Ord?

This doesn't work

``````data Cutlery = Knife | Fork deriving (Show,Eq)
let x = [Knife,Fork]
let set1 = Set.fromList x
``````

while defining

``````data Cutlery = Knife | Fork deriving (Show,Ord,Eq)
``````

solves the issue but doesn't make sense. Is Data.Set different than the mathematical definition of a set?

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A `Data.Set` captures the mathematical abstraction of a set, but it is not identical. The main difference is that a `Data.Set` requires its elements to be ordered, whereas a mathematical set only requires that its elements be comparable for equality.

The reason for requiring `Ord` is efficiency. It would be perfectly possible to build a set abstraction by defining

``````data Set a = Set [a]
``````

i.e. under the hood it is just a list, and we make sure we never insert duplicate elements. The `elem` and `insert` operations would be

``````elem a (Set as) = any (a ==) as

insert a (Set as) | a `elem` as = Set as
| otherwise   = Set (a:as)
``````

However, this means that both `elem` and `insert` are O(n) operations. If we want to do any better than this, the standard approaches are

1. Store the elements in a balanced binary tree (which requires an `Ord` instance)
2. Hash the elements and store them in an array (which requires a `Hashable` instance).

## TreeSet

The implementation chosen by the authors of `Data.Set` was to use a binary tree, which you can see by going to the source. The implementation is more or less

``````data Set a = Bin a (Set a) (Set a)
| Tip
``````

Now you can write the `elem` function as

``````elem :: Ord a => a -> Set a -> Bool
elem = go
where
go _  Tip = False
go x (Bin y l r) = case compare x y of
LT -> go x l
GT -> go x r
EQ -> True
``````

which is an O(log n) operation, rather than O(n). Insertions are trickier (as you need to keep the tree balanced) but similar.

## HashSet

In a hash set, you don't directly compare elements when inserting and removing them. Instead, each element is hashed to an integer, and stored in a location based on that integer.

In theory this doesn't require an `Ord` instance. In practice, you need some method of keeping track of multiple elements that hash to the same value, and the method chosen by the developers of `Data.HashSet` is to store multiple elements in a regular `Data.Set`, so it turns out you do need the `Ord` instance after all!

``````data HashSet a = HashSet (Data.IntMap.IntMap (Data.Set.Set a))
``````

It could have been written instead as

``````data HashSet a = HashSet (Data.IntMap.IntMap [a])
``````

instead, which removes out the `Ord` requirement at the cost of some inefficiency if there are many elements which has to the same value.

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In comparison to Java say there is a HashSet and a TreeSet where the elements of a TreeSet are comparable but the elements in a HashSet are not. Should Haskell employ a similar approach? – medPhys-pl Jan 2 '14 at 10:30
@medPhys-pl: the elements of HashSet need to be hashable. This is true for the Haskell implementation as well as for the Java one, only I reckon Java cheats by hashing memory adresses, which Haskell shuns because it's unsafe (identical values may have different hashes). – leftaroundabout Jan 2 '14 at 10:49
@leftaroundabout: Actually, in Java, the `Object` class has the `hashCode` and `equals` methods, and `HashMap`/`HashSet` use those; you're supposed to override them in order to get correct behavior with hash-based collections. This leads to three of the most common bugs I see among Java newcomers: (a) not knowing or forgetting to implement `hashCode` and `equals` for your map keys; (b) implementing the `hashCode` method incorrectly; and (c) implementing `hashCode` as `return toString().hashCode()`, with horrible performance... – Luis Casillas Jan 2 '14 at 22:56

Is `Data.Set` different than the mathematical definition of a set?

Obviously, mathematical sets can be uncountable infinite – you won’t be able to represent that in all generality with a computer, or even a Turing machine.

But the answer you are looking for is this: `Data.Set` is a data type based on binary trees, and needs a total linear order on the elements to know whether to put and later find something on the left or right subtree of a node. So while it would be possible to implement a set datatype without an `Ord` constraint, this particular, more efficient implementation would not.

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