For an automata algorithm, I require a fast Union-Find data structure in a functional language. Since I need to formally prove the correctness of the data structure, I would prefer a simple structure.

What I am trying to do is to compute the equivalence classes of elements in a set `S`

w.r.t. a relation `R ⊆ S × S`

. What I want to get out in the end is some function `f: S → S`

that maps any element of `S`

to a (canonical) representative of its `R`

-equivalence class. By "canonical", I mean that I don't care which representative it is as long as it is the same for all elements of one equivalence class, i.e. I want `f x = f y ⟺ (x,y) ∈ R`

to hold.

What would the best data structure and algorithm for this be in a functional language? I should add that I really need "normal" functional code, i.e. no mutability/state transformer monads.

EDIT: In the mean time, I have come up with this algorithm:

```
m := empty map
for each s ∈ S do
if m s = None then
for each t in {t | (s,t) ∈ R}
m := m[t ↦ s]
```

This creates a map that maps any element of `S`

to the representative of its equivalence class, where the representative is the first element that is reached by the iteration over `S`

. I think this actually has linear time (if map operations are constant). However, I am still interested in other solutions, since I don't know how efficient this is in practice.

(my relation is internally represented as a "S → (S Set) option", hence the iteration over {t | (s,t) ∈ R} - this is a cheap operation on that structure.)