--- title: "Union Find" date: 2024-06-24T21:07:49+01:00 draft: false # I don't care for draft mode, git has branches for that description: "My favorite data structure" tags: - algorithms - data structures - python categories: - programming series: - Cool algorithms favorite: false disable_feed: false --- To kickoff the [series]({{< ref "/series/cool-algorithms/">}}) of posts about algorithms and data structures I find interesting, I will be talking about my favorite one: the [_Disjoint Set_][wiki]. Also known as the _Union-Find_ data structure, so named because of its two main operations: `ds.union(lhs, rhs)` and `ds.find(elem)`. [wiki]: https://en.wikipedia.org/wiki/Disjoint-set_data_structure ## What does it do? The _Union-Find_ data structure allows one to store a collection of sets of elements, with operations for adding new sets, merging two sets into one, and finding the representative member of a set. Not only does it do all that, but it does it in almost constant (amortized) time! Here is a small motivating example for using the _Disjoint Set_ data structure: ```python def connected_components(graph: Graph) -> list[set[Node]]: # Initialize the disjoint set so that each node is in its own set ds: DisjointSet[Node] = DisjointSet(graph.nodes) # Each edge is a connection, merge both sides into the same set for (start, dest) in graph.edges: ds.union(start, dest) # Connected components share the same (arbitrary) root components: dict[Node, set[Node]] = defaultdict(set) for n in graph.nodes: components[ds.find(n)].add(n) # Return a list of disjoint sets corresponding to each connected component return list(components.values()) ``` ## Implementation I will show how to implement `UnionFind` for integers, though it can easily be extended to be used with arbitrary types (e.g: by mapping each element one-to-one to a distinct integer, or using a different set representation). ### Representation Creating a new disjoint set is easy enough: ```python class UnionFind: _parent: list[int] _rank: list[int] def __init__(self, size: int): # Each node is in its own set, making it its own parent... self._parents = list(range(size)) # ... And its rank 0 self._rank = [0] * size ``` We represent each set through the `_parent` field: each element of the set is linked to its parent, until the root node which is its own parent. When first initializing the structure, each element is in its own set, so we initialize each element to be a root and make it its own parent (`_parent[i] == i` for all `i`). The `_rank` field is an optimization which we will touch on in a later section. ### Find A naive Implementation of `find(...)` is simple enough to write: ```python def find(self, elem: int) -> int: # If `elem` is its own parent, then it is the root of the tree if (parent: = self._parent[elem]) == elem: return elem # Otherwise, recurse on the parent return self.find(parent) ``` However, going back up the chain of parents each time we want to find the root node (an `O(n)` operation) would make for disastrous performance. Instead we can do a small optimization called _path splitting. ```python def find(self, elem: int) -> int: while (parent: = self._parent[elem]) != elem: # Replace each parent link by a link to the grand-parent elem, self._parent[elem] = parent, self._parent[parent] return elem ``` This flattens the links so that each node links directly to the root, making each subsequent `find(...)` constant time. Other compression schemes exist, along the spectrum between faster shortening the chain faster earlier, or updating `_parent` fewer times per `find(...)`.