For many problems I see the solution recommended is to use a unionfind data structure. I tried to read about it and think about how it is implemented (using C++). My current understanding is that it is nothing but a list of sets. So to find which set an element belongs we require n*log n
operations. And when we have to perform union, then we have to find the two sets which needs to be merged and do a set_union
on them. This doesn't look terribly efficient to me. Is my understanding of this data structure correct or am I missing something?



The data structure can be represented as a tree, with branches reversed (instead of pointing down, the branches point upwards to the parentand link a child with its parent). If I remember correctly, it can be shown (easily):
A more involved proof can show that when you combine both optimizations, you obtain an average complexity that is the inverse of ackermann, and this was Tarjan's main invention for this structure. It was later shown, I believe, that for some specific usage patterns, this complexity is actually constant. But I don't think it was ever proven that it is globally constant (though for all practical purpose inverse of ackermann is about 4). 


A proper unionfind data structure uses path compression during every find. This amortizes the cost and each operation is then proportional to the inverse of the ackermann function which basically makes it constant (but not quite). If you are implementing it from scratch then I would suggest using a treebased approach. 


A simple unionset structure keeps an array (element > set), making finding which set constant time; updating them is amortized log n time and concatenating the lists is constant. Not as quick as some of the approaches above, but trivial to program and more then good enough to improve the BigO running time of, say, Kruskal's Minimal Spanning Tree Algorithm. 


This is quite late reply, but this has probably not been answered elsewhere on stackoverflow, and since this is top most page for someone searching for unionfind, here is the detailed solution. FindUnion is a very fast operation, performing in near constant time. It follows Jeremie's insights of path compression, and tracking set sizes. Path compression is performed on each find operation itself, thereby taking amortized lg*(n) time. lg* is the inverse Ackerman function, growing so very slow that it is rarely beyond 5 (at least till n< 2^65535). Union/Merge sets is performed lazy, by just pointing 1 root to another, specifically smaller set's root to larger set's root, which is completed in constant time. Refer the below code from https://github.com/kartikkukreja/blogcodes/blob/master/src/Union%20Find%20%28Disjoint%20Set%29%20Data%20Structure.cpp
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