Local Search for Clustering in Almost-linear Time
Abstract
We propose the first local search algorithm for Euclidean clustering that attains an O(1)-approximation in almost-linear time. Specifically, for Euclidean k-Means, our algorithm achieves an O(c)-approximation in O(n1 + 1 / c) time, for any constant c 1, maintaining the same running time as the previous (non-local-search-based) approach [la Tour and Saulpic, arXiv'2407.11217] while improving the approximation factor from O(c6) to O(c). The algorithm generalizes to any metric space with sparse spanners, delivering efficient constant approximation in p metrics, doubling metrics, Jaccard metrics, etc. This generality derives from our main technical contribution: a local search algorithm on general graphs that obtains an O(1)-approximation in almost-linear time. We establish this through a new 1-swap local search framework featuring a novel swap selection rule. At a high level, this rule ``scores'' every possible swap, based on both its modification to the clustering and its improvement to the clustering objective, and then selects those high-scoring swaps. To implement this, we design a new data structure for maintaining approximate nearest neighbors with amortized guarantees tailored to our framework.
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