New Graph Decompositions and Combinatorial Boolean Matrix Multiplication Algorithms
Abstract
We revisit the fundamental Boolean Matrix Multiplication (BMM) problem. With the invention of algebraic fast matrix multiplication over 50 years ago, it also became known that BMM can be solved in truly subcubic O(nω) time, where ω<3; much work has gone into bringing ω closer to 2. Since then, a parallel line of work has sought comparably fast combinatorial algorithms but with limited success. The naive O(n3)-time algorithm was initially improved by a 2n factor [Arlazarov et al.; RAS'70], then by 2.25n [Bansal and Williams; FOCS'09], then by 3n [Chan; SODA'15], and finally by 4n [Yu; ICALP'15]. We design a combinatorial algorithm for BMM running in time n3 / 2([7] n) -- a speed-up over cubic time that is stronger than any poly-log factor. This comes tantalizingly close to refuting the conjecture from the 90s that truly subcubic combinatorial algorithms for BMM are impossible. This popular conjecture is the basis for dozens of fine-grained hardness results. Our main technical contribution is a new regularity decomposition theorem for Boolean matrices (or equivalently, bipartite graphs) under a notion of regularity that was recently introduced and analyzed analytically in the context of communication complexity [Kelley, Lovett, Meka; arXiv'23], and is related to a similar notion from the recent work on 3-term arithmetic progression free sets [Kelley, Meka; FOCS'23].
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.