An almost-linear time algorithm for uniform random spanning tree generation

Abstract

We give an m1+o(1)βo(1)-time algorithm for generating a uniformly random spanning tree in an undirected, weighted graph with max-to-min weight ratio β. We also give an m1+o(1)ε-o(1)-time algorithm for generating a random spanning tree with total variation distance ε from the true uniform distribution. Our second algorithm's runtime does not depend on the edge weights. Our m1+o(1)βo(1)-time algorithm is the first almost-linear time algorithm for the problem --- even on unweighted graphs --- and is the first subquadratic time algorithm for sparse weighted graphs. Our algorithms improve on the random walk-based approach given in Kelner-Madry and Madry-Straszak-Tarnawski. We introduce a new way of using Laplacian solvers to shortcut a random walk. In order to fully exploit this shortcutting technique, we prove a number of new facts about electrical flows in graphs. These facts seek to better understand sets of vertices that are well-separated in the effective resistance metric in connection with Schur complements, concentration phenomena for electrical flows after conditioning on partial samples of a random spanning tree, and more.