Sublinear-Time Decremental Algorithms for Single-Source Reachability and Shortest Paths on Directed Graphs

Abstract

We consider dynamic algorithms for maintaining Single-Source Reachability (SSR) and approximate Single-Source Shortest Paths (SSSP) on n-node m-edge directed graphs under edge deletions (decremental algorithms). The previous fastest algorithm for SSR and SSSP goes back three decades to Even and Shiloach [JACM 1981]; it has O(1) query time and O (mn) total update time (i.e., linear amortized update time if all edges are deleted). This algorithm serves as a building block for several other dynamic algorithms. The question whether its total update time can be improved is a major, long standing, open problem. In this paper, we answer this question affirmatively. We obtain a randomized algorithm with an expected total update time of O( (m7/6 n2/3 + o(1), m3/4 n5/4 + o(1)) ) = O (m n9/10 + o(1)) for SSR and (1+ε)-approximate SSSP if the edge weights are integers from 1 to W ≤ 2^cn and ε ≥ 1 / cn for some constant c . We also extend our algorithm to achieve roughly the same running time for Strongly Connected Components (SCC), improving the algorithm of Roditty and Zwick [FOCS 2002]. Our algorithm is most efficient for sparse and dense graphs. When m = (n) its running time is O (n1 + 5/6 + o(1)) and when m = (n2) its running time is O (n2 + 3/4 + o(1)) . For SSR we also obtain an algorithm that is faster for dense graphs and has a total update time of O ( m2/3 n4/3 + o(1) + m3/7 n12/7 + o(1)) which is O (n2 + 2/3) when m = (n2) . All our algorithms have constant query time in the worst case and are correct with high probability against an oblivious adversary.