Exact Distance Oracles for Planar Graphs

Abstract

We present new and improved data structures that answer exact node-to-node distance queries in planar graphs. Such data structures are also known as distance oracles. For any directed planar graph on n nodes with non-negative lengths we obtain the following: * Given a desired space allocation S∈[n n,n2], we show how to construct in O(S) time a data structure of size O(S) that answers distance queries in O(n/ S) time per query. As a consequence, we obtain an improvement over the fastest algorithm for k-many distances in planar graphs whenever k∈[ n,n). * We provide a linear-space exact distance oracle for planar graphs with query time O(n1/2+eps) for any constant eps>0. This is the first such data structure with provable sublinear query time. * For edge lengths at least one, we provide an exact distance oracle of space O(n) such that for any pair of nodes at distance D the query time is O(min D, n). Comparable query performance had been observed experimentally but has never been explained theoretically. Our data structures are based on the following new tool: given a non-self-crossing cycle C with c = O( n) nodes, we can preprocess G in O(n) time to produce a data structure of size O(n c) that can answer the following queries in O(c) time: for a query node u, output the distance from u to all the nodes of C. This data structure builds on and extends a related data structure of Klein (SODA'05), which reports distances to the boundary of a face, rather than a cycle. The best distance oracles for planar graphs until the current work are due to Cabello (SODA'06), Djidjev (WG'96), and Fakcharoenphol and Rao (FOCS'01). For σ∈(1,4/3) and space S=nσ, we essentially improve the query time from n2/S to n2/S.