The Advice Complexity of a Class of Hard Online Problems

Abstract

The advice complexity of an online problem is a measure of how much knowledge of the future an online algorithm needs in order to achieve a certain competitive ratio. Using advice complexity, we define the first online complexity class, AOC. The class includes independent set, vertex cover, dominating set, and several others as complete problems. AOC-complete problems are hard, since a single wrong answer by the online algorithm can have devastating consequences. For each of these problems, we show that (1+(c-1)c-1/cc)n= (n/c) bits of advice are necessary and sufficient (up to an additive term of O( n)) to achieve a competitive ratio of c. The results are obtained by introducing a new string guessing problem related to those of Emek et al. (TCS 2011) and B\"ockenhauer et al. (TCS 2014). It turns out that this gives a powerful but easy-to-use method for providing both upper and lower bounds on the advice complexity of an entire class of online problems, the AOC-complete problems. Previous results of Halld\'orsson et al. (TCS 2002) on online independent set, in a related model, imply that the advice complexity of the problem is (n/c). Our results improve on this by providing an exact formula for the higher-order term. For online disjoint path allocation, B\"ockenhauer et al. (ISAAC 2009) gave a lower bound of (n/c) and an upper bound of O((n c)/c) on the advice complexity. We improve on the upper bound by a factor of c. For the remaining problems, no bounds on their advice complexity were previously known.