Nearly Optimal Average-Case Complexity of Counting Bicliques Under SETH

Abstract

In this paper, we seek a natural problem and a natural distribution of instances such that any O(nc-ε)-time algorithm fails to solve most instances drawn from the distribution, while the problem admits an nc+o(1)-time algorithm that correctly solves all instances. Specifically, we consider the Ka,b counting problem in a random bipartite graph, where Ka,b is a complete bipartite graph for constants a and b. We proved that the Ka,b counting problem admits an na+o(1)-time algorithm if a≥ 8, while any na-ε-time algorithm fails to solve it even on random bipartite graph for any constant ε>0 under the Strong Exponential Time Hypotheis. Then, we amplify the hardness of this problem using the direct product theorem and Yao's XOR lemma by presenting a general framework of hardness amplification in the setting of fine-grained complexity.