Defense Against Shortest Path Attacks

Identifying shortest paths between nodes in a network is an important task in applications involving routing of resources. Recent work has shown that a malicious actor can manipulate a graph to make traffic between two nodes of interest follow their target path. In this paper, we develop a defense against such attacks by modifying the weights of the graph that users observe. The defender must balance inhibiting the attacker against any negative effects of the defense on benign users. Specifically, the defender's goals are: (a) to recommend the shortest paths possible to users, (b) for the lengths of the shortest paths in the published graph to be close to those of the same paths in the true graph, and (c) to minimize the probability of an attack. We formulate the defense as a Stackelberg game in which the defender is the leader and the attacker is the follower. In this context, we also consider a zero-sum version of the game, in which the defender's goal is to minimize cost while achieving the minimum possible attack probability. We show that this problem is NP-hard and propose heuristic solutions based on increasing edge weights along target paths in both the zero-sum and non-zero-sum settings. Relaxing some constraints of the original problem, we formulate a linear program for local optimization around a feasible point. We present defense results with both synthetic and real network datasets and show that these methods often reach the lower bound of the defender's cost.