Centralized vs Decentralized Targeted Brute-Force Attacks: Guessing with Side-Information

TL;DR

This paper analyzes the effectiveness of coordinated versus uncoordinated distributed brute-force attacks using side-information, providing asymptotic expressions and demonstrating the significant advantage of coordination in password guessing scenarios.

Contribution

It derives asymptotic formulas for both attack strategies under memoryless side-information channels, highlighting the value of coordination in distributed password guessing.

Findings

Coordinated attacks outperform uncoordinated ones asymptotically.

Sharing side-information significantly improves attack success.

Results are illustrated for binary symmetric and erasure channels.

Abstract

According to recent empirical studies, a majority of users have the same, or very similar, passwords across multiple password-secured online services. This practice can have disastrous consequences, as one password being compromised puts all the other accounts at much higher risk. Generally, an adversary may use any side-information he/she possesses about the user, be it demographic information, password reuse on a previously compromised account, or any other relevant information to devise a better brute-force strategy (so called targeted attack). In this work, we consider a distributed brute-force attack scenario in which $m$ adversaries, each observing some side information, attempt breaching a password secured system. We compare two strategies: an uncoordinated attack in which the adversaries query the system based on their own side-information until they find the correct password, and a fully coordinated attack in which the adversaries pool their side-information and query the system together. For passwords $\mathbf{X}$ of length $n$, generated independently and identically from a distribution $P_X$, we establish an asymptotic closed-form expression for the uncoordinated and coordinated strategies when the side-information $\mathbf{Y}_{(m)}$ are generated independently from passing $\mathbf{X}$ through a memoryless channel $P_{Y|X}$, as the length of the password $n$ goes to infinity. We illustrate our results for binary symmetric channels and binary erasure channels, two families of side-information channels which model password reuse. We demonstrate that two coordinated agents perform asymptotically better than any finite number of uncoordinated agents for these channels, meaning that sharing side-information is very valuable in distributed attacks.