International Association
for Cryptologic Research

Last year CRYSTALS-Kyber was chosen by NIST as a new, post-quantum secure key encapsulation mechanism to be standardized. This makes it important to assess the resistance of CRYSTALS-Kyber implementations to physical attacks. Pure side-channel attacks on post-quantum cryptographic algorithms have already been well-explored. In this paper, we present an attack on a masked and shuffled software implementation of CRYSTALS-Kyber that combines fault injection with side-channel analysis. First, a voltage fault injection is performed to bypass the shuffling. We found settings that consistently glitch the desired instructions without crashing the device. After the successful fault injection, a deep learning-assisted profiled power analysis based on the Hamming weight leakage model is used to recover the message (shared key). We propose a partial key enumeration method that allows us to significantly increase the success rate of message recovery (from 0.122 without enumeration to 0.887 with 32 enumerated bits).