Low-Latency Hardware Masking with Application to AES

Authors

  • Pascal Sasdrich Rambus Cryptography Research, 425 Market Street, 11th Floor, San Francisco, CA 94105, United States
  • Begül Bilgin Rambus Cryptography Research, 425 Market Street, 11th Floor, San Francisco, CA 94105, United States
  • Michael Hutter Rambus Cryptography Research, 425 Market Street, 11th Floor, San Francisco, CA 94105, United States
  • Mark E. Marson Rambus Cryptography Research, 425 Market Street, 11th Floor, San Francisco, CA 94105, United States

DOI:

https://doi.org/10.13154/tches.v2020.i2.300-326

Keywords:

AES, Low-Latency Hardware, LMDPL, Masking, Secure Logic Styles, Differential Power Analysis, TVLA, Embedded Security

Abstract

During the past two decades there has been a great deal of research published on masked hardware implementations of AES and other cryptographic primitives. Unfortunately, many hardware masking techniques can lead to increased latency compared to unprotected circuits for algorithms such as AES, due to the high-degree of nonlinear functions in their designs. In this paper, we present a hardware masking technique which does not increase the latency for such algorithms. It is based on the LUT-based Masked Dual-Rail with Pre-charge Logic (LMDPL) technique presented at CHES 2014. First, we show 1-glitch extended strong noninterference of a nonlinear LMDPL gadget under the 1-glitch extended probing model. We then use this knowledge to design an AES implementation which computes a full AES-128 operation in 10 cycles and a full AES-256 operation in 14 cycles. We perform practical side-channel analysis of our implementation using the Test Vector Leakage Assessment (TVLA) methodology and analyze univariate as well as bivariate t-statistics to demonstrate its DPA resistance level.

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Published

2020-03-02

Issue

Section

Articles

How to Cite

Low-Latency Hardware Masking with Application to AES. (2020). IACR Transactions on Cryptographic Hardware and Embedded Systems, 2020(2), 300-326. https://doi.org/10.13154/tches.v2020.i2.300-326