Paper 2014/386
Chaskey: An Efficient MAC Algorithm for 32-bit Microcontrollers
Nicky Mouha and Bart Mennink and Anthony Van Herrewege and Dai Watanabe and Bart Preneel and Ingrid Verbauwhede
Abstract
We propose Chaskey: a very efficient Message Authentication Code (MAC) algorithm for 32-bit microcontrollers. It is intended for applications that require 128-bit security, yet cannot implement standard MAC algorithms because of stringent requirements on speed, energy consumption, or code size. Chaskey is a permutation-based MAC algorithm that uses the Addition-Rotation-XOR (ARX) design methodology. We formally prove that Chaskey is secure in the standard model, based on the security of an underlying Even-Mansour block cipher. Chaskey is designed to perform well on a wide range of 32-bit microcontrollers. Our benchmarks show that on the ARM Cortex-M3/M4, our Chaskey implementation reaches a speed of 7.0 cycles/byte, compared to 89.4 cycles/byte for AES-128-CMAC. For the ARM Cortex-M0, our benchmark results give 16.9 cycles/byte and 136.5 cycles/byte for Chaskey and AES-128-CMAC respectively.
Metadata
- Available format(s)
- Category
- Secret-key cryptography
- Publication info
- Preprint. MINOR revision.
- Keywords
- MicrocontrollerMessage Authentication CodeStandard Model SecurityPermutation-BasedARX
- Contact author(s)
- Nicky Mouha @ esat kuleuven be
- History
- 2015-03-20: last of 3 revisions
- 2014-05-30: received
- See all versions
- Short URL
- https://ia.cr/2014/386
- License
-
CC BY