Cryptology ePrint Archive: Report 2013/773

CBEAM: Efficient Authenticated Encryption from Feebly One-Way $\phi$ Functions

Markku-Juhani O. Saarinen

Abstract: We show how efficient and secure cryptographic mixing functions can be constructed from low-degree rotation-invariant $\phi$ functions rather than conventional S-Boxes. These novel functions have surprising properties; many exhibit inherent feeble (Boolean circuit) one-wayness and offer speed/area tradeoffs unobtainable with traditional constructs. Recent theoretical results indicate that even if the inverse is not explicitly computed in an implementation, its degree plays a fundamental role to the security of the iterated composition. To illustrate these properties, we present CBEAM, a Cryptographic Sponge Permutation based on a single $5 \times 1$-bit Boolean function. This simple nonlinear function is used to construct a 16-bit rotation-invariant$\phi$ function of Degree 4 (but with a very complex Degree 11 inverse), which in turn is expanded into an efficient 256-bit mixing function. In addition to flexible tradeoffs in hardware we show that efficient implementation strategies exist for software platforms ranging from low-end microcontrollers to the very latest x86-64 AVX2 instruction set. A rotational bit-sliced software implementation offers not only comparable speeds to AES but also increased security against cache side channel attacks. Our construction supports Sponge-based Authenticated Encryption, Hashing, and PRF/PRNG modes and is highly useful as a compact ``all-in-one'' primitive for pervasive security.

Category / Keywords: secret-key cryptography / CBEAM, Authenticated Encryption, Cryptographic Sponge Functions, Trapdoor $\phi$ functions, Lightweight Cryptography

Original Publication (with minor differences): CT-RSA 2014

Date: received 21 Nov 2013, last revised 12 Dec 2013

Contact author: mjos at iki fi

Available format(s): PDF | BibTeX Citation

Note: Accepted to Cryptographers' Track, RSA Conference USA 2014 (CT-RSA 2014), 25--28 February 2014, San Francisco, US.

Version: 20131212:174846 (All versions of this report)

Short URL:

[ Cryptology ePrint archive ]