This research was supported by the European Union Regional Development Fund within the framework of the ERDF Operational Program of Catalonia 2014-2020 with a grant of 50% of the total cost eligible, under the DRAC project [001- P-001723]. It was also supported by the Spanish goverment (grant RTI2018-095094-B-C21 “CONSENT”), by the Spanish Ministry of Science and Innovation (contracts PID2019- 107255GB-C21, PID2019-107255GB-C21) and by the Catalan Government (contracts 2017-SGR-1414, 2017-SGR-705). This work has also received funding from the European Union Horizon 2020 research and innovation programme under grant agreement No. 871467. V. Kostalabros has been partially supported by the Agency for Management of University and Research Grants (AGAUR) of the Government of Catalonia under "Ajuts per a la contractació de personal investigador novell" fellowship No. 2019FI B01274. M. Moreto was also partially supported by the Spanish Ministry of Economy, Industry and Competitiveness under "Ramón y Cajal" fellowship No. RYC-2016-21104.

While quantum computers are rapidly becoming more powerful, the current cryptographic infrastructure is imminently threatened. In a preventive manner, the U.S. National Institute of Standards and Technology (NIST) has initiated a process to evaluate quantum-resistant cryptosystems, to form the first post-quantum (PQ) cryptographic standard. Classic McEliece (CM) is one of the most prominent cryptosystems considered for standardization in NIST’s PQ cryptography contest. However, its computational cost poses notable challenges to a big fraction of existing computing devices. This work presents an HLS-based, HW/SW co-design acceleration of the CM Key Encapsulation Mechanism (CM KEM). We demonstrate significant maximum speedups of up to 55.2 ×, 3.3 ×, and 8.7 × in the CM KEM algorithms of key generation, encapsulation, and decapsulation respectively, comparing to a SW-only scalar implementation.

Peer Reviewed