Formal analysis of fault-injection countermeasures within a secure RISC-V processor H/F

With the rise of new development models based on open source, secure hardware components are increasingly being developed in public implementations, notably within the OpenHW Group [1]. The possibility of building a complete system from publicly available, open-source components is becoming a reality. For example, the CV32E40S RISC-V processor [2], derived from the CV32E40P [3], incorporates several hardware countermeasures against fault injection and side-channel attacks. However, a significant challenge lies in evaluating both the security level of each individual countermeasure and the overall effectiveness of these countermeasures when combined. In [4], we introduced a method for partitioning hardware designs to formally prove the security guarantees of hardware countermeasures. This approach helps to reduce the residual attack surface that needs to be analyzed when checking vulnerabilities at the software level. However, the types and granularity of the hardware countermeasures in the CV32E40S differ from those discussed in [4]. The goal of this internship is to adapt this partitioning methodology to the CV32E40S processor. A key challenge will be composing the produced countermeasure-level partitions to assess the overall security of the processor against a specific fault-injection model. Additionally, the partitioning methodology could be optimized through structural analysis of the hardware circuits, though these potential improvements have not yet been fully evaluated. Benchmarking the impact of these optimizations when building partitions could be another possible outcome of this internship.   Opportunities: Practical Application: Work on an open-source, real-world processor, the CV32E40S, and apply advanced methodologies to enhance its security Technical Skills: Develop expertise in formal analysis, security verification, and countermeasures. Publication: Potential to publish results in renowned conferences Collaboration: Work alongside experienced researchers and engineers from CEA and LIP6 Resources: Access to state-of-the-art facilities and infrastructure. [1] OpenHW Group. https://www.openhwgroup.org [2] Processeur RISC-V CV32E40S. https://github.com/openhwgroup/cv32e40s [3] Processeur RISC-V CV32E40P. https://github.com/openhwgroup/cv32e40p [4] Fault-Resistant Partitioning of Secure CPUs for System Co-Verification against Faults. S. Tollec, V. Hadzic, P. Nasahl, M. Asavoae, R. Bloem, D. Couroussé, K. Heydemann, M. Jan, S. Mangard. IACR Trans. Cryptogr. Hardw. Embed. Syst. 2024(4): 179-204 (2024) [5] µArchiFI: Formal Modeling and Verification Strategies for Microarchitectural Fault Injections. S. Tollec, M. Asavoae, D. Couroussé, K. Heydemann, et M. Jan. in FMCAD. 2023 https://doi.org/10.34727/2023/isbn.978-3-85448-060-0_18

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