ERASER: Early-stage Reliability And Security Estimation for RISC-V

RISC-V processors have gained acceptance across a wide range of computing domains, from IoT to embedded/mobile class and even in server-class processing systems. In processing systems ranging from connected cars and autonomous vehicles, to those on-board satellites and spacecrafts, these processors are targeted to function in safety-critical systems, where Reliability, Availability and Serviceability (RAS)-based considerations are of paramount importance. Along with potential system vulnerabilities caused primarily due to random errors, these processors may also be sensitive to targeted errors, possibly from malicious entities, which raises serious concerns regarding the security and safety of the processing system. Consequently, such systems necessitate the incorporation of RAS-based considerations right from an early stage of processor design. While the hardware and software ecosystem around RISC-V has been steadily maturing, there have, however, been limited developments in early stage reliability-aware design and verification. The Early-stage Reliability And Security Estimation for RISC-V (ERASER) tool attempts to address this shortcoming. It consists of an open source framework aimed at providing directions to incorporate such reliability and security features at an early, pre-silicon stage of design. These features may include what kind of protection to be applied and which components within the processor should they be applied to. The proposed infrastructure comprises of an open source toolchain for early stage modeling of latch vulnerability in a RISC-V core (SERMiner [1]), a tool for automated generation of stress marks that maximize the likelihood of a transient-failure induced error (Microprobe (RISC-V) [2]), and verification by means of statistical and/or targeted fault injection (Chiffre [3]). While the infrastructure is targeted towards any core that uses the RISC-V ISA, the repository provides an end-to-end flow for the Rocket core [4]. ERASER thus evaluates “RAS-readiness”, or the effectiveness of protection techniques in processor design such that processor vulnerability in terms of Failures-In-time (FIT) rate is minimized, for a specified power/performance overhead. FIT rate is defined as the number of failures in one billion hours of operation and is a standard vulnerability metric used in industry. ERASER is an open source tool available for download at https://github.com/IBM/eraser. The tool currently supports analysis of all latches in the design across a single Rocket core and the generation of stressmarks that can be used to evaluate the vulnerability of these latches. In addition to radiation-induced soft errors, we plan to extend ERASER to also model errors due to voltage noise, thermal and aging-induced failures, both in memory and logic, and generate representative stressmarks. ERASER is an initial effort to devise a comprehensive methodology for RAS analysis, particularly for open-source hardware, with the hope that it spurs further research and development into reliability-aware design both in industry and academia. References: K. Swaminathan, R. Bertran, H. Jacobson, P. Kudva, P. Bose, ‘Generation of Stressmarks for Early-stage Soft-error Modeling’, International Conference on Dependable Systems and Networks (DSN) 2019 S. Eldridge R. Bertran, A. Buyuktosunoglu, P. Bose, ‘MicroProbe: An Open Source Microbenchmark Generator, ported to the RISC-V ISA, the 7th RISC-V workshop, 2017 S. Eldridge, A. Buyuktosunoglu and P. Bose, ‘Chiffre A Configurable Hardware Fault Injection Framework for RISC-V Systems’ 2nd Workshop on Computer Architecture Research with RISC-V (CARRV), 2018 Krste Asanović, Rimas Avižienis, Jonathan Bachrach, Scott Beamer, David Biancolin, Christopher Celio, Henry Cook, Palmer Dabbelt, John Hauser, Adam Izraelevitz, Sagar Karandikar, Benjamin Keller, Donggyu Kim, John Koenig, Yunsup Lee, Eric Love, Martin Maas, Albert Magyar, Howard Mao, Miquel Moreto, Albert Ou, David Patterson, Brian Richards, Colin Schmidt, Stephen Twigg, Huy Vo, and Andrew Waterman, The Rocket Chip Generator, Technical Report UCB/EECS-2016-17, EECS Department, University of California, Berkeley, April 2016