This is a draft programme and probably still subject to change. All times are in CEST/UTC+2.

09:00 Opening and Workshop Introduction
09:15 Invited Talk: The Case for System Integrity Monitors based on A Hardware Memory Snooper
Prof. Brent Byunghoon Kang (KAIST)
10:15 Break (Coffee)
10:30 BugsBunny: Hopping to RTL Targets with a Directed Hardware-Design Fuzzer
Hany Ragab, Koen Koning, Cristiano Giuffrida and Herbert Bos
11:00 Invited Talk: Hardware-assisted memory protection
Dr. Jan-Erik Ekberg (Huawei)
12:00 Break (Lunch)
13:00 Invited Talk: Principled foundations for microarchitectural security
Prof. Marco Guarnieri (IMDEA)
14:00 Work in progress: A formally verified shadow stack for RISC-V
Matthieu Baty, Guillaume Hiet and Pierre Wilke
14:30 Break (whatever)
14:45 BEERR: Bench of Embedded system Experiments for Reproducible Research
Paul Olivier, Huy Ngo Xuan and Aurélien Francillon
15:15 Invited Talk: Configuring Security for Intermittent Computing
Dr. Archanaa Krishnan (Texas Instruments)
16:15 Break (Coffee)
16:30 Short Talks and Discussion (details to be announced)
18:00 Closing Remarks

Presentation Details

Invited Talk: The Case for System Integrity Monitors based on A Hardware Memory Snooper

Speaker: Prof. Brent Byunghoon Kang (KAIST)
Graduate School of Information Security, School of Computing at KAIST

Abstract: The advanced malware binaries have shown great sophistication in compromising system kernel, persisting their attacks against the host system without being detected. To counter this serious threat, our team has been working on creating a series of system integrity monitors based on snooping on the kernel activities with no performance hits on the host system.
I will introduce our first prototype, called Vigilare, a kernel integrity monitor architected to snoop on the bus traffic of the host system from separate independent hardware. This snoop-based monitoring of Vigilare overcomes the limitations of the previous snapshot-based monitoring solutions that cannot detect transient attacks that occur in between snapshots. Vigilare snoops the bus traffic on the host and can catch all the transient attacks with no performance degradation. In contrast, the snapshot-based monitor could not detect all the attacks and induced considerable performance degradation.
I will further describe KI-Mon as our next effort to protect dynamic kernel regions. Monitoring dynamic data structures manipulated by modern advanced rootkits has been considered a complex and challenging problem as they are frequently and constantly modified during normal operations of the kernel. I will present how we addressed the challenges in tracking mutable data objects by creating an advanced snooper module with a white-listed values filter that can also provide on-demand verification of related data structures to assure the semantic invariants of dynamic data structures.
Finally, I will present an “Address Translation Redirection Attack” (ATRA)” that may allow an attacker to evade all the existing hardware-based monitors. ATRA exploits the memory management subsystem required for translating the virtual address space in which all the programs execute into the physical address space that the actual machine hardware operates on. This work motivated the importance of hardening the memory translation mechanism to ensure robust hardware-based kernel integrity monitors.

Speaker's Bio: Brent ByungHoon Kang received Ph.D. in Computer Science from the University of California at Berkeley, an M.S. from the University of Maryland at College Park, and a B.S. from Seoul National University. He is a professor at the School of Computing at KAIST and has served as Chief Professor of the Graduate School of Information Security. He has also been with George Mason University as an associate professor in the Volgenau School of Engineering. His academic services include Program Committee for IEEE Security and Privacy, ACM CCS, USENIX SECURITY, and NDSS.
His research interests include designing Trusted Computing Environment (TCE) and securing host systems based on the TCE (e.g., System integrity monitors, HW-based trusted execution environment, Memory address translation integrity, Code-Reuse-Attack (CRA) defenses, Heap memory defenses, Malware analysis, and Dialects computing).
He has advised and educated the next-generation cyber security researchers, managers, the federal workforce, and policymakers. He has created a series of NSF-funded hands-on Information Assurance (IA) education programs. His research efforts have been sponsored by IITP, ONR, NRF, NSF, IARPA, ARO, ADD, NSRi, ETRI, TIAA-CREF Faculty Fellowship, Bank of America, SK Telecom, and Samsung.

BugsBunny: Hopping to RTL Targets with a Directed Hardware-Design Fuzzer

Authors: Hany Ragab, Koen Koning, Cristiano Giuffrida and Herbert Bos

Abstract: Recent attacks on modern processors have demonstrated the severe consequences of discovering and exploiting hardware vulnerabilities. Simultaneously, the increasing complexity of modern chip designs and the ever-limited testing time presents numerous challenges to existing pre-silicon hardware-design verification tools.
Fuzzing is increasingly the technique of choice for discovering software vulnerabilities, but the same cannot be said about fuzzing for hardware designs vulnerabilities. Due to the data-flow nature of how hardware is designed, existing software fuzzing solutions cannot be readily applied in the hardware context, and the performance of the proposed hardware fuzzing solutions suffers from state explosion when applied on complex hardware designs.
In this work, we present BugsBunny, a feedback-guided directed hardware-design fuzzer which aims to reduce the costs of pre-silicon validation. BugsBunny focusses the testing resources only on the relevant parts of the design-under-test (DUT), by fuzzing towards a certain target state of the DUT and eliminating irrelevant parts of the design. We propose a novel distance-to-target feedback metric, capable of directing and guiding the fuzzer towards the desired target state, which is based on lightweight data-flow analysis and instrumentation of the DUT. By running the DUT on an FPGA, BugsBunny achieves high fuzzing throughput, outperforming existing simulation-based solutions.
We perform an end-to-end evaluation of BugsBunny on complex SoC designs (e.g., the RISC-V BOOM), where preliminary experiments demonstrate a significant reduction in the number of fuzzing seeds that are required before the DUT reaches the target state.

Paper: silm2022-bugsbunny.pdf

Invited Talk: Hardware-assisted memory protection

Speaker: Dr. Jan-Erik Ekberg (Huawei)

Abstract: Contemporary and soon-to emerge commercial processors carry architectural features that, when used, allows for authentication of register content when such are stored in memory, memory tagging (or coloring) so that mutually exclusive memory domains at a high resolution can be set up. Flow-control features such as shadow stacks and branch-target protections complete the picture. My talk will be about recent and ongoing research where we leverage these features in the compiler pipeline or by software design -- providing solutions for call-flow integrity and data safety for both user-space programs and code at higher privilege levels. My intent is to provide a panorama and share insight into how these features can be leveraged for security, as well as to shed light on the functional and performance cost of doing so.

Speaker's Bio: Dr. Jan-Erik Ekberg has worked in the telecom industry with the topic of securing mobile and embedded devices for 20+ years. He has participated in security standardization (Mobile TPM, WLAN, BT, BLE security, GP TEE standards) and he is the holder of 80+ patent families in the field of trusted execution environments, secure enclaves, smart cards etc. Jan-Erik's current affiliation is Head of Helsinki System Security Laboratory in Huawei, Finland, but he also serves as adjunct professor in Computer Science (Security) in his alma mater, Aalto University. One of Jan-Erik's recent research interests is on hardware-assisted memory protection technologies, and how these are efficiently used to mitigate attacks in contemporary computing devices.

Invited Talk: Principled foundations for microarchitectural security

Speaker: Prof. Marco Guarnieri (IMDEA)

Abstract: Microarchitectural attacks, such as Spectre and Meltdown, illustrate that artifacts of hardware implementations (like speculative and out-of-order execution) can result in measurable side-effects on program execution time that attackers can exploit to compromise a system’s security. These attacks arise from emerging behaviors obtained when combining hardware and software. Building systems that are resistant against these attacks requires fundamentally rethinking the design of existing security mechanisms.
In this talk, I will focus on speculative execution attacks--a specific class of microarchitectural attacks--and I will illustrate a principled approach for reasoning about security against these attacks. The key component of this approach is a hardware-software contract, a formal ISA-level specification of the information that may be leaked through microarchitectural side-effects. Concretely, I will present (1) how to model the information flows at the core of Spectre-style attacks, (2) how to formalize hardware-software contracts, (3) how to use contracts to reason about the security of hardware and software.

Speaker's Bio: Marco Guarnieri is an assistant professor at the IMDEA Software Institute. Before that, he completed a Ph.D. at the Institute of Information Security at ETH Zurich.
His research focuses on the design, analysis, and implementation of practical systems for securely storing and processing sensitive data. He applies his research to the analysis of micro-architectural side-channel attacks (and countermeasures) and to database security.

Work in progress: A formally verified shadow stack for RISC-V

Authors: Matthieu Baty, Guillaume Hiet and Pierre Wilke

Abstract: In recent years, the disclosure of several significant security vulnerabilities such as Spectre and Meltdown has revealed the trust put in some presumed security properties of commonplace hardware to be misplaced. A way of rebuilding this trust would be to make these security properties explicit and offer corresponding computer-checked proofs.
Formally proving security properties about hardware systems might seem prohibitively complex and expensive. This paper addresses this concern by describing a realistic and accessible methodology for specifying and proving security properties during hardware development. We describe the formal specification and implementation of a shadow stack mechanism on an RV32I processor. Our final objective would be to prove that this security mechanism is correct, i.e., any illegal modification of a return address does indeed result in the termination of the whole system.

Paper: silm2022-shadowstack.pdf

BEERR: Bench of Embedded system Experiments for Reproducible Research

Authors: Paul Olivier, Huy Ngo Xuan and Aurélien Francillon

Abstract: Reproducing experiments is a key component to further research and knowledge. Testbeds provide a controlled and configurable environment in which experiments can be conducted in a repeatable and observable manner. In the field of system security, and binary analysis, several challenges hinder reproducible research, in particular when code is interacting tightly with low level hardware and physical devices. In those conditions, dynamic analysis techniques often require the physical device to correctly complete (hardware-in-the-loop). In recent years many re-hosting techniques have been developed and evaluating their respective performance requires to compare them with an hardware-in-the-loop evaluation. However, it is challenging to share, acquire or maintain the original devices.
In this paper, we tackle this problem by proposing a new infrastructure, and online service called "Bench of Embedded system Experiments for Reproducible Research" (BEERR). It aims to both make physical devices available remotely and facilitate the setup and reproduction of published experiments.

Paper: silm2022-beerr.pdf

Invited Talk: Configuring Security for Intermittent Computing

Speaker: Dr. Archanaa Krishnan (Texas Instruments)

Abstract: Intermittent computing devices are powered by energy harvested from ambient sources. They are ideal as edge devices in several applications, such as medical implants, energy meters, and the outer space, because of their energy autonomous operation. The security for intermittent computing lies at the intersection of the world of intermittent computing and the world of secure embedded devices. This talk will provide an introduction on the what, when, why, and how to secure an embedded device at the intersection of these two worlds. It will provide several design factors between the two worlds that affect the net performance of secure intermittent systems. It will also provide insight into combining key software and hardware concepts towards designing a secure intermittent system.

Speaker's Bio: Archanaa S. Krishnan is working at Texas Instruments' Software R&D team designing and implementing security features for wireless connectivity devices including the security for Texas Instruments' Wireless Battery Management Protocol. She received her Ph.D. in Computer Engineering from the Secure Embedded Systems Lab, Virginia Tech. During her Ph.D., she was a visiting scholar at the Vernam Lab in Worcester Polytechnique Institute in 2020-21. She also obtained her M.S. in Computer Engineering from Virginia Tech and B. Tech in Electrical and Electronics Engineering from Vellore Institute of Technology.

Short Talks and Discussion

Details to be announced.