International Association for Cryptologic Research

International Association
for Cryptologic Research

CryptoDB

Nicolai Müller

Publications

Year
Venue
Title
2022
TCHES
Automated Generation of Masked Hardware
Masking has been recognized as a sound and secure countermeasure for cryptographic implementations, protecting against physical side-channel attacks. Even though many different masking schemes have been presented over time, design and implementation of protected cryptographic Integrated Circuits (ICs) remains a challenging task. More specifically, correct and efficient implementation usually requires manual interactions accompanied by longstanding experience in hardware design and physical security. To this end, design and implementation of masked hardware often proves to be an error-prone task for engineers and practitioners. As a result, our novel tool for automated generation of masked hardware (AGEMA) allows even inexperienced engineers and hardware designers to create secure and efficient masked cryptograhic circuits originating from an unprotected design. More precisely, exploiting the concepts of Probe-Isolating Non-Interference (PINI) for secure composition of masked circuits, our tool provides various processing techniques to transform an unprotected design into a secure one, eventually accelerating and safeguarding the process of masking cryptographic hardware. Ultimately, we evaluate our tool in several case studies, emphasizing different trade-offs for the transformation techniques with respect to common performance metrics, such as latency, area, and randomness.
2022
TCHES
Transitional Leakage in Theory and Practice - Unveiling Security Flaws in Masked Circuits
Accelerated by the increased interconnection of highly accessible devices, the demand for effective and efficient protection of hardware designs against SCA is ever rising, causing its topical relevance to remain immense in both, academia and industry. Among a wide range of proposed countermeasures against SCA, masking is a highly promising candidate due to its sound foundations and well-understood security requirements. In addition, formal adversary models have been introduced, aiming to accurately capture real-world attack scenarios while remaining sufficiently simple to efficiently reason about the SCA resilience of designs. Here, the d-probing model is the most prominent and well-studied adversary model. Its extension, introduced as the robust d-probing model, covers physical defaults occurring in hardware implementations, particularly focusing on combinational recombinations (glitches), memory recombinations (transitions), and routing recombinations (coupling). With increasing complexity of modern cryptographic designs and logic circuits, formal security verification becomes ever more cumbersome. This started to spark innovative research on automated verification frameworks. Unfortunately, these verification frameworks mostly focus on security verification of hardware circuits in the presence of glitches, but remain limited in identification and verification of transitional leakage. To this end, we extend SILVER, a recently proposed tool for formal security verification of masked logic circuits, to also detect and verify information leakage resulting from combinations of glitches and transitions. Based on extensive case studies, we further confirm the accuracy and practical relevance of our methodology when assessing and verifying information leakage in hardware implementations.
2022
TCHES
Transitional Leakage in Theory and Practice: Unveiling Security Flaws in Masked Circuits
Accelerated by the increased interconnection of highly accessible devices, the demand for effective and efficient protection of hardware designs against Side-Channel Analysis (SCA) is ever rising, causing its topical relevance to remain immense in both, academia and industry. Among a wide range of proposed countermeasures against SCA, masking is a highly promising candidate due to its sound foundations and well-understood security requirements. In addition, formal adversary models have been introduced, aiming to accurately capture real-world attack scenarios while remaining sufficiently simple to efficiently reason about the SCA resilience of designs. Here, the d-probing model is the most prominent and well-studied adversary model. Its extension, introduced as the robust d-probing model, covers physical defaults occurring in hardware implementations, particularly focusing on combinational recombinations (glitches), memory recombinations (transitions), and routing recombinations (coupling).With increasing complexity of modern cryptographic designs and logic circuits, formal security verification becomes ever more cumbersome. This started to spark innovative research on automated verification frameworks. Unfortunately, these verification frameworks mostly focus on security verification of hardware circuits in the presence of glitches, but remain limited in identification and verification of transitional leakage. To this end, we extend SILVER, a recently proposed tool for formal security verification of masked logic circuits, to also detect and verify information leakage resulting from combinations of glitches and transitions. Based on extensive case studies, we further confirm the accuracy and practical relevance of our methodology when assessing and verifying information leakage in hardware implementations.
2021
TCHES
Automated Generation of Masked Hardware
Masking has been recognized as a sound and secure countermeasure for cryptographic implementations, protecting against physical side-channel attacks. Even though many different masking schemes have been presented over time, design and implementation of protected cryptographic Integrated Circuits (ICs) remains a challenging task. More specifically, correct and efficient implementation usually requires manual interactions accompanied by longstanding experience in hardware design and physical security. To this end, design and implementation of masked hardware often proves to be an error-prone task for engineers and practitioners. As a result, our novel tool for automated generation of masked hardware (AGEMA) allows even inexperienced engineers and hardware designers to create secure and efficient masked cryptograhic circuits originating from an unprotected design. More precisely, exploiting the concepts of Probe-Isolating Non-Interference (PINI) for secure composition of masked circuits, our tool provides various processing techniques to transform an unprotected design into a secure one, eventually accelerating and safeguarding the process of masking cryptographic hardware. Ultimately, we evaluate our tool in several case studies, emphasizing different trade-offs for the transformation techniques with respect to common performance metrics, such as latency, area, andrandomness.

Coauthors

David Knichel (4)
Amir Moradi (4)
Pascal Sasdrich (4)