Subversion-resilient signature schemes

Conference contribution
(Conference Contribution)

Publication Details

Author(s): Ateniese G, Magri B, Venturi D
Publisher: Association for Computing Machinery
Publication year: 2015
Pages range: 364-375
ISBN: 9781450338325


We provide a formal treatment of security of digital signatures against subversion attacks (SAs). Our model of subversion generalizes previous work in several directions, and is inspired by the proliferation of software attacks (e.g., malware and buffer overflow attacks), and by the recent revelations of Edward Snowden about intelligence agencies trying to surreptitiously sabotage cryptographic algorithms. The main security requirement we put forward demands that a signature scheme should remain unforgeable even in the presence of an attacker applying SAs (within a certain class of allowed attacks) in a fully-adaptive and continuous fashion. Previous notions - e.g., security against algorithm-substitution attacks introduced by Bellare et al. (CRYPTO '14) for symmetric encryption - were non-adaptive and non-continuous. In this vein, we show both positive and negative results for constructing subversion-resilient signature schemes. • Negative results. As our main negative result, we show that a broad class of randomized schemes is unavoidably insecure against SAs, even if using just a single bit of randomness. This improves upon earlier work that was only able to attack schemes with larger randomness space. When designing our attack we consider undetectability to be an explicit adversarial goal, meaning that the end-users (even the ones knowing the signing key) should not be able to detect that the signature scheme was subverted. • Positive results. We complement the above negative results by showing that signature schemes with unique signatures are subversion-resilient against all attacks that meet a basic undetectability requirement. A similar result was shown by Bellare et al. for symmetric encryption, who proved the necessity to rely on stateful schemes; in contrast unique signatures are stateless, and in fact they are among the fastest and most established digital signatures available. We finally show that it is possible to devise signature schemes secure against arbitrary tampering with the computation, by making use of an un-tamperable cryptographic reverse firewall (Mironov and Stephens-Davidowitz, EUROCRYPT '15), i.e., an algorithm that " sanitizes" any signature given as input (using only public information). The firewall we design allows to successfully protect so-called re-randomizable signature schemes (which include unique signatures). While our study is mainly theoretical, due to its strong practical motivation, we believe that our results have important implications in practice and might inuence the way digital signature schemes are selected or adopted in standards and protocols.

FAU Authors / FAU Editors

Magri, Bernardo, Ph.D.
Lehrstuhl für Informatik 13 (Angewandte Kryptographie)

External institutions with authors

Università degli studi "La Sapienza"

How to cite

Ateniese, G., Magri, B., & Venturi, D. (2015). Subversion-resilient signature schemes. (pp. 364-375). Association for Computing Machinery.

Ateniese, Giuseppe, Bernardo Magri, and Daniele Venturi. "Subversion-resilient signature schemes." Proceedings of the 22nd ACM SIGSAC Conference on Computer and Communications Security, CCS 2015 Association for Computing Machinery, 2015. 364-375.


Last updated on 2018-22-11 at 20:50

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