Abstract
Subversion attacks against cryptosystems have already received wide attentions since several decades ago, while the Snowden revelations in 2013 reemphasized the need to further exploring potential avenues for undermining the cryptography in practice. In this work, inspired by the kleptographic attacks introduced by Young and Yung in 1990s [Crypto’96], we initiate a formal study of asymmetric subversion attacks against signature schemes. Our contributions can be summarized as follows.
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We provide a formal definition of asymmetric subversion model for signature schemes. Our asymmetric model improves the existing symmetric subversion model proposed by Ateniese, Magri and Venturi [CCS’15] in the sense that the undetectability is strengthened and the signing key recoverability is defined as a strong subversion attack goal.
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We introduce a special type of signature schemes that are splittable and show how to universally mount the subversion attack against such signature schemes in the asymmetric subversion model. Compared with the symmetric attacks introduced by Ateniese, Magri and Venturi [CCS’15], our proposed attack enables much more efficient key recovery that is independent of the signing key size.
Our asymmetric subversion framework is somewhat conceptually simple but well demonstrates that subversion attacks against signature schemes could be quite practical, and thus increases awareness and spurs the search for deterrents.
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Notes
- 1.
In this work, honest algorithms are referred to as algorithms that are not subverted.
- 2.
Although the subverted algorithm needs to take as input the randomness used in the previous session, we insist that it is typically not an internal state that should be always maintained by the algorithm.
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Acknowledgment
The work of Rongmao Chen is supported by the National Natural Science Foundation of China (Grant No. 61702541), the Young Elite Scientists Sponsorship Program by CAST (Grant No. 2017QNRC001), and the Science Research Plan Program by NUDT (Grant No. ZK17-03-46). The work of Yongjun Wang is supported by the National Natural Science Foundation of China under Grant No. 61472439.
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Liu, C., Chen, R., Wang, Y., Wang, Y. (2018). Asymmetric Subversion Attacks on Signature Schemes. In: Susilo, W., Yang, G. (eds) Information Security and Privacy. ACISP 2018. Lecture Notes in Computer Science(), vol 10946. Springer, Cham. https://doi.org/10.1007/978-3-319-93638-3_22
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