TY - GEN
T1 - ppSAT
T2 - 31st USENIX Security Symposium, Security 2022
AU - Luo, Ning
AU - Judson, Samuel
AU - Antonopoulos, Timos
AU - Piskac, Ruzica
AU - Wang, Xiao
N1 - Publisher Copyright:
© USENIX Security Symposium, Security 2022.All rights reserved.
PY - 2022
Y1 - 2022
N2 - We design and implement a privacy-preserving Boolean satisfiability (ppSAT) solver, which allows mutually distrustful parties to evaluate the conjunction of their input formulas while maintaining privacy. We first define a family of security guarantees reconcilable with the (known) exponential complexity of SAT solving, and then construct an oblivious variant of the classic DPLL algorithm which can be integrated with existing secure two-party computation (2PC) techniques. We further observe that most known SAT solving heuristics are unsuitable for 2PC, as they are highly data-dependent in order to minimize the number of exploration steps. Faced with how best to trade off between the number of steps and the cost of obliviously executing each one, we design three efficient oblivious heuristics, one deterministic and two randomized. As a result of this effort we are able to evaluate our ppSAT solver on small but practical instances arising from the haplotype inference problem in bioinformatics. We conclude by looking towards future directions for making ppSAT solving more practical, most especially the integration of conflict-driven clause learning (CDCL).
AB - We design and implement a privacy-preserving Boolean satisfiability (ppSAT) solver, which allows mutually distrustful parties to evaluate the conjunction of their input formulas while maintaining privacy. We first define a family of security guarantees reconcilable with the (known) exponential complexity of SAT solving, and then construct an oblivious variant of the classic DPLL algorithm which can be integrated with existing secure two-party computation (2PC) techniques. We further observe that most known SAT solving heuristics are unsuitable for 2PC, as they are highly data-dependent in order to minimize the number of exploration steps. Faced with how best to trade off between the number of steps and the cost of obliviously executing each one, we design three efficient oblivious heuristics, one deterministic and two randomized. As a result of this effort we are able to evaluate our ppSAT solver on small but practical instances arising from the haplotype inference problem in bioinformatics. We conclude by looking towards future directions for making ppSAT solving more practical, most especially the integration of conflict-driven clause learning (CDCL).
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M3 - Conference contribution
AN - SCOPUS:85140959606
T3 - Proceedings of the 31st USENIX Security Symposium, Security 2022
SP - 2983
EP - 3000
BT - Proceedings of the 31st USENIX Security Symposium, Security 2022
PB - USENIX Association
Y2 - 10 August 2022 through 12 August 2022
ER -