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Paper detail

Precision-based attacks and interval refining: how to break, then fix, differential privacy on finite computers

Despite being raised as a problem over ten years ago, the imprecision of floating point arithmetic continues to cause privacy failures in the implementations of differentially private noise mechanisms. In this paper, we highlight a new class of vulnerabilities, which we call \emph{precision-based attacks}, and which affect several open source libraries. To address this vulnerability and implement differentially private mechanisms on floating-point space in a safe way, we propose a novel technique, called \emph{interval refining}. This technique has minimal error, provable privacy, and broad applicability. We use interval refining to design and implement a variant of the Laplace mechanism that is equivalent to sampling from the Laplace distribution and rounding to a float. We report on the performance of this approach, and discuss how interval refining can be used to implement other mechanisms safely, including the Gaussian mechanism and the exponential mechanism.

preprint2022arXivOpen access
Samuel HaneyDamien DesfontainesLuke HartmanRuchit ShresthaMichael Hay
Cryptography and Security
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Samuel HaneyDamien DesfontainesLuke HartmanRuchit ShresthaMichael Hay

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