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Candidate iO from Homomorphic Encryption Schemes

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journal contribution
posted on 2024-03-26, 10:32 authored by Zvika Brakerski, Nico Döttling, Sanjam Garg, Giulio Malavolta
We propose a new approach to construct general-purpose indistinguishability obfuscation (iO). Our construction is obtained via a new intermediate primitive that we call split fully homomorphic encryption (split FHE), which we show to be sufficient for constructing iO. Specifically, split FHE is FHE where decryption takes the following two-step syntactic form: (i) a secret decryption step that uses the secret key and produces a hint which is (asymptotically) shorter than the length of the encrypted message, and (ii) a public decryption step that only requires the ciphertext and the previously generated hint (and not the entire secret key) and recovers the encrypted message. In terms of security, the hints for a set of ciphertexts should not allow one to violate semantic security for any other ciphertexts. Next, we show a generic candidate construction of split FHE based on three building blocks: (i) A standard FHE scheme with linear decrypt-and-multiply (which can be instantiated with essentially all LWE-based constructions), (ii) a linearly homomorphic encryption scheme with short decryption hints (such as the Damgård-Jurik encryption scheme, based on the DCR problem), and (iii) a cryptographic hash function (which can be based on a variety of standard assumptions). Our approach is heuristic in the sense that our construction is not provably secure and makes implicit assumptions about the interplay between these underlying primitives. We show evidence that this construction is secure by providing an argument in an appropriately defined oracle model. We view our construction as a big departure from the state-of-the-art constructions, and it is in fact quite simple.

History

Primary Research Area

  • Algorithmic Foundations and Cryptography

Journal

Journal of Cryptology

Volume

36

Page Range

27-27

Publisher

Springer Nature

Open Access Type

  • Hybrid

Sub Type

  • Article

BibTeX

@article{Brakerski:Döttling:Garg:Malavolta:2023, title = "Candidate iO from Homomorphic Encryption Schemes", author = "Brakerski, Zvika" AND "Döttling, Nico" AND "Garg, Sanjam" AND "Malavolta, Giulio", year = 2023, month = 7, journal = "Journal of Cryptology", number = "3", pages = "27--27", publisher = "Springer Nature", issn = "0933-2790", doi = "10.1007/s00145-023-09471-5" }