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OpenFHE: Open-Source Fully Homomorphic Encryption Library

Published: 07 November 2022 Publication History

Abstract

Fully Homomorphic Encryption (FHE) is a powerful cryptographic primitive that enables performing computations over encrypted data without having access to the secret key. We introduce OpenFHE, a new open-source FHE software library that incorporates selected design ideas from prior FHE projects, such as PALISADE, HElib, and HEAAN, and includes several new design concepts and ideas. The main new design features can be summarized as follows: (1) we assume from the very beginning that all implemented FHE schemes will support bootstrapping and scheme switching; (2) OpenFHE supports multiple hardware acceleration backends using a standard Hardware Abstraction Layer (HAL); (3) OpenFHE includes both user-friendly modes, where all maintenance operations, such as modulus switching, key switching, and bootstrapping, are automatically invoked by the library, and compiler-friendly modes, where an external compiler makes these decisions. This paper focuses on high-level description of OpenFHE design, and the reader is pointed to external OpenFHE references for a more detailed/technical description of the software library.

Supplementary Material

MP4 File (WAHC22-3563379.mp4)
This talk presents the paper "OpenFHE: Open-Source Fully Homomorphic Encryption Library", which introduces OpenFHE, an open-source and comprehensive library for FHE. The talk gives an overview of OpenFHE design principles and the main cryptographic capabilities. The design principles are governed by three perspectives: 1) Cryptography, 2) Performance, and 3) Usability which will be highlighted in the talk. We also summarize new features in OpenFHE and provide a comparison with existing libraries. Our vision for a broader OpenFHE community and machine learning applications is also highlighted. Finally, the talk ends with some demonstrations of use cases built in OpenFHE and made publicly available for the community.

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cover image ACM Conferences
WAHC'22: Proceedings of the 10th Workshop on Encrypted Computing & Applied Homomorphic Cryptography
November 2022
70 pages
ISBN:9781450398770
DOI:10.1145/3560827
Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

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Published: 07 November 2022

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Author Tags

  1. bfv
  2. bgv
  3. bootstrapping
  4. cggi
  5. ckks
  6. dm
  7. fhew
  8. fully homomorphic encryption
  9. hardware acceleration
  10. heaan
  11. scheme switching
  12. software implementation
  13. tfhe

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  • (2024)A Central Limit Approach for Ring-LWE Noise AnalysisIACR Communications in Cryptology10.62056/ay76c0krOnline publication date: 8-Jul-2024
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