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FUSE - Flexible File Format and Intermediate Representation for Secure Multi-Party Computation

Braun, Lennart ; Huppert, Moritz ; Khayata, Nora ; Tkachenko, Oleksandr ; Schneider, Thomas (2023)
FUSE - Flexible File Format and Intermediate Representation for Secure Multi-Party Computation.
ASIA CCS '23: ACM ASIA Conference on Computer and Communications Security. Melbourne, Australia (10.07.2023-14.07.2023)
doi: 10.1145/3579856.3590340
Konferenzveröffentlichung, Bibliographie

Kurzbeschreibung (Abstract)

Secure Multi-Party Computation (MPC) is continuously becoming more and more practical. Many optimizations have been introduced, making MPC protocols more suitable for solving real-world problems. However, the MPC protocols and optimizations are usually implemented as a standalone proof of concept or in an MPC framework and are tightly coupled with special-purpose circuit formats, such as Bristol Format. This makes it very hard and time-consuming to re-use algorithmic advances and implemented applications in a different context. Developing generic algorithmic optimizations is exceptionally hard because the available MPC tools and formats are not generic and do not provide the necessary infrastructure.

In this paper, we present FUSE: A Framework for Unifying and Optimizing Secure Multi-Party Computation Implementations with Efficient Circuit Storage. FUSE provides a flexible intermediate representation (FUSE IR) that can be used across different platforms and in different programming languages, including C/C++, Java, Rust, and Python. We aim at making MPC tools more interoperable, removing the tight coupling between high-level compilers for MPC and specific MPC protocol engines, thus driving knowledge transfer. Our framework is inspired by the widely known LLVM compiler framework. FUSE is portable, extensible, and it provides implementation-agnostic optimizations.

As frontends, we implement HyCC (CCS'18), the Bristol circuit format, and MOTION (TOPS'22), meaning that these can be automatically converted to FUSE IR. We implement several generic optimization passes, such as automatic subgraph replacement and vectorization, to showcase the utility and efficiency of our framework. Finally, we implement as backends MOTION and MP-SPDZ (CCS'20), so that FUSE IR can be run by these frameworks in an MPC protocol, as well as other useful backends for JSON output and the DOT language for graph visualization. With FUSE, it is possible to use any implemented frontend with any implemented backend and vice-versa. FUSE IR is not only efficient to work on and much more generic than any other format so far -- supporting, e.g., function calls, hybrid MPC protocols as well as user-defined building blocks, and annotations -- while maintaining backwards-compatibility, but also compact, with smaller storage size than even minimalistic formats such as Bristol already for a few hundred operations.

Typ des Eintrags: Konferenzveröffentlichung
Erschienen: 2023
Autor(en): Braun, Lennart ; Huppert, Moritz ; Khayata, Nora ; Tkachenko, Oleksandr ; Schneider, Thomas
Art des Eintrags: Bibliographie
Titel: FUSE - Flexible File Format and Intermediate Representation for Secure Multi-Party Computation
Sprache: Englisch
Publikationsjahr: 10 Juli 2023
Verlag: ACM
Buchtitel: ASIA CCS '23: Proceedings of the 2023 ACM Asia Conference on Computer and Communications Security
Veranstaltungstitel: ASIA CCS '23: ACM ASIA Conference on Computer and Communications Security
Veranstaltungsort: Melbourne, Australia
Veranstaltungsdatum: 10.07.2023-14.07.2023
DOI: 10.1145/3579856.3590340
URL / URN: https://dl.acm.org/doi/10.1145/3579856.3590340
Zugehörige Links:
Kurzbeschreibung (Abstract):

Secure Multi-Party Computation (MPC) is continuously becoming more and more practical. Many optimizations have been introduced, making MPC protocols more suitable for solving real-world problems. However, the MPC protocols and optimizations are usually implemented as a standalone proof of concept or in an MPC framework and are tightly coupled with special-purpose circuit formats, such as Bristol Format. This makes it very hard and time-consuming to re-use algorithmic advances and implemented applications in a different context. Developing generic algorithmic optimizations is exceptionally hard because the available MPC tools and formats are not generic and do not provide the necessary infrastructure.

In this paper, we present FUSE: A Framework for Unifying and Optimizing Secure Multi-Party Computation Implementations with Efficient Circuit Storage. FUSE provides a flexible intermediate representation (FUSE IR) that can be used across different platforms and in different programming languages, including C/C++, Java, Rust, and Python. We aim at making MPC tools more interoperable, removing the tight coupling between high-level compilers for MPC and specific MPC protocol engines, thus driving knowledge transfer. Our framework is inspired by the widely known LLVM compiler framework. FUSE is portable, extensible, and it provides implementation-agnostic optimizations.

As frontends, we implement HyCC (CCS'18), the Bristol circuit format, and MOTION (TOPS'22), meaning that these can be automatically converted to FUSE IR. We implement several generic optimization passes, such as automatic subgraph replacement and vectorization, to showcase the utility and efficiency of our framework. Finally, we implement as backends MOTION and MP-SPDZ (CCS'20), so that FUSE IR can be run by these frameworks in an MPC protocol, as well as other useful backends for JSON output and the DOT language for graph visualization. With FUSE, it is possible to use any implemented frontend with any implemented backend and vice-versa. FUSE IR is not only efficient to work on and much more generic than any other format so far -- supporting, e.g., function calls, hybrid MPC protocols as well as user-defined building blocks, and annotations -- while maintaining backwards-compatibility, but also compact, with smaller storage size than even minimalistic formats such as Bristol already for a few hundred operations.

Freie Schlagworte: Engineering E4, Cryptography and Privacy Engineering (ENCRYPTO)
Fachbereich(e)/-gebiet(e): 20 Fachbereich Informatik
20 Fachbereich Informatik > Praktische Kryptographie und Privatheit
20 Fachbereich Informatik > Kryptographische Protokolle
DFG-Sonderforschungsbereiche (inkl. Transregio)
DFG-Sonderforschungsbereiche (inkl. Transregio) > Sonderforschungsbereiche
DFG-Sonderforschungsbereiche (inkl. Transregio) > Sonderforschungsbereiche > SFB 1119: CROSSING – Kryptographiebasierte Sicherheitslösungen als Grundlage für Vertrauen in heutigen und zukünftigen IT-Systemen
Hinterlegungsdatum: 10 Jul 2023 09:04
Letzte Änderung: 10 Jul 2023 09:04
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