DDH-based schemes for multi-party Function Secret Sharing

Marc Damie; Florian Hahn; Andreas Peter; Jan Ramon

doi:10.48550/arXiv.2603.17453

DDH-based schemes for multi-party Function Secret Sharing

Marc Damie^*
, Florian Hahn
, Andreas Peter
, Jan Ramon

^*Corresponding author for this work

Research output: Working paper › Preprint › Academic

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Abstract

Function Secret Sharing (FSS) schemes enable sharing efficiently secret functions. Schemes dedicated to point functions, referred to as Distributed Point Functions (DPFs), are the center of FSS literature thanks to their numerous applications including private information retrieval, anonymous communications, and machine learning. While two-party DPFs benefit from schemes with logarithmic key sizes, multi-party DPFs have seen limited advancements: key sizes (with N, the function domain size) and/or exponential factors in the key size. We propose a DDH-based technique reducing the key size of existing multi-party schemes. In particular, we build an honest-majority DPF with key size. Our benchmark highlights key sizes up to 10 times smaller (on realistic problem sizes) than state-of-the-art schemes. Finally, we extend our technique to schemes supporting comparison functions.

Original language	English
Publisher	ArXiv.org
Number of pages	20
DOIs	https://doi.org/10.48550/arXiv.2603.17453
Publication status	Published - 18 Mar 2026

Keywords

cs.CR
Function Secret Sharing
FSS
Distributed Point Function
DPF
DDH
Multi-Party Computations

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title = "DDH-based schemes for multi-party Function Secret Sharing",

abstract = "Function Secret Sharing (FSS) schemes enable sharing efficiently secret functions. Schemes dedicated to point functions, referred to as Distributed Point Functions (DPFs), are the center of FSS literature thanks to their numerous applications including private information retrieval, anonymous communications, and machine learning. While two-party DPFs benefit from schemes with logarithmic key sizes, multi-party DPFs have seen limited advancements: key sizes (with N, the function domain size) and/or exponential factors in the key size. We propose a DDH-based technique reducing the key size of existing multi-party schemes. In particular, we build an honest-majority DPF with key size. Our benchmark highlights key sizes up to 10 times smaller (on realistic problem sizes) than state-of-the-art schemes. Finally, we extend our technique to schemes supporting comparison functions.",

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DDH-based schemes for multi-party Function Secret Sharing

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Keywords

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