On information-theoretic secure multiparty computation with local repairability
In this work we consider the task of designing information-theoretic MPC protocols for which the state of a given party can be recovered from a small amount of parties, a property we refer to as \emph{local repairability}. This is useful when considering MPC over dynamic settings where parties le...
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sg-ntu-dr.10356-1734492024-04-19T15:39:19Z On information-theoretic secure multiparty computation with local repairability Escudero, Daniel Tjuawinata, Ivan Xing, Chaoping School of Computer Science and Engineering Public Key Cryptography (PKC 2024) Strategic Centre for Research in Privacy-Preserving Technologies & Systems (SCRIPTS) Computer and Information Science Secret sharing Secure multiparty computation Threshold cryptography In this work we consider the task of designing information-theoretic MPC protocols for which the state of a given party can be recovered from a small amount of parties, a property we refer to as \emph{local repairability}. This is useful when considering MPC over dynamic settings where parties leave and join a computation, a scenario that has gained notable attention in recent literature. Thanks to the results of (Cramer \emph{et al.}~EUROCRYPT'00), designing such protocols boils down to constructing a linear secret-sharing scheme (LSSS) with good locality, that is, each share is determined by only a small amount of other shares, that also satisfies the so-called multiplicativity property. Previous constructions that achieve locality (\emph{e.g.}~using locally recoverable codes---LRCs) do not enjoy multiplicativity, and LSSS that are multiplicative (\emph{e.g.}~Shamir's secret-sharing) do not satisfy locality. Our construction bridges this literature gap by showing the existence of an LSSS that achieves both properties simultaneously. Our results are obtained by making use of well known connection between error correcting codes and LSSS, in order to adapt the LRC construction by (Tamo \& Barg, IEEE Transactions on Information Theory 2014) to turn it into a LSSS. With enough care, such coding-theoretic construction yields our desired locality property, but it falls short at satisfying multiplicativity. In order to address this, we perform an extensive analysis of the privacy properties of our scheme in order to identify parameter regimes where our construction satisfies multiplicativity. Finally, since our LSSS satisfies locality, every share is determined by a small amount of shares. However, in an MPC context it is not enough to let the (small set of) parties to send their shares to the repaired party, since this may leak more information than the regenerated share. To obtain our final result regarding MPC with local repairability, we construct a lightweight MPC protocol that performs such repairing process without any leakage. We provide both a passively secure construction (for the \emph{plain} multiplicative regime) and an actively secure one (for \emph{strong} multiplicativity). National Research Foundation (NRF) Submitted/Accepted version This research is supported by the National Research Foundation, Singapore under its Strategic Capability Research Centres Funding Initiative. The work of Chaoping Xing was supported in part by the National Key Research and Development Project under Grant 2022YFA1004900, in part by the National Natural Science Foundation of China under Grants 12031011, 12361141818 and 12271084. 2024-04-18T02:26:24Z 2024-04-18T02:26:24Z 2024 Conference Paper Escudero, D., Tjuawinata, I. & Xing, C. (2024). On information-theoretic secure multiparty computation with local repairability. Public Key Cryptography (PKC 2024), LNCS 14602, 205-239. https://dx.doi.org/10.1007/978-3-031-57722-2_7 978-3-031-57721-5 https://hdl.handle.net/10356/173449 10.1007/978-3-031-57722-2_7 LNCS 14602 205 239 en 2021YFE109900 © 2024 International Association for Cryptologic Research. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1007/978-3-031-57722-2_7. application/pdf |
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Computer and Information Science Secret sharing Secure multiparty computation Threshold cryptography |
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Computer and Information Science Secret sharing Secure multiparty computation Threshold cryptography Escudero, Daniel Tjuawinata, Ivan Xing, Chaoping On information-theoretic secure multiparty computation with local repairability |
| description |
In this work we consider the task of designing information-theoretic MPC protocols for which the state of a given party can be recovered from a small amount of parties, a property we refer to as \emph{local repairability}.
This is useful when considering MPC over dynamic settings where parties leave and join a computation, a scenario that has gained notable attention in recent literature.
Thanks to the results of (Cramer \emph{et al.}~EUROCRYPT'00), designing such protocols boils down to constructing a linear secret-sharing scheme (LSSS) with good locality, that is, each share is determined by only a small amount of other shares, that also satisfies the so-called multiplicativity property.
Previous constructions that achieve locality (\emph{e.g.}~using locally recoverable codes---LRCs) do not enjoy multiplicativity, and LSSS that are multiplicative (\emph{e.g.}~Shamir's secret-sharing) do not satisfy locality.
Our construction bridges this literature gap by showing the existence of an LSSS that achieves both properties simultaneously.
Our results are obtained by making use of well known connection between error correcting codes and LSSS, in order to adapt the LRC construction by (Tamo \& Barg, IEEE Transactions on Information Theory 2014) to turn it into a LSSS.
With enough care, such coding-theoretic construction yields our desired locality property, but it falls short at satisfying multiplicativity.
In order to address this, we perform an extensive analysis of the privacy properties of our scheme in order to identify parameter regimes where our construction satisfies multiplicativity.
Finally, since our LSSS satisfies locality, every share is determined by a small amount of shares.
However, in an MPC context it is not enough to let the (small set of) parties to send their shares to the repaired party, since this may leak more information than the regenerated share.
To obtain our final result regarding MPC with local repairability, we construct a lightweight MPC protocol that performs such repairing process without any leakage.
We provide both a passively secure construction (for the \emph{plain} multiplicative regime) and an actively secure one (for \emph{strong} multiplicativity). |
| author2 |
School of Computer Science and Engineering |
| author_facet |
School of Computer Science and Engineering Escudero, Daniel Tjuawinata, Ivan Xing, Chaoping |
| format |
Conference or Workshop Item |
| author |
Escudero, Daniel Tjuawinata, Ivan Xing, Chaoping |
| author_sort |
Escudero, Daniel |
| title |
On information-theoretic secure multiparty computation with local repairability |
| title_short |
On information-theoretic secure multiparty computation with local repairability |
| title_full |
On information-theoretic secure multiparty computation with local repairability |
| title_fullStr |
On information-theoretic secure multiparty computation with local repairability |
| title_full_unstemmed |
On information-theoretic secure multiparty computation with local repairability |
| title_sort |
on information-theoretic secure multiparty computation with local repairability |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173449 |
| _version_ |
1800916296267726848 |