Paper 2025/1767

Polylogarithmic Polynomial Commitment Scheme over Galois Rings

Zhuo Wu, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Xinxuan Zhang, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Yi Deng, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Yuanju Wei, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Zhongliang Zhang, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Liuyu Yang, State Key Laboratory of Cyberspace Security Defense, Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China
Abstract

This paper introduces the first multilinear polynomial commitment scheme (PCS) over Galois rings achieving $\bigO{\log^2 n}$ verification cost. It achieves $\bigO{n\log n}$ committing time and $\bigO{n}$ evaluation opening prover time. This PCS can be used to construct zero-knowledge proofs for arithmetic circuits over Galois rings, facilitating verifiable computation in applications requiring proofs of polynomial ring operations (e.g., verifiable fully homomorphic encryption). First we construct random foldable linear codes over Galois rings with sufficient code distance and present a distance preservation theorem over Galois rings. Second we extend the $\textsf{Basefold}$ commitment (Zeilberger et al., Crypto 2024) to multilinear polynomials over Galois rings. Our approach reduces proof size and verifier time from $\bigO{\sqrt{n}}$ to $\bigO{\log^2 n}$ compared to Wei et al., PKC 2025. Furthermore, we give a batched multipoint openning protocol for evaluation phase that collapses the proof size and verifier time of $N$ polynomials at $M$ points from $\bigO{NM \log^2 n}$ to $\bigO{\log^2 n}$, prover time from $\bigO{NMn}$ to $\bigO{n}$, further enhancing efficiency.

Metadata
Available format(s)
PDF
Category
Cryptographic protocols
Publication info
Published elsewhere. Minor revision. ESORICS 2025
Keywords
Polynomial CommitmentGalois Ring
Contact author(s)
wuzhuo @ iie ac cn
zhangxinxuan @ iie ac cn
deng @ iie ac cn
weiyuanju @ iie ac cn
zhangzhongliang @ iie ac cn
yangliuyu @ iie ac cn
History
2025-09-30: approved
2025-09-27: received
See all versions
Short URL
https://ia.cr/2025/1767
License
Creative Commons Attribution
CC BY

BibTeX

@misc{cryptoeprint:2025/1767,
      author = {Zhuo Wu and Xinxuan Zhang and Yi Deng and Yuanju Wei and Zhongliang Zhang and Liuyu Yang},
      title = {Polylogarithmic Polynomial Commitment Scheme over Galois Rings},
      howpublished = {Cryptology {ePrint} Archive, Paper 2025/1767},
      year = {2025},
      url = {https://eprint.iacr.org/2025/1767}
}
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