Ring of Gyges : Accountable Anonymous Broadcast via Secret-Shared Shuffle
Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review
Author(s)
Related Research Unit(s)
Detail(s)
Original language | English |
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Title of host publication | Network and Distributed System Security (NDSS) Symposium 2025 |
ISBN (electronic) | 979-8-9894372-8-3 |
Publication status | Accepted/In press/Filed - 1 Nov 2024 |
Conference
Title | NDSS Symposium 2025 |
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Location | |
Place | United States |
City | San Diego, California |
Period | 24 - 28 February 2025 |
Link(s)
DOI | DOI |
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Permanent Link | https://scholars.cityu.edu.hk/en/publications/publication(e3521814-95e3-4f90-a690-b1ec33d4482f).html |
Abstract
Anonymous broadcast systems, which enable users to post messages on a public bulletin board while hiding their identities, have been of persistent interest over the years. Recent designs utilizing multi-party computation (MPC) techniques have shown competitive computational efficiency (CCS’20, NDSS’22, PETS’23). However, these systems still fall short in communication overhead, which also dominates the overall performance. Besides, they fail to adequately address threats from misbehaving users, such as repeatedly spamming the system with inappropriate, illegal content. These often undermine the practical adoption of anonymous broadcast systems.
This work presents Gyges, an MPC-based anonymous broadcast system that minimizes its inter-server communication costs while reconciling key anonymity and accountability guarantees. At its crux is an honest-majority four-party secret-shared relay. These relay parties jointly execute two essential protocols: 1) a “silent shuffling” protocol – requiring no online communication but non-interactive, local computation only – that unlinks users from submitted messages to obtain sender anonymity; and 2) a companion fast and lean tracing protocol that, when necessary, relinks a certain shuffled message back to its originator if content violates established moderation policies, without jeopardizing the anonymity of others. Additionally, Gyges adheres to the notion of private robustness to defend against malicious disruptions, while ensuring the guaranteed output delivery and preserving sender anonymity. The system also supports both vertical and horizontal scaling to enhance practical service performance. Our evaluation results show that Gyges outperforms state-of-the-art MPC-based anonymous broadcast systems like Clarion (NDSS’22) and RPM (PETS’23), while its secret-shared tracing technique can swiftly track down misbehaving clients (when necessary), giving orders of magnitude overhead reductions compared to recent traceable mixnets (PETS’24) that offers similar tracking capabilities
This work presents Gyges, an MPC-based anonymous broadcast system that minimizes its inter-server communication costs while reconciling key anonymity and accountability guarantees. At its crux is an honest-majority four-party secret-shared relay. These relay parties jointly execute two essential protocols: 1) a “silent shuffling” protocol – requiring no online communication but non-interactive, local computation only – that unlinks users from submitted messages to obtain sender anonymity; and 2) a companion fast and lean tracing protocol that, when necessary, relinks a certain shuffled message back to its originator if content violates established moderation policies, without jeopardizing the anonymity of others. Additionally, Gyges adheres to the notion of private robustness to defend against malicious disruptions, while ensuring the guaranteed output delivery and preserving sender anonymity. The system also supports both vertical and horizontal scaling to enhance practical service performance. Our evaluation results show that Gyges outperforms state-of-the-art MPC-based anonymous broadcast systems like Clarion (NDSS’22) and RPM (PETS’23), while its secret-shared tracing technique can swiftly track down misbehaving clients (when necessary), giving orders of magnitude overhead reductions compared to recent traceable mixnets (PETS’24) that offers similar tracking capabilities
Research Area(s)
- Anonymous broadcast, Secret-shared shuffle, Secret-shared trace
Bibliographic Note
Information for this record is supplemented by the author(s) concerned.
Citation Format(s)
Ring of Gyges: Accountable Anonymous Broadcast via Secret-Shared Shuffle. / Dong, Wentao; Jiang, Peipei; Duan, Huayi et al.
Network and Distributed System Security (NDSS) Symposium 2025. 2024.
Network and Distributed System Security (NDSS) Symposium 2025. 2024.
Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review