Saved in:
Bibliographic Details
Main Authors: Shen, Bowen, Chen, Yuyue, Yang, Peng, Zhang, Bin, Zhang, Xi, Jiang, Zoe L.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.06790
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911366349062144
author Shen, Bowen
Chen, Yuyue
Yang, Peng
Zhang, Bin
Zhang, Xi
Jiang, Zoe L.
author_facet Shen, Bowen
Chen, Yuyue
Yang, Peng
Zhang, Bin
Zhang, Xi
Jiang, Zoe L.
contents Privacy-preserving Transformer inference has gained attention due to the potential leakage of private information. Despite recent progress, existing frameworks still fall short of practical model scales, with gaps up to a hundredfold. A possible way to close this gap is the Mixture of Experts (MoE) architecture, which has emerged as a promising technique to scale up model capacity with minimal overhead. However, given that the current secure two-party (2-PC) protocols allow the server to homomorphically compute the FFN layer with its plaintext model weight, under the MoE setting, this could reveal which expert is activated to the server, exposing token-level privacy about the client's input. While naively evaluating all the experts before selection could protect privacy, it nullifies MoE sparsity and incurs the heavy computational overhead that sparse MoE seeks to avoid. To address the privacy and efficiency limitations above, we propose a 2-PC privacy-preserving inference framework, \SecMoE. Unifying per-entry circuits in both the MoE layer and piecewise polynomial functions, \SecMoE obliviously selects the extracted parameters from circuits and only computes one encrypted entry, which we refer to as Select-Then-Compute. This makes the model for private inference scale to 63$\times$ larger while only having a 15.2$\times$ increase in end-to-end runtime. Extensive experiments show that, under 5 expert settings, \SecMoE lowers the end-to-end private inference communication by 1.8$\sim$7.1$\times$ and achieves 1.3$\sim$3.8$\times$ speedup compared to the state-of-the-art (SOTA) protocols.
format Preprint
id arxiv_https___arxiv_org_abs_2601_06790
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle SecMoE: Communication-Efficient Secure MoE Inference via Select-Then-Compute
Shen, Bowen
Chen, Yuyue
Yang, Peng
Zhang, Bin
Zhang, Xi
Jiang, Zoe L.
Cryptography and Security
Artificial Intelligence
Privacy-preserving Transformer inference has gained attention due to the potential leakage of private information. Despite recent progress, existing frameworks still fall short of practical model scales, with gaps up to a hundredfold. A possible way to close this gap is the Mixture of Experts (MoE) architecture, which has emerged as a promising technique to scale up model capacity with minimal overhead. However, given that the current secure two-party (2-PC) protocols allow the server to homomorphically compute the FFN layer with its plaintext model weight, under the MoE setting, this could reveal which expert is activated to the server, exposing token-level privacy about the client's input. While naively evaluating all the experts before selection could protect privacy, it nullifies MoE sparsity and incurs the heavy computational overhead that sparse MoE seeks to avoid. To address the privacy and efficiency limitations above, we propose a 2-PC privacy-preserving inference framework, \SecMoE. Unifying per-entry circuits in both the MoE layer and piecewise polynomial functions, \SecMoE obliviously selects the extracted parameters from circuits and only computes one encrypted entry, which we refer to as Select-Then-Compute. This makes the model for private inference scale to 63$\times$ larger while only having a 15.2$\times$ increase in end-to-end runtime. Extensive experiments show that, under 5 expert settings, \SecMoE lowers the end-to-end private inference communication by 1.8$\sim$7.1$\times$ and achieves 1.3$\sim$3.8$\times$ speedup compared to the state-of-the-art (SOTA) protocols.
title SecMoE: Communication-Efficient Secure MoE Inference via Select-Then-Compute
topic Cryptography and Security
Artificial Intelligence
url https://arxiv.org/abs/2601.06790