English

Power-Softmax: Towards Secure LLM Inference over Encrypted Data

Machine Learning 2026-05-06 v2 Cryptography and Security

Abstract

Modern cryptographic methods for implementing privacy-preserving LLMs such as \gls{HE} require the LLMs to have a polynomial form. Forming such a representation is challenging because transformers include non-polynomial components, such as \Softmax and layer normalization. Previous approaches have either directly approximated pre-trained models with large-degree polynomials, which are less efficient over HE, or replaced non-polynomial components with easier-to-approximate primitives before training, e.g., \Softmax with pointwise attention. The latter approach might introduce scalability challenges. We present a new HE-friendly variant of self-attention that offers a stable form for training and is easy to approximate with polynomials for secure inference. Our work introduces the first polynomial LLMs over a billion parameters, exceeding the size of previous models by more than tenfold. The resulting models demonstrate reasoning and in-context learning (ICL) capabilities comparable to standard transformers of the same size, representing a breakthrough in the field. Finally, we provide a detailed latency breakdown for each computation over encrypted data, paving the way for further optimization, and explore the differences in inductive bias between models relying on our HE-friendly variant and standard transformers.

Keywords

Cite

@article{arxiv.2410.09457,
  title  = {Power-Softmax: Towards Secure LLM Inference over Encrypted Data},
  author = {Itamar Zimerman and Allon Adir and Ehud Aharoni and Matan Avitan and Moran Baruch and Nir Drucker and Jenny Lerner and Ramy Masalha and Reut Meiri and Omri Soceanu},
  journal= {arXiv preprint arXiv:2410.09457},
  year   = {2026}
}
R2 v1 2026-06-28T19:18:54.838Z