English

Unextractable Protocol Models: Collaborative Training and Inference without Weight Materialization

Machine Learning 2026-05-25 v1

Abstract

We consider a decentralized setup in which the participants collaboratively train and serve a large neural network, and where each participant only processes a subset of the model. In this setup, we explore the possibility of unmaterializable weights, where a full weight set is never available to any one participant. We introduce Unextractable Protocol Models (UPMs): a training and inference framework that leverages the sharded model setup to ensure model shards (i.e., subsets) held by participants are incompatible at different time steps. UPMs periodically inject time-varying, random, invertible transforms at participant boundaries; preserving the overall network function yet rendering cross-time assemblies incoherent. On Qwen-2.5-0.5B and Llama-3.2-1B, 10,000 transforms leave FP32 perplexity unchanged (Δ\DeltaPPL <0.01< 0.01; Jensen-Shannon drift <4×105< 4 \times 10^{-5}), and we show how to control growth for lower precision datatypes. Applying a transform every 30s adds 3% latency, 0.1% bandwidth, and 10% GPU-memory overhead at inference, while training overhead falls to 1.6% time and <1< 1% memory. We consider several attacks, showing that the requirements of direct attacks are impractical and easy to defend against, and that gradient-based fine-tuning of stitched partitions consumes 60\geq 60% of the tokens required to train from scratch. By enabling models to be collaboratively trained yet not extracted, UPMs make it practical to embed programmatic incentive mechanisms in community-driven decentralized training.

Keywords

Cite

@article{arxiv.2605.23464,
  title  = {Unextractable Protocol Models: Collaborative Training and Inference without Weight Materialization},
  author = {Alexander Long and Chamin Hewa Koneputugodage and Thalaiyasingam Ajanthan and Yan Zuo and Gil Avraham and Violetta Shevchenko and Hadi Mohaghegh Dolatabadi and Sameera Ramasinghe},
  journal= {arXiv preprint arXiv:2605.23464},
  year   = {2026}
}

Comments

Accepted at NeurIPS 2025. 34 pages, 6 figures (5 in main body, 1 in appendix). Alexander Long and Chamin Hewa Koneputugodage contributed equally