Saved in:
Bibliographic Details
Main Authors: Diao, Zibo, Gai, Jingchu, Ai, Xinyue, Zhang, Zhang, He, Zhenyu, He, Di
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.18829
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913143538581504
author Diao, Zibo
Gai, Jingchu
Ai, Xinyue
Zhang, Zhang
He, Zhenyu
He, Di
author_facet Diao, Zibo
Gai, Jingchu
Ai, Xinyue
Zhang, Zhang
He, Zhenyu
He, Di
contents Frontier commercial generative models face a growing threat from distillation, whereby a distiller harvests generated responses and trains a competing model of its own at drastically lower cost. Existing defenses either rely on modifying the models outputs, thereby sacrificing response quality for benign users, or on behavioral detection methods, which can be readily circumvented by distributing queries across multiple accounts. In this work, we propose Lossless Anti-Distillation Sampling (LADS), a novel sampling scheme specifically designed to counter multi-account distillation while maintaining a lossless experience for benign users. Concretely, LADS derives the randomness underlying each generation from a private seed determined by the semantic content of the query and the number of times the user has queried the model. By construction, every benign user receives a response independently sampled from the original model at each visit, and thus experiences no distortion. In contrast, for a distiller, different accounts share latent randomness whenever their queries fall in the same semantic bucket. As a result, the harvested data becomes correlated, potentially reducing sample diversity and degrading generalization. Using uniform convergence theory, we show that LADS provably degrades the convergence rate of the distillers generalization gap relative to standard i.i.d. sampling in both unconditional and conditional generation settings. Experiments on image generation, mathematical reasoning, and code generation confirm that LADS substantially degrades the performance of distilled students while preserving exact statistical fidelity for individual users.
format Preprint
id arxiv_https___arxiv_org_abs_2605_18829
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Lossless Anti-Distillation Sampling
Diao, Zibo
Gai, Jingchu
Ai, Xinyue
Zhang, Zhang
He, Zhenyu
He, Di
Machine Learning
Cryptography and Security
Frontier commercial generative models face a growing threat from distillation, whereby a distiller harvests generated responses and trains a competing model of its own at drastically lower cost. Existing defenses either rely on modifying the models outputs, thereby sacrificing response quality for benign users, or on behavioral detection methods, which can be readily circumvented by distributing queries across multiple accounts. In this work, we propose Lossless Anti-Distillation Sampling (LADS), a novel sampling scheme specifically designed to counter multi-account distillation while maintaining a lossless experience for benign users. Concretely, LADS derives the randomness underlying each generation from a private seed determined by the semantic content of the query and the number of times the user has queried the model. By construction, every benign user receives a response independently sampled from the original model at each visit, and thus experiences no distortion. In contrast, for a distiller, different accounts share latent randomness whenever their queries fall in the same semantic bucket. As a result, the harvested data becomes correlated, potentially reducing sample diversity and degrading generalization. Using uniform convergence theory, we show that LADS provably degrades the convergence rate of the distillers generalization gap relative to standard i.i.d. sampling in both unconditional and conditional generation settings. Experiments on image generation, mathematical reasoning, and code generation confirm that LADS substantially degrades the performance of distilled students while preserving exact statistical fidelity for individual users.
title Lossless Anti-Distillation Sampling
topic Machine Learning
Cryptography and Security
url https://arxiv.org/abs/2605.18829