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Provable Adversarial Robustness in In-Context Learning

Machine Learning 2026-02-23 v1 Machine Learning

Abstract

Large language models adapt to new tasks through in-context learning (ICL) without parameter updates. Current theoretical explanations for this capability assume test tasks are drawn from a distribution similar to that seen during pretraining. This assumption overlooks adversarial distribution shifts that threaten real-world reliability. To address this gap, we introduce a distributionally robust meta-learning framework that provides worst-case performance guarantees for ICL under Wasserstein-based distribution shifts. Focusing on linear self-attention Transformers, we derive a non-asymptotic bound linking adversarial perturbation strength (ρ\rho), model capacity (mm), and the number of in-context examples (NN). The analysis reveals that model robustness scales with the square root of its capacity (ρmaxm\rho_{\text{max}} \propto \sqrt{m}), while adversarial settings impose a sample complexity penalty proportional to the square of the perturbation magnitude (NρN0ρ2N_\rho - N_0 \propto \rho^2). Experiments on synthetic tasks confirm these scaling laws. These findings advance the theoretical understanding of ICL's limits under adversarial conditions and suggest that model capacity serves as a fundamental resource for distributional robustness.

Keywords

Cite

@article{arxiv.2602.17743,
  title  = {Provable Adversarial Robustness in In-Context Learning},
  author = {Di Zhang},
  journal= {arXiv preprint arXiv:2602.17743},
  year   = {2026}
}

Comments

16 pages

R2 v1 2026-07-01T10:43:29.757Z