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arxiv: 2412.12157 · v1 · pith:KOJWUW4Jnew · submitted 2024-12-11 · 💻 cs.CL · cs.AI

What Makes In-context Learning Effective for Mathematical Reasoning: A Theoretical Analysis

classification 💻 cs.CL cs.AI
keywords reasoningfew-shotllmsdemonstrationsin-contextlearningperformancebenchmarks
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Owing to the capability of in-context learning, large language models (LLMs) have shown impressive performance across diverse mathematical reasoning benchmarks. However, we find that few-shot demonstrations can sometimes bring negative performance and their effectiveness on LLMs' reasoning abilities remains unreliable. To this end, in this paper, we aim to theoretically analyze the impact of in-context demonstrations on LLMs' reasoning performance. We prove that the reasoning efficacy (measured by empirical prediction loss) can be bounded by a LLM-oriented semantic similarity and an inference stability of demonstrations, which is general for both one-shot and few-shot scenarios. Based on this finding, we propose a straightforward, generalizable, and low-complexity demonstration selection method named LMS3. It can adaptively facilitate to select the most pertinent samples for different LLMs and includes a novel demonstration rejection mechanism to automatically filter out samples that are unsuitable for few-shot learning. Through experiments on three representative benchmarks, two LLM backbones, and multiple few-shot settings, we verify that our LMS3 has superiority and achieves consistent improvements on all datasets, which existing methods have been unable to accomplish.

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  1. LLMs with in-context learning for Algorithmic Theoretical Physics

    cs.LG 2026-05 unverdicted novelty 5.0

    Frontier LLMs with in-context learning and CAS integration solve most algorithmic tasks in theoretical physics when supplied with worked examples.