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Main Authors: Liu, Zhichen, Lun, Tianle, Wen, Zhibin, An, Hao, Ou, Yulin, Xu, Jianhui, Zhang, Hao, Fang, Wenyi, Zheng, Yang, Xu, Yang
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.01025
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author Liu, Zhichen
Lun, Tianle
Wen, Zhibin
An, Hao
Ou, Yulin
Xu, Jianhui
Zhang, Hao
Fang, Wenyi
Zheng, Yang
Xu, Yang
author_facet Liu, Zhichen
Lun, Tianle
Wen, Zhibin
An, Hao
Ou, Yulin
Xu, Jianhui
Zhang, Hao
Fang, Wenyi
Zheng, Yang
Xu, Yang
contents The paradigm of scaling Large Language Models (LLMs) in both parameter size and test time has pushed the boundaries of AI capabilities, but at the cost of making the traditional generative evaluation paradigm prohibitively expensive, therefore making the latency of LLM's in-training downstream performance evaluation unbearable. However, simple metrics like training loss (perplexity) are not always correlated with downstream performance, as sometimes their trends diverge from the actual task outcomes. This dilemma calls for a method that is computationally efficient and sufficiently accurate in measuring model capabilities. To address this challenge, we introduce a new in-training evaluation paradigm that uses a lightweight probe for monitoring downstream performance. The probes take the internal representations of LLM checkpoints (during training) as input and directly predict the checkpoint's performance on downstream tasks measured by success probability (i.e., pass@1). We design several probe architectures, validating their effectiveness using the OLMo3-7B's checkpoints across a diverse set of downstream tasks. The probes can accurately predict a checkpoint's performance (with avg. AUROC$>$0.75), have decent generalizability across checkpoints (earlier predicts later), and reduce the computation latency from $\sim$1 hr (using conventional generative evaluation method) to $\sim$3 min. In sum, this work presents a practical and scalable in-training downstream evaluation paradigm, enabling a more agile, informed, and efficient LLM development process.
format Preprint
id arxiv_https___arxiv_org_abs_2604_01025
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Fast and Accurate Probing of In-Training LLMs' Downstream Performances
Liu, Zhichen
Lun, Tianle
Wen, Zhibin
An, Hao
Ou, Yulin
Xu, Jianhui
Zhang, Hao
Fang, Wenyi
Zheng, Yang
Xu, Yang
Machine Learning
Artificial Intelligence
The paradigm of scaling Large Language Models (LLMs) in both parameter size and test time has pushed the boundaries of AI capabilities, but at the cost of making the traditional generative evaluation paradigm prohibitively expensive, therefore making the latency of LLM's in-training downstream performance evaluation unbearable. However, simple metrics like training loss (perplexity) are not always correlated with downstream performance, as sometimes their trends diverge from the actual task outcomes. This dilemma calls for a method that is computationally efficient and sufficiently accurate in measuring model capabilities. To address this challenge, we introduce a new in-training evaluation paradigm that uses a lightweight probe for monitoring downstream performance. The probes take the internal representations of LLM checkpoints (during training) as input and directly predict the checkpoint's performance on downstream tasks measured by success probability (i.e., pass@1). We design several probe architectures, validating their effectiveness using the OLMo3-7B's checkpoints across a diverse set of downstream tasks. The probes can accurately predict a checkpoint's performance (with avg. AUROC$>$0.75), have decent generalizability across checkpoints (earlier predicts later), and reduce the computation latency from $\sim$1 hr (using conventional generative evaluation method) to $\sim$3 min. In sum, this work presents a practical and scalable in-training downstream evaluation paradigm, enabling a more agile, informed, and efficient LLM development process.
title Fast and Accurate Probing of In-Training LLMs' Downstream Performances
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2604.01025