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Main Authors: Huang, Chenxi, Mathai, Alex, Yu, Feiyang, Nogikh, Aleksandr, Maniatis, Petros, Ivančić, Franjo, Wu, Eugene, Kaffes, Kostis, Yang, Junfeng, Ray, Baishakhi
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.02690
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author Huang, Chenxi
Mathai, Alex
Yu, Feiyang
Nogikh, Aleksandr
Maniatis, Petros
Ivančić, Franjo
Wu, Eugene
Kaffes, Kostis
Yang, Junfeng
Ray, Baishakhi
author_facet Huang, Chenxi
Mathai, Alex
Yu, Feiyang
Nogikh, Aleksandr
Maniatis, Petros
Ivančić, Franjo
Wu, Eugene
Kaffes, Kostis
Yang, Junfeng
Ray, Baishakhi
contents Repairing system crashes discovered by kernel fuzzers like Syzkaller is a critical yet underexplored challenge in software engineering. While recent works have introduced Large Language Model (LLM) based agents for Linux kernel crash-resolution, their evaluation benchmarks are usually static and thus, do not capture the evolving nature of the Linux kernel, and suffer from potential data contamination due to LLM knowledge cutoffs. To address the above problem, we present (i) Live-kBench, an evaluation framework for self-evolving benchmarks that continuously scrapes and evaluates agents on freshly discovered kernel bugs, and (ii) kEnv, an agent-agnostic standardized crash-resolution environment for kernel compilation, execution, and feedback. This design decouples agent workflows from heavy-weight execution, enabling fair and scalable comparison across diverse agent frameworks under identical conditions. To this end, we curate an inaugural dataset of 534 Linux kernel bugs and empirically demonstrate a significant performance gap, with agents achieving up to 25% higher equivalent patch rate on bugs fixed before the LLM knowledge cutoff. Using kEnv, we benchmark three state-of-the-art agents, showing that they resolve 74% of crashes on the first attempt (plausible patches); however only ~20% of generated patches closely match developer fixes. Additionally, exposing crash resolution feedback improves crash resolution rate by 29%. Live-kBench provides the community with an evaluation infrastructure for self-evolving benchmarks that is both time and attribute sensitive; complete with a public dashboard to track agent progress on Linux kernel bugs.
format Preprint
id arxiv_https___arxiv_org_abs_2602_02690
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Outrunning LLM Cutoffs: A Live Kernel Crash Resolution Benchmark for All
Huang, Chenxi
Mathai, Alex
Yu, Feiyang
Nogikh, Aleksandr
Maniatis, Petros
Ivančić, Franjo
Wu, Eugene
Kaffes, Kostis
Yang, Junfeng
Ray, Baishakhi
Software Engineering
Repairing system crashes discovered by kernel fuzzers like Syzkaller is a critical yet underexplored challenge in software engineering. While recent works have introduced Large Language Model (LLM) based agents for Linux kernel crash-resolution, their evaluation benchmarks are usually static and thus, do not capture the evolving nature of the Linux kernel, and suffer from potential data contamination due to LLM knowledge cutoffs. To address the above problem, we present (i) Live-kBench, an evaluation framework for self-evolving benchmarks that continuously scrapes and evaluates agents on freshly discovered kernel bugs, and (ii) kEnv, an agent-agnostic standardized crash-resolution environment for kernel compilation, execution, and feedback. This design decouples agent workflows from heavy-weight execution, enabling fair and scalable comparison across diverse agent frameworks under identical conditions. To this end, we curate an inaugural dataset of 534 Linux kernel bugs and empirically demonstrate a significant performance gap, with agents achieving up to 25% higher equivalent patch rate on bugs fixed before the LLM knowledge cutoff. Using kEnv, we benchmark three state-of-the-art agents, showing that they resolve 74% of crashes on the first attempt (plausible patches); however only ~20% of generated patches closely match developer fixes. Additionally, exposing crash resolution feedback improves crash resolution rate by 29%. Live-kBench provides the community with an evaluation infrastructure for self-evolving benchmarks that is both time and attribute sensitive; complete with a public dashboard to track agent progress on Linux kernel bugs.
title Outrunning LLM Cutoffs: A Live Kernel Crash Resolution Benchmark for All
topic Software Engineering
url https://arxiv.org/abs/2602.02690