Tracing Agentic Failure from the Flow of Success
Abstract
Failure attribution for LLM-based agentic systems, i.e., identifying which steps in a failure trajectory caused the task to fail, is critical for debugging and improving these systems. Existing approaches either rely on prompting-based pipelines, which are computationally expensive, or require post-training on failure trajectories with step-level error annotations, which are costly to collect and difficult to scale. We argue that a practical failure attribution model should be lightweight and trainable without step-level supervision on failure data. To this end, we address unsupervised failure attribution, i.e., training exclusively on successful trajectories and identifying error steps at inference time given a failure trajectory. We propose OAT, which casts this problem as one-class learning with neural controlled differential equations, modeling the dynamical pattern of successful trajectories in latent space. At inference time, each step in a failure trajectory is assigned an anomaly score based on its deviation from the dynamics learned on successful trajectories, which is then used to form a set of error steps. With training on only 100 successful trajectories, experiments show that OAT is 200--5000 times faster than prompting-based baselines, and, at the same time, consistently outperforms them in both in-domain and out-of-distribution datasets with +20% and +7% F1 scores, respectively, demonstrating that OAT is a promising and efficient direction for diagnosing agentic system failures.
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When an LLM agent fails on a long-horizon task, pinpointing which step caused the failure is hard. Existing approaches either rely on expensive prompting pipelines or require costly step-level annotated failure data to train on.
We introduce unsupervised failure attribution: train a model exclusively on successful trajectories (easy to collect, no annotation needed), then identify error steps in a failed trajectory at inference time.
Our method, OAT (One-class Agent Tracing), models the dynamics of successful trajectories in latent space using Neural Controlled Differential Equations, then flags steps in a failure trajectory that deviate from this learned "normal flow" as anomaly scores. A gated control path improves robustness to out-of-distribution trajectories, and conformal prediction gives a principled, adaptive detection threshold.
With training on just 100 successful trajectories, OAT outperforms prompting-based baselines by +20% F1 in-domain and +7% F1 out-of-distribution, while running 200–5000x faster with zero inference-time token cost.
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