Algorithms for Deciding the Safety of States in Fully Observable Non-deterministic Problems
DOI:
https://doi.org/10.1609/icaps.v36i1.42858Abstract
Learned action policies are increasingly popular in sequential decision-making, but suffer from a lack of safety guarantees. Recent work introduced a pipeline for testing the safety of such policies under initial-state and action-outcome non-determinism. At the pipeline's core, is the problem of deciding whether a state is safe (a safe policy exists from the state) and finding faults, which are state-action pairs that transition from a safe state to an unsafe one. Their most effective algorithm for deciding safety, TarjanSafe, is effective on their benchmarks, but we show that it has exponential worst-case runtime with respect to the state space. A linear-time alternative exists, but it is slower in practice. We close this gap with a new policy-iteration algorithm iPI, that combines the best of both: it matches TarjanSafe's best-case runtime while guaranteeing a polynomial worst-case. Experiments confirm our theory and show that in problems amenable to TarjanSafe iPI has similar performance, whereas in ill-suited problems iPI scales exponentially better.
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Published
2026-06-08
How to Cite
Schmalz, J., & Jain, C. (2026). Algorithms for Deciding the Safety of States in Fully Observable Non-deterministic Problems. Proceedings of the International Conference on Automated Planning and Scheduling, 36(1), 425–429. https://doi.org/10.1609/icaps.v36i1.42858
