English

GSM-SEM: Benchmark and Framework for Generating Semantically Variant Augmentations

Computation and Language 2026-05-27 v2 Artificial Intelligence

Abstract

Benchmarks like GSM8K are popular measures of mathematical reasoning, but leaderboard gains can overstate true capability due to memorization of fixed test sets. Most robustness variants apply surface-level perturbations (paraphrases, renamings, number swaps, distractors) that largely preserve the underlying facts, and static releases can themselves become memorization targets over time. We introduce GSM-SEM, a reusable and stochastic framework for generating semantically diverse benchmark variants with substantially higher semantic variance than prior approaches. GSM-SEM perturbs problem statements by modifying entities, attributes, and/or relationships, frequently altering underlying facts and requiring models to recompute solutions under new conditions, while constraining generation to preserve the original calculations/answer and approximate problem difficulty. GSM-SEM generates fresh variants on each run without requiring re-annotation, reducing reliance on static public benchmarks for evaluation and thereby lowering the bias of memorization. We apply GSM-SEM on GSM8K and two existing variation suites (GSM-Symbolic and GSM-Plus), producing GSM8K-SEM, GSM-Symbolic-SEM, and GSM-Plus-SEM. Evaluating 14 SOTA LLMs, we observe consistent performance drops with larger decline when semantic perturbations are coupled with symbolic/plus variations (average drop rate 28% in maximum strictness configuration of GSM-SEM). We publicly release the three SEM variants as fully human-validated datasets. Finally, to demonstrate applicability beyond GSM-style math problems, we apply GSM-SEM to additional benchmarks including BigBenchHard, LogicBench, and NLR-BIRD.

Keywords

Cite

@article{arxiv.2605.07053,
  title  = {GSM-SEM: Benchmark and Framework for Generating Semantically Variant Augmentations},
  author = {Jyotika Singh and Fang Tu and Aziza Mirsaidova and Amit Agarwal and Hitesh Laxmichand Patel and Sandip Ghoshal and Miguel Ballesteros and Karan Dua and Yassine Benajiba and Weiyi Sun and Tao Sheng and Graham Horwood and Sujith Ravi and Dan Roth},
  journal= {arXiv preprint arXiv:2605.07053},
  year   = {2026}
}
R2 v1 2026-07-01T12:56:33.825Z