Smart Cuts: Enhance Active Learning for Vulnerability Detection by Pruning Bad Seeds

Vulnerability detection is crucial for identifying security weaknesses in software systems. However, the effectiveness of machine learning models in this domain is often hindered by low-quality training datasets, which contain noisy, mislabeled, or imbalanced samples. This paper proposes a novel dataset maps-empowered approach that systematically identifies and mitigates hard-to-learn outliers, referred to as "bad seeds", to improve model training efficiency. Our approach can categorize training examples based on learning difficulty and integrate this information into an active learning framework. Unlike traditional methods that focus on uncertainty-based sampling, our strategy prioritizes dataset quality by filtering out performance-harmful samples while emphasizing informative ones. Our experimental results show that our approach can improve F1 score over random selection by 45.36% (DeepGini) and 45.91% (K-Means) and outperforms standard active learning by 61.46% (DeepGini) and 32.65% (K-Means) for CodeBERT on the Big-Vul dataset, demonstrating the effectiveness of integrating dataset maps for optimizing sample selection in vulnerability detection. Furthermore, our approach also enhances model robustness, improves sample selection by filtering bad seeds, and stabilizes active learning performance across iterations. By analyzing the characteristics of these outliers, we provide insights for future improvements in dataset construction, making vulnerability detection more reliable and cost-effective.