Can Search-Based Testing with Pareto Optimization Effectively Cover Failure-Revealing Test Inputs?
October 15, 2024 Β· Declared Dead Β· π Empirical Software Engineering
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Authors
Lev Sorokin, Damir Safin, Shiva Nejati
arXiv ID
2410.11769
Category
cs.SE: Software Engineering
Cross-listed
cs.AI,
cs.LG
Citations
5
Venue
Empirical Software Engineering
Last Checked
4 months ago
Abstract
Search-based software testing (SBST) is a widely adopted technique for testing complex systems with large input spaces, such as Deep Learning-enabled (DL-enabled) systems. Many SBST techniques focus on Pareto-based optimization, where multiple objectives are optimized in parallel to reveal failures. However, it is important to ensure that identified failures are spread throughout the entire failure-inducing area of a search domain and not clustered in a sub-region. This ensures that identified failures are semantically diverse and reveal a wide range of underlying causes. In this paper, we present a theoretical argument explaining why testing based on Pareto optimization is inadequate for covering failure-inducing areas within a search domain. We support our argument with empirical results obtained by applying two widely used types of Pareto-based optimization techniques, namely NSGA-II (an evolutionary algorithm) and OMOPSO (a swarm-based Pareto-optimization algorithm), to two DL-enabled systems: an industrial Automated Valet Parking (AVP) system and a system for classifying handwritten digits. We measure the coverage of failure-revealing test inputs in the input space using a metric that we refer to as the Coverage Inverted Distance quality indicator. Our results show that NSGA-II-based search and OMOPSO are not more effective than a naΓ―ve random search baseline in covering test inputs that reveal failures. The replication package for this study is available in a GitHub repository.
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