Efficient coverage of parallel and hierarchical stateflow models for test case generation

Proceedings of the 38th International Conference on Software Engineering

Briand

et al. 2016

All engineering disciplines are founded and rely on models, although they may differ on purposes and usages of modeling. Interdisciplinary domains such as Cyber Physical Systems (CPSs) seek approaches that incorporate different modeling needs and usages. Specifically, the Simulink modeling platform greatly appeals to CPS engineers due to its seamless support for simulation and code generation. In this paper, we propose a test generation approach that is applicable to Simulink models built for both purposes of simulation and code generation. We define test inputs and outputs as signals that capture evolution of values over time. Our test generation approach is implemented as a meta-heuristic search algorithm and is guided to produce test outputs with diverse shapes according to our proposed notion of diversity. Our evaluation, performed on industrial and public domain models, demonstrates that: (1) In contrast to the existing tools for testing Simulink models that are only applicable to a subset of code generation models, our approach is applicable to both code generation and simulation Simulink models. (2) Our new notion of diversity for output signals outperforms random baseline testing and an existing notion of signal diversity in revealing faults in Simulink models. (3) The fault revealing ability of our test generation approach outperforms that of the Simulink Design Verifier, the only testing toolbox for Simulink.

Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Automated test suite generation for time-continuous simulink models

Matinnejad

Proceedings of the 38th International Conference on Software Engineering

Briand

et al. 2016

“…RELATED WORK Many test generation techniques have been proposed for different purposes e.g., maximizing program coverage ( [22], [39]- [52]) and revealing faults ( [43], [44], [53]- [64]) for programs, or maximizing structural coverage [65]- [74] and revealing faults [19], [28], [75]- [83] for Simulink models. Nevertheless, only a few test generation techniques aim to improve fault localization accuracy.…”

Section: Rq3 [Effectiveness Of Our Stoptestgeneration Subroutine]mentioning

confidence: 99%

Improving fault localization for Simulink models using search-based testing and prediction models

Liu

Lucia

2017 IEEE 24th International Conference on Software Analysis, Evolution and Reengineering (SANER)

et al. 2017

Abstract-One promising way to improve the accuracy of fault localization based on statistical debugging is to increase diversity among test cases in the underlying test suite. In many practical situations, adding test cases is not a cost-free option because test oracles are developed manually or running test cases is expensive. Hence, we require to have test suites that are both diverse and small to improve debugging. In this paper, we focus on improving fault localization of Simulink models by generating test cases. We identify three test objectives that aim to increase test suite diversity. We use these objectives in a search-based algorithm to generate diversified but small test suites. To further minimize test suite sizes, we develop a prediction model to stop test generation when adding test cases is unlikely to improve fault localization. We evaluate our approach using three industrial subjects. Our results show (1) the three selected test objectives are able to significantly improve the accuracy of fault localization for small test suite sizes, and (2) our prediction model is able to maintain almost the same fault localization accuracy while reducing the average number of newly generated test cases by more than half.

“…These model-based testing approaches often generate test cases from models using various automation mechanisms, e.g., search-based techniques [50], model checking [27,42], guided random testing [37,33,11] or a combination of these techniques [36,30]. In [31], a model-based testing approach for mixed discrete-continuous Stateflow models is proposed where test inputs are generated based on discrete fragments of Stateflow models, and are applied to the original models to obtain test oracles in terms of continuous signals.…”

Section: Related Workmentioning

confidence: 99%

Effective test suites for mixed discrete-continuous stateflow controllers

Matinnejad

Proceedings of the 2015 10th Joint Meeting on Foundations of Software Engineering

Briand

et al. 2015

Modeling mixed discrete-continuous controllers using Stateflow is common practice and has a long tradition in the embedded software system industry. Testing Stateflow models is complicated by expensive and manual test oracles that are not amenable to full automation due to the complex continuous behaviors of such models. In this paper, we reduce the cost of manual test oracles by providing test case selection algorithms that help engineers develop small test suites with high fault revealing power for Stateflow models. We present six test selection algorithms for discrete-continuous Stateflows: An adaptive random test selection algorithm that diversifies test inputs, two white-box coverage-based algorithms, a black-box algorithm that diversifies test outputs, and two search-based blackbox algorithms that aim to maximize the likelihood of presence of continuous output failure patterns. We evaluate and compare our test selection algorithms, and find that our three output-based algorithms consistently outperform the coverage-and input-based algorithms in revealing faults in discrete-continuous Stateflow models. Further, we show that our output-based algorithms are complementary as the two search-based algorithms perform best in revealing specific failures with small test suites, while the output diversity algorithm is able to identify different failure types better than other algorithms when test suites are above a certain size.