A method for testing and validating executable statechart models


Statecharts constitute an executable language for modelling event-based reactive systems. The essential complexity of statechart models solicits the need for advanced model testing and validation techniques. In this article, we propose a method aimed at enhancing statechart design with a range of techniques that have proven their usefulness to increase the quality and reliability of source code. The method is accompanied by a process that flexibly accommodates testing and validation techniques such as test-driven development, behaviour-driven development, design by contract, and property statecharts that check for violations of behavioural properties during statechart execution. The method is supported by the Sismic tool, an open-source statechart interpreter library in Python, which supports all the aforementioned techniques. Based on this tooling, we carry out a controlled user study to evaluate the feasibility, usefulness and adequacy of the proposed techniques for statechart testing and validation.

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We express our gratitude to Jordi Cabot, Simon Van Mierlo, Gauvain Devillez and Mathieu Goeminne, and several anonymous reviewers for providing comments on earlier versions of this article.

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Correspondence to Tom Mens.

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Communicated by Dr. M. Papadakis, S. Ali, and G. Perrouin.

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Mens, T., Decan, A. & Spanoudakis, N.I. A method for testing and validating executable statechart models. Softw Syst Model 18, 837–863 (2019). https://doi.org/10.1007/s10270-018-0676-3

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  • Statechart
  • Executable modeling
  • Behaviour-driven development
  • Design by contract
  • Runtime verification