This paper presents a combination between the assume-guarantee paradigm and the testing relation ioco. The assume-guarantee paradigm is a ”divide and conquer” technique that decomposes the verification of a system into smaller tasks that involve the verification of its components. The principal aspect of assume-guarantee reasoning is to consider each component separately, while taking into account assumptions about the context of the component. The testing relation ioco is a formal conformance relation for model-based testing that works on labeled transition systems. Our main result shows that, with certain restrictions, assume-guarantee reasoning can be applied in the context of ioco. This enables testing ioco-conformance of a system by te...
Model checking is an automated technique that can be used to determine whether a system satisfies ce...
We show how game semantics, counterexample-guided abstraction refinement, assume-guarantee reasoning...
We present a compositional verification technique for systems that exhibit both probabilistic and no...
Abstract. This paper presents a combination between the assume-guarantee paradigm and the testing re...
Finite-state verification techniques are often hampered by the stateexplosion problem. One proposed ...
Software systems are taking on an increasingly important role in society and are being used in criti...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Assume-guarantee reasoning enables a “divide-and-conquer” approach to the verification of large syst...
Model checking is an automated technique that can be used to determine whether a system satisfies ce...
This paper provides a comprehensive introduction to a framework for formal testing using labelled tr...
The assume-guarantee paradigm is a powerful divide-and-conquer mechanism for decomposing a verifica...
AbstractThe article introduces an extension of the well-known conformance relation ioco on labeled t...
Abstract. A new model based testing theory built on simulation semantics is presented. At the core o...
Model checking is an automated technique that can be used to determine whether a system satisfies ce...
We show how game semantics, counterexample-guided abstraction refinement, assume-guarantee reasoning...
We present a compositional verification technique for systems that exhibit both probabilistic and no...
Abstract. This paper presents a combination between the assume-guarantee paradigm and the testing re...
Finite-state verification techniques are often hampered by the stateexplosion problem. One proposed ...
Software systems are taking on an increasingly important role in society and are being used in criti...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Finite-state verification techniques are often hampered by the state-explosion problem. One proposed...
Assume-guarantee reasoning enables a “divide-and-conquer” approach to the verification of large syst...
Model checking is an automated technique that can be used to determine whether a system satisfies ce...
This paper provides a comprehensive introduction to a framework for formal testing using labelled tr...
The assume-guarantee paradigm is a powerful divide-and-conquer mechanism for decomposing a verifica...
AbstractThe article introduces an extension of the well-known conformance relation ioco on labeled t...
Abstract. A new model based testing theory built on simulation semantics is presented. At the core o...
Model checking is an automated technique that can be used to determine whether a system satisfies ce...
We show how game semantics, counterexample-guided abstraction refinement, assume-guarantee reasoning...
We present a compositional verification technique for systems that exhibit both probabilistic and no...