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Checking Interaction Consistency in MARMOT Component Refinements Yunja Choi School of Electrical Engineering and Computer Science Kyungpook National University Overview MARMOT methodology Component and refinements Interaction consistency A general framework for consistency checking
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Checking Interaction Consistency in MARMOT Component Refinements Yunja Choi School of Electrical Engineering and Computer Science Kyungpook National University
Overview • MARMOT methodology • Component and refinements • Interaction consistency • A general framework for consistency checking • Case example • Model checking elevator system • Performance improvement through abstraction • Discussion
MARMOT Methodology • Branched from KobrA by Atkinson et. al • Designed for the development of embedded systems • High quality system through systematic, structured development • Components are the focus of entire development process • Tree-structured hierarchy of components • Flexibility and reuse of components
Statecharts Specification Operation Schemata Class Diagram Sequence Diagram Class Diagram Realization Object Diagram(Architecture) MARMOT Component Refined component Refining component
Recursive Development Identification Specification Realization Kpt A Component Reuse Kpt B Kpt C Kpt D COTS Component
Quality Control • MAMOT supports systematic identification and refinements of a component • the principle of “separation of concerns”: specification vs. realization • Iterative decomposition and refinements • There can be many issues in consistency • Structural consistency • Behavioral consistency • Behavioral consistency between the realization of refined component and the specification of its refining components
Interaction Consistency • at ith refinement step, the realization of the refined component constrains the environment of the refining components • A system is consistent with its environment in its behavior if it either terminates normally or runs infinitely under the infinite sequence of stimuli generated from its environment • A system is inconsistent with its environment in its behavior if it terminates abnormally under the infinite sequence of stimuli generated from its environment
A component and its environment are specified as two processes P and E, where each of them is represented as a labeled transition system (Sp, Lp, Rp, Ip, Tp) and (Se, Le, Re, Ie, Te) A restricted form of process composition of P and E is defined as P↑E = (Sp× Se, Lp∪ Le, Rp× Re, Ip× Ie, Tp× Te) where Process model
Formal definitions • Termination • Terminate(P(s))↑E : P terminates to a state s that belongs to the pre-defined set of terminal states T under the environment E • P(s) ∧ s ∈T, • If P is a compositional process, P = P1∥ P2∥.. ∥ Pn • Terminate(P(s)) ↑E if and only if ∀i, Terminate(Pi(si)) ↑Ei , where Ei = E ∥ P1∥ P2∥.. Pi-1 ∥ Pi+1 ∥ … ∥ Pn
Formal definitions • Progressiveness • Progress(P(s)) ↑E : eventually, there is a transition out of the state s under the environment E • Interaction Consistency • Consistent(P(s)) ↑E = Terminate(P(s))↑E ∨ Progress(P(s)) ↑E
Model checking consistency • Based on the exhaustive search of system state-space • Fully automated • SPIN: invalid-endstate checking • SMV: we can formulate the consistency property in temporal logic and use model checker to verify it • Provide counter-examples • Need translation to PROMELA or SMV input language • A number of translation approaches are available
Abstraction techniques • Trigger-based abstraction • Abstract the environment so that it contains all the transitions generating a triggering event for the process P, and all the transitions from the initial state leading to the transition • Transition reduction • collapse several transitions into one if the intermediate transitions do not generate triggering actions for the process P ti /ai s0 s1 s2 si Si+1 ti /ai s0 si Si+1
Discussion • Formal methods can be effective and useful when integrated into development process • Our work focuses on the seamless integration • There are a number of existing works on UML consistency, refinements, CBD methodology, and the use of model checking • However, they mostly focus on one of the issues separately. • Hardly any of the earlier works concerns on performance issue when using model checking • Environment constraints have been manually identified in the previous works • More investigation is needed on optimization and automation • Translation and abstraction