Petri nets: an introduction
Modeling concurrency with partial orders
International Journal of Parallel Programming
Theoretical Computer Science - International Joint Conference on Theory and Practice of Software Development, P
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Refinement of actions in event structures and causal trees
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Flow models of distributed computations: three equivalent semantics for CCS
Information and Computation
Full abstraction and recursion
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The Theory and Practice of Concurrency
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The Book of Traces
Resource traces: a domain for processes sharing exclusive resources
Theoretical Computer Science
A truly concurrent semantics for a process algebra using resource pomsets
Theoretical Computer Science
Event Structures, Causal Trees, and Refinements
MFCS '90 Proceedings of the Mathematical Foundations of Computer Science 1990
ICALP '89 Proceedings of the 16th International Colloquium on Automata, Languages and Programming
Event Structure Semantics for CCS and Related Languages
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Degrees of Non-Determinism and Concurrency: A Petri Net View
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Partial Order and SOS Semantics for Linear Constraint Programs
COORDINATION '97 Proceedings of the Second International Conference on Coordination Languages and Models
Operational Petri net semantics for CCSP
Advances in Petri Nets 1987, covers the 7th European Workshop on Applications and Theory of Petri Nets
Permutation of transitions: An event structure semantics for CCS and SCCS
Linear Time, Branching Time and Partial Order in Logics and Models for Concurrency, School/Workshop
Nets, Terms and Formulas (Cambridge Tracts in Theoretical Computer Science)
Nets, Terms and Formulas (Cambridge Tracts in Theoretical Computer Science)
Systems Modelling via Resources and Processes: Philosophy, Calculus, Semantics, and Logic
Electronic Notes in Theoretical Computer Science (ENTCS)
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This paper initiates the study of a process algebra based on atomic actions that are assigned resources, and that supports true concurrency. By true concurrency we mean that the parallel composition of concurrent processes does not rely on an interleaving of concurrent actions for its definition. Our process algebra includes a number of interesting operators that can be defined using resources of atomic actions to control their behaviour: of particular note is a (weak) sequential composition operator that exploits the truly concurrent nature of the semantics; this operator extends significantly the operation of prefixing by atomic actions that is supported in most truly concurrent semantics. Our language also includes a parallel composition operator that allows local events to execute asynchronously, while requiring synchronising events to execute simultaneously. In addition, the language supports a restriction operator and includes (unguarded) recursion.We present both a denotational semantics and a companion operational semantics for our language. The denotational semantics supports true concurrency, so that parallel composition is defined without non-determinism or interleaving. This semantics also is novel for its treatment of recursion. The meaning of a recursive process is defined using a least fixed point on a subdomain that is determined by the body of the recursion, and that varies from one process to another. Nonetheless, the recursion operators in the language have continuous interpretations in the denotational model. In fact, our denotational model is based on a domain-theoretic generalisation of Mazurkiewicz traces in which the concatenation operator, as well as the other operators from our language, can be given continuous interpretations.The operational model is presented in a natural SOS style. We prove a congruence theorem relating the two semantics, which implies the operational model itself is compositional. The congruence theorem also implies the denotational model is adequate with respect to the operational semantics, and we characterise the relatively mild conditions under which the denotational semantics is fully abstract with respect to the operational semantics.