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Annual Conference: Communicating Process Architectures

Communicating Process Architectures 2018, the 40th. WoTUG conference on concurrent and parallel systems, takes place from Sunday August 19th. to Wednesday August 22nd. 2018 and is hosted by Professor Dr. Rainer Spallek, Chair of VLSI Design, Diagnostics and Architecture at the Faculty of Computer Science, Technische Universität Dresden, Germany. The conference is organised by Dr. Spallek in collboration with Oliver Knodel and Uwe Mielke and in partnership with WoTUG.

About WoTUG

WoTUG provides a forum for the discussion and promotion of concurrency ideas, tools and products in computer science. It organises specialist workshops and annual conferences that address key concurrency issues at all levels of software and hardware granularity. WoTUG aims to progress the leading state of the art in:

theory (programming models, process algebra, semantics, ...);

practice (multicore processors and run-times, clusters, clouds, libraries, languages, verification, model checking, ...);

education (at school, undergraduate and postgraduate levels, ...);

applications (complex systems, modelling, supercomputing, embedded systems, robotics, games, e-commerce, ...);

for the next generation of scalable computer infrastructure (hard and soft) and application, where scaling means the ability to ramp up functionality (stay in control as complexity increases) as well as physical metrics (such as absolute performance and response times);

for system integrity (dependability, security, safety, liveness, ...);

for making things simple.

WoTUG publications

A database of papers and presentations from WoTUG conferences is here. The Abstract below has been randomly selected from this database.

Formal Analysis of Concurrent Java Systems

Java threads are synchronised through primitives based upon monitor concepts developed in the early 1970s. The semantics of Java's primitives have only been presented in natural language -- this paper remedies this with a simple and formal CSP model. In view of the difficulties encountered in reasoning about any non-trivial interactions between Java threads, being able to perform that reasoning in a formal context (where careless errors can be highlighted by mechanical checks) should be a considerable confidence boost. Further, automated model-checking tools can be used to root out dangerous states (such as deadlock and livelock), find overlooked race hazards and prove equivalence between algorithms (e.g. between optimised and unoptimised versions). A case study using the CSP model to prove the correctness of the JCSP and CTJ channel implementations (which are built using standard Java monitor synchronisation) is presented. In addition, the JCSP mechanism for ALTing (i.e. waiting for and, then, choosing between multiple events) is verified. Given the history of erroneous implementations of this key primitive, this is a considerable relief.