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EPSRC Reference: EP/R019045/1
Title: Verifiably correct concurrency abstractions
Principal Investigator: Dongol, Dr B
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Department: Computer Science
Organisation: Brunel University London
Scheme: Overseas Travel Grants (OTGS)
Starts: 01 December 2017 Ends: 30 November 2019 Value (£): 14,370
EPSRC Research Topic Classifications:
Fundamentals of Computing Software Engineering
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
Related Grants:
EP/R018936/1
Panel History:  
Summary on Grant Application Form
Multi-core computing architectures have become ubiquitous over the last decade. This has been driven by the demand for continual performance improvements to cope with the ever-increasing sophistication of applications, combined with physical limitations on chip designs, whereby speed-up via higher clock speeds has become infeasible. The inherent parallelism that multi-core architectures entail offers great technical opportunities, however, exploiting these opportunities presents a number of technical challenges.

To ensure correctness, concurrent programs must be properly synchronised, but synchronisation invariably introduces sequential bottlenecks, causing performance to suffer. Fully exploiting the potential for concurrency requires optimisations to consider executions at low levels of abstraction, e.g., the underlying memory model, compiler optimisations, cache-coherency protocols etc. The complexity of such considerations means that checking correctness with a high degree of confidence is extremely difficult. Concurrency bugs have specifically been attributed to disasters such as a power blackout in north-eastern USA, Nasdaq's botched IPO of Facebook shares, and the near failure of NASA's Mars Pathfinder mission. Other safety-critical errors have manifested from using low-level optimisations, e.g., the double-checked locking bug and the Java Parker bug.

This project improves programmability of concurrent programs through the use of scalable atomicity abstractions such as TM and concurrent objects that make low-level optimisations available to general application programmers. Operations of such objects are highly concurrent (which improves efficiency), yet manage synchronisation on behalf of a programmer to provide an illusion of atomicity. Thus, by using TM, the focus of a programmer switches from what should be made atomic, as opposed to how atomicity should be guaranteed. This means concurrent systems can be developed in a layered manner (enabling a separation of concerns).

The attractive set of features that TM promises means that TM implementations are increasingly being incorporated into mainstream systems (hardware and software). Since the adaptation of transactions from database theory in the mid 1990s, software TM implementations are now available for all major programming languages. Recent advances include experimental features in compilers such as G++ 4.7 that directly enable compilation of transactional code; standardisation work to include TM within C++ is ongoing. There is extensive research interest in hybrid TM within both academia and industry to make best use of, for example, TM features in Intel's Haswell/Broadwell and IBM's Blue Gene/Q processors.

The high level of complexity, yet wide-scale applicability of TM means that implementations must be formally verified to ensure dependability and reliability. Overall, we will improve the dependability, performance, and flexibility of TM implementations.

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Organisation Website: http://www.brunel.ac.uk