Using Hardware Transactional Memory for High-Performance Computing

This work investigates the benefits of transactional memory for high-performance and scientific computing by examining n-body and unstructured mesh applications on a prototype computer system with transactional memory support in hardware. Transactional memory systems have the potential to both improve performance, through reduced lock overhead, and ease development, by providing simplified synchronization semantics. To date, only a few early experiments have been presented on actual transactional memory hardware, with none of them investigating the benefits of transactional memory for scientific computing. We investigate straight-forward implementations to see if replacing locks by transactions can yield better performance and compete with more complex algorithms. Our experiments show that using transactions is the fastest way to concurrently update shared floating-point variables, which is of interest in many scientific computing applications. However, if it is possible, avoiding concurrent updates altogether yields the best performance.