Browsing by Subject "Critical issues"
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Item Open Access Code scheduling for optimizing parallelism and data locality(Springer, 2010-08-09) Yemliha, T.; Kandemir, M.; Öztürk, Özcan; Kultursay, E.; Muralidhara, S. P.As chip multiprocessors proliferate, programming support for these devices is likely to receive a lot of attention in the near future. Parallelism and data locality are two critical issues in a chip multiprocessor environment. Unfortunately, most of the published work in the literature focuses only on one of these problems, and this can prevent one from achieving the best possible performance. The main goal of this paper is to propose and evaluate a compiler-directed code parallelization scheme, which considers both parallelism and data locality at the same time. Our compiler captures the inherent parallelism and data reuse in the application code being analyzed using a novel representation called the locality-parallelism graph (LPG). Our partitioning/scheduling algorithm assigns the nodes of this graph to the processors in the architecture and schedules them for execution. We implemented this algorithm and evaluated its effectiveness using a set of benchmark codes. The results collected so far indicate that our approach improves overall execution latency significantly. In this paper, we also introduce an ILP (Integer Linear Programming) based formulation of the problem, and implement the schedule obtained by the ILP solver. The results indicate that our approach gets within 4% of the ILP solution. © 2010 Springer-Verlag.Item Open Access A scratch-pad memory aware dynamic loop scheduling algorithm(IEEE, 2008-03) Öztürk, Özcan; Kandemir, M.; Narayanan, S. H. K.Executing array based applications on a chip multiprocessor requires effective loop parallelization techniques. One of the critical issues that need to be tackled by an optimizing compiler in this context is loop scheduling, which distributes the iterations of a loop to be executed in parallel across the available processors. Most of the existing work in this area targets cache based execution platforms. In comparison, this paper proposes the first dynamic loop scheduler, to our knowledge, that targets scratch-pad memory (SPM) based chip multiprocessors, and presents an experimental evaluation of it. The main idea behind our approach is to identify the set of loop iterations that access the SPM and those that do not. This information is exploited at runtime to balance the loads of the processors involved in executing the loop nest at hand. Therefore, the proposed dynamic scheduler takes advantage of the SPM in performing the loop iteration-to-processor mapping. Our experimental evaluation with eight array/loop intensive applications reveals that the proposed scheduler is very effective in practice and brings between 13.7% and 41.7% performance savings over a static loop scheduling scheme, which is also tested in our experiments. © 2008 IEEE.