为了提高非平衡进程到达(unbalanced process arrival,简称UPA)模式下MPI广播的性能,对UPA模式下的广播问题进行了理论分析,证明了在多核集群环境中通过节点内多个MPI进程的竞争可以有效减少UPA对MPI广播性能的影响,并在此基础上提出了一种新的优化方法,即竞争式流水化方法(competitive and pipelined method.称CP).CP方法通过一种节点内进程竞争机制在广播过程中尽早启动节点间通信,经该方法优化的广播算法利用共rn享内存在节点内通信,利用由竞争机制产生的引导进程执行原算法在节点间通信,并且,该方法使节点间通信和节点rn内通信以流水方式重叠执行,能够有效利用集群系统各节点的多核优势,减少了MPI广播受UPA的影响,提高了性rn能,为了验证CP方法的有效性,基于此方法优化了3种典型的MPI广播算法,分别适用于不同消息长度的广播.在真rn实系统中,通过微基准测试和两个实际的应用程序对CP广播进行了性能评价,结果表明,该方法能够有效地提高传rn统广播算法在UPA模式下的性能,在应用程序的负载测试实验结果中,CP广播的性能较流水化广播的性能提高约rn16%,较MVAPICH2 1.2中广播的性能提高l8%~24%.%This paper aims at improving the performance of MPI broadcasts under unbalanced process arrival (UPA) patterns. This paper analyzes this problem with a performance model and proves that the negative impact of UPA on MPI broadcast can be effectively reduced by the competition of intra-node MPI processes on a multicore cluster. Based on this theory, a new optimizing method, called competitive and pipelined method (CP), is proposed. The CP method can start inter-node communications during the broadcast process through an intra-node competitive mechanism. In a CP method based broadcast algorithm, intra-node communications overlap inter-node communications through a pipelined method, and intra-node communications are implemented through shared memory while inter-node communications are executed by a set of leader MPI processes, which is selected by the competitive mechanism. In order to verify the CP method, this paper improves three typical broadcast algorithms by using this method and evaluates these algorithms in a real platform by using a micro-benchmark case and two practical applications. The results show that the performance of the CP method can effectively improve the performance of broadcast algorithms in the condition of UPA patterns. In the experimental results of the performance of the practical applications, the performance of CP broadcasts is about 16% higher than the performance of P broadcasts and is 18% to 24% higher than the performance of broadcast operation in MVAPICH2 1.2.
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