Abstract
Parallel computation has been widely applied in a variety of large-scale scientific and engineering applications. Many studies indicate that exploiting both task and data parallelisms, i.e. mixed-parallel workflows, to solve large computational problems can get better efficacy compared with either pure task parallelism or pure data parallelism. Scheduling traditional workflows of pure task parallelism on parallel systems has long been known to be an NP-complete problem. Mixed-parallel workflow scheduling has to deal with an additional challenging issue of processor allocation. In this paper, we explore the processor allocation issue in scheduling mixed-parallel workflows of moldable tasks, called M-task, and propose an Iterative Allocation Expanding and Shrinking (IAES) approach. Compared to previous approaches, our IAES has two distinguishing features. The first is allocating more processors to the tasks on allocated critical paths for effectively reducing the makespan of workflow execution. The second is allowing the processor allocation of an M-task to shrink during the iterative procedure, resulting in a more flexible and effective process for finding better allocation. The proposed IAES approach has been evaluated with a series of simulation experiments and compared to several well-known previous methods, including CPR, CPA, MCPA, and MCPA2. The experimental results indicate that our IAES approach outperforms those previous methods significantly in most situations, especially when nodes of the same layer in a workflow might have unequal workloads.
Highlights
Parallel processing (Konstantopoulos 2015) has been applied to many computation demanding applications, especially a variety of large-scale scientific and engineering applications (Feitelson et al 1997)
The first one is that Iterative Allocation Expanding and Shrinking (IAES) allows the allocation of an M-task to shrink during the iterative procedure, leading to a more flexible and effective processor allocation process
Processor allocation for M‐tasks in mixed‐parallel workflows we explore the issues of processor allocation for M-tasks when scheduling mixed-parallel workflows, discuss the pros and cons of previous methods, and propose a new Iterative Allocation Expanding and Shrinking (IAES) approach to the processor allocation problem
Summary
Parallel processing (Konstantopoulos 2015) has been applied to many computation demanding applications, especially a variety of large-scale scientific and engineering applications (Feitelson et al 1997). For applications with data parallelism, usually a single program is executed on several processors simultaneously and each processor is responsible for processing a specific portion of data. Huang et al SpringerPlus (2016) 5:1138 with task parallelism usually can be represented by a Directed-Acyclic-Graph (DAG) (Topcuoglu et al 2002; Ramaswamy et al 1997) based task dependency graph, commonly called a workflow, and looks like Fig. 1. Each node represents a task which usually executes a specific program. The number next to each node indicates the computation workload of the task. Based on the computation workload and processor speed, the required execution time of a task on a processor can be derived. The edges represent the dependence between tasks and the number next to an edge means the amount of data to transfer between two tasks. Many heuristic methods have been proposed to produce efficient schedules within a reasonable time period (Topcuoglu et al 2002; Ramaswamy et al 1997; Radulescu et al 2001; Radulescu and van Gemund 2001; Bansal et al 2006; N’Takṕe et al 2007; Yu and Shi 2009)
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