Parallel Task Scheduling for Resource Consumption Minimization with Reliability Constraint

Xu Hongzhi; Li Renfa; Zeng Lining

doi:10.7544/issn1000-1239.2018.20170893

Journal of Computer Research and Development > 2018 > 55(11): 2569-2583. > DOI: 10.7544/issn1000-1239.2018.20170893 CSTR: 32373.14.issn1000-1239.2018.20170893

Xu Hongzhi, Li Renfa, Zeng Lining. Parallel Task Scheduling for Resource Consumption Minimization with Reliability Constraint[J]. Journal of Computer Research and Development, 2018, 55(11): 2569-2583. DOI: 10.7544/issn1000-1239.2018.20170893

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Parallel Task Scheduling for Resource Consumption Minimization with Reliability Constraint

¹(湖南大学信息科学与工程学院长沙 410082)
²(吉首大学软件学院湖南张家界 427000) (xuhongzhi9@163.com)

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Published Date: October 31, 2018

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Abstract

Abstract

Reliability is an important figure of merit for the system and it must be satisfied in safety-critical applications. The systems’ reliability can be improved by resource redundancy, however, it must consume more system resources. The problem of minimizing resource consumption to satisfy reliability goal for parallel applications on heterogeneous systems is investigated. First, the reliability goal of the system is transformed to that of each single task, in which the average worst-case execution time (WCET) of a task on each processor is used as a reference for calculating the reliability goal. Two methods for calculating the reliability goal of each task are proposed for task replication and non-replication. Then, an algorithm of task non-replication for minimizing resource consumption with reliability goal (MRC) is designed. When the system reliability goal requirement isn’t higher than the reachable maximum reliability, the tasks can always be assigned to the appropriate processor so that the reliability goal of the system can be satisfied. Considering that the high-reliability requirements of the system cannot be satisfied by using MRC. Finally, two algorithms for task replication are designed to satisfy system reliability goal. The proposed algorithms are compared with MaxRe, RR, and MRCRG by using real parallel applications and randomly generated parallel applications. Experimental results demonstrate that the proposed algorithms consume fewer resources while satisfying the system reliability goal.
- heterogeneous systems,
- parallel task,
- reliability goal,
- resource consumption,
- scheduling

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