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

Citation:

PDF (4542 KB)

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)

More Information

Published Date: October 31, 2018

Graphical Abstract

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

FullText(HTML)

References (0)

[1]	Lu Yuxuan, Kong Lanju, Zhang Baochen, Min Xinping. MC-RHotStuff: Multi-Chain Oriented HotStuff Consensus Mechanism Based on Reputation[J]. Journal of Computer Research and Development, 2024, 61(6): 1559-1572. DOI: 10.7544/issn1000-1239.202330195
[2]	Yu Xiao, Liu Hui, Lin Yuxiu, Zhang Caiming. Consensus Guided Auto-Weighted Multi-View Clustering[J]. Journal of Computer Research and Development, 2022, 59(7): 1496-1508. DOI: 10.7544/issn1000-1239.20210126
[3]	Yang Hongzhang, Yang Yahui, Tu Yaofeng, Sun Guangyu, Wu Zhonghai. Proactive Fault Tolerance Based on “Collection—Prediction—Migration—Feedback” Mechanism[J]. Journal of Computer Research and Development, 2020, 57(2): 306-317. DOI: 10.7544/issn1000-1239.2020.20190549
[4]	Wang Zuan, Tian Youliang, Yue Chaoyue, Zhang Duo. Consensus Mechanism Based on Threshold Cryptography Scheme[J]. Journal of Computer Research and Development, 2019, 56(12): 2671-2683. DOI: 10.7544/issn1000-1239.2019.20190053
[5]	Wei Songjie, Li Shuai, Mo Bing, Wang Jiahe. Regional Cooperative Authentication Protocol for LEO Satellite Networks Based on Consensus Mechanism[J]. Journal of Computer Research and Development, 2018, 55(10): 2244-2255. DOI: 10.7544/issn1000-1239.2018.20180431
[6]	Liu Yiran, Ke Junming, Jiang Han, Song Xiangfu. Improvement of the PoS Consensus Mechanism in Blockchain Based on Shapley Value[J]. Journal of Computer Research and Development, 2018, 55(10): 2208-2218. DOI: 10.7544/issn1000-1239.2018.20180439
[7]	Ye Songtao, Lin Yaping, Hu Yupeng, Zhou Siwang, You Zhiqiang. A Faulty Sensor Node Tolerance Algorithm Based on Cut Point Set[J]. Journal of Computer Research and Development, 2009, 46(12): 2117-2125.
[8]	Han Jianjun, Gan Lu, Ruan Youlin, Li Qinghua, Abbas A.Essa. Real-Time Dynamic Scheduling Algorithms for the Savings of Power Consumption and Fault Tolerance in Multi-Processor Computing Environment[J]. Journal of Computer Research and Development, 2008, 45(4): 706-715.
[9]	Cheng Xin, Liu Hongwei, Dong Jian, Yang Xiaozong. A Fault Tolerance Deadlock Detection/Resolution Algorithm for the AND-OR Model[J]. Journal of Computer Research and Development, 2007, 44(5): 798-805.
[10]	Luo Wei, Yang Fumin, Pang Liping, and Li Jun. A Real-Time Fault-Tolerant Scheduling Algorithm for Distributed Systems Based on Deferred Active Backup-Copy[J]. Journal of Computer Research and Development, 2007, 44(3).

Cited By

Cited by

Periodical cited type(10)

1.	王娟，努尔买买提·黑力力. 基于字典分级和属性加权的密文排序检索方案. 新疆大学学报(自然科学版)(中英文). 2024(02): 246-256 .
2.	刘佩恒，张劼，张华，张欣，王梦迪. 支持语义扩展的多关键词密文检索方案. 中国电子科学研究院学报. 2024(01): 42-52 .
3.	於湘涛，温刚，刘冉，舒斐，刘威麟，赛峰. 电力调度自动化网络安全防护技术研究. 微型电脑应用. 2024(12): 187-190+198 .
4.	刘宁，牛佳乐，郑剑，李思岑，王丹丹. 基于向量空间模型的信息资源关键词智能检索工具的研究. 自动化技术与应用. 2023(10): 105-107+161 .
5.	管小明，李宏俊. 基于支持可验证的物联网感知层信息加密仿真. 计算机仿真. 2023(11): 357-360+441 .
6.	黄健，铁治欣，宋滢锟. 云存储环境中多关键词加密排序搜索方法研究. 软件导刊. 2022(01): 226-232 .
7.	牛淑芬，张美玲，周思玮，闫森. 面向移动终端的密文可验证属性基可搜索加密方案. 计算机工程与科学. 2022(11): 1941-1950 .
8.	陈红鹏，樊增辉. 基于数据加密技术的海外数据中心拓扑架构设计. 微型电脑应用. 2022(12): 204-208 .
9.	王娜，郑坤，付俊松，李剑. 基于分块的移动边缘计算密文检索方法. 通信学报. 2020(07): 95-102 .
10.	霍颖瑜. 基于混沌算法的高端装备指令数据加密方法. 兵器装备工程学报. 2020(11): 190-193 .