Pewss: A platform of extensible workflow simulation service for workflow scheduling research

Tsai, Meng-Han; Lai, Kuan‐Chou; Chang, Hsi-Ya; Chen, Kuan Fu; Huang, Kuo-Chan

doi:10.1002/spe.2555

Cited by 4 publications

(8 citation statements)

References 28 publications

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“…A number of simulators have been developed that target scientific workflows. Some of them are stand-alone simulators [11], [35]- [37]. Others are integrated with a particular WMS to promote more faithful simulation and code reuse [38], [39] or to execute simulations at runtime to guide on-line scheduling decisions made by the WMS [40].…”

Section: Related Workmentioning

confidence: 99%

“…They observe that many of these simulators do not capture the details of underlying infrastructures and/or use naive simulation models. This is the case with custom simulators such as that in [36], [37], [40]. But it is also the case with workflow simulators built on top of generic simulation frameworks that provide convenient userlevel abstractions but fail to model the details of the underlying infrastructure, e.g., the simulators in [11], [35], [38], which build on the CloudSim [25] or GroudSim [24] frameworks.…”

Section: Related Workmentioning

confidence: 99%

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WRENCH: A Framework for Simulating Workflow Management Systems

Casanova

Pandey

Oeth

et al. 2018

2018 IEEE/ACM Workflows in Support of Large-Scale Science (WORKS)

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Scientific workflows are used routinely in numerous scientific domains, and Workflow Management Systems (WMSs) have been developed to orchestrate and optimize workflow executions on distributed platforms. WMSs are complex software systems that interact with complex software infrastructures. Most WMS research and development activities rely on empirical experiments conducted with full-fledged software stacks on actual hardware platforms. Such experiments, however, are limited to hardware and software infrastructures at hand and can be labor-and/or time-intensive. As a result, relying solely on realworld experiments impedes WMS research and development. An alternative is to conduct experiments in simulation. In this work we present WRENCH, a WMS simulation framework, whose objectives are (i) accurate and scalable simulations; and (ii) easy simulation software development. WRENCH achieves its first objective by building on the SimGrid framework. While SimGrid is recognized for the accuracy and scalability of its simulation models, it only provides low-level simulation abstractions and thus large software development efforts are required when implementing simulators of complex systems. WRENCH thus achieves its second objective by providing highlevel and directly re-usable simulation abstractions on top of SimGrid. After describing and giving rationales for WRENCH's software architecture and APIs, we present a case study in which we apply WRENCH to simulate the Pegasus production WMS. We report on ease of implementation, simulation accuracy, and simulation scalability so as to determine to which extent WRENCH achieves its two above objectives. We also draw both qualitative and quantitative comparisons with a previously proposed workflow simulator.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

WRENCH: A Framework for Simulating Workflow Management Systems

Casanova

Pandey

Oeth

et al. 2018

2018 IEEE/ACM Workflows in Support of Large-Scale Science (WORKS)

View full text Add to dashboard Cite

show abstract

“…A number of simulators have been developed that target scientific workflows. Some of them are stand-alone simulators [35,36,37,11,53]. Others are integrated with a particular WMS to promote more faithful simulation and code reuse [38,39,54] or to execute simulations at runtime to guide on-line scheduling decisions made by the WMS [40].…”

Section: Related Workmentioning

confidence: 99%

“…They observe that many of these simulators do not capture the details of underlying infrastructures and/or use naive simulation models. This is the case with custom simulators such as that in [40,36,37]. But it is also the case with workflow simulators built on top of generic simulation frameworks that provide convenient user-level abstractions but fail to model the details of the underlying infrastructure, e.g., the simulators in [35,38,11], which build on the CloudSim [25] or GroudSim [24] frameworks.…”

Section: Related Workmentioning

confidence: 99%

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Developing accurate and scalable simulators of production workflow management systems with WRENCH

Casanova

Silva

Tanaka

et al. 2020

Future Generation Computer Systems

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Scientific workflows are used routinely in numerous scientific domains, and Workflow Management Systems (WMSs) have been developed to orchestrate and optimize workflow executions on distributed platforms. WMSs are complex software systems that interact with complex software infrastructures. Most WMS research and development activities rely on empirical experiments conducted with full-fledged software stacks on actual hardware platforms. These experiments, however, are limited to hardware and software infrastructures at hand and can be labor-and/or time-intensive. As a result, relying solely on real-world experiments impedes WMS research and development. An alternative is to conduct experiments in simulation. In this work we present WRENCH, a WMS simulation framework, whose objectives are (i) accurate and scalable simulations; and (ii) easy simulation software development. WRENCH achieves its first objective by building on the SimGrid framework. While SimGrid is recognized for the accuracy and scalability of its simulation models, it only provides low-level simulation abstractions and thus large software development efforts are required when implementing simulators of complex systems. WRENCH thus achieves its second objective by providing high-level and directly re-usable simulation abstractions on top of SimGrid. After describing and giving rationales for WRENCH's software architecture and APIs, we present two case studies in which we apply WRENCH to simulate the Pegasus production WMS and the WorkQueue application execution framework. We report on ease of implementation, simulation accuracy, and simulation scalability so as to determine to which extent WRENCH achieves its objectives. We also draw both qualitative and quantitative comparisons with a previously proposed workflow simulator.

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Developing a Workflow Management System Simulation for Capturing Internal IaaS Behavioural Knowledge

Al-Haboobi

Kecskeméti

2022

J Grid Computing

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Scientific workflows are becoming increasingly important for complex scientific applications. Conducting real experiments for large-scale workflows is challenging because they are very expensive and time consuming. A simulation is an alternative approach to a real experiment that can help evaluating the performance of workflow management systems (WMS) and optimise workflow management techniques. Although there are several workflow simulators available today, they are often user-oriented and treat the cloud as a black box. Unfortunately, this behaviour prevents the evaluation of the infrastructure level impact of the various decisions made by the WMSs. To address these issues, we have developed a WMS simulator (called DISSECT-CF-WMS) on DISSECT-CF that exposes the internal details of cloud infrastructures. DISSECT-CF-WMS enables better energy awareness by allowing the study of schedulers for physical machines. It also enables dynamic provisioning to meet the resource needs of the workflow application while considering the provisioning delay of a VM in the cloud. We evaluated our simulation extension by running several workflow applications on a given infrastructure. The experimental results show that we can investigate different schedulers for physical machines on different numbers of virtual machines to reduce energy consumption. The experiments also show that DISSECT-CF-WMS is up to 295× faster than WorkflowSim and still provides equivalent results. The experimental results of auto-scaling show that it can optimise makespan, energy consumption and VM utilisation in contrast to static VM provisioning.

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Pewss: A platform of extensible workflow simulation service for workflow scheduling research

Cited by 4 publications

References 28 publications

WRENCH: A Framework for Simulating Workflow Management Systems

WRENCH: A Framework for Simulating Workflow Management Systems

Developing accurate and scalable simulators of production workflow management systems with WRENCH

Developing a Workflow Management System Simulation for Capturing Internal IaaS Behavioural Knowledge

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