Differential approximation and sprinting for multi-priority big data engines

Robert Birke; Isabelly Rocha; Juan Perez; Valerio Schiavoni; Pascal Felber; Lydia Y. Chen

doi:10.1145/3361525.3361547

Differential approximation and sprinting for multi-priority big data engines

Robert Birke, Isabelly Rocha, Juan Perez, Valerio Schiavoni, Pascal Felber, Lydia Y. Chen

Universidad del Rosario

Producción científica: Capítulo en Libro/Reporte › Contribución a la conferencia

1 Cita (Scopus)

Resumen

Today’s big data clusters based on the MapReduce paradigm are capable of executing analysis jobs with multiple priorities, providing differential latency guarantees. Traces from production systems show that the latency advantage of high-priority jobs comes at the cost of severe latency degradation of low-priority jobs as well as daunting resource waste caused by repetitive eviction and re-execution of low-priority jobs. We advocate a new resource management design that exploits the idea of differential approximation and sprinting. The unique combination of approximation and sprinting avoids the eviction of low-priority jobs and its consequent latency degradation and resource waste. To this end, we designed, implemented and evaluated DiAS, an extension of the Spark processing engine to support deflate jobs by dropping tasks and to sprint jobs. Our experiments on scenarios with two and three priority classes indicate that DiAS achieves up to 90% and 60% latency reduction for low- and high-priority jobs, respectively. DiAS not only eliminates resource waste but also (surprisingly) lowers energy consumption up to 30% at only a marginal accuracy loss for low-priority jobs.

Idioma original	Inglés estadounidense
Título de la publicación alojada	Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference
Editorial	Association for Computing Machinery
Páginas	202-214
Número de páginas	13
ISBN (versión digital)	9781450370097
DOI	https://doi.org/10.1145/3361525.3361547
Estado	Publicada - dic. 9 2019
Evento	20th ACM/IFIP/USENIX Middleware Conference, Middleware 2019 - Davis, Estados Unidos Duración: dic. 9 2019 → dic. 13 2019

Serie de la publicación

Nombre	Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference

Conferencia

Conferencia	20th ACM/IFIP/USENIX Middleware Conference, Middleware 2019
País/Territorio	Estados Unidos
Ciudad	Davis
Período	12/9/19 → 12/13/19

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Software

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

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10.1145/3361525.3361547

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Birke, R., Rocha, I., Perez, J., Schiavoni, V., Felber, P., & Chen, L. Y. (2019). Differential approximation and sprinting for multi-priority big data engines. En Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference (pp. 202-214). (Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference). Association for Computing Machinery. https://doi.org/10.1145/3361525.3361547

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title = "Differential approximation and sprinting for multi-priority big data engines",

abstract = "Today{\textquoteright}s big data clusters based on the MapReduce paradigm are capable of executing analysis jobs with multiple priorities, providing differential latency guarantees. Traces from production systems show that the latency advantage of high-priority jobs comes at the cost of severe latency degradation of low-priority jobs as well as daunting resource waste caused by repetitive eviction and re-execution of low-priority jobs. We advocate a new resource management design that exploits the idea of differential approximation and sprinting. The unique combination of approximation and sprinting avoids the eviction of low-priority jobs and its consequent latency degradation and resource waste. To this end, we designed, implemented and evaluated DiAS, an extension of the Spark processing engine to support deflate jobs by dropping tasks and to sprint jobs. Our experiments on scenarios with two and three priority classes indicate that DiAS achieves up to 90% and 60% latency reduction for low- and high-priority jobs, respectively. DiAS not only eliminates resource waste but also (surprisingly) lowers energy consumption up to 30% at only a marginal accuracy loss for low-priority jobs.",

author = "Robert Birke and Isabelly Rocha and Juan Perez and Valerio Schiavoni and Pascal Felber and Chen, {Lydia Y.}",

note = "Funding Information: The research leading to these results has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation programme under the LEGaTO Project (legato-project. eu), grant agreement No 780681. This work has been partly funded by the Swiss National Science Foundation NRP75 project 407540_167266. Publisher Copyright: {\textcopyright} 2019 Association for Computing Machinery. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.; 20th ACM/IFIP/USENIX Middleware Conference, Middleware 2019 ; Conference date: 09-12-2019 Through 13-12-2019",

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doi = "10.1145/3361525.3361547",

language = "English (US)",

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Birke, R, Rocha, I, Perez, J, Schiavoni, V, Felber, P & Chen, LY 2019, Differential approximation and sprinting for multi-priority big data engines. En Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference. Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference, Association for Computing Machinery, pp. 202-214, 20th ACM/IFIP/USENIX Middleware Conference, Middleware 2019, Davis, Estados Unidos, 12/9/19. https://doi.org/10.1145/3361525.3361547

Differential approximation and sprinting for multi-priority big data engines. / Birke, Robert; Rocha, Isabelly; Perez, Juan et al.
Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference. Association for Computing Machinery, 2019. p. 202-214 (Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference).

Producción científica: Capítulo en Libro/Reporte › Contribución a la conferencia

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N1 - Funding Information: The research leading to these results has received funding from the European Union’s Horizon 2020 research and innovation programme under the LEGaTO Project (legato-project. eu), grant agreement No 780681. This work has been partly funded by the Swiss National Science Foundation NRP75 project 407540_167266. Publisher Copyright: © 2019 Association for Computing Machinery. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2019/12/9

Y1 - 2019/12/9

N2 - Today’s big data clusters based on the MapReduce paradigm are capable of executing analysis jobs with multiple priorities, providing differential latency guarantees. Traces from production systems show that the latency advantage of high-priority jobs comes at the cost of severe latency degradation of low-priority jobs as well as daunting resource waste caused by repetitive eviction and re-execution of low-priority jobs. We advocate a new resource management design that exploits the idea of differential approximation and sprinting. The unique combination of approximation and sprinting avoids the eviction of low-priority jobs and its consequent latency degradation and resource waste. To this end, we designed, implemented and evaluated DiAS, an extension of the Spark processing engine to support deflate jobs by dropping tasks and to sprint jobs. Our experiments on scenarios with two and three priority classes indicate that DiAS achieves up to 90% and 60% latency reduction for low- and high-priority jobs, respectively. DiAS not only eliminates resource waste but also (surprisingly) lowers energy consumption up to 30% at only a marginal accuracy loss for low-priority jobs.

AB - Today’s big data clusters based on the MapReduce paradigm are capable of executing analysis jobs with multiple priorities, providing differential latency guarantees. Traces from production systems show that the latency advantage of high-priority jobs comes at the cost of severe latency degradation of low-priority jobs as well as daunting resource waste caused by repetitive eviction and re-execution of low-priority jobs. We advocate a new resource management design that exploits the idea of differential approximation and sprinting. The unique combination of approximation and sprinting avoids the eviction of low-priority jobs and its consequent latency degradation and resource waste. To this end, we designed, implemented and evaluated DiAS, an extension of the Spark processing engine to support deflate jobs by dropping tasks and to sprint jobs. Our experiments on scenarios with two and three priority classes indicate that DiAS achieves up to 90% and 60% latency reduction for low- and high-priority jobs, respectively. DiAS not only eliminates resource waste but also (surprisingly) lowers energy consumption up to 30% at only a marginal accuracy loss for low-priority jobs.

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M3 - Conference contribution

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Birke R, Rocha I, Perez J, Schiavoni V, Felber P, Chen LY. Differential approximation and sprinting for multi-priority big data engines. En Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference. Association for Computing Machinery. 2019. p. 202-214. (Middleware 2019 - Proceedings of the 2019 20th International Middleware Conference). doi: 10.1145/3361525.3361547

Differential approximation and sprinting for multi-priority big data engines

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