Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/72657
Título: Evaluation of the field-programmable cache: performance and energy consumption
Autores/as: Benitez, Domingo 
Moure, Juan C.
Rexachs, Dolores I.
Luque, Emilio
Clasificación UNESCO: 330406 Arquitectura de ordenadores
3304 Tecnología de los ordenadores
Palabras clave: Adaptive processors
Performance evaluation
Reconfigurable cache memory
Run-time adaptation
Static and dynamic energy consumption
Fecha de publicación: 2006
Publicación seriada: Proceedings Of The 3Rd Conference On Computing Frontiers 2006, Cf '06
Conferencia: 3rd Conference on Computing Frontiers 2006, CF '06 
Resumen: Many authors have proposed power management techniques for general-purpose processors at the cost of degraded performance such as lower IPC or longer delay. Some proposals have focused on cache memories because they consume a significant fraction of total microprocessor power. We propose a reconfigurable and adaptive cache microarchitecture based on field-programmable technology that is intended to deliver high performance at low energy consumption. In this paper, we evaluate the performance and energy consumption of a run-time algorithm when used to manage a field-programmable L1 data cache. The adaptation strategy is based on two techniques: a learning process provides the best cache configuration for each program phase, and a recognition process detects program phase changes by using data working-set signatures to activate a low-overhead reconfiguration mechanism. Our proposals achieve performance improvement and cache energy saving at the same time. Considering a design scenario driven by performance constraints, we show that processor execution time and cache energy consumption can be reduced on average by 15.2% and 9.9% compared to a non-adaptive high-performance microarchitecture. Alternatively, when energy saving is prioritized and considering a non-adaptive energy-efficient microarchitecture as baseline, cache energy and processor execution time are reduced on average by 46.7% and 9.4% respectively. In addition to comparing to conventional microarchitectures, we show that the proposed microarchitecture achieves better performance and more cache energy reduction than other configurable caches.
URI: http://hdl.handle.net/10553/72657
ISBN: 978-1-59593-302-7
DOI: 10.1145/1128022.1128070
Fuente: Proceedings of the 3rd Conference on Computing Frontiers 2006, CF '06, v. 2006, p. 361-372, (Diciembre 2006)
Colección:Actas de congresos
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