Composable accelerator-rich microprocessor enhanced for adaptivity and longevity

Author

Cong, J. ; Ghodrat, Mohammad Ali ; Gill, Michael ; Grigorian, Beayna ; Hui Huang ; Reinman, Glenn

fYear

2013

fDate

4-6 Sept. 2013

Firstpage

305

Lastpage

310

Abstract

Accelerator-rich platforms demonstrate orders of magnitude improvement in performance and energy efficiency over software, yet they lack adaptivity to new algorithms and can see low accelerator utilization. To address these issues we propose CAMEL: Composable Accelerator-rich Microprocessor Enhanced for Longevity. CAMEL features programmable fabric (PF) to extend the use of ASIC composable accelerators in supporting algorithms that are beyond the scope of the baseline platform. Using a combination of hardware extensions and compiler support, we demonstrate on average 11.6X performance improvement and 13.9X energy savings across benchmarks that deviate from the original domain for our baseline platform.

Keywords

application specific integrated circuits; benchmark testing; energy conservation; microprocessor chips; performance evaluation; power aware computing; program compilers; ASIC composable accelerators; CAMEL; accelerator utilization; accelerator-rich platforms; composable accelerator-rich microprocessor enhanced for longevity; energy efficiency; energy savings; performance improvement; programmable fabric; software performance; Acceleration; Application specific integrated circuits; Benchmark testing; Computer architecture; Fabrics; Hardware; Resource management; Accelerator Composition; Adaptivity; Hardware Accelerators; Longevity; Programmable Fabric;

fLanguage

English

Publisher

ieee

Conference_Titel

Low Power Electronics and Design (ISLPED), 2013 IEEE International Symposium on

Conference_Location

Beijing

Print_ISBN

978-1-4799-1234-6

Type

conf

DOI

10.1109/ISLPED.2013.6629314

Filename

6629314