The Celerity Open-Source 511-Core RISC-V Tiered Accelerator Fabric: Fast Architectures and Design Methodologies for Fast Chips

Scott Davidson; Shaolin Xie; Christopher Torng; Khalid Al-Hawai; Austin Rovinski; Tutu Ajayi; Luis Vega; Chun Zhao; Ritchie Zhao; Steve Dai; Aporva Amarnath; Bandhav Veluri; Paul Gao; Anuj Rao; Gai Liu; Rajesh K. Gupta; Zhiru Zhang; Ronald Dreslinski; Christopher Batten; Michael Bedford Taylor

doi:10.1109/MM.2018.022071133

The Celerity Open-Source 511-Core RISC-V Tiered Accelerator Fabric: Fast Architectures and Design Methodologies for Fast Chips

Scott Davidson
, Shaolin Xie
, Christopher Torng
, Khalid Al-Hawai
, Austin Rovinski
, Tutu Ajayi
, Luis Vega
, Chun Zhao
, Ritchie Zhao
, Steve Dai
, Aporva Amarnath
, Bandhav Veluri
, Paul Gao
, Anuj Rao
, Gai Liu
, Rajesh K. Gupta
, Zhiru Zhang
, Ronald Dreslinski
, Christopher Batten
, Michael Bedford Taylor

Research output: Contribution to journal › Article › peer-review

78 Scopus citations

Abstract

Rapidly emerging workloads require rapidly developed chips. The Celerity 16-nm open-source SoC was implemented in nine months using an architectural trifecta to minimize development time: a general-purpose tier comprised of open-source Linux-capable RISC-V cores, a massively parallel tier comprised of a RISC-V tiled manycore array that can be scaled to arbitrary sizes, and a specialization tier that uses high-level synthesis (HLS) to create an algorithmic neural-network accelerator. These tiers are tied together with an efficient heterogeneous remote store programming model on top of a flexible partial global address space memory system.

Original language	English
Pages (from-to)	30-41
Number of pages	12
Journal	IEEE Micro
Volume	38
Issue number	2
DOIs	https://doi.org/10.1109/MM.2018.022071133
State	Published - 1 Mar 2018
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 1981-2012 IEEE.

Keywords

hardware
microchips

ASJC Scopus subject areas

Software
Hardware and Architecture
Electrical and Electronic Engineering

Access to Document

10.1109/MM.2018.022071133

Cite this

Davidson, S., Xie, S., Torng, C., Al-Hawai, K., Rovinski, A., Ajayi, T., Vega, L., Zhao, C., Zhao, R., Dai, S., Amarnath, A., Veluri, B., Gao, P., Rao, A., Liu, G., Gupta, R. K., Zhang, Z., Dreslinski, R., Batten, C., & Taylor, M. B. (2018). The Celerity Open-Source 511-Core RISC-V Tiered Accelerator Fabric: Fast Architectures and Design Methodologies for Fast Chips. IEEE Micro, 38(2), 30-41. https://doi.org/10.1109/MM.2018.022071133

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abstract = "Rapidly emerging workloads require rapidly developed chips. The Celerity 16-nm open-source SoC was implemented in nine months using an architectural trifecta to minimize development time: a general-purpose tier comprised of open-source Linux-capable RISC-V cores, a massively parallel tier comprised of a RISC-V tiled manycore array that can be scaled to arbitrary sizes, and a specialization tier that uses high-level synthesis (HLS) to create an algorithmic neural-network accelerator. These tiers are tied together with an efficient heterogeneous remote store programming model on top of a flexible partial global address space memory system.",

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author = "Scott Davidson and Shaolin Xie and Christopher Torng and Khalid Al-Hawai and Austin Rovinski and Tutu Ajayi and Luis Vega and Chun Zhao and Ritchie Zhao and Steve Dai and Aporva Amarnath and Bandhav Veluri and Paul Gao and Anuj Rao and Gai Liu and Gupta, \{Rajesh K.\} and Zhiru Zhang and Ronald Dreslinski and Christopher Batten and Taylor, \{Michael Bedford\}",

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year = "2018",

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doi = "10.1109/MM.2018.022071133",

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Davidson, S, Xie, S, Torng, C, Al-Hawai, K, Rovinski, A, Ajayi, T, Vega, L, Zhao, C, Zhao, R, Dai, S, Amarnath, A, Veluri, B, Gao, P, Rao, A, Liu, G, Gupta, RK, Zhang, Z, Dreslinski, R, Batten, C & Taylor, MB 2018, 'The Celerity Open-Source 511-Core RISC-V Tiered Accelerator Fabric: Fast Architectures and Design Methodologies for Fast Chips', IEEE Micro, vol. 38, no. 2, pp. 30-41. https://doi.org/10.1109/MM.2018.022071133

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AU - Zhao, Chun

AU - Zhao, Ritchie

AU - Dai, Steve

AU - Amarnath, Aporva

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The Celerity Open-Source 511-Core RISC-V Tiered Accelerator Fabric: Fast Architectures and Design Methodologies for Fast Chips

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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