TY - GEN
T1 - ScaleHLS
T2 - 28th Annual IEEE International Symposium on High-Performance Computer Architecture
AU - Ye, Hanchen
AU - Hao, Cong
AU - Cheng, Jianyi
AU - Jeong, Hyunmin
AU - Huang, Jack
AU - Neuendorffer, Stephen
AU - Chen, Deming
PY - 2022/5/17
Y1 - 2022/5/17
N2 - High-level synthesis (HLS) has been widely adopted as it significantly improves the hardware design productivity and enables efficient design space exploration (DSE). Existing HLS tools are built using compiler infrastructures largely based on a single-level abstraction, such as LLVM. How-ever, as HLS designs typically come with intrinsic structural or functional hierarchies, different HLS optimization problems are often better solved with different levels of abstractions. This paper proposes ScaleHLS 1, a new scalable and customizable HLS framework, on top of a multi-level compiler infrastructure called MLIR. ScaleHLS represents HLS designs at multiple representation levels and provides an HLS-dedicated analysis and transform library to solve the optimization problems at the suitable levels. Using this library, we provide a DSE engine to generate optimized HLS designs automatically. In addition, we develop an HLS C front-end and a C/C++ emission back-end to translate HLS designs into/from MLIR for enabling an end-to-end compilation flow. Experimental results show that, comparing to the baseline designs without manual directives insertion and code-rewriting, that are only optimized by Xilinx Vivado HLS, ScaleHLS improves the performances with amazing quality-of-results - up to 768.1× better on computation kernel level programs and up to 3825.0× better on neural network models.
AB - High-level synthesis (HLS) has been widely adopted as it significantly improves the hardware design productivity and enables efficient design space exploration (DSE). Existing HLS tools are built using compiler infrastructures largely based on a single-level abstraction, such as LLVM. How-ever, as HLS designs typically come with intrinsic structural or functional hierarchies, different HLS optimization problems are often better solved with different levels of abstractions. This paper proposes ScaleHLS 1, a new scalable and customizable HLS framework, on top of a multi-level compiler infrastructure called MLIR. ScaleHLS represents HLS designs at multiple representation levels and provides an HLS-dedicated analysis and transform library to solve the optimization problems at the suitable levels. Using this library, we provide a DSE engine to generate optimized HLS designs automatically. In addition, we develop an HLS C front-end and a C/C++ emission back-end to translate HLS designs into/from MLIR for enabling an end-to-end compilation flow. Experimental results show that, comparing to the baseline designs without manual directives insertion and code-rewriting, that are only optimized by Xilinx Vivado HLS, ScaleHLS improves the performances with amazing quality-of-results - up to 768.1× better on computation kernel level programs and up to 3825.0× better on neural network models.
KW - compiler
KW - design space exploration
KW - FPGA
KW - high-level synthesis
KW - MLIR
KW - optimization
UR - http://www.scopus.com/inward/record.url?scp=85130728665&partnerID=8YFLogxK
U2 - 10.1109/HPCA53966.2022.00060
DO - 10.1109/HPCA53966.2022.00060
M3 - Conference contribution
AN - SCOPUS:85130728665
SN - 9781665420280
T3 - Proceedings of the International Symposium on High-Performance Computer Architecture
SP - 741
EP - 755
BT - 2022 IEEE International Symposium on High-Performance Computer Architecture
PB - Institute of Electrical and Electronics Engineers
Y2 - 2 April 2022 through 6 April 2022
ER -