An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads
Parallel graph-oriented applications expressed in the Bulk-Synchronous Parallel (BSP) and Token Dataflow compute models generate highly-structured communication workloads from messages propagating along graph edges. We can statially expose this structure to traffic compilers and optimization tools t...
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sg-ntu-dr.10356-811182020-05-28T07:18:18Z An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads Kapre, Nachiket Dehon, André School of Computer Engineering Computer Science and Engineering Parallel graph-oriented applications expressed in the Bulk-Synchronous Parallel (BSP) and Token Dataflow compute models generate highly-structured communication workloads from messages propagating along graph edges. We can statially expose this structure to traffic compilers and optimization tools to reshape and reduce traffic for higher performance (or lower area, lower energy, lower cost). Such offline traffic optimization eliminates the need for complex, runtime NoC hardware and enables lightweight, scalable NoCs. We perform load balancing, placement, fanout routing, and fine-grained synchronization to optimize our workloads for large networks up to 2025 parallel elements for BSP model and 25 parallel elements for Token Dataflow. This allows us to demonstrate speedups between 1.2× and 22× (3.5× mean), area reductions (number of Processing Elements) between 3× and 15× (9× mean) and dynamic energy savings between 2× and 3.5× (2.7× mean) over a range of real-world graph applications in the BSP compute model. We deliver speedups of 0.5–13× (geomean 3.6×) for Sparse Direct Matrix Solve (Token Dataflow compute model) applied to a range of sparse matrices when using a high-quality placement algorithm. We expect such traffic optimization tools and techniques to become an essential part of the NoC application-mapping flow. Published version 2015-12-17T04:05:09Z 2019-12-06T14:21:48Z 2015-12-17T04:05:09Z 2019-12-06T14:21:48Z 2011 Journal Article Kapre, N., & Dehon, A. (2011). An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads. International Journal of Reconfigurable Computing, 2011, 745147-. 1687-7195 https://hdl.handle.net/10356/81118 http://hdl.handle.net/10220/39124 10.1155/2011/745147 en International Journal of Reconfigurable Computing © 2011 Nachiket Kapre and André Dehon. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 14 p. application/pdf |
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Computer Science and Engineering Kapre, Nachiket Dehon, André An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| description |
Parallel graph-oriented applications expressed in the Bulk-Synchronous Parallel (BSP) and Token Dataflow compute models generate highly-structured communication workloads from messages propagating along graph edges. We can statially expose this structure to traffic compilers and optimization tools to reshape and reduce traffic for higher performance (or lower area, lower energy, lower cost). Such offline traffic optimization eliminates the need for complex, runtime NoC hardware and enables lightweight, scalable NoCs. We perform load balancing, placement, fanout routing, and fine-grained synchronization to optimize our workloads for large networks up to 2025 parallel elements for BSP model and 25 parallel elements for Token Dataflow. This allows us to demonstrate speedups between 1.2× and 22× (3.5× mean), area reductions (number of Processing Elements) between 3× and 15× (9× mean) and dynamic energy savings between 2× and 3.5× (2.7× mean) over a range of real-world graph applications in the BSP compute model. We deliver speedups of 0.5–13× (geomean 3.6×) for Sparse Direct Matrix Solve (Token Dataflow compute model) applied to a range of sparse matrices when using a high-quality placement algorithm. We expect such traffic optimization tools and techniques to become an essential part of the NoC application-mapping flow. |
| author2 |
School of Computer Engineering |
| author_facet |
School of Computer Engineering Kapre, Nachiket Dehon, André |
| format |
Article |
| author |
Kapre, Nachiket Dehon, André |
| author_sort |
Kapre, Nachiket |
| title |
An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| title_short |
An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| title_full |
An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| title_fullStr |
An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| title_full_unstemmed |
An NoC Traffic Compiler for Efficient FPGA Implementation of Sparse Graph-Oriented Workloads |
| title_sort |
noc traffic compiler for efficient fpga implementation of sparse graph-oriented workloads |
| publishDate |
2015 |
| url |
https://hdl.handle.net/10356/81118 http://hdl.handle.net/10220/39124 |
| _version_ |
1681057057493483520 |