Existing high-performance computing (HPC) interconnection architectures are based on high-radix switches, which limits the injection/local performance and introduces latency/energy/cost overhead. The new wafer-scale packaging and high-speed wireline technologies provide high-density, low-latency, and high-bandwidth connectivity, thus promising to support direct-connected high-radix interconnection architecture. In this paper, we propose a wafer-based interconnection architecture called Switch-Less-Dragonfly-on-Wafers. By utilizing distributed high-bandwidth networks-on-chip-on-wafer, costly high-radix switches of the Dragonfly topology are eliminated while increasing the injection/local throughput and maintaining the global throughput. Based on the proposed architecture, we also introduce baseline and improved deadlock-free minimal/non-minimal routing algorithms with only one additional virtual channel. Extensive evaluations show that the Switch-Less-Dragonfly-on-Wafers outperforms the traditional switch-based Dragonfly in both cost and performance. Similar approaches can be applied to other switch-based direct topologies, thus promising to power future large-scale supercomputers.
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