Abstract

Nanophotonics is a promising solution for on-chip interconnection due to its intrinsic low-latency and low-power features, which can be useful for performance and energy in future Chip Multi-Processors (CMPs). This article proposes a novel arbitrated all-optical path-setup scheme for tiled CMPs adopting circuit-switched optical networks. It aims at significantly reducing path-setup latency and overall energy consumption. The proposed arbitrated scheme is able to configure multiple photonic switches simultaneously, instead of sequentially as it is done in state-of-the-art proposals. The proposed fast optical path-setup solution reduces the overhead in each transmission and, most importantly, allows optical circuit-switched networks to effectively serve cache coherence traffic, which is mainly composed of relatively small messages. Specifically, we propose a single-arbiter scheme where the whole topology is managed by a central module (single-arbiter) that takes care of the path-setup procedures. Then, to tackle scalability, we propose a logically clustered architecture (multi-arbiter) in which an arbiter is allocated in each logical core-cluster and an ad hoc distributed reservation protocol coordinates arbiters to manage inter-cluster path reservations. We show that our proposed single-arbiter architecture outperforms a state-of-the-art optical network with sequential path-setup (optical baseline) in the case of 8- and 16-core tiled CMP setups. However, due to serialization issues, the single-arbiter solution is not able to compete with a reference electronic baseline for bigger 32- and 64-core setups even if still performing much better than the optical baseline. Conversely, our multi-arbiter hierarchical solution allows us to improve performance up to almost 20% and 40% for 32- and 64-core setups, respectively, demonstrating a wide applicability of the proposed technique. Energy-wise, the analyzed solutions enable significant savings compared to both the optical baseline with sequential path setup, and to the electronic counterpart. Specifically, results show more than 25% average improvement for the single-arbiter in the 8- and 16-core cases, and more than 40% and 15% savings for the multi-arbiter in the 32- and 64-core cases, respectively.

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