Lightweight Emulation of Virtual Channels using Swaps

Proceedings of the 10th International Workshop on Network on Chip Architectures Pub Date : 2017-10-14 DOI:10.1145/3139540.3139541

Mayank Parasar, T. Krishna

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引用次数: 5

Abstract

Virtual Channels (VCs) are a fundamental design feature across networks, both on-chip and off-chip. They provide two key benefits - deadlock avoidance and head-of-line (HoL) blocking mitigation. However, VCs increase the router critical path, and add significant area and power overheads compared to simple wormhole routers. This is especially challenging in the era of energy-constrained many-core chips. The number of VCs required for deadlock avoidance is unavoidable, but those required for mitigating HoL depend on runtime factors such as the distribution and size of single and multi-flit packets, and their intended destinations. In some cases more VCs are beneficial, while in others they may actually harm performance, as we demonstrate. In this work, we provide a low-cost microarchitectural technique to emulate the HoL mitigation behavior of VCs inside routers, without requiring the expensive data path or control path (vc state and vc allocation) for VCs. We augment wormhole routers with the ability to do an in-place swap of blocked packets to the head of the queue. Our design (SwapNoC) can operate at low area and power specs like wormhole designs, without incurring their HoL challenges.

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使用交换的虚拟通道的轻量级仿真

虚拟通道(vc)是跨网络的基本设计特征，包括片内和片外。它们提供了两个关键的好处——避免死锁和缓解排队头阻塞。然而，与简单的虫洞路由器相比，风险投资增加了路由器的关键路径，并增加了显着的面积和功率开销。在能量受限的多核芯片时代，这尤其具有挑战性。避免死锁所需的vc数量是不可避免的，但减轻HoL所需的vc数量取决于运行时因素，例如单和多飞行数据包的分布和大小，以及它们的预期目的地。在某些情况下，更多的风投是有益的，而在其他情况下，他们实际上可能会损害业绩，正如我们所证明的那样。在这项工作中，我们提供了一种低成本的微架构技术来模拟路由器内vc的HoL缓解行为，而不需要昂贵的vc数据路径或控制路径(vc状态和vc分配)。我们增强了虫洞路由器，使其能够将阻塞的数据包就地交换到队列的头部。我们的设计(SwapNoC)可以像虫洞设计一样在低面积和低功率规格下工作，而不会遇到HoL的挑战。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 10th International Workshop on Network on Chip Architectures

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