Adaptive Channel Buffers in On-Chip Interconnection Networks— A Power and Performance Analysis

Abstract

On-chip interconnection networks (OCINs) have emerged as a modular and scalable solution for wire delay constraints in deep submicron VLSI design. OCIN research has shown that the design of buffers in the router influences the energy consumption, area overhead, and overall performance of the network. In this paper, we propose a low-power low-area OCIN architecture by reducing the number of buffers within the router. To minimize the performance degradation due to the reduced buffer size, we use the already existing repeaters along the inter-router channels to double as buffers along the channel when required. At low network loads, the proposed adaptive channel buffers function as conventional repeaters, propagating the signals. At high network loads, the adaptive channel buffers function as storage elements in addition to the router buffers. The router buffers can be assigned either statically or dynamically to the incoming packets. Static allocation reserves equal buffer space partitioned among all of the incoming packets, whereas dynamic allocation reserves buffer space on a per-flit basis, enabling higher buffer occupancy. We evaluate the proposed adaptive channel buffers with both static and dynamic buffer allocation policies in the 90-nm technology node, using 8 times 8 mesh and folded torus network topologies. Simulation results using the SPLASH-2 suite benchmarks and synthetic traffic patterns show that, by reducing the router buffer size, our proposed architecture achieves nearly 40 percent savings in router buffer power, 30 percent savings in overall network power, and 41 percent savings in area, with only a marginal 1-5 percent drop in throughput under dynamic buffer allocation and about 10-20 percent drop in throughput for statically assigned buffers.