TY - GEN
T1 - Design of randomized multichannel packet storage for high performance routers
AU - Kumar, Sailesh
AU - Crowley, Patrick
AU - Turner, Jonathan
PY - 2005
Y1 - 2005
N2 - High performance routers require substantial amounts of memory to store packets awaiting transmission, requiring the use of dedicated memory devices with the density and capacity to provide the required storage economically. The memory bandwidth required for packet storage subsystems often exceeds the bandwidth of individual memory devices, making it necessary to implement packet storage using multiple memory channels. This raises the question of how to design multichannel storage systems that make effective use of the available memory and memory bandwidth, while forwarding packets at link rate in the presence of arbitrary packet retrieval patterns. A recent series of papers has demonstrated an architecture that uses on-chip SRAM to buffer packets going to/from a multichannel storage system, while maintaining high performance in the presence worst-case traffic patterns. Unfortunately, the amount of on-chip storage required grows as the product of the number of channels and the number of separate queues served by the packet storage system. This makes it too expensive to use in systems with large numbers of queues. We show how to design a practical randomized packet storage system that can sustain high performance using an amount of on-chip storage that is independent of the number of queues.
AB - High performance routers require substantial amounts of memory to store packets awaiting transmission, requiring the use of dedicated memory devices with the density and capacity to provide the required storage economically. The memory bandwidth required for packet storage subsystems often exceeds the bandwidth of individual memory devices, making it necessary to implement packet storage using multiple memory channels. This raises the question of how to design multichannel storage systems that make effective use of the available memory and memory bandwidth, while forwarding packets at link rate in the presence of arbitrary packet retrieval patterns. A recent series of papers has demonstrated an architecture that uses on-chip SRAM to buffer packets going to/from a multichannel storage system, while maintaining high performance in the presence worst-case traffic patterns. Unfortunately, the amount of on-chip storage required grows as the product of the number of channels and the number of separate queues served by the packet storage system. This makes it too expensive to use in systems with large numbers of queues. We show how to design a practical randomized packet storage system that can sustain high performance using an amount of on-chip storage that is independent of the number of queues.
UR - https://www.scopus.com/pages/publications/33751172530
U2 - 10.1109/CONECT.2005.17
DO - 10.1109/CONECT.2005.17
M3 - Conference contribution
AN - SCOPUS:33751172530
SN - 0769524494
SN - 9780769524498
T3 - Proceedings - Symposium on the High Performance Interconnects, Hot Interconnects
SP - 100
EP - 106
BT - Proceedings - 13th Symposium on High Performance Interconnects, Hot Interconnects 13
T2 - 13th Symposium on High Performance Interconnects, Hot Interconnects 13
Y2 - 17 August 2005 through 19 August 2005
ER -