The design of nectar: a network backplane for heterogeneous multicomputers

Arnould, E.; Kung, H. T.; Bitz, Francois; Sansom, Robert D.; Cooperm, Eric C.

doi:10.1145/68182.68202

Cited by 66 publications

(12 citation statements)

References 10 publications

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“…Interestingly, with only a few exceptions [YKS86], [F93], [ABC89] this class of switch is not well represented in the literature. Part of the rationale for the development of array switches was that not all of the crosspoints were needed [C53].…”

Section: Crossbar Switchesmentioning

confidence: 99%

Perspectives on ATM switch architecture and the influence of traffic pattern assumptions on switch design

Simcoe

Pei

1995

SIGCOMM Comput. Commun. Rev.

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Switch designs and the uniform distribution traffic pattern that has been the basis of much switch design analysis are discussed. In particular it is shown that head of line blocking is not the major cause of switch and link underutilization. Switch fabric and buffer system input bandwidth tradeoffs are described. For client server applications it is shown that having the majority of switch buffers on the input side of a switch reduces overall switch buffeting.

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Section: Crossbar Switchesmentioning

confidence: 99%

Perspectives on ATM switch architecture and the influence of traffic pattern assumptions on switch design

Simcoe

Pei

1995

SIGCOMM Comput. Commun. Rev.

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“…Figure 2 shows a pathway between node (0,O) and node (1,3) that consists of four pathway segments: (0,O) -9 (OJ), (0,l) 3 (l,l), (1,l) + (1,2), and (1,2) 4 (1.3). The communication agents of nodes (OJ), (1,l) and (1,2) provide resources to implement the pathway segments that form this pathway, but these nodes cannot access any data that is transmitted over the pathway (nor can they use this pathway to send data). An iWarp network consists of nodes and pathways between these nodes.…”

Section: Networkmentioning

confidence: 99%

Communication in iWarp systems

Groß

1989

Proceedings of the 1989 ACM/IEEE Conference on Supercomputing - Supercomputing '89

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The iWarp processor is a buildiig block for parallel systems and is developed in a joint project by Carnegie Mellon University and Intel Corporation.The iWarp processor integrates computation and communication:the iWarp component architecture consists of a computation agent. capable of delivering 20 MFLOPS and 20 MIPS, and a communication agent that provides a bandwidth of 320 MBytes&c.We expect the first iWarp-based system to be available early 1990, organized as a 8x8 two-dimensional torus.Fast inter-processor communication is crucial for the success of a parallel system, and this paper describes communication in iWarp systems. We review the communication models, message passing and systolic communication, that this architecture aims to support and introduce the types of networks that can be realized by the iWarp communication agent. We also sketch a programmer interface to these networks and give usage examples for iWarp networks.

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“…Many high-performance computing systems (e.g., clusters [2] and grids [19]) employ such high-speed networks [1,3,23,42]. On the other hand, with the rapid increase of data volume to process, efficient data exchange between the computing nodes becomes more critical for many parallel/distributed applications.…”

Section: Introductionmentioning

confidence: 99%

Impact of protocol overheads on network throughput over high-speed interconnects: measurement, analysis, and improvement

Jin

2007

J Supercomput

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Although extremely high-speed interconnects are available today, the traditional protocol stacks such as TCP/IP and UDP/IP are not able to utilize the maximum network bandwidth due to inherent overheads in the protocol stacks. Such overheads are a big obstacle for high-performance computing applications to exploit highspeed interconnects in cluster environments. To address this issue, many researchers have been presenting analyses of protocol overheads and suggesting a number of optimization approaches to harness the TCP/IP suite over high-speed interconnects. However, to the best of our knowledge, there is no study that analyzes and optimizes the protocol overheads thoroughly in an integrated manner. In this paper, we exploit a set of protocol optimization mechanisms in an integrated manner while dealing with the full spectrum of the protocol layers from the transport layer to the physical layer. To evaluate the impact of each protocol overhead, we apply the optimization mechanisms one by one and perform detailed analyses at each step. The thorough overhead measurements and analyses reveal the dependencies between protocol overheads. With our comprehensive optimizations, we show that UDP/IP can utilize more than 95% of the maximum network throughput a Myrinet-based experimental system can provide.

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The design of nectar: a network backplane for heterogeneous multicomputers

Cited by 66 publications

References 10 publications

Perspectives on ATM switch architecture and the influence of traffic pattern assumptions on switch design

Perspectives on ATM switch architecture and the influence of traffic pattern assumptions on switch design

Communication in iWarp systems

Impact of protocol overheads on network throughput over high-speed interconnects: measurement, analysis, and improvement

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