E. Baydal scite author profile

Multiprocessor interconnection networks may reach congestion with high traffic loads, which prevents reaching the wished performance. Unfortunately, many of the mechanisms proposed in the literature for congestion control either suffer from a lack of robustness, being unable to work properly with different traffic patterns or message lengths, or detect congestion relying on global information that wastes some network bandwidth. This paper presents a family of mechanisms to avoid network congestion in wormhole networks. All of them need only local information, applying message throttling when it is required. The proposed mechanisms use different strategies to detect network congestion and also apply different corrective actions. The mechanisms are evaluated and compared for several network loads and topologies, noticeably improving network performance with high loads but without penalizing network behavior for low and medium traffic rates, where no congestion control is required.

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A simple and efficient mechanism to prevent saturation in wormhole networks

Baydal

López

Duato

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Both deadlock avoidance and recovery techniques suffer from severe performance degradation when the network is close to or beyond saturation. This performance degradation appears because messages block in the network faster than they are drained by the escape paths in the deadlock avoidance strategies or the deadlock recovery mechanism.Many parallel applications produce bursty traffic that may saturate the network during some intervals [14,8], significantly increasing execution time. Therefore, the use of techniques that prevent network saturation are of crucial importance. Although several mechanisms have been proposed in the literature to reach this goal, some of them introduce some penalty when the network is not fully saturated, require complex hardware to be implemented or do not behave well under all network load conditions. In this paper, we propose a new mechanism to avoid network saturation that overcomes these drawbacks.

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Towards an efficient switch architecture for high-radix switches

Mora

Flich

Duato

et al. 2006

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The interconnection network plays a key role in the overall performance achieved by high performance computing systems, also contributing an increasing fraction of its cost and power consumption. Current trends in interconnection network technology suggest that high-radix switches will be preferred as networks will become smaller (in terms of switch count) with the associated savings in packet latency, cost, and power consumption. Unfortunately, current switch architectures have scalability problems that prevent them from being effective when implemented with a high number of ports.In this paper, an efficient and cost-effective architecture for high-radix switches is proposed. The architecture, referred to as Partitioned Crossbar Input Queued (PCIQ), relies on three key components: a partitioned crossbar organization that allows the use of simple arbiters and crossbars, a packet-based arbiter, and a mechanism to eliminate the switch-level HOL blocking.Under uniform traffic, maximum switch efficiency is achieved. Furthermore, switch-level HOL blocking is completely eliminated under hot-spot traffic, again delivering maximum throughput. Additionally, PCIQ inherently implements an efficient congestion management technique that eliminates all the network-wide HOL blocking. On the contrary, the previously proposed architectures either show poor performance or they require significantly higher costs than PCIQ (in both components and complexity).

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A Robust Mechanism for Congestion Control: INC

Baydal

López

2003

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Several techniques to prevent congestion in multiprocessor interconnection networks have been recently proposed. Unfortunately, they either suffer from a lack of robustness or detect congestion relying on global information that wastes a lot of transmission resources. This paper presents a new mechanism that uses only local information to avoid network saturation in wormhole networks. It is robust and works properly in different conditions. It first applies preventive measures of different intensity depending on the estimated traffic level; and if necessary, it uses message throttling during predefined time intervals that are extended if congestion is repeatedly detected. Evaluation results for different network loads and topologies show that the proposed mechanism avoids network performance degradation. Most important, without introducing any penalty for low and medium network loads.

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Avoiding Network Congestion with Local Information

Baydal

López

Duato

2002

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E. Baydal

A family of mechanisms for congestion control in wormhole networks

A simple and efficient mechanism to prevent saturation in wormhole networks

Towards an efficient switch architecture for high-radix switches

A Robust Mechanism for Congestion Control: INC

Avoiding Network Congestion with Local Information

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