Integrating a parallel computer and a heterogeneous workstation cluster into a metacomputer system

Two types of parallel computers commonly used or solving large scientific problems are clusters of workstations and distributed-memory multicomputers. Each system has strengths and weaknesses for this task. Workstation clusters have a high performance to cost ratio and the advantage of the latest processors. Workstations are commonly under-utilized and can provide an inexpensive source of CPU cycles. However, clusters of workstations cannot compete with the performance of a dedicated supercomputer. This research proposes that creating a metacomputer combining different types of parallel computers can provide some of the advantages of each separate system. Specifically, I have inte­grated a distributed-memory parallel computer (the MEIKO CS-2) with a heterogeneous cluster of workstations. The integrated system uses the CHARM parallel-programming environment to provide for machine-independence and ease of programming in this heterogeneous environment. The availability of processing capacity limits the size and complexity of the types o[ problems that can be efficiently solved. By creating a meta.computer the amount of processing capacity can be increased at relatively low costs. The low cost of the system and the fact that it is easily reconfigurable make it a good choice for solving large-scale Grand Challenge type scientific problems

An Empirical Comparison of Networks and Routing Strategies for Parallel Computation

This paper compares message routing capabilities of important networks proposed for general-purpose parallel computing. All the networks have been proven to have some type of universality property, i.e., an ability to simulate other networks of comparable cost with modest slowdown, using appropriate cost and communication models. But in this paper we seek an empirical comparison of communication capability under typical direct use rather than an analysis of worst-case results for simulating message traffic of another network

Designing Efficient Network Interfaces For System Area Networks

The network is the key component of a Cluster of Workstations/PCs. Its performance, measured in terms of bandwidth and latency, has a great impact on the overall system performance. It quickly became clear that traditional WAN/LAN technology is not too well suited for interconnecting powerful nodes into a cluster. Their poor performance too often slows down communication-intensive applications. This observation led to the birth of a new class of networks called System Area Networks (SAN). The ATOLL network introduces a new optimized architecture for SANs. On a single chip, not one but four network interfaces (NI) have been implemented, together with an on-chip 4x4 full-duplex switch and four link interfaces. This unique "Network on a Chip" architecture is best suited for interconnecting SMP nodes, where multiple CPUs are given an exclusive NI and do not have to share a single interface. It also removes the need for any additional switching hardware, since the four byte-wide full-duplex links can be connected by cables with neighbor nodes in an arbitrary network topology