A general analytical model of adaptive wormhole routing in k-ary n-cubes

Several analytical models of fully adaptive routing have recently been proposed for k-ary n-cubes and hypercube networks under the uniform traffic pattern. Although,hypercube is a special case of k-ary n-cubes topology, the modeling approach for hypercube is more accurate than karyn-cubes due to its simpler structure. This paper proposes a general analytical model to predict message latency in wormhole-routed k-ary n-cubes with fully adaptive routing that uses a similar modeling approach to hypercube. The analysis focuses Duato's fully adaptive routing algorithm [12], which is widely accepted as the most general algorithm for achieving adaptivity in wormhole-routed networks while allowing for an efficient router implementation. The proposed model is general enough that it can be used for hypercube and other fully adaptive routing algorithms

The impacts of timing constraints on virtual channels multiplexing in interconnect networks

Interconnect networks employing wormhole-switching play a critical role in shared memory multiprocessor systems-on-chip (MPSoC) designs, multicomputer systems and system area networks. Virtual channels greatly improve the performance of wormhole-switched networks because they reduce blocking by acting as "bypass" lanes for non-blocked messages. Capturing the effects of virtual channel multiplexing has always been a crucial issue for any analytical model proposed for wormhole-switched networks. Dally has developed a model to investigate the behaviour of this multiplexing which have been widely employed in the subsequent analytical models of most routing algorithms suggested in the literature. It is indispensable to modify Dally's model in order to evaluate the performance of channel multiplexing in more general networks where restrictions such as timing constraints of input arrivals and finite buffer size of queues are common. In this paper we consider timing constraints of input arrivals to investigate the virtual channel multiplexing problem inherent in most current networks. The analysis that we propose is completely general and therefore can be used with any interconnect networks employing virtual channels. The validity of the proposed equations has been verified through simulation experiments under different working conditions

High Performance and Power Efficient On-Chip Network Designs through Multiple Injection Ports

Las redes dentro de un chip se están convirtiendo en el elemento principal de los sistemas multiprocesador. A medida que aumenta la escala de integración, más elementos de cómputo (procesadores) se incluyen en el mismo chip. Estos componentes se interconectan con una red dentro del chip que debe ofrecer latencias de transmisión ultra bajas (orden de nanosegundos) y anchos de banda elevados. El diseño, pues, de una red eficiente dentro del chip juega un papel fundamental. En la presente tesis se analizan diferentes alternativas de diseño de las redes en el chip. En particular, se hace uso de la posibilidad de utilizar diferentes puertos de inyección desde los procesadores con el fin de obtener diferentes mejoras. En primer lugar, las prestaciones aumentan al tener procesadores con distintas alternativas de inyección de tráfico. En segundo lugar, además aumenta la tolerancia a fallos frente a defectos de fabricación (mas importantes conforme avanza la tecnología). Y en tercer lugar, permite una política de apagado de componentes más agresiva que nos permita un ahorro significativo de energía. Hemos evaluado diferentes topologías derivadas del mecanismo de inyección en términos de prestaciones, coste de implementación, y ahorro de consumo. Además, hemos desarrollado simuladores específicos para las distintas técnicas utilizadas. Cada topología diseñada supone una mejora respecto a la anterior, y por supuesto, teniendo en cuenta las topologías existentes. En resumen, nuestro esfuerzo se centra en conseguir un excelente compromiso entre prestaciones, consumo y tolerancia a fallos dentro de una red en chip. Para la primera propuesta (topología NR-Mesh), se alcanzan mejoras en prestaciones de un 7\% y hasta de un 75\% en reducción de consumo de media, comparado con la malla 2D o malla de 2 dimensiones. Para la siguiente propuesta, la malla concentrada paralela (PC-Mesh), el beneficio en prestaciones que se obtiene es de hasta un 20\%, así cómo de un 60\% en reducción deCamacho Villanueva, J. (2012). High Performance and Power Efficient On-Chip Network Designs through Multiple Injection Ports [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/18235Palanci

A performance model of multicast communication in wormhole-routed networks on-chip

Collective communication operations form a part of overall traffic in most applications running on platforms employing direct interconnection networks. This paper presents a novel analytical model to compute communication latency of multicast as a widely used collective communication operation. The novelty of the model lies in its ability to predict the latency of the multicast communication in wormhole-routed architectures employing asynchronous multi-port routers scheme. The model is applied to the Quarc NoC and its validity is verified by comparing the model predictions against the results obtained from a discrete-event simulator developed using OMNET++

Quarc: an architecture for efficient on-chip communication

The exponential downscaling of the feature size has enforced a paradigm shift from computation-based design to communication-based design in system on chip development. Buses, the traditional communication architecture in systems on chip, are incapable of addressing the increasing bandwidth requirements of future large systems. Networks on chip have emerged as an interconnection architecture offering unique solutions to the technological and design issues related to communication in future systems on chip. The transition from buses as a shared medium to networks on chip as a segmented medium has given rise to new challenges in system on chip realm. By leveraging the shared nature of the communication medium, buses have been highly efficient in delivering multicast communication. The segmented nature of networks, however, inhibits the multicast messages to be delivered as efficiently by networks on chip. Relying on extensive research on multicast communication in parallel computers, several network on chip architectures have offered mechanisms to perform the operation, while conforming to resource constraints of the network on chip paradigm. Multicast communication in majority of these networks on chip is implemented by establishing a connection between source and all multicast destinations before the message transmission commences. Establishing the connections incurs an overhead and, therefore, is not desirable; in particular in latency sensitive services such as cache coherence. To address high performance multicast communication, this research presents Quarc, a novel network on chip architecture. The Quarc architecture targets an area-efficient, low power, high performance implementation. The thesis covers a detailed representation of the building blocks of the architecture, including topology, router and network interface. The cost and performance comparison of the Quarc architecture against other network on chip architectures reveals that the Quarc architecture is a highly efficient architecture. Moreover, the thesis introduces novel performance models of complex traffic patterns, including multicast and quality of service-aware communication