An Embedded Java Virtual Machine Using Network-on-Chip Design

Seventeenth IEEE International Workshop on Rapid System Prototyping (RSP'06) Pub Date : 2006-06-14 DOI:10.1109/RSP.2006.7

Graham Mathias, K. Kent

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引用次数: 7

Abstract

Virtual machine technology allows for the reuse of applications and code over various heterogeneous platforms. A virtual machine simply adds another layer of abstraction between the application and the native hardware. A major drawback of an application running on a virtual machine, however, is that the performance is below that of an application targeted for a native platform. Previous work has dealt with improving the performance of a virtual machine through hardware support using field programmable gate arrays (FPGAs). With the growing capacities of FPGAs it is becoming possible to provide higher levels of hardware support. This work examines the Java virtual machine (JVM), by implementing it in hardware, using a network-on-chip (NoC) design methodology. A subset of the JVM instructions are implemented in a hardware engine, with the more complex operations performed in software, and this hardware engine is replicated numerous times within the FPGA. By having several JVM instances execute in hardware concurrently, multiple applications and/or threads can simultaneously benefit from hardware implementation

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基于片上网络设计的嵌入式Java虚拟机

虚拟机技术允许在各种异构平台上重用应用程序和代码。虚拟机只是在应用程序和本机硬件之间添加了另一层抽象。然而，在虚拟机上运行应用程序的一个主要缺点是其性能低于针对本机平台的应用程序。以前的工作是通过使用现场可编程门阵列(fpga)的硬件支持来提高虚拟机的性能。随着fpga容量的不断增长，提供更高级别的硬件支持成为可能。这项工作通过使用片上网络(NoC)设计方法在硬件中实现Java虚拟机(JVM)来研究它。JVM指令的子集在硬件引擎中实现，更复杂的操作在软件中执行，并且该硬件引擎在FPGA中被复制多次。通过在硬件中并发执行多个JVM实例，多个应用程序和/或线程可以同时受益于硬件实现

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Seventeenth IEEE International Workshop on Rapid System Prototyping (RSP'06)

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