A next generation channeled-DRAM architecture with direct background-operation and delayed channel-replacement techniques

Y. Yabe, N. Nakamura, Y. Aimoto, M. Motomura, Yasuhiro Matsui, Y. Adakura
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引用次数: 2

Abstract

As processor performance is reaching the level of executing a single instruction in 1 ns, long memory latencies have become a critical problem, because a single memory access could stall the execution of hundreds of instructions. A recently announced channeled-DRAM approaches this problem by integrating a small low-latency buffer, called "channels", in front of a DRAM core in order to reduce the effective memory latency. Since the channels can provide intrinsically faster access than that of a bare DRAM core when they hit, key considerations in this architecture become (1) how to achieve high channel hit rates and (2) how to reduce the channel-miss latencies. Since channeled-DRAMs rely on an external memory controller to handle all the channel management, design of the memory controller heavily dominates the first issue. In this paper, we propose two novel techniques for reducing the channel-miss latencies: direct background operation and delayed channel replacement. We examined these techniques in a future 256-Mb DRAM with a 200-MHz double-data-rate (DDR) synchronous interface. Both SPICE simulation results (that show channel-miss latency reduction) and system-level simulation results (that reveal system-level performance improvement) are presented.
具有直接后台操作和延迟通道替换技术的下一代通道dram架构
随着处理器性能达到在1ns内执行一条指令的水平,长内存延迟已经成为一个关键问题,因为单个内存访问可能会使数百条指令的执行停滞。最近发布的通道DRAM解决了这个问题,它在DRAM核心前面集成了一个小的低延迟缓冲区,称为“通道”,以减少有效的内存延迟。由于通道在命中时可以提供比裸DRAM内核更快的访问速度,因此该体系结构中的关键考虑因素是:(1)如何实现高通道命中率和(2)如何减少通道丢失延迟。由于通道dram依赖于外部存储器控制器来处理所有的通道管理,因此存储器控制器的设计在很大程度上主导了第一个问题。在本文中,我们提出了两种新的技术来减少信道缺失延迟:直接后台操作和延迟信道替换。我们在未来具有200 mhz双数据速率(DDR)同步接口的256 mb DRAM中测试了这些技术。给出了SPICE仿真结果(显示信道丢失延迟减少)和系统级仿真结果(显示系统级性能改进)。
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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