Architecture and synthesis for multi-cycle on-chip communication

First IEEE/ACM/IFIP International Conference on Hardware/ Software Codesign and Systems Synthesis (IEEE Cat. No.03TH8721) Pub Date : 2003-10-01 DOI:10.1145/944645.944667

J. Cong, Yiping Fan, Guoling Han, Xun Yang, Zhiru Zhang

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引用次数: 5

Abstract

There are two important infection points in the development of deep submicron (DSM) process technologies. The first point is when the average interconnect delay exceeds the gate delay, which happened during mid 1990s and led to the so-called timing closure problem. The second point is when single-cycle full chip synchronization is no longer possible, which is about to happen soon. It can be shown that, even with the aggressive interconnect optimization techniques (e.g., buffer insertion and wire-sizing), 5 clock cycles are still needed to go from corner-to-corner for the die of 28.3 mm /spl times/ 28.3 mm in the 0.07 /spl mu/m technology generation, assuming a 5.63 GHz clock by 2006 predicted in ITRS'01 (2001). This clearly suggests that multi-cycle on-chip communication is a necessity in multi-gigahertz synchronous designs. However, it is not supported in the current design tools and methodologies, as most of these implicitly assume that full chip synchronization in a single clock cycle is feasible. Our contributions are as follows: (i) we propose a regular distributed register (RDR) microarchitecture which offers high regularity and direct support of multi-cycle communication; (ii) we develop a set of novel architectural synthesis algorithms to efficiently synthesize behavior-level designs onto the RDR architecture.

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多周期片上通信的体系结构与综合

深亚微米(DSM)工艺技术的发展有两个重要的关键点。第一个点是当平均互连延迟超过门延迟时，这种情况发生在20世纪90年代中期，导致所谓的定时关闭问题。第二个点是单周期全芯片同步不再可能，这很快就会发生。可以证明，即使采用积极的互连优化技术(例如，缓冲器插入和导线尺寸)，对于28.3 mm /spl倍/ 28.3 mm的0.07 /spl mu/m技术一代的芯片，仍然需要5个时钟周期，假设ITRS'01(2001)预测到2006年的5.63 GHz时钟。这清楚地表明，在多千兆赫同步设计中，多周期片上通信是必要的。然而，目前的设计工具和方法并不支持它，因为大多数设计工具和方法都隐含地假设在单个时钟周期内实现全芯片同步是可行的。我们的贡献如下:(i)我们提出了一个规则的分布式寄存器(RDR)微架构，它提供了高规律性和直接支持多周期通信;(ii)我们开发了一套新颖的架构合成算法，以有效地将行为级设计合成到RDR架构上。

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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来源期刊

First IEEE/ACM/IFIP International Conference on Hardware/ Software Codesign and Systems Synthesis (IEEE Cat. No.03TH8721)

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