RAPPID: an asynchronous instruction length decoder

Rotem, S.; Stevens, Kenneth S.; Ginosar, Ran; Beerel, Peter A.; Myers, Chris J.; Yun, K.Y.; Kol, Rakefet; Dike, C.; Roncken, Marly; Agapiev, B.

doi:10.1109/async.1999.761523

Cited by 57 publications

(35 citation statements)

References 11 publications

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“…A research group at Intel demonstrated this with their asynchronous instruction length decoder design called RAPPID ("Revolving Asynchronous Pentium Processor c Instruction Decoder") [60]. The RAPPID's length decoding out-performs, by a factor of 3, the same function inside a 400MHz Pentium II fabricated in the identical 0.25µm CMOS process.…”

Section: Large Scale Examplesmentioning

confidence: 99%

“…Work at Sun Labs [15] shows that asynchronous pipelines, if designed properly, can approach the speed of synchronous shift registers. However, it is unclear if asynchronous pipelines, except in some special cases [60], can ever out-perform synchronous counterparts. A goal is therefore to aim for comparable performance as a synchronous pipeline, but with the added benefits of "elasticity" (variable rate operation).…”

Section: Datapathmentioning

confidence: 99%

“…Burstmode CAD tools have been applied to several industrial designs, including an experimental routing chip [17] and low-power infrared communications chip [40] at HP Laboratories, an experimental SCSI controller at AMD [81], and a high-performance experimental instruction-length decoder at Intel [60].…”

Section: Asynchronous State Machinesmentioning

confidence: 99%

See 2 more Smart Citations

Practical advances in asynchronous design and in asynchronous/synchronous interfaces

Brunvand

Nowick

Yun

1999

Proceedings of the 36th Annual ACM/IEEE Design Automation Conference

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Section: Large Scale Examplesmentioning

confidence: 99%

Section: Datapathmentioning

confidence: 99%

See 1 more Smart Citation

Practical advances in asynchronous design and in asynchronous/synchronous interfaces

Brunvand

Nowick

Yun

1999

Proceedings of the 36th Annual ACM/IEEE Design Automation Conference

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show abstract

“…One potential advantage of asynchronous systems over their clocked counterparts, in certain applications, is better average-case performance [1,19,25]. However, the performance analysis of asynchronous systems remains a challenge.…”

Section: Introductionmentioning

confidence: 99%

Efficient performance analysis of asynchronous systems based on periodicity

McGee

Nowick

Coffman

2005

Proceedings of the 3rd IEEE/ACM/IFIP International Conference on Hardware/Software Codesign and System Synthesis

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This paper presents an efficient method for the performance analysis and optimization of asynchronous systems. An asynchronous system is modeled as a marked graph with probabilistic delay distributions. We show that these systems exhibit inherent periodic behaviors. Based on this property, we derive an algorithm to construct the state space of the system through composition and capture the time evolution of the states into a periodic Markov chain. The system is solved for important performance metrics such as the distribution of input arrival time at a component, which is useful for subsequent system optimization, as well as relative component utilization, system latency and throughput. We also present a tool to demonstrate the feasibility of this method. Initial experimental results are promising, showing over three orders of magnitude improvement in runtime and nearly two orders of magnitude decrease in the size of the state space over previously published results. While the focus of this paper is on asynchronous digital systems, our technique can be applied to other concurrent systems that exhibit global asynchronous behavior, such as GALS and embedded systems.

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“…To reduce these overheads, we propose using relative-timing analysis [15] to optimize these asynchronous implementations by reducing the size of the CD logic. One such system where relative-timing optimizations played a crucial role is the Intel Asynchronous InstructionLength Decoder [13], which was several times faster than its synchronous counterpart. This paper introduces several novel relative-timing algorithms that optimize asynchronous circuits for area.…”

Section: Introductionmentioning

confidence: 99%

Area Optimizations for Dual-Rail Circuits Using Relative-Timing Analysis

Chelcea

Venkataramani

Goldstein

2007

13th IEEE International Symposium on Asynchronous Circuits and Systems (ASYNC'07)

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Future deep sub-micron technologies will be characterized by large parametric variations, which could make asynchronous design an attractive solution for use on large scale. However, the investment in asynchronous CAD tools does not approach that in synchronous ones. Even when asynchronous tools leverage existing synchronous toolflows, they introduce large area and speed overheads. This paper proposes several heuristic and optimal algorithms, based on timing interval analysis, for improving existing asynchronous CAD solutions by optimizing area. The optimized circuits are 2.4 times smaller for an optimal algorithm and 1.8 times smaller for a heuristic one than the existing solutions. The optimized circuits are also shown to be resilient to large parametric variations, yielding better average-case latencies than their synchronous counterparts.

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RAPPID: an asynchronous instruction length decoder

Cited by 57 publications

References 11 publications

Practical advances in asynchronous design and in asynchronous/synchronous interfaces

Practical advances in asynchronous design and in asynchronous/synchronous interfaces

Efficient performance analysis of asynchronous systems based on periodicity

Area Optimizations for Dual-Rail Circuits Using Relative-Timing Analysis

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