进程变化感知缓存泄漏管理

Ke Meng, R. Joseph
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引用次数: 76

摘要

在几代技术中,制造工艺的局限性使得精确的设计时间功率估计成为一项艰巨的挑战。由于片上高速缓存,静态泄漏电流占总功率的很大一部分,它与栅极长度、栅极氧化物厚度和掺杂离子浓度等广泛变化的物理参数呈指数关系。在像片上缓存这样的大型结构中,这可能意味着缓存的一部分可能比同等大小的区域消耗一个数量级的静态功率。在这种氛围下,对物质资源的平等主义管理显然是站不住脚的。在本文中,我们分析了模内和模间泄漏变化对片上高速缓存的影响。然后,我们提出了方法优先化,这是一种制造变化感知方案,可以最大限度地减少缓存泄漏能量。我们的结果表明,在不损害硬件复杂性或性能的情况下,显著的平均功耗降低是可能的
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Process Variation Aware Cache Leakage Management
In a few technology generations, limitations of fabrication processes have made accurate design time power estimates a daunting challenge. Static leakage current which comprises a significant fraction of total power due to large on-chip caches, is exponentially dependent on widely varying physical parameters such as gate length, gate oxide thickness, and dopant ion concentration. In large structures like on-chip caches, this may mean that one portion of a cache may consume an order of magnitude larger static power than equivalently sized regions. Under this climate, egalitarian management of physical resources is clearly untenable. In this paper, we analyze the effects of within-die and die-to-die leakage variation for on-chip caches. We then propose way prioritization, a manufacturing variation aware scheme that minimizes cache leakage energy. Our results show that significant average power reductions are possible without undue hardware complexity or performance compromise
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