流体:通过控制依赖性放松实现近似并发的框架

Huaipan Jiang, Haibo Zhang, Xulong Tang, V. Govindaraj, J. Sampson, M. Kandemir, Danfeng Zhang
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引用次数: 0

摘要

在这项工作中,我们引入了Fluid框架,这是一组语言、编译器和运行时扩展,允许以一种有纪律的方式近似地表达数据流依赖关系的区域。我们的框架允许在依赖任务的输入完成之前急切地执行,以便利用在保守/精确执行计划中产生的最终值的值或结构的高概率的情况。我们引入了对中间值的早期消费的受控访问,并为用户指定的质量保证机制提供了挂钩,如果它们的输出值不符合启发式期望,这些机制可以自动强制重新执行急切执行的任务。我们的实验分析表明,在我们的流化参数的默认值下,应用程序的流化版本比原始版本的平均执行时间提高了22.2%。Fluid方法与旨在减少任务工作量的方法在很大程度上是正交的,我们表明,利用Fluid框架可以为最初精确的和最初近似的计算版本带来好处。
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Fluid: a framework for approximate concurrency via controlled dependency relaxation
In this work, we introduce the Fluid framework, a set of language, compiler and runtime extensions that allow for the expression of regions within which dataflow dependencies can be approximated in a disciplined manner. Our framework allows the eager execution of dependent tasks before their inputs have finalized in order to capitalize on situations where an eagerly-consumed input has a high probability of sufficiently resembling the value or structure of the final value that would have been produced in a conservative/precise execution schedule. We introduce controlled access to the early consumption of intermediate values and provide hooks for user-specified quality assurance mechanisms that can automatically enforce re-execution of eagerly-executed tasks if their output values do not meet heuristic expectations. Our experimental analysis indicates that the fluidized versions of the applications bring 22.2% average execution time improvements, over their original counterparts, under the default values of our fluidization parameters. The Fluid approach is largely orthogonal to approaches that aim to reduce the task effort itself and we show that utilizing the Fluid framework can yield benefits for both originally precise and originally approximate versions of computation.
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