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引用次数: 7
摘要
随着功能尺寸越来越小,现代处理器和内存芯片的集成密度越来越高,软错误对在现代硬件上运行的应用程序构成了真正的挑战。软错误表现为改变用户值的位翻转,而数字软件是一类对此类数据变化敏感的软件。在本文中,我们提出了一种对软错误具有弹性的双对角约简算法的设计,并描述了其在混合CPU-GPU架构上的实现。我们的容错算法采用基于算法的容错,结合反向计算来检测、定位和纠正软错误。测试是在Sandy Bridge CPU和NVIDIA Kepler GPU上进行的。所包含的实验表明,与容易出错的代码相比,我们的弹性双对角约简算法增加的开销非常小。在矩阵大小为10110 x 10110的情况下,当出现一个错误时,我们的算法的性能开销仅为1.085%,当没有错误时,性能开销为0.354%。
CPU-GPU hybrid bidiagonal reduction with soft error resilience
Soft errors pose a real challenge to applications running on modern hardware as the feature size becomes smaller and the integration density increases for both the modern processors and the memory chips. Soft errors manifest themselves as bit-flips that alter the user value, and numerical software is a category of software that is sensitive to such data changes. In this paper, we present a design of a bidiagonal reduction algorithm that is resilient to soft errors, and we also describe its implementation on hybrid CPU-GPU architectures. Our fault-tolerant algorithm employs Algorithm Based Fault Tolerance, combined with reverse computation, to detect, locate, and correct soft errors. The tests were performed on a Sandy Bridge CPU coupled with an NVIDIA Kepler GPU. The included experiments show that our resilient bidiagonal reduction algorithm adds very little overhead compared to the error-prone code. At matrix size 10110 x 10110, our algorithm only has a performance overhead of 1.085% when one error occurs, and 0.354% when no errors occur.
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