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Sara S. Hamouda, Josh Milthorpe, Peter E. Strazdins, Vijay Saraswat
16th IEEE International Workshop on Parallel and Distributed Scientific and Engineering Computing (PDSEC)
Publication year: 2015

The Global Matrix Library (GML) is a distributed matrix library in the X10 language. GML is designed to simplify the development of scalable linear algebra applications. By hiding the communication and parallelism details, GML programs are written in a sequential style that is easy to use and understand by non expert programmers. Resilience is becoming a major challenge for HPC applications as the number of components in a typical system continues to increase. To address this challenge, we improved GML’ s adaptability to process failure and provided a mechanism for automatic data recovery. As iterative algorithms are commonly used in linear algebra applications, we also created a checkpoint/restore framework for developing resilient iterative applications using GML. Using three example machine learning applications, we demonstrate that this framework supports resilient application development with minimal additional code compared to a non-resilient implementation. Performance measurements in a typical cluster environment show that the major cost of resilient execution is due to resilient X10 itself, and that the additional cost due to our framework is acceptable.