Scidac-Data: Enabling Data Driven Modeling of Exascale Computing

Mubarak, Misbah; Ding, Pengfei; Aliaga, Leo; Tsaris, Aristeidis; Norman, Andrew; Lyon, Adam; Ross, Robert

doi:10.1088/1742-6596/898/6/062048

Title: Scidac-Data: Enabling Data Driven Modeling of Exascale Computing

Journal Article · Thu Nov 23 00:00:00 EST 2017 · Journal of Physics. Conference Series

DOI:https://doi.org/10.1088/1742-6596/898/6/062048· OSTI ID:1437988

Mubarak, Misbah ^[1]; Ding, Pengfei ^[2]; Aliaga, Leo ^[2]; Tsaris, Aristeidis ^[2]; Norman, Andrew ^[2]; Lyon, Adam ^[2]; Ross, Robert ^[1]

Argonne National Lab. (ANL), Lemont, IL (United States)
Fermi National Accelerator Lab. (FNAL), Batavia, IL (United States)

Here, the SciDAC-Data project is a DOE-funded initiative to analyze and exploit two decades of information and analytics that have been collected by the Fermilab data center on the organization, movement, and consumption of high energy physics (HEP) data. The project analyzes the analysis patterns and data organization that have been used by NOvA, MicroBooNE, MINERvA, CDF, D0, and other experiments to develop realistic models of HEP analysis workflows and data processing. The SciDAC-Data project aims to provide both realistic input vectors and corresponding output data that can be used to optimize and validate simulations of HEP analysis. These simulations are designed to address questions of data handling, cache optimization, and workflow structures that are the prerequisites for modern HEP analysis chains to be mapped and optimized to run on the next generation of leadership-class exascale computing facilities. We present the use of a subset of the SciDAC-Data distributions, acquired from analysis of approximately 71,000 HEP workflows run on the Fermilab data center and corresponding to over 9 million individual analysis jobs, as the input to detailed queuing simulations that model the expected data consumption and caching behaviors of the work running in high performance computing (HPC) and high throughput computing (HTC) environments. In particular we describe how the Sequential Access via Metadata (SAM) data-handling system in combination with the dCache/Enstore-based data archive facilities has been used to develop radically different models for analyzing the HEP data. We also show how the simulations may be used to assess the impact of design choices in archive facilities.

View Accepted Manuscript (DOE)

Cite