Credit: Zhengchun Liu / Argonne National Laboratory
An extensive collaboration led by Argonne recently won the Inaugural SCinet Technology Challenge at the Supercomputing 19 conference by demonstrating real-time analysis of light source data from Argonne’s APS to the ALCF.
Accelerator-based light sources — large-scale instruments used to investigate the fundamental properties of matter — generate large amounts of data that require computational analysis. By designing an innovative method to support such investigations, a large collaboration led by the U.S. Department of Energy’s (DOE) Argonne National Laboratory recently won the Inaugural SCinet Technology Challenge during the recent Supercomputing 19 (SC19) conference in Denver.
In addition to those from Argonne, the extensive team included members from Northwestern University, the Starlight Communications Exchange, Northern Illinois University, the University of Chicago and the Metropolitan Research and Education Network.
“We built a software infrastructure that connects APS beamlines with remote high-performance computing resources and demonstrated that even computationally demanding data streams can be analyzed with low latency.” — Tekin Bicer, Argonne assistant computer scientist.
Working directly from the SC19 show floor, the team demonstrated real-time analysis of light source data from Argonne’s Advanced Photon Source (APS) streamed at close to 100 gigabits per second to the Argonne Leadership Computing Facility (ALCF), both DOE Office of Science User Facilities.
“We built a software infrastructure that connects APS beamlines with remote high-performance computing resources and demonstrated that even computationally demanding data streams can be analyzed with low latency,” said Tekin Bicer, an assistant computer scientist at Argonne, who led the demonstration at SC19. “We put significant time and effort into this work, so I am very happy that the importance of our project and demonstration has been recognized.”
The team analyzed a portion of the data using 16,384 cores on Argonne’s Theta supercomputer. The analysis output was then streamed to Argonne’s visualization cluster, Cooley, which rendered a 3D image. The final output was streamed back to the show floor in real time, approximately 10-20 projections per frame, and with data remaining in memory throughout the entire workflow.
“This is truly fabulous, and a great testament to the effort of the entire team,” said Stephen Streiffer, interim deputy laboratory director for science, associate laboratory director for Photon Sciences, and director of the APS at Argonne.
“In order to make full use of the upcoming APS Upgrade, we really need to be able to analyze data in close to real time to make decisions on what to do next,” added Stefan Vogt, associate director of Argonne’s X-ray Science division. “Such analysis, and the fact that we have no place to put huge amounts of raw data, will require the ability to stream data into HPC-type resources as we acquire it.”
The seed for Argonne’s participation in the technology challenge was sown in May 2019, when Cees de Laat, a professor at the University of Amsterdam and an SC19 technology challenge jury member, encouraged Argonne’s Rajkumar Kettimuthu to participate.
“I got very excited about the technology challenge as its goal was very much in line with the research and development activities of our group,” said Kettimuthu, a computer scientist on the team. “My colleagues, Tekin Bicer and Zhengchun Liu, readily took the lead on this project and put in a tremendous amount of work. Such contributions from the entire team and strong support from the ALCF operations team made the demo successful.”
As part of the workflow demonstrated by the team during the competition, the researchers streamed data from the SC19 show floor in Denver to Argonne’s Theta system using zeroMQ and Globus data transfer software. The data streamed was equivalent to that from 10 high-data-rate light source beamlines.
The supercomputer processed the data from one of the beamlines in real time, storing the remainder for later analysis. This real-time processing step involves using the lab’s Cooley visualization cluster for iterative reconstructions of a 3D volume from 2D images obtained at a microtomography imaging beamline.
The team streamed the processed results back to the SC19 show floor in Denver for near real-time visualization. The first results streamed within 5-10 seconds of the start of the experiment and continued at that rate until the end of the experiment. Careful management was required to ensure that the streaming flows of various data acquisition and analyses could co-exist without interference.
“The team really pushed forward the limits of technology,” said Ian Foster, Argonne distinguished fellow and director of the Data Science and Learning division. Foster initiated the ?”bandwidth challenge” at SC2000 — a precursor to the inaugural SCinet Technology Challenge — to spur the HPC community toward delivering innovative applications that will efficiently utilize the SCinet network and add significant value.
A demonstration of this scale requires a tremendous amount of teamwork, particularly when last-minute obstacles arise. For example, the team ran into an unexpected network problem just a few hours before the demonstration. Significant coordination and outstanding teamwork by ALCF operations and Argonne networking staff resulted in diagnosis and repair of a subtle network failure just 20 minutes before the demonstration.
“Demonstrations like this provide a glimpse into the future of how science will be done across DOE facilities, while at the same time stress testing the infrastructure we have in place today,” said Michael E. Papka, deputy associate laboratory director and director of the ALCF.
Joe Mambretti, director of StarLight and the International Center for Advanced Internet Research at Northwestern, agrees. ?”The innovative techniques shown throughout this demonstration can not only be applied to light source investigations, they can be more broadly applied to many types of science workflows requiring real-time, data-intensive streaming from source to computational resources to visualization.”
The winning team consists of Tekin Bicer, Zhengchun Liu, Doga Gursoy, Junjing Deng, Jeff Klug, Vincent De Andrade, Pavel Shevchenko, Francesco De Carlo, Stefan Vogt, Venkatram Vishwanath, and Stefan Wild, Argonne National Laboratory; Michael E. Papka, Argonne National Laboratory and Northern Illinois University; Rajkumar Kettimuthu and Ian T. Foster, Argonne National Laboratory and the University of Chicago; Jim Chen, Starlight Communications Exchange and Northwestern University; and Joe Mambretti, Starlight Communications Exchange, Northwestern University and the Metropolitan Research and Education Network.
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