Lessons learned at 208K: Towards debugging millions of cores

Petascale systems will present several new challenges to performance and correctness tools. Such machines may contain millions of cores, requiring that tools use scalable data structures and analysis algorithms to collect and to process application data. In addition, at such scales, each tool itself...

Full description

Saved in:
Bibliographic Details
Main Authors: Lee, G.L., Ahn, D.H., Arnold, D.C., de Supinski, B.R., Legendre, M., Miller, B.P., Schulz, M., Liblit, B.
Format: Conference Proceeding
Language:English
Subjects:
Algorithm design and analysis
Application software
Data analysis
Data structures
Debugging
File systems
Laboratories
Large-scale systems
Scalability
System software
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Petascale systems will present several new challenges to performance and correctness tools. Such machines may contain millions of cores, requiring that tools use scalable data structures and analysis algorithms to collect and to process application data. In addition, at such scales, each tool itself will become a large parallel application - already, debugging the full Blue-Gene/L (BG/L) installation at the Lawrence Livermore National Laboratory requires employing 1664 tool daemons. To reach such sizes and beyond, tools must use a scalable communication infrastructure and manage their own tool processes efficiently. Some system resources, such as the file system, may also become tool bottlenecks. In this paper, we present challenges to petascale tool development, using the stack trace analysis tool (STAT) as a case study. STAT is a lightweight tool that gathers and merges stack traces from a parallel application to identify process equivalence classes. We use results gathered at thousands of tasks on an Infiniband cluster and results up to 208 K processes on BG/L to identify current scalability issues as well as challenges that will be faced at the petascale. We then present implemented solutions to these challenges and show the resulting performance improvements. We also discuss future plans to meet the debugging demands of petascale machines.
ISSN:2167-4329
2167-4337
DOI:10.1109/SC.2008.5218557