Toward a Proof of Concept Implementation of a Cloud Infrastructure on the Blue Gene/Q
Abstract
Conventional cloud computing architectures may seriously constrain computational throughput for HPC applications and data analysis. The traditional approach to circumvent such problems has been to map such applications onto specialized hardware and co-processor architectures. These shortcomings have given rise to calls for software that can provide richer environments for implementing clouds on these HPC architectures. It was recently reported that a proof of concept cloud computing system was successfully embedded in a standard Blue Gene/P HPC supercomputer. This software defined system re-arranged user access to nodes and dynamically customized features of the BG/P architecture to map clouds systems and applications onto the BG/P. This paper reports on efforts to extend the results achieved on the BG/P to the newer BG/Q architecture. This work demonstrates a potential for a cloud to capitalize on the BG/Q infrastructure and provides a platform for developing better hybrid workflows and for experimentation with new schedulers and operating systems within a working HPC environment.
References
[1]
Amazon Web Services. 2014, retrieved from http://aws.amazon.com
[2]
Apache.org. 2014 retrieved from http://vcl.apache.org
[3]
Appavoo, J. U. V., Rosenburg, B., DaSilva, D., & Moreira, J. 2009. Kittyhawk: Enabling Cooperation and Competition in a Global Shared Computational System. IBM Journal of Research and Development, 1-15.
[4]
Blue Gene/Q. By Co-design, 2013, Computer Science, 28, 2-3, p.127-135, Springer-Verlag Inc., New York
[5]
Dreher, P., & Mathew, G. 2014. Toward Implementation of a Software Defined Cloud on a Supercomputer. IEEE Computer Society Conference Publishing Services.
[6]
Dreher, P., Vouk, M., Sills, E., & Averitt, S. 2009. Evidence for a Cost Effective Cloud Computing Implementation based Upon the NC State Virtual Computing Laboratory Model. Advances in Parallel Computing; High Speed and Large Scale Scientific Computing pp. 236-250. Amsterdam: IOS Press.
[7]
GitHub. 2014, retrieved from https://github.com/opendwarfs/OpenDwarfs
[8]
Kittyhawk Project. 2009. Retrieved from http://kittyhawk.bu.edu/kittyhawk/Kittyhawk.html
[9]
Lattice Computation, M. I. M. D. MILC Collaboration 2014 http://www.physics.utah.edu/~detar/milc/
[10]
Mell, P., & Grance, T. 2011. The NIST Definition of Cloud Computing. NIST Special Publication 800-145, Gaithersburg: National Institute of Standards and Technology.
[11]
Moustafa AbelBaky, et.al "Enabling High Performance Computing as a Service" Computer Vol 45 10, p72-80. 2012
[12]
ParkY.Van HensbergenE.HillenbrandM.InglettT.RosenburgB.RyuK.WisniewskiR. 2012, FusedOS: Fusing LWK Performance with FWK Functionality in a Heterogeneous Environment, Proceedings of the 2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing, 8, p. 211-218, IEEE Computer Society, Washington. DC. 10.1109/SBAC-PAD.2012.14
[13]
Park, Y., Van Hensbergen, E., Hillenbrand, M., Inglett, T., Rosenburg, B. S., Ryu, K. D., & Wisniewski, R. W. 2012. Poster: FusedOS: A Hybrid Approach to Exascale Operating Systems p. 1417. SC Companion.
[14]
Redbooks, I. B. M. 2012. IBM System Blue Gene Solution: Blue Gene/Q System Administration. Vervante.
[15]
Research, I. B. M. 2014, FusedOS, GitHub repository, https://github.com/ibm-research/fusedos
[16]
Schaffer, H., Averitt, S., Hoit, M., Peeler, A., Sills, E., & Vouk, M. 2009. NCSUs Virtual Computing Laboratory: A Cloud Computing Solution. IEEE Computer, 94-97.
[17]
UberCloud Experiment. 2014, retrieved from https://www.theubercloud.com/hpc- experiment/
[18]
Virtual Computing Laboratory. 2014 retrieved from http://vcl.ncsu.edu
[19]
Vouk, M. 2008. Cloud Computing: Issues, Research and Implementations. Journal of Computing and Information Technology, 235-246.
- Toward a Proof of Concept Implementation of a Cloud Infrastructure on the Blue Gene/Q
Recommendations
Toward Implementation of a Software Defined Cloud on a Supercomputer
IC2E '14: Proceedings of the 2014 IEEE International Conference on Cloud EngineeringConventional cloud computing architectures may seriously constrain computational throughput for high performance computing (HPC) and high-performance data (HPD) applications. The traditional approach to circumvent such problems has been to map these ...
Cloud resource management: towards efficient execution of large-scale scientific applications and workflows on complex infrastructures
Cloud computing evolved from the concept of utility computing, which is defined as the provision of computational and storage resources as a metered service. Another key characteristic of cloud computing is multitenancy, which enables resource and cost ...
VM auto-scaling methods for high throughput computing on hybrid infrastructure
Cloud computing provides on-demand resource provisioning and scalable resources dynamically for the efficient use of computing resources. Scientific applications recently need a very large number of loosely coupled tasks to be handled efficiently. In ...
Comments
Information & Contributors
Information
Published In
Publisher
IGI Global
United States
Publication History
Published: 01 January 2015
Author Tags
Qualifiers
- Article
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 0Total Downloads
- Downloads (Last 12 months)0
- Downloads (Last 6 weeks)0
Reflects downloads up to 12 Jan 2025