Scott Kruger

FES Requirements Worksheet

1.1. Project Information - Title

Document Prepared By	Scott Kruger
Project Title	Title
Principal Investigator	Scott Kruger
Participating Organizations
Funding Agencies	DOE SC DOE NSA NSF NOAA NIH Other:

2. Project Summary & Scientific Objectives for the Next 5 Years

Please give a brief description of your project - highlighting its computational aspect - and outline its scientific objectives for the next 3-5 years. Please list one or two specific goals you hope to reach in 5 years.

3. Current HPC Usage and Methods

3a. Please list your current primary codes and their main mathematical methods and/or algorithms. Include quantities that characterize the size or scale of your simulations or numerical experiments; e.g., size of grid, number of particles, basis sets, etc. Also indicate how parallelism is expressed (e.g., MPI, OpenMP, MPI/OpenMP hybrid)

3b. Please list known limitations, obstacles, and/or bottlenecks that currently limit your ability to perform simulations you would like to run. Is there anything specific to NERSC?

3c. Please fill out the following table to the best of your ability. This table provides baseline data to help extrapolate to requirements for future years. If you are uncertain about any item, please use your best estimate to use as a starting point for discussions.

Facilities Used or Using	NERSC OLCF ACLF NSF Centers Other:
Architectures Used	Cray XT IBM Power BlueGene Linux Cluster Other:
Total Computational Hours Used per Year	Core-Hours
NERSC Hours Used in 2009	Core-Hours
Number of Cores Used in Typical Production Run
Wallclock Hours of Single Typical Production Run
Total Memory Used per Run	GB
Minimum Memory Required per Core	GB
Total Data Read & Written per Run	GB
Size of Checkpoint File(s)	GB
Amount of Data Moved In/Out of NERSC	GB per
On-Line File Storage Required (For I/O from a Running Job)	TB and Files
Off-Line Archival Storage Required	TB and Files

Please list any required or important software, services, or infrastructure (beyond supercomputing and standard storage infrastructure) provided by HPC centers or system vendors.

4. HPC Requirements in 5 Years

4a. We are formulating the requirements for NERSC that will enable you to meet the goals you outlined in Section 2 above. Please fill out the following table to the best of your ability. If you are uncertain about any item, please use your best estimate to use as a starting point for discussions at the workshop.

Computational Hours Required per Year
Anticipated Number of Cores to be Used in a Typical Production Run
Anticipated Wallclock to be Used in a Typical Production Run Using the Number of Cores Given Above
Anticipated Total Memory Used per Run	GB
Anticipated Minimum Memory Required per Core	GB
Anticipated total data read & written per run	GB

Anticipated size of checkpoint file(s)	GB
Anticipated Amount of Data Moved In/Out of NERSC	GB per
Anticipated On-Line File Storage Required (For I/O from a Running Job)	TB and Files
Anticipated Off-Line Archival Storage Required	TB and Files

4b. What changes to codes, mathematical methods and/or algorithms do you anticipate will be needed to achieve this project's scientific objectives over the next 5 years.

4c. Please list any known or anticipated architectural requirements (e.g., 2 GB memory/core, interconnect latency < 1 μs).

4d. Please list any new software, services, or infrastructure support you will need over the next 5 years.

4e. It is believed that the dominant HPC architecture in the next 3-5 years will incorporate processing elements composed of 10s-1,000s of individual cores, perhaps GPUs or other accelerators. It is unlikely that a programming model based solely on MPI will be effective, or even supported, on these machines. Do you have a strategy for computing in such an environment? If so, please briefly describe it.

New Science With New Resources

To help us get a better understanding of the quantitative requirements we've asked for above, please tell us: What significant scientific progress could you achieve over the next 5 years with access to 50X the HPC resources you currently have access to at NERSC? What would be the benefits to your research field if you were given access to these kinds of resources?

Please explain what aspects of "expanded HPC resources" are important for your project (e.g., more CPU hours, more memory, more storage, more throughput for small jobs, ability to handle very large jobs).