SCIENTIFIC COMPUTING AND VISUALIZATION (Fall 07)

Course Description
Particle and continuum simulations are used as a vehicle to learn basic elements of high performance scientific computing and visualization. Students will obtain hands-on experience in: 1) formulating a mathematical model to describe a physical phenomenon; 2) discretizing the model, which often consists of continuous differential or integral equations, into algebraic forms in order to allow numerical solution on computers; 3) designing/analyzing numerical algorithms to solve the algebraic equations efficiently on parallel computers; 4) translating the algorithms into a program; 5) performing a computer experiment by executing the program; 6) visualizing simulation data in an immersive and interactive virtual environment; and 7) managing/mining large datasets.

Visualization of 209 million-atom simulation of hypervelocity impact on a high-strength ceramic plate on a tiled display.

Syllabus

• Basic molecular dynamics (MD) algorithms
  • Integration of ordinary differential equations; periodic boundary condition; linked-list cells
• Parallel MD
  • Spatial decomposition (interprocessor caching and migration); load balancing; scalability analysis; asynchronous MD
  • Message passing interface (MPI) vs. shared memory (OpenMP) programming
  • Build-it-yourself PC cluster
• Scientific visualization
  • OpenGL programming
  • Virtual environment programming--CAVE Library, ImmersaDesk, tiled display
• Scientific data management/mining
  • Data compression for scalable I/O
  • Graph-based knowledge discovery
• Grid scientific computing
  • Computation steering on the Grid-integrated parallel computing, data storage, and visualization resources via high-speed networks
  • Grid enabling parallel applications
• Object-oriented scientific programming
  • Parallel software tools for irregular data structures (e.g., KeLP C++ runtime library); object-oriented MD (e.g., NAMD); Python wrappers
• Other simulation methods
  • Stochastic simulations: Monte Carlo method
  • Continuum simulations: Schrodinger equation in quantum mechanics

Announcements

• 8/27/07: Please email your answers to the questionnaire to anakano@usc.edu by Friday, August 31; it will be used to set up your account on USC's High Performance Computing cluster.
• 8/27/07: Information on Master of Science degree in Computer Science with specialization in High Performance Computing & Simulations (MSCS-HPCS).
• 9/12/07: A note on least-square fitting of a line is available, which is needed to complete question 2 of assignment 1.
• 9/19/07: For the use of MPI Communicators in Grid computing, see Kikuchi et al., SC02, which is a natural migration path to hybrid MPI/GridRPC Grid computing that allows dynamic resource allocation on demand, see Takemiya et al., SC06.
• 9/21/07 (F): Discussion session for HW 1 from 1:00pm in VHE 610.
• 9/28/07 (F): Special lecture on PlayStation3 cluster and Graphics Processing Unit (GPU) programming at 10:00 am in SSL 104 (CACS Visualization Lab); discussion session for HW 2 from 4:00pm in VHE 610.
• 10/1/07 (M): Please see Gideon's Shell script for performing multiple performance-test runs.
• 10/5/07 (F): Discussion session for HW 3 from 5:00pm in VHE 610.
• 10/8/07: An instruction on installing OpenGL and GLUT is available; see also how to use OpenGL and GLUT with Microsoft Visual Studio.
• 10/10/07 (W): Tour of the high performance computing (HPC) facility; we will meet at the regular class and take a shuttle together to the HPC.
• 10/22/07 (M): Class will be held in SSL 104 and will cover: (1) tiled display + virtual reality (Yi-Chun Chen); and (2) Playstation3 cluster (Liu Peng).
• 10/24/07: A coloring scheme for visualizing complex electronic wave functions is found in J. L. Richardson, Comput. Phys. Commun. 63, 84 (1991).
• 11/2/07 (F): Discussion session for HW 5 from 3:30pm in VHE 610.
• 11/14/07 (W): Lecture on (1) multidimensional parallel QD (see p. 3), (2) stationary and dynamic Green's function boundary conditions, and (3) load balancing.
• 11/19/07 (M): Supplementary papers for the lecture on "optimizing molecular dynamics": (1) "improving memory hierarchy performance for irregular applications," J. Mellor-Crummey et al., ICS99 (ACM, '99); (2) "analysis of the clustering properties of the Hilbert space-filling curve," B. Moon et al., IEEE TKDE 13, 124 ('01); (3) "optimization of sparse matrix-vector multiplication on emerging multicore platforms," S. Williams et al., SC07 (ACM, '07).
• 11/20/07 (T): Discussion session for HW 6 from 5:00pm in VHE 610.
• 11/20/07 (T): (1) if you have not got the supplementary reading, "Performance Optimization of Numerically Intensive Codes" by S. Goedecker and A. Hoisie (SIAM, 2001), please pick it up at my office before Wednesday's lecture; (2) you are encouraged to present your final project (just a plan or preliminary report of progress will suffice, but it is required) at any class before Nov. 28 (Wed), so that you do not need to stay until Dec. 19.

Lecture Notes

• Introduction
• Basic molecular dynamics algorithms
• Linked-list cell MD algorithm
• Message Passing Interface
• Parallel MD algorithm
• Visualizing molecular dynamics
• Quantum dynamics simulation
• Parallel quantum-dynamics algorithm
• OpenMP
• Hybrid MPI+OpenMP parallel MD
• How to run a hybrid MPI+OpenMP job at HPC
• Optimizing molecular dynamics
• Summary

Assignments

• 1: Molecular dynamics (due Monday, Sep. 24)
• 2: Message Passing Interface (due Wednesday, Oct. 3)
• 3: Parallel molecular dynamics (due Wednesday, Oct. 10)
• 4: Animating molecular dynamics (due Wednesday, Oct. 24)
• 5: Parallel quantum dynamics (due Monday, Nov. 5)
• 6: Hybrid MPI+OpenMP parallel molecular dynamics (due Wednesday, Nov. 21)
• Final project (due Wednesday, Dec. 19); sample final project--performance tuning

Source Codes

• Sequential MD program: md.c, md.h, md.in
• MPI basics: mpi_simple.c, mpi_comm.c, irecv_comm.c
• Parallel MD program: pmd.c, pmd.h, pmd.in
• Visualizing MD simulation: atomv.c, atomv.h, md.conf
• Quantum dynamics: qd.c, qd.h, qd.in; qd1.c, qd1.h, qd1.in
• OpenMP basics: omp_example.c, omp_pi_critical.c, omp_pi.c
• Hybrid MPI+OpenMP: hpi.c

Useful Links

• Message Passing Interface (MPI)
  • Argonne National Laboratory MPI page
  • MPI, The Complete Reference on line
  • MPICH-G2--Grid-enabled MPI
• OpenMP
  • OpenMP homepage
  • OpenMP tutorial
• OpenGL
  • OpenGL homepage
  • OpenGL Programming Guide on line
• Virtual Reality/Visualization
  • CAVE programming at Electronic Visualization Laboratory at University of Illinois at Chicago
  • IEEE Virtual Reality Conference
  • ACM SIGGRAPH Conference
  • IEEE Visualization Conference
  • VMD: Visual Molecular Dynamics at University of Illinois at Urbana-Champaign
  • Atomsviewer: A scalable molecular visualization code
• Network/Grid Scientific Computing
  • Globus project
  • Global Grid Forum
  • PUNCH: Purdue University Network Computing Hub
• Scientific Object Oriented Programming
  • NAMD--an object-oriented molecular dynamics at Urbana-Champaign
  • KeLP (Kernel Lattice Parallelism) at San Diego
• Linux Cluster
  • HPC cluster at USC
• Network/Interconnect
  • Myrinet
  • Infiniband
  • Intenet2 homepage
• Supercomputing & Information Technology for Science & Engineering
  • Microsoft report on Towards 2020 Science
  • Nature special issue on Future of Computing
  • Ultrascale Simulation for Science at the U.S. Department of Energy; see also reports at the DOE Office of Advanced Scientific Computing Research
  • NSF Report on Revolutionizing Science & Engineering through Cyberinfrastructure
  • NSF Report on Cyberscience
  • Top 500 supercomputer list
  • IEEE/ACM Supercomputing Conference
  • IEEE International Parallel & Distributed Processing Symposium
• Computational Science
  • IEEE Computing in Science and Engineering magazine
• Numerical Methods
  • W. H. Press, B. P. Flannery, S. A. Teukolsky, and W. T. Vetterling, "Numerical Recipes, 2nd Ed." (Cambridge U Press, C: 1993)