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README.md |
MD-Bench
MD-Bench is a toolbox for the performance engineering of short-range force calculation kernels on molecular-dynamics applications. It aims at covering all available state-of-the-art algorithms from different community codes such as LAMMPS and GROMACS.
Build instructions
Properly configure your building by changing config.mk
file. The following
options are available:
- TAG: Compiler tag (available options: GCC, CLANG, ICC, ONEAPI, NVCC).
- ISA: Instruction set (available options: SSE, AVX, AVX_FMA, AVX2, AVX512).
- MASK_REGISTERS: Use AVX512 mask registers (always true when ISA is set to AVX512).
- OPT_SCHEME: Optimization algorithm (available options: lammps, gromacs).
- ENABLE_LIKWID: Enable likwid to make use of HPM counters.
- DATA_TYPE: Floating-point precision (available options: SP, DP).
- DATA_LAYOUT: Data layout for atom vector properties (available options: AOS, SOA).
- ASM_SYNTAX: Assembly syntax to use when generating assembly files (available options: ATT, INTEL).
- DEBUG: Toggle debug mode.
- EXPLICIT_TYPES: Explicitly store and load atom types.
- MEM_TRACER: Trace memory addresses for cache simulator.
- INDEX_TRACER: Trace indexes and distances for gather-md.
- COMPUTE_STATS: Compute statistics.
Configurations for LAMMPS Verlet Lists optimization scheme:
- ENABLE_OMP_SIMD: Use omp simd pragma on half neighbor-lists kernels.
- USE_SIMD_KERNEL: Compile kernel with explicit SIMD intrinsics.
Configurations for GROMACS MxN optimization scheme:
- USE_REFERENCE_VERSION: Use reference version (only for correction purposes).
- XTC_OUTPUT: Enable XTC output.
- HALF_NEIGHBOR_LISTS_CHECK_CJ: Check if j-clusters are local when decreasing the reaction force.
Configurations for CUDA:
- USE_CUDA_HOST_MEMORY: Use CUDA host memory to optimize host-device transfers.
When done, just use make
to compile the code.
You can clean intermediate build results with make clean
, and all build results with make distclean
.
You have to call make clean
before make
if you changed the build settings.
Usage
Use the following command to run a simulation:
./MD-Bench-<TAG>-<OPT_SCHEME> [OPTION]...
Where TAG
and OPT_SCHEME
correspond to the building options with the same
name. Without any options, a Copper FCC lattice system with size 32x32x32
(131072 atoms) over 200 time-steps using the Lennard-Jones potential (sigma=1.0,
epsilon=1.0) is simulated.
The default behavior and other options can be changed using the following parameters:
-p <string>: file to read parameters from (can be specified more than once)
-f <string>: force field (lj or eam), default lj
-i <string>: input file with atom positions (dump)
-e <string>: input file for EAM
-n / --nsteps <int>: set number of timesteps for simulation
-nx/-ny/-nz <int>: set linear dimension of systembox in x/y/z direction
-r / --radius <real>: set cutoff radius
-s / --skin <real>: set skin (verlet buffer)
--freq <real>: processor frequency (GHz)
--vtk <string>: VTK file for visualization
--xtc <string>: XTC file for visualization
Examples
TBD
Citations
Rafael Ravedutti Lucio Machado, Jan Eitzinger, Harald Köstler, and Gerhard Wellein: MD-Bench: A generic proxy-app toolbox for state-of-the-art molecular dynamics algorithms. Accepted for PPAM 2022, the 14th International Conference on Parallel Processing and Applied Mathematics, Gdansk, Poland, September 11-14, 2022. PPAM 2022 Best Paper Award. Preprint: arXiv:2207.13094
Credits
MD-Bench is developed by the Erlangen National High Performance Computing Center (NHR@FAU) at the University of Erlangen-Nürnberg.