MOLECULAR DYNAMICS PERFORMANCE GUIDE - Digital Research Alliance of CANADA

BENCHMARK DETAILS

ID=143

  • Dataset: 6n4o
  • Software: OPENMM.cuda (openmm/7.7.0-gofbc-2020.1.403.114-avx2)
  • Resource: 1 tasks, 4 cores, nodes, 4 GPUs, with NVLink
  • CPU: Xeon Silver 4216 (Cascade Lake), 2.1 GHz
  • GPU: Tesla-V100-SXM2-32GB, 8 cores/GPU
  • Simulation speed: 36.964211653334665 ns/day
  • Efficiency: 39.5 %
  • Site: Cedar
  • Date: Aug. 30, 2023, 12:58 a.m.
  • Submission script:
    #!/bin/bash
    #SBATCH -c4 --gpus-per-node=v100l:4
    #SBATCH --mem-per-cpu=4000 --time=1:0:0
    


    module purge
    ml StdEnv/2020  gcc/9.3.0  cuda/11.4  openmpi/4.0.3 python/3.8.10
    ml openmm/7.7.0 netcdf/4.7.4 hdf5/1.10.6 mpi4py/3.0.3
    


    virtualenv ${SLURM_TMPDIR}/env
    source ${SLURM_TMPDIR}/env/bin/activate
    pip install --no-index netCDF4 parmed
    


    python openmm_input.py
  • Notes:

    Benchmark time: 31.405654910102527 ns/day, Using 4 GPUs, cdr2648
    Benchmark time: 32.08694780170591 ns/day, Using 4 GPUs, cdr2600
    Benchmark time: 36.24232091113525 ns/day, Using 4 GPUs, cdr2603
    Benchmark time: 36.964211653334665 ns/day, Using 4 GPUs, cdr2643

  • Simulation input file:
    #!/cvmfs/soft.computecanada.ca/easybuild/software/2020/avx512/Core/python/3.8.10/bin/python
    


    # FILE openmm_input.py
    


    import openmm as mm
    import openmm.app as app
    from openmm.unit import *
    import sys, time, netCDF4, ctypes
    from parmed import load_file
    from parmed.openmm import StateDataReporter, NetCDFReporter
    


    CUDA_SUCCESS = 0
    cuda = ctypes.CDLL("libcuda.so")
    device = ctypes.c_int()
    nGpus = ctypes.c_int()
    name = b" " * 100
    devID=[]
    


    result = cuda.cuInit(0)
    if result != CUDA_SUCCESS:
        print("CUDA is not available")
        quit()
    cuda.cuDeviceGetCount(ctypes.byref(nGpus))
    for i in range(nGpus.value):
        result = cuda.cuDeviceGet(ctypes.byref(device), i)
        result = cuda.cuDeviceGetName(ctypes.c_char_p(name), len(name), device)
        print("Device %s:  %s"  % (device.value, name.split(b"\0", 1)[0].decode()))
        devID.append(device.value)
    dvi=",".join(str(i) for i in devID)
    


    amber_sys=load_file("prmtop.parm7", "restart.rst7")
    ncrst=app.amberinpcrdfile.AmberInpcrdFile("restart.rst7")
    


    nsteps=100000
    system=amber_sys.createSystem(
                nonbondedMethod=app.PME, 
                ewaldErrorTolerance=0.0004,
                nonbondedCutoff=8.0*angstroms,
                constraints=app.HBonds,
                removeCMMotion = True,
    )
    


    #PME Grids:
    #EwaldTolerance=0.00040  Grid=[144, 144, 144]
    #EwaldTolerance=0.00045  Grid=[140, 140, 140]
    #EwaldTolerance=0.00050  Grid=[135, 135, 135]
    #EwaldTolerance=0.00065  Grid=[128, 128, 128]
    


    integrator = mm.LangevinIntegrator(300*kelvin, 1.0/picoseconds, 1.0*femtoseconds,)
    barostat = mm.MonteCarloBarostat(1.0*atmosphere, 300.0*kelvin, 25)
    system.addForce(barostat)
    


    platform = mm.Platform.getPlatformByName("CUDA")
    prop = dict(CudaPrecision="mixed", DeviceIndex=dvi)
    


    sim = app.Simulation(amber_sys.topology, system, integrator, platform, prop)
    sim.context.setPositions(amber_sys.positions)
    sim.context.setVelocities(ncrst.velocities)
    


    sim.reporters.append(
            StateDataReporter(
                sys.stdout, 
                400, 
                step=True,
                time=False, 
                potentialEnergy=True,
                kineticEnergy=True, 
                temperature=True, 
                volume=True
            )
    )
    


    sim.reporters.append(
            NetCDFReporter(
                "trajectory.nc", 
                50000, 
                crds=True
            )
    )
    


    print("Running dynamics")
    start = time.time()
    sim.step(nsteps)
    elapsed=time.time() - start
    benchmark_time=3.6*2.4*nsteps*0.01/elapsed
    print(f"Elapsed time: {elapsed} sec\nBenchmark time: {benchmark_time} ns/day")