Command line options


Arguments are processed in hoomd.context.initialize(). Call hoomd.context.initialize() immediately after importing hoomd so that the requested MPI and GPU options can be initialized as early as possible.

There are two ways to specify arguments.

  1. On the command line: python [options]:

    import hoomd
  2. Within your script:

    import hoomd

With no arguments, hoomd.context.initialize() will attempt to parse all arguments from the command line, whether it understands them or not. When you pass a string, it ignores the command line (sys.argv) and parses the given string as if it were issued on the command line. In jupyter notebooks, use context.initialize("") to avoid errors from jupyter specific command line arguments.


  • no options given

    hoomd will automatically detect the fastest GPU and run on it, or fall back on the CPU if no GPU is found.

  • -h, –help

    print a description of all the command line options

  • –mode ={cpu | gpu}

    force hoomd to run either on the cpu or gpu

  • –gpu =#

    specify the GPU id that hoomd will use. Implies –mode=gpu.

  • –ignore-display-gpu

    prevent hoomd from using any GPU that is attached to a display

  • –minimize-cpu-usage

    minimize the CPU usage of hoomd when it runs on a GPU at reduced performance

  • –gpu_error_checking

    enable error checks after every GPU kernel call

  • –notice-level =#

    specifies the level of notice messages to print

  • –msg-file=filename

    specifies a file to write messages (the file is overwritten)

  • –user

    user options

  • MPI only options
    • –nx

      Number of domains along the x-direction

    • –ny

      Number of domains along the y-direction

    • –nz

      Number of domains along the z-direction

    • –linear

      Force a slab (1D) decomposition along the z-direction

    • –nrank

      Number of ranks per partition

    • –shared-msg-file =prefix

      specifies the prefix of files to write per-partition output to (filename: prefix.<partition_id>)

Detailed description

Control hoomd execution

HOOMD-blue can run on the CPU or the GPU. To control which, set the --mode option on the script command line. Valid settings are cpu and gpu:

python --mode=cpu

When --mode is set to gpu and no other options are specified, hoomd will choose a GPU automatically. It will prioritize the GPU choice based on speed and whether it is attached to a display. Unless you take steps to configure your system (see below), then running a second instance of HOOMD-blue will place it on the same GPU as the first. HOOMD-blue will run correctly with more than one simulation on a GPU as long as there is enough memory, but at reduced performance.

You can select the GPU on which to run using the --gpu command line option:

python --gpu=1


--gpu implies --mode=gpu. To find out which id is assigned to each GPU in your system, download the CUDA SDK for your system from and run the deviceQuery sample.

If you run a script without any options:


hoomd first checks if there are any GPUs in the system. If it finds one or more, it makes the same automatic choice described previously. If none are found, it runs on the CPU.

Multi-GPU (and multi-CPU) execution

HOOMD-blue uses MPI domain decomposition for parallel execution. Execute python with mpirun, mpiexec, or whatever the appropriate launcher is on your system. For more information, see MPI domain decomposition:

mpirun -n 8 python

All command line options apply to MPI execution in the same way as single process runs.

Automatic free GPU selection

You can configure your system for HOOMD-blue to choose free GPUs automatically when each instance is run. To utilize this capability, the system administrator (root) must first use the nvidia-smi utility to enable the compute-exclusive mode on all GPUs in the system. With this mode enabled, running hoomd with no options or with the --mode=gpu option will result in an automatic choice of the first free GPU from the prioritized list.

The compute-exclusive mode allows only a single CUDA application to run on each GPU. If you have 4 compute-exclusive GPUs available in the system, executing a fifth instance of hoomd with python will result in the error: ***Error! no CUDA-capable device is available.

Minimize the CPU usage of HOOMD-blue

When hoomd is running on a GPU, it uses 100% of one CPU core by default. This CPU usage can be decreased significantly by specifying the --minimize-cpu-usage command line option:

python --minimize-cpu-usage

Enabling this option incurs a 10% overall performance reduction, but the CPU usage of hoomd is reduced to only 10% of a single CPU core.

Prevent HOOMD-blue from running on the display GPU

Running hoomd on the display GPU works just fine, but it does moderately slow the simulation and causes the display to lag. If you wish to prevent hoomd from running on the display, add the --ignore-display-gpu command line flag:

python --ignore-display-gpu

Enable error checking on the GPU

Detailed error checking is off by default to enable the best performance. If you have trouble that appears to be caused by the failure of a calculation to run on the GPU, you should run with GPU error checking enabled to check for any errors returned by the GPU.

To do this, run the script with the --gpu_error_checking command line option:

python --gpu_error_checking

Control message output

You can adjust the level of messages written to sys.stdout by a running hoomd script. Set the notice level to a high value to help debug where problems occur. Or set it to a low number to suppress messages. Set it to 0 to remove all notices (warnings and errors are still output):

python --notice-level=10

All messages (notices, warnings, and errors) can be redirected to a file. The file is overwritten:

python --msg-file=messages.out

In MPI simulations, messages can be aggregated per partition. To write output for partition 0,1,.. in files messages.0, messages.1, etc., use:

mpirun python --shared-msg-file=messages

Set the MPI domain decomposition

When no MPI options are specified, HOOMD uses a minimum surface area selection of the domain decomposition strategy:

mpirun -n 8 python
# 2x2x2 domain

The linear option forces HOOMD-blue to use a 1D slab domain decomposition, which may be faster than a 3D decomposition when running jobs on a single node:

mpirun -n 4 python --linear
# 1x1x4 domain

You can also override the automatic choices completely:

mpirun -n 4 python --nx=1 --ny=2 --nz=2
# 1x2x2 domain

You can group multiple MPI ranks into partitions, to simulate independent replicas:

mpirun -n 12 python --nrank=3

This sub-divides the total of 12 MPI ranks into four independent partitions, with to which 3 GPUs each are assigned.

User options

User defined options may be passed to a job script via --user and retrieved by calling hoomd.option.get_user(). For example, if hoomd is executed with:

python --gpu=2 --ignore-display-gpu --user="--N=5 --rho=0.5"

then hoomd.option.get_user() will return ['--N=5', '--rho=0.5'], which is a format suitable for processing by standard tools such as optparse.