Documentation: https://xbout.readthedocs.io

Examples: https://github.com/boutproject/xBOUT-examples

xBOUT provides an interface for collecting the output data from a BOUT++ simulation into an xarray dataset in an efficient and scalable way, as well as accessor methods for common BOUT++ analysis and plotting tasks.

Currently only in alpha (until 1.0 released) so please report any bugs, and feel free to raise issues asking questions or making suggestions.

With pip:

pip install --user xbout

With conda:

conda install -c conda-forge xbout

You can test your installation of xBOUT by running pytest --pyargs xbout.

xBOUT requires other python packages, which will be installed when you run one of the above install commands if they are not already installed on your system.

The function open_boutdataset() uses xarray & dask to collect BOUT++ data spread across multiple NetCDF files into one contiguous xarray dataset.

The data from a BOUT++ run can be loaded with just

bd = open_boutdataset('./run_dir*/BOUT.dmp.*.nc', inputfilepath='./BOUT.inp')

open_boutdataset() returns an instance of an xarray.Dataset which contains BOUT-specific information in the attrs, so represents a general structure for storing all of the output of a simulation, including data, input options and (soon) grid data.

xBOUT defines a set of accessor methods on the loaded Datasets and DataArrays, which are called by ds.bout.method().

This is where BOUT-specific data manipulation, analysis and plotting functionality is stored, for example

ds['n'].bout.animate2D(animate_over='t', x='x', y='z')

or

ds.bout.create_restarts(savepath='.', nxpe=4, nype=4)

The accessor classes BoutDatasetAccessor and BoutDataArrayAccessor are intended to be subclassed for specific BOUT++ modules. The subclass accessor will then inherit all the .bout accessor methods, but you will also be able to override these and define your own methods within your new accessor.

For example to add an extra method specific to the STORM BOUT++ module:

from xarray import register_dataset_accessor
from xbout.boutdataset import BoutDatasetAccessor

@register_dataset_accessor('storm')
class StormAccessor(BoutAccessor):
    def __init__(self, ds_object):
        super().__init__(ds_object)

    def special_method(self):
        print("Do something only STORM users would want to do")

ds.storm.special_method()

Out [1]: Do something only STORM users would want to do

There is included an example of a StormDataset which contains all the data from a STORM simulation, as well as extra calculated quantities which are specific to the STORM module.

Feel free to raise issues about anything, or submit pull requests, though I would encourage you to submit an issue before writing a pull request. For a general guide on how to contribute to an open-source python project see xarray's guide for contributors.

The existing code was written using Test-Driven Development, and I would like to continue this, so please include pytest tests with any pull requests.

If you write a new accessor, then this should really live with the code for your BOUT module, but it could potentially be added as an example to this repository too.

Clone the repository with:

git clone [email protected]:boutproject/xBOUT.git

The recommended way to work with xBOUT from the git repo is to do an editable install with pip. Run this command from the xBOUT/ directory:

pip install --user -e .

which will also install all the required dependencies. Dependencies can also be installed using pip

pip install --user -r requirements.txt

or conda

conda install --file requirements.txt

It is possible to use xBOUT by adding the xBOUT/ directory to your $PYTHONPATH.

Test by running pytest in the xBOUT/ directory.

Things which definitely need to be included (see the 1.0 milestone):

• More tests, both with and against the original boutdata.collect()
• Speed test against old collect

Things which would be nice and I plan to do:

• Infer concatenation order from global indexes (see issue)
• Real-space coordinates
• Variable names and units (following CF conventions)
• Unit-aware arrays
• Variable normalisations

Things which might require a fair amount of effort by another developer but could be very powerful:

• Using real-space coordinates to create tokamak-shaped plots
• Support for staggered grids using xgcm
• Support for encoding topology using xgcm
• API for applying BoutCore operations (hopefully using xr.apply_ufunc)