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General Relativistic Neutrino Radiation Magnetohydrodynamics for Neutron Star Merger Disks

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nubhlight: General Relativistic Neutrino Radiation Magnetohydrodynamics with Monte Carlo Transport

divergence-rates

Build Status

This software is approved for open-source release under LA-CC number C20019. Nubhlight was first presented in

and is based on ebhlight, first presented in

The above picture is from nubhlight's first application, modeling the 2017 neutron star merger event:

All academic work derived from this software should reference these publications. Questions, comments, and bug reports should be filed as github issues. Pull requests are welcome.

NUMERICAL SCHEME

nubhlight solves the equations of general relativistic radiation magnetohydrodynamics in stationary spacetimes. Fluid integration is performed with a second order shock-capturing scheme (HARM; Gammie, McKinney & Toth 2003). Frequency-dependent radiation transport is performed with a second order Monte Carlo scheme (GRMONTY; Dolence et al. 2009). Fluid and radiation exchange four- momentum in an explicit first-order operator-split fashion.

DEPENDENCIES

Software

nubhlight is written in C99. It requires the following external libraries:

  • GSL
  • MPI
  • Parallel HDF5
  • gfortran (if Burrows opacities are used)

Configuration and analysis scripts are written in Python 3, and employ matplotlib, numpy, and h5py.

If using gcc, version 4.9 or later is recommended.

Data

For realistic problems, nubhlight relies on tabulated nuclear equations of state and opacities and emissivities.

  • A native reader exists for the opacities released on stellarcollapse.org.
  • A FORTRAN reader exists for opacities developed by the Adam Burrows' group.
  • An HDF5 reader exists for opacities defined in nubhlight format. See core/opac_emis_hdf.c for the reader and for information for how to define your own such table.

CLANG FORMAT

clang-format is used to format source files. It's part of the clang toolchain and can be found and described here.

You can integrate clang-format into your editor. You can also add it as a git pre-commit hook so that all your changes are automatically formatted. To enable this, copy script/dependencies/pre-commit.clang-format into your git hook. e.g.,

cp script/dependencies/pre-commit.clang-format .git/hooks/pre-commit

CONFIGURATION

A custom build script is used for each problem to:

  • Set compile-time code parameters
  • Set machine-specific dependency locations
  • Collect copies of all required source files
  • Write a problem-specific makefile
  • Call make to compile the source and create an executable
  • Clean up temporary files

To run, for example, the Sod shocktube problem:

cd bhlight/prob/sod
python build.py
./bhlight -p param_template.dat

I/O

File input and output are performed with HDF5. In the active output directory, dumps/ and restarts/ folders are created, holding dump and restart output, respectively. Output directories may be specified at runtime by passing the flag

-o /path/to/output/directory/

to the executable.

AUTOMATIC TESTING

Scripts are provided for automatically running and analyzing certain test problems.

To run, for example, the Sod shocktube test:

cd bhlight/test/
python sod.py

which will produce sod.png in the current directory, showing the numerical and analytic solutions.

Several automatic tests are run through continuous integration on commit. Tests must pass before a pull request will be merged.

RUNTIME PARAMETERS

Runtime parameters are read in from a (required) parameters file passed to the executable as -p path/to/parameter/file. A default param.dat file is generated alongside the executable by the build routine. Note that this build routine overwrites param.dat each time it is called -- if you wish to preserve your runtime parameters, change the filename from param.dat.

Problem-specific runtime parameters are also available. Each problem.c file contains a routine void set_problem_params(). To include a problem parameter "test" (here a double, but 'int' and 'string' are also allowed) accessible from the parameter file, there are three steps:

  • Define your variable in problem.c in file scope (internal linkage recommended)

  • Call the parameter read function inside set_problem_params()

After these steps you should have

static double test;
void set_problem_params()
{
  set_param("test", &test);
}
  • Use the problem's build.py script to request your new variable as a runtime parameter, with the line bhl.config.set_rparm('test', 'double', default = 100)

The 'default' parameter is optional.

Copyright

copyright 2020. Triad National Security, LLC. All rights reserved. This program was produced under U.S. Government contract 89233218CNA000001 for Los Alamos National Laboratory (LANL), which is operated by Triad National Security, LLC for the U.S. Department of Energy/National Nuclear Security Administration. All rights in the program are reserved by Triad National Security, LLC, and the U.S. Department of Energy/National Nuclear Security Administration. The Government is granted for itself and others acting on its behalf a nonexclusive, paid-up, irrevocable worldwide license in this material to reproduce, prepare derivative works, distribute copies to the public, perform publicly and display publicly, and to permit others to do so.

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