https://github.com/idaholab/montepy

MontePy is the most user friendly Python library (API) to read, edit, and write MCNP input files.
https://github.com/idaholab/montepy

api mcnp mcnp6 monte-carlo neutronics radiation-transport

Last synced: 5 days ago
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MontePy is the most user friendly Python library (API) to read, edit, and write MCNP input files.

• Host: GitHub
• URL: https://github.com/idaholab/montepy
• Owner: idaholab
• License: mit
• Created: 2024-01-09T23:30:28.000Z (about 1 year ago)
• Default Branch: develop
• Last Pushed: 2024-10-30T00:47:36.000Z (3 months ago)
• Last Synced: 2024-10-30T02:44:25.139Z (3 months ago)
• Topics: api, mcnp, mcnp6, monte-carlo, neutronics, radiation-transport
• Language: Python
• Homepage: https://www.montepy.org/
• Size: 2.9 MB
• Stars: 32
• Watchers: 6
• Forks: 6
• Open Issues: 107
• Metadata Files:
  • Readme: README.md
  • Changelog: CHANGELOG.rst
  • Contributing: CONTRIBUTING.md
  • License: LICENSE
  • Code of conduct: CODE_OF_CONDUCT.md
  • Authors: AUTHORS

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• awesome-nuclear - MontePy

README

        
# MontePy



[![license](https://img.shields.io/github/license/idaholab/MontePy.svg)](https://github.com/idaholab/MontePy/blob/develop/LICENSE)

[![JOSS article status](https://joss.theoj.org/papers/e5b5dc8cea19605a1507dd4d420d5199/status.svg)](https://joss.theoj.org/papers/e5b5dc8cea19605a1507dd4d420d5199)

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[![Project Status: Active – The project has reached a stable, usable state and is being actively developed.](https://www.repostatus.org/badges/latest/active.svg)](https://www.repostatus.org/#active)

[![PyPI version](https://badge.fury.io/py/montepy.svg)](https://badge.fury.io/py/montepy)

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MontePy is the most user friendly Python library for reading, editing, and writing MCNP input files. 

## Installing

Simply run:

```

pip install montepy

```

For more complicated setups

see the [Installing section in the user guide](https://www.montepy.org/en/stable/starting.html#installing).

## User Documentation

MontePy has a website [documenting how to work with MCNP in python with MontePy](https://www.montepy.org/). 

The website contains a user's guide for getting started, 

a developer's guide covering the design and approach of MontePy,

instructions for contributing, 

and the Python API documentation.

## Features

	

* Handles almost all MCNP input syntax.

* Parses Cells, Surfaces, Materials, and Transforms very well.	

* Can parse all surface types except macrobody facets ([Issue #354](https://github.com/idaholab/MontePy/issues/354)).

* Can read and write out all other MCNP inputs, even if it doesn't not understand them	

* Attempts to write out the MCNP problem verbatim, even matching the original user formatting. (See some of the [open issues](https://github.com/idaholab/MontePy/issues).)

* Can quickly [access cells, surfaces, and materials by their numbers](https://www.montepy.org/en/stable/starting.html#collections-are-accessible-by-number). For example: `cell = problem.cells[105]`.

* Can quickly update cell parameters, [such as importances](https://www.montepy.org/en/stable/starting.html#setting-cell-importances). For example `cell.importance.neutron = 2.0`.

* Can easily [create universes, and fill other cells with universes](https://www.montepy.org/en/stable/starting.html#universes).

* Currently has over 550 test cases.

 

Here is a quick example showing multiple tasks in MontePy:

``` python

import montepy

# read in file

problem = montepy.read_input("tests/inputs/test.imcnp")

  

# set photon importance for multiple cells

importances = {1: 0.005,

   2: 0.1,

   3: 1.0,

   99: 1.235

}

for cell_num, importance in importances.items():

   problem.cells[cell_num].importance.photon = importance

#create a universe and fill another cell with it

universe = montepy.Universe(123)

problem.universes.append(universe)

# add all cells with numbers between 1 and 4

universe.claim(problem.cells[1:5])

# fill cell 99 with universe 123

problem.cells[99].fill.universe = universe

# update all surfaces numbers by adding 1000 to them

for surface in problem.surfaces:

   surface.number += 1000

# all cells using these surfaces will be automatically updated as well

#write out an updated file

problem.write_problem("foo_update.imcnp")

```

## Limitations

Here a few of the known bugs and limitations:

	

* Cannot handle vertical input mode.

* Does not support editing tallies in a user-friendly way.

* Does not support editing source definition in a user-friendly way.

* Cannot parse all valid material definitions. There is a known bug ([#182](https://github.com/idaholab/MontePy/issues/182)) that MontePy can only parse materials where all

    keyword-value pairs show up after the nuclide definitions. For example:

   * `M1 1001.80c 1.0 plib=80p` can be parsed.

   * `M1 plib=80p 1001.80c 1.0` cannot be parsed; despite it being a valid input.

## Alternatives

There are some python packages that offer some of the same features as MontePy,

    but don't offer the same level of robustness, ease of installation, and user friendliness.

Many of the competitors do not offer the robustness that MontePy does becuase,

    they do not utilize context-free parsing (as of 2024). 

These packages are:

* [pyMCNP](https://github.com/FSIBT/PyMCNP)

* [MCNP-Input-Reader](https://github.com/ENEA-Fusion-Neutronics/MCNP-Input-Reader)

* [numjuggler](https://github.com/inr-kit/numjuggler)

The only other library that does utilize context-free parsing that we are aware is

[MCNP™y](https://github.rpi.edu/NuCoMP/mcnpy). MontePy differs by being:

* On PyPI, and can be installed via pip.

* Only requires a python interpreter, and not a Java virtual machine. 

* Allowing contributions from anyone with a public GitHub account

For only writing, or templating an input file there are also some great tools out there. 

These packages don't provide the same functionality as MontePy inherently,

    but could be the right tool for the job depending on the user's needs.

* [Workflow and Template Toolkit for Simulation (WATTS)](https://github.com/watts-dev/watts)

* [Advanced Reactor Modeling Interface (ARMI)](https://github.com/terrapower/armi)

Another honorable mention that doesn't replicate the features of MontePy,

    but could be a great supplement to MontePy for defining materials, performing activations, etc.

    is [PyNE --- the Nuclear Engineering Toolkit](https://pyne.io/).

	

## Bugs, Requests and Development

So MontePy doesn't do what you want? 

Add an issue here with the "feature request" tag. 

The system is very modular and you should be able to develop it pretty quickly.

Read the [developer's guide](https://www.montepy.org/en/stable/developing.html) for more details.

If you have any questions feel free to ask [@micahgale](mailto:[email protected]).

## Citation

For citing MontePy in a publication a [Journal of Open Source Software](https://joss.readthedocs.io/en/latest/) article is under review. 

In the meantime there is a DOI for the software from [OSTI](https://osti.gov): [DOI:10.11578/dc.20240115.1](https://doi.org/10.11578/dc.20240115.1).

You can cite MontePy as:

> M. Gale, T. Labossiere-Hickman, B. Carbno, A. Bascom, and MontePy contributors, "MontePy", 2024, [doi: 10.11578/dc.20240115.1](https://doi.org/10.11578/dc.20240115.1).

 

# Finally: make objects, not regexes!