Metadata-Version: 2.1
Name: tad_dftd4
Version: 0.0.2
Summary: Torch autodiff DFT-D4 implementation
Author: "Marvin Friede"
License: LGPL-3.0
Classifier: Framework :: Pytest
Classifier: License :: OSI Approved :: GNU Lesser General Public License v3 (LGPLv3)
Classifier: Natural Language :: English
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3 :: Only
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: Implementation :: CPython
Classifier: Topic :: Scientific/Engineering
Classifier: Typing :: Typed
Requires-Python: >=3.8
Description-Content-Type: text/x-rst
Provides-Extra: dev
License-File: COPYING
License-File: COPYING.LESSER

Torch autodiff for DFT-D4
=========================

.. image:: https://img.shields.io/badge/python-%3E=3.8-blue.svg
    :target: https://img.shields.io/badge/python-3.8%20|%203.9%20|%203.10%20|%203.11-blue.svg
    :alt: Python Versions

.. image:: https://img.shields.io/github/v/release/dftd4/tad-dftd4
    :target: https://github.com/dftd4/tad-dftd4/releases/latest
    :alt: Release

.. image:: https://img.shields.io/pypi/v/tad-dftd4
    :target: https://pypi.org/project/tad-dftd4/
    :alt: PyPI

.. image:: https://img.shields.io/badge/License-LGPL_v3-blue.svg
    :target: https://www.gnu.org/licenses/lgpl-3.0
    :alt: LGPL-3.0

.. image:: https://github.com/dftd4/dftd4/workflows/CI/badge.svg
    :target: https://github.com/dftd4/dftd4/actions
    :alt: CI

.. image:: https://readthedocs.org/projects/tad-dftd4/badge/?version=latest
    :target: https://tad-dftd4.readthedocs.io
    :alt: Documentation Status

.. image:: https://codecov.io/gh/dftd4/tad-dftd4/branch/main/graph/badge.svg?token=OGJJnZ6t4G
    :target: https://codecov.io/gh/dftd4/tad-dftd4
    :alt: Coverage

.. image:: https://results.pre-commit.ci/badge/github/dftd4/tad-dftd4/main.svg
    :target: https://results.pre-commit.ci/latest/github/dftd4/tad-dftd4/main
    :alt: pre-commit.ci status

Implementation of the DFT-D4 dispersion model in PyTorch.
This module allows to process a single structure or a batch of structures for the calculation of atom-resolved dispersion energies.

For details on the D4 dispersion model, see

- \E. Caldeweyher, C. Bannwarth and S. Grimme, *J. Chem. Phys.*, **2017**, *147*, 034112. DOI: `10.1063/1.4993215 <https://dx.doi.org/10.1063/1.4993215>`__

- \E. Caldeweyher, S. Ehlert, A. Hansen, H. Neugebauer, S. Spicher, C. Bannwarth and S. Grimme, *J. Chem. Phys.*, **2019**, *150*, 154122. DOI: `10.1063/1.5090222 <https://dx.doi.org/10.1063/1.5090222>`__

- \E. Caldeweyher, J.-M. Mewes, S. Ehlert and S. Grimme, *Phys. Chem. Chem. Phys.*, **2020**, *22*, 8499-8512. DOI: `10.1039/D0CP00502A <https://doi.org/10.1039/D0CP00502A>`__

For alternative implementations, also check out

`dftd4 <https://dftd4.readthedocs.io>`__:
  Implementation of the DFT-D4 dispersion model in Fortran with Python bindings.

`cpp-d4 <https://github.com/dftd4/cpp-d4>`__:
  Implementation of the DFT-D4 dispersion model in C++.

Installation
------------

pip
~~~

*tad-dftd4* can easily be installed with ``pip``.

.. code::

    pip install tad-dftd4


From source
~~~~~~~~~~~

This project is hosted on GitHub at `dftd4/tad-dftd4 <https://github.com/dftd4/tad-dftd4>`__.
Obtain the source by cloning the repository with

.. code::

    git clone https://github.com/dftd4/tad-dftd4
    cd tad-dftd4

We recommend using a `conda <https://conda.io/>`__ environment to install the package.
You can setup the environment manager using a `mambaforge <https://github.com/conda-forge/miniforge>`__ installer.
Install the required dependencies from the conda-forge channel.

.. code::

    mamba env create -n torch -f environment.yaml
    mamba activate torch

Development
-----------

For development, additionally install the following tools in your environment.

.. code::

    mamba install black covdefaults coverage mypy pre-commit pylint tox

With pip, add the option ``-e`` and the development dependencies for installing in development mode.

.. code::

    pip install -e .[dev]

The pre-commit hooks are initialized by running the following command in the root of the repository.

.. code::

    pre-commit install

For testing all Python environments, simply run `tox`.

.. code::

    tox

Note that this randomizes the order of tests but skips "large" tests. To modify this behavior, `tox` has to skip the optional _posargs_.

.. code::

    tox -- test

Examples
--------

The following example shows how to calculate the DFT-D3 dispersion energy for a single structure.

.. code:: python

    import torch
    import tad_dftd4 as d4

    numbers = d4.utils.to_number(symbols="C C C C N C S H H H H H".split())

    # coordinates in Bohr
    positions = torch.tensor(
        [
            [-2.56745685564671, -0.02509985979910, 0.00000000000000],
            [-1.39177582455797, +2.27696188880014, 0.00000000000000],
            [+1.27784995624894, +2.45107479759386, 0.00000000000000],
            [+2.62801937615793, +0.25927727028120, 0.00000000000000],
            [+1.41097033661123, -1.99890996077412, 0.00000000000000],
            [-1.17186102298849, -2.34220576284180, 0.00000000000000],
            [-2.39505990368378, -5.22635838332362, 0.00000000000000],
            [+2.41961980455457, -3.62158019253045, 0.00000000000000],
            [-2.51744374846065, +3.98181713686746, 0.00000000000000],
            [+2.24269048384775, +4.24389473203647, 0.00000000000000],
            [+4.66488984573956, +0.17907568006409, 0.00000000000000],
            [-4.60044244782237, -0.17794734637413, 0.00000000000000],
        ]
    )

    # total charge of the system
    charge = torch.tensor(0.0)

    # TPSS0-D4-ATM parameters
    param = {
        "s6": positions.new_tensor(1.0),
        "s8": positions.new_tensor(1.85897750),
        "s9": positions.new_tensor(1.0),
        "a1": positions.new_tensor(0.44286966),
        "a2": positions.new_tensor(4.60230534),
    }

    energy = d4.dftd4(numbers, positions, charge, param)
    torch.set_printoptions(precision=10)
    print(energy)
    # tensor([-0.0020841344, -0.0018971195, -0.0018107513, -0.0018305695,
    #         -0.0021737693, -0.0019484236, -0.0022788253, -0.0004080658,
    #         -0.0004261866, -0.0004199839, -0.0004280768, -0.0005108935])

The next example shows the calculation of dispersion energies for a batch of structures.

.. code:: python

    import torch
    import tad_dftd4 as d4

    # S22 system 4: formamide dimer
    numbers = d4.utils.pack((
        d4.utils.to_number("C C N N H H H H H H O O".split()),
        d4.utils.to_number("C O N H H H".split()),
    ))

    # coordinates in Bohr
    positions = d4.utils.pack((
        torch.tensor([
            [-3.81469488143921, +0.09993441402912, 0.00000000000000],
            [+3.81469488143921, -0.09993441402912, 0.00000000000000],
            [-2.66030049324036, -2.15898251533508, 0.00000000000000],
            [+2.66030049324036, +2.15898251533508, 0.00000000000000],
            [-0.73178529739380, -2.28237795829773, 0.00000000000000],
            [-5.89039325714111, -0.02589114569128, 0.00000000000000],
            [-3.71254944801331, -3.73605775833130, 0.00000000000000],
            [+3.71254944801331, +3.73605775833130, 0.00000000000000],
            [+0.73178529739380, +2.28237795829773, 0.00000000000000],
            [+5.89039325714111, +0.02589114569128, 0.00000000000000],
            [-2.74426102638245, +2.16115570068359, 0.00000000000000],
            [+2.74426102638245, -2.16115570068359, 0.00000000000000],
        ]),
        torch.tensor([
            [-0.55569743203406, +1.09030425468557, 0.00000000000000],
            [+0.51473634678469, +3.15152550263611, 0.00000000000000],
            [+0.59869690244446, -1.16861263789477, 0.00000000000000],
            [-0.45355203669134, -2.74568780438064, 0.00000000000000],
            [+2.52721209544999, -1.29200800956867, 0.00000000000000],
            [-2.63139587595376, +0.96447869452240, 0.00000000000000],
        ]),
    ))

    # total charge of both system
    charge = torch.tensor([0.0, 0.0])

    # TPSS0-D4-ATM parameters
    param = {
        "s6": positions.new_tensor(1.0),
        "s8": positions.new_tensor(1.85897750),
        "s9": positions.new_tensor(1.0),
        "a1": positions.new_tensor(0.44286966),
        "a2": positions.new_tensor(4.60230534),
    }

    # calculate dispersion energy in Hartree
    energy = torch.sum(d4.dftd4(numbers, positions, charge, param), -1)
    torch.set_printoptions(precision=10)
    print(energy)
    # tensor([-0.0088341432, -0.0027013607])
    print(energy[0] - 2*energy[1])
    # tensor(-0.0034314217)

Contributing
------------

This is a volunteer open source projects and contributions are always welcome.
Please, take a moment to read the `contributing guidelines <CONTRIBUTING.md>`__.

License
-------

This project is free software: you can redistribute it and/or modify it under the terms of the Lesser GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.

This project is distributed in the hope that it will be useful, but without any warranty; without even the implied warranty of merchantability or fitness for a particular purpose. See the Lesser GNU General Public License for more details.

Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in this project by you, as defined in the Lesser GNU General Public license, shall be licensed as above, without any additional terms or conditions.
