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# GPAW - A Projected Augmented Wave code

[GPAW](https://wiki.fysik.dtu.dk/gpaw/) is a density-functional theory (DFT)
program for ab initio electronic structure calculations using the projector
augmented wave method. It uses a uniform real-space grid representation of the
electronic wavefunctions that allows for excellent computational scalability
and systematic converge properties.

The GPAW benchmark tests MPI parallelization and the quality of the provided mathematical
libraries, including BLAS, LAPACK, ScaLAPACK, and FFTW-compatible library. There is
also a CUDA-based implementation for GPU systems.


## Characteristics of the benchmark

GPAW is written mostly in Python, but includes also computational kernels
written in C as well as leveraging external libraries such as NumPy, BLAS and
ScaLAPACK. Parallelisation is based on message-passing using MPI with no
support for multithreading.

There have been various developments for GPGPUs and MICs in the past
using either CUDA or pyMIC/libxstream. Many of those branches see no
development anymore. The relevant CUDA version for this benchmark is available in a
[separate GitLab for CUDA development, cuda branch](https://gitlab.com/mlouhivu/gpaw/tree/cuda).
This version corresponds to the Aalto version mentioned on the
[GPU page of the GPAW Wiki](https://wiki.fysik.dtu.dk/gpaw/devel/projects/gpu.html).
As of early 2020, that version seems to be derived from the 1.5.2 CPU version
(at least, I could find a commit that claims to merge the 1.5.2 code).

There is currently no active support for non-CUDA accelerator platforms.

For the UEABS benchmark version 2.2, the following versions of GPAW were tested:
  * CPU-based:
      * Version 20.1.0, as this one is the version on which the most recent GPU commits
        are based.
      * Version 20.10.0, as it was the most recent version during the development of
        the IEABS 2.2. benchmark suite.
  * GPU-based: As there is no official release of the GPU version and as it is
    at the moment of the release of the UEABS version 2.2 under heavy development
    to also support AMD GPUs, there is no official support for the GPU version
    ([the cuda branch of the GitLab for CUDA development](https://gitlab.com/mlouhivu/gpaw/tree/cuda))
    in UEABS version 2.2.

Versions 1.5.2 and 19.8.1 were also considered but are not compatible with the regular
input files provided here. Hence support for those versions of GPAW was dropped in
this version of the UEABS.

There are three benchmark cases, denotes S, M and L.

### Case S: Carbon nanotube

A ground state calculation for a carbon nanotube in vacuum. By default uses a
6-6-10 nanotube with 240 atoms (freely adjustable) and serial LAPACK with an
option to use ScaLAPACK. Expected to scale up to 10 nodes and/or 100 MPI
tasks. This benchmark runs fast. Expect execution times around 1 minutes
on 100 cores of a modern x86 cluster.

Input file: [benchmark/1_S_carbon-nanotube/input.py](benchmark/1_S_carbon-nanotube/input.py)
This input file still works with version 1.5.2 and 19.8.1 of GPAW.


A ground state calculation for a copper filament in vacuum. By default uses a
3x4x4 FCC lattice with 71 atoms (freely adjustable through the variables `x`,
`y` and `z` in the input file) and ScaLAPACK for
parallelisation. Expected to scale up to 100 nodes and/or 1000 MPI tasks.
Input file: [benchmark/2_M_copper-filament/input.py](benchmark/2_M_copper-filament/input.py)

This input file does not work with GPAW 1.5.2 and 19.8.1. It requires GPAW
20.1.0 or 20.10.0. Please try older versions of the UEABS if you want to use
these versions of GPAW.

The benchmark runs best when using full nodes. Expect a
performance drop on other configurations.


### Case L: Silicon cluster

A ground state calculation for a silicon cluster in vacuum. By default the
cluster has a radius of 15Å (freely adjustable) and consists of 702 atoms,
and ScaLAPACK is used for parallelisation. Expected to scale up to 1000 nodes
and/or 10000 MPI tasks.

Input file: [benchmark/3_L_silicon-cluster/input.py](benchmark/3_L_silicon-cluster/input.py)
This input file does not work with GPAW 1.5.2 and 19.8.1. It requires GPAW
20.1.0 or 20.10.0. Please try older versions of the UEABS if you want to use
these versions of GPAW.



## Mechanics of building the benchmark
Installing and running GPAW has changed a lot in the since the previous
versions of the UEABS. GPAW version numbering changed in 2019. Version 1.5.3 is the
last version with the old numbering. In 2019 the development team switched
to a version numbering scheme based on year, month and patchlevel, e.g.,
19.8.1 for the second version released in August 2019.
Another change is in the Python packages used to install GPAW. Versions up to
and including 19.8.1 use the `distutils` package while versions 20.1.0 and later
are based on `setuptools`. This does affect the installation process.

Running GPAW is no longer done via a wrapper executable `gpaw-python` that
replaces the Python interpreter (it internally links to the libpython library)
and that provides the MPI functionality. Since version 20.1.0, the standard Python
interpreter is used and the MPI functionality is included in the `_gpaw.so` shared library.


### Available instructions

The [GPAW wiki](https://wiki.fysik.dtu.dk/gpaw/) only contains the
[installation instructions](https://wiki.fysik.dtu.dk/gpaw/index.html) for the current version.
For the installation instructions with a list of dependencies for older versions,
download the code (see below) and look for the file `doc/install.rst` or go to the
[GPAW GitLab](https://gitlab.com/gpaw), select the tag for the desired version and
view the file `doc/install.rst`.

The [GPAW wiki](https://wiki.fysik.dtu.dk/gpaw/) also provides some
[platform specific examples](https://wiki.fysik.dtu.dk/gpaw/platforms/platforms.html).
GPAW is Python code but it also contains some C code for some performance-critical
parts and to interface to a number of libraries on which it depends.

Hence GPAW has the following requirements:
  * C compiler with MPI support
  * BLAS, LAPACK, BLACS and ScaLAPACK. ScaLAPACK is optional for GPAW, but mandatory
    for the UEABS benchmarks. It is used by the medium and large cases and optional
  * Python. GPAW 20.1.0 requires Python 3.5-3.8 and GPAW 20.10.0 Python 3.6-3.9.
      * [NumPY](https://pypi.org/project/numpy/) 1.9 or later (for GPAW 20.1.0/20.10.0)
        GPAW versions before 20.10.0 produce warnings when used with NumPy 1.19.x.
      * [SciPy](https://pypi.org/project/scipy/) 0.14 or later (for GPAW 20.1.0/20.10.0)
  * [FFTW](http://www.fftw.org) is highly recommended. As long as the optional libvdwxc
    component is not used, the MKL FFTW wrappers can also be used. Recent versions of
    GPAW also show good performance using just the NumPy-provided FFT routines provided
    that NumPy has been built with a highly optimized FFT library.
  * [LibXC](https://www.tddft.org/programs/libxc/) 3.X or 4.X for GPAW 20.1.0 and 20.10.0.
    LibXC is a library of exchange-correlation functions for density-functional theory.
    None of the versions currently mentions LibXC 5.X as officially supported.
  * [ASE, Atomic Simulation Environment](https://wiki.fysik.dtu.dk/ase/), a Python package
    from the same group that develops GPAW
      * Check the release notes of GPAW as the releases of ASE and GPAW should match.
        The benchmarks were tested using ASE 3.19.3 with GPAW 20.1.0 and ASE 3.20.1
        with GPAW 20.1.0.
      * ASE has some optional dependencies that are not needed for the benchmarking: Matplotlib (2.0.0 or newer),
        tkinter (Tk interface, part of the Standard Python Library) and Flask.
  * Optional components of GPAW that are not used by the UEABS benchmarks:
      * [libvdwxc](https://gitlab.com/libvdwxc/libvdwxc), a portable C library
        of density functionals with van der Waals interactions for density functional theory.
        This library does not work with the MKL FFTW wrappers.
      * [ELPA](https://elpa.mpcdf.mpg.de/),
        which should improve performance for large systems when GPAW is used in
        [LCAO mode](https://wiki.fysik.dtu.dk/gpaw/documentation/lcao/lcao.html)
  * NVIDIA CUDA toolkit
  * [PyCUDA](https://pypi.org/project/pycuda/)

Installing GPAW also requires a number of standard build tools on the system, including
  * [GNU autoconf](https://www.gnu.org/software/autoconf/) is needed to generate the
    configure script for libxc
  * [GNU Libtool](https://www.gnu.org/software/libtool/) is needed. If not found,
    the configure process of libxc produces very misleading
    error messages that do not immediately point to libtool missing.
  * [GNU make](https://www.gnu.org/software/make/)

GPAW is freely available under the GPL license.

The source code of the CPU version can be
downloaded from the [GitLab repository](https://gitlab.com/gpaw/gpaw) or as
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a tar package for each release from [PyPi](https://pypi.org/simple/gpaw/).

For example, to get version 20.1.0 using git:
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```bash
git clone -b 20.1.0 https://gitlab.com/gpaw/gpaw.git
The CUDA development version is available in
[the cuda branch of a separate GitLab](https://gitlab.com/mlouhivu/gpaw/tree/cuda).
To get the current development version using git:
```bash
git clone -b cuda https://gitlab.com/mlouhivu/gpaw.git
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```
Crucial for the configuration of GPAW is a proper `siteconfig.py` file (GPAW 20.1.0 and later,
earlier versions used `customize.py`). The defaults used by GPAW
may not offer optimal performance and the automatic detection of the libraries also

The UEABS repository contains additional instructions:
  * [general instructions](build/build-cpu.md)
Example [build scripts](build/examples/) are also available.
## Mechanics of Running the Benchmark
### Download of the benchmark sets
As each benchmark has only a single input file, these can be downloaded
right from this repository.
  1. [Testcase S: Carbon nanotube input file](benchmark/1_S_carbon-nanotube/input.py)
  2. [Testcase M: Copper filament input file](benchmark/2_M_copper-filament/input.py)
  3. [Testcase L: Silicon cluster input file](benchmark/3_L_silicon-cluster/input.py)
These instructions are exclusively for GPAW 20.1.0 and later.
There are two different ways to start GPAW.
One way is through `mpirun`, `srun` or an equivalent process starter and the
`gpaw python` command:
```
srun gpaw python input.py
```
The second way is by simply using the `-P` flag of the `gpaw` command and let it
use a process starter internally:
```
gpaw -P 100 python input.py
```
will run on 100 cores.
There is a third but non-recommended option:
```
srun python3 input.py
```
That option however doesn't do the imports in the same way that the `gpaw` script
would do.
TODO. Convergence problems.
TODO. Get the medium case to run before spending time on the large one.