Install and Run¶
Prerequisites¶
In this guide, it is assumed that readers have a basic knowledge of Linux and its command line operations. For the installation of SALMON, following packages are required.
Fortran90/C compiler. SALMON assumes users have one of the following compilers:
GCC (Gnu Compiler Collection)
Intel Compiler
Fujitsu Compiler (at FX100 and A64FX)
One of the following library packages for linear algebra:
Netlib BLAS/LAPACK/ScaLAPACK
Intel Math Kernel Library (MKL)
Fujitsu Scientific Subroutine Library 2 (SSL-II)
Build tools:
CMake
If you use other compilers, you may need to change build scripts (CMake). See Additional options in configure.py script. If no numerical library is installed on your computer system, you may need to install BLAS/LAPACK by yourself. See Troubleshooting of the Installation Process.
For the installation of SALMON, we adopt the CMake tools as the first option. If there were any problems to use CMake tools in your environment, you may use the GNU make tools. See Troubleshooting of the Installation Process.
Download¶
The newest version of SALMON can be downloaded from download page. You can also get the file by
To extract files from the downloaded file SALMON-<VERSION>.tar.gz
, type the following command in the command-line:
$ tar -zxvf ./SALMON-<VERSION>.tar.gz
After the extraction, the following directories will be created:
SALMON
|- src Source codes
|- example Samples
|- cmakefiles CMake related files
|- gnumakefiles GNU Makefiles for building
Build and Install¶
To compile SALMON to create executable the binary files, we adopt to use CMake tools as the first option. In case you fail to build SALMON using CMake in your environment, we may use Gnu Make. See Build using GNU Makefile.
Checking CMake availability¶
First, examine whether CMake is usable in your environment or not. Type the following in Linux command-line:
$ cmake --version
If CMake is not installed in your system, an error message such as cmake: command not found
will appear.
If CMake is installed on your system, the version number will be shown.
To build SALMON, CMake of version 3.14.0 or later is required.
If you confirm that CMake of version 3.14.0 or later is installed in your system, proceed to Build using CMake.
However, we realize that old versions of CMake are installed in many systems.
If CMake is not installed or CMake of older versions is installed in your system, you need to install the new version by yourself.
It is a simple procedure and explained below.
Installation of CMake (pre-compiled binary of Linux)¶
CMake is a cross-platform build tool.
The simplest way to make CMake usable in your environment is to get the binary distribution of CMake from the download page. (The file name of the binary distribution will be cmake-<VERSION>-<PLATFORM>.tar.gz
). In standard Linux environment, a file for the platform of Linux x86_64 will be appropriate.
To download the file, proceed as follows: We assume that you are in the directory that you extracted files from the downloaded file of SALMON,
and that you will use the version 3.16.8. First get the URL of the download link from your browser, and use wget
command in your Linux command-line:
$ wget https://cmake.org/files/v3.16/cmake-3.16.8-Linux-x86_64.tar.gz
Next, unpack the archive by:
$ tar -zxvf cmake-3.16.8-Linux-x86_64.tar.gz
and you will have the binary make-3.16.8-Linux-x86_64/bin/cmake
in your directory.
To make the cmake
command usable in your command-line, you need to modify the environment variable $PATH
so that the executable of CMake are settled inside the directory specified in your $PATH
.
If you use the bash shell, you need to modify the file ~/.bashrc
that specifies the $PATH
variable. It can be done by typing the following command in your login directory:
$ export PATH=<SALMON_INSTALLATION_DIRECTORY>/cmake-3.16.8-Linux-x86_64/bin:$PATH
and then reload the configuration by typing:
$ source ~/.bashrc
See Installation of CMake describes Other way of the installation.
Build using CMake¶
Confirming that CMake of version 3.14.0 or later can be usable in your environment, proceed the following steps. We assume that you are in the directory SALMON.
Create a new temporary directory
build
and move to the directory:$ mkdir build $ cd build
Execute the python script ''configure.py'' and then make:
$ python ../configure.py --arch=ARCHITECTURE --prefix=../ $ make $ make install
In executing the python script, you need to specify ARCHITECTURE
that indicates the architecture of the CPU in your computer system such as intel-avx
. The options of the ARCHITECUTRE
are as follows:
arch |
Detail |
Compiler |
Numerical Library |
---|---|---|---|
intel-knl |
Intel Knights Landing |
Intel Compiler |
Intel MKL |
intel-knc |
Intel Knights Corner |
Intel Compiler |
Intel MKL |
intel-avx |
Intel Processer (Ivy-, Sandy-Bridge) |
Intel Compiler |
Intel MKL |
intel-avx2 |
Intel Processer (Haswell, Broadwell ..) |
Intel Compiler |
Intel MKL |
intel-avx512 |
Intel Processer (Skylake-SP) |
Intel Compiler |
Intel MKL |
fujitsu-fx100 |
FX100 Supercomputer |
Fujitsu Compiler |
SSL-II |
fujitsu-a64fx-ea |
A64FX processor (Fugaku, FX1000, FX700) |
Fujitsu Compiler |
SSL-II |
If the build is successful, you will get a file salmon
at the top-level build directory.
Files necessary to run SALMON¶
To run SALMON, at least two kinds of files are required for any calculations.
One is an input file with the filename extension *.inp
that should be read from the standard input stdin
.
This file should be prepared in the Fortran90 namelist format.
Pseudopotential files of relevant elements are also required.
Depending on your purpose, some other files may also be necessary.
For example, coordinates of atomic positions of the target material may be either written in the input file or prepared as a separate file.
Pseudopotentials¶
SALMON utilizes norm-conserving (NC) pseudpotentials. Filenames of pseudopotentials should be written in the input file.
You may find pseudopotentials of some elements in the samples prepared in Exercises.
In SALMON, several formats of pseudopotentials may be usable (listed below).
For example, pseudopotentials with an extension .fhi
can be obtained from the ABINIT website (this is a part of previous atomic data files for the ABINIT code).
Pseudopotential |
extension |
Website |
---|---|---|
Fritz-Haber-Institute (FHI) pseudopotentials |
|
https://www.abinit.org/sites/default/files/PrevAtomicData/psp-links/lda_fhi.html (for LDA), https://www.abinit.org/sites/default/files/PrevAtomicData/psp-links/gga_fhi.html (for GGA) |
Pseudopotentials for the OpenMX code |
|
|
Format 8 for ABINIT norm-conserving pseudopotentials |
|
https://www.abinit.org/psps_abinit , http://www.pseudo-dojo.org/ |
Unified-pseudopotential-format (NC type only in SALMON) |
|
http://www.quantum-espresso.org/pseudopotentials/unified-pseudopotential-format , http://www.pseudo-dojo.org/ |
input file¶
Input files are composed of several blocks of namelists:
&namelist1
variable1 = int_value
variable2 = 'char_value'
/
&namelist2
variable1 = real8_value
variable2 = int_value1, int_value2, int_value3
/
A block of namelists starts with &namelist
line and ends with /
line.
The blocks may appear in any order.
Between two lines of &namelist
and /
, descriptions of variables and their values appear.
Note that many variables have their default values so that it is not necessary to give values for all variables.
Descriptions of the variables may appear at any position if they are between &namelist
and /
.
SALMON describes electron dynamics in systems with both isolated and periodic boundary conditions.
The boundary condition is specified by the variable iperiodic
in the namelist &system
.
Calculations are usually achieved in two steps; first, the ground state calculation is carried out and then electron dynamics calculations in real time is carried out. A choice of the calculation mode or theory in the calculation is specified by the variable theory
in the namelist &calculation
.
In the typical way, the ground state calculation based on DFT is first carried out specifying theory = 'dft'
.
Then the real-time electron dynamics calculation based on TDDFT is carried out specifying theory = 'tddft_pulse'
.
In Exercises, we prepare six exercises that cover typical calculations feasible by SALMON. We prepare explanations of the input files of the exercises that will help to prepare input files of your own interests.
There are more than 20 groups of namelists. A complete list of namelist variables is given in the file SALMON/manual/input_variables.md
.
Namelist variables that are used in our exercises are explained at Inputs
.
Run SALMON¶
Before running SALMON, the following preparations are required as described above: The executable file of salmon
should be built from the source file of SALMON. An input file inputfile.inp
and pseudopotential files should also be prepared.
The execution of the calculation can be done as follows: In single process environment, type the following command:
$ salmon < inputfile.inp > fileout.out
In multiprocess environment in which the command to execute parallel calculations using MPI is mpiexec
, type the following command:
$ mpiexec -n NPROC salmon < inputfile.inp > fileout.out
where NPROC is the number of MPI processes that you will use.
The execution command and the job submission procedure depends much on local environment. We summarize general conditions to execute SALMON:
SALMON runs in both single-process and multi-process environments using MPI.
Executable file is prepared as
salmon
in the standard build procedure.To start calculations,
inputfile.inp
should be read throughstdin
.
MPI process distribution¶
SALMON provides three variables to determine the process distribution/allocation.
nproc_k
nproc_ob
nproc_rgrid(3)
In SALMON, the process distribution is determined automatically as default. However, in many situations, an explicit assignment of the process distribution will provide a better performance than the default setting.
We recommend to distribute the processes as follows,
If you use k-points ( the number of k-points is greater than 1) and the number of
the real-space grid (num_rgrid
) is not very large (about 16^3):
First, assign many processes to
nproc_k
.Then, assign the remaining processes to
nproc_ob
.Not dividing the spatial grid,
nproc_rgrid = 1, 1, 1
.
Else:
First, assign the processes to
nproc_ob
.Then, assign the remaining processes to
nproc_rgrid
.
If real-space grid size (
num_rgrid(1:3) = al(1:3) / dl(1:3)
) is equal to or larger than about 64^3,you should find a balanced distribution between
nproc_rgrid
andnproc_ob
.
Tips for large-scale calculation¶
We explain below some tips that will be useful to improve performance when you carry out large scale simulations using world top-level supercomputers. Therefore, the following contents will only be useful only for limited users.
Improve the performance of the eigenvalues solver¶
In DFT calculations of large systems, subspace diagonalization becomes the performance bottleneck in the entire calculation. Therefore, it is important to use a parallel eigenvalues solver. In SALMON, a LAPACK routine without parallelization is used for the diagonalization as default. As parallelized solvers, ScaLAPACK and EigenExa are usable. To use them, it is necessary to rebuild SALMON enabling ScaLAPACK/EigenExa. You can find the instruction in Install and Run.
To execute SALMON using ScaLAPACK/EigenExa, either yn_scalapack = 'y'
or yn_eigenexa = 'y'
should be
included in the inputfile:
¶llel
yn_scalapack = 'y' ! use ScaLAPACK for diagonalization
!yn_eigenexa = 'y' ! use EigenExa
yn_scalapack_red_mem = 'y' ! to reduce the memory consumption
/
ScaLAPACK/EigenExa solves the eigenvalue problem with nproc_ob
process distribution.
If nproc_ob = 1
, ScaLAPACK/EigenExa will perform in the same way as the LAPACK library.
Improve the performance of Hartree solver¶
For periodic systems, a Fourier transformation is used to solve the Poisson equation (to calculate the Hartree potential). In SALMON, a simple Fourier transformation without Fast Fourier Transformation (FFT) is used as default. In SALMON, a parallelized FFT routine, FFTE, is usable and works efficiently for large systems. In using FFTE, the following conditions should be satisfied:
num_rgrid(1) mod nproc_rgrid(2) = 0
num_rgrid(2) mod nproc_rgrid(2) = 0
num_rgrid(2) mod nproc_rgrid(3) = 0
num_rgrid(3) mod nproc_rgrid(3) = 0
In addition, the prime factors for the number of real-space grid of each direction (num_rgrid(1:3)) must be a combination of 2, 3 or 5.
To use FFTE, yn_ffte = 'y'
should be included in the input file:
¶llel
yn_ffte = 'y'
/
Improve IO performance (write/read wavefunction)¶
Almost all supercomputer systems provide distributed filesystems such as Lustre. Distributed filesystems are equipped with a meta-data server (MDS) and an object-storage server (OST). The OST stores real user data files, and the MDS stores the address of the user date files in the OST. When accessing to the data files in the OST, the process send a query about the OST address to MDS. Then, a network contention may occur in the query process.
In most implementations of the filesystem, the MDS that replies to the query is determined by the directory structure.
For a calculation in which k-point is not used,
method_wf_distributor
and nblock_wf_distribute
are prepared to reduce the network contention:
&control
method_wf_distributor = 'slice' ! every orbital function is stored as a single file.
nblock_wf_distribute = 32 ! files of 32 orbital functions are stored in one directory.
/
Improve the communication performance for mesh-torus network system¶
Large-scale supercomputers often adopt a mesh-torus network system such as Cray dragon-fly and Fujitsu Tofu to achieve high scalability with relatively low cost. In SALMON, a special MPI process distribution (communicator creation rule) is prepared to improve the performance in large-scale mesh-torus network systems.
Currently, we provide the communicator creation rule for "Supercomputer Fugaku", which is developed by RIKEN R-CCS and Fujitsu limited. Fugaku is equipped with a 6-D mesh-torus network which is called "Tofu-D". Users may control it as a 3-D logical network. SALMON utilizes 5-D array (wavefunction(x, y, z, orbital, k-point)) as a domain for parallelization. We create a map that connects the 3-D network to the 5-D array distribution.
We introduce the following variables and conditons to assign the 3-D mesh-torus network to the 5-D array distribution:
PW = nproc_ob * nproc_k
(PX, PY, PZ) = nproc_rgrid
PPN = '# of process per node' (we recommend the value 4 in Fugaku)
Requested process shape: (PX, PY, PZ, PW)
Tofu-D network shape: (TX, TY, TZ)
Actual process shape: (TX * PPN, TY, TZ)
if (process_allocation == 'grid_sequential'):
PW = PW1 * PW2 * PW3
PW1 = (TX * PPN) / PX
PW2 = TY / PY
PW3 = TZ / PZ
TX = (PX * PW1) / PPN
TY = PY * PW2
TZ = PZ * PW3
else if (process_allocation == 'orbital_sequential'):
PX = PX1 * PX2 * PX3
PX1 = (TX * PPN) / PW
PX2 = TY / PY
PX3 = TZ / PZ
TX = (PW * PX1) / PPN
TY = PY * PX2
TZ = PZ * PX3
From these conditions, you can determine the suitable process distribution and the Tofu-D network shape (compute node shape).
process_allocation
input variable controls the order of the process distribution.
It indicates which communications should be executed in closer processes.
process_allocation = 'grid_sequential'
(PX, PY, PZ, PW)
,nproc_rgrid
major orderingimproves
nproc_rgrid
related communication performancecommunicator:
s_parallel_info::icomm_r, icomm_x, icomm_y, icomm_z, icomm_xy
suitable
theory
:'dft'
and'dft_md'
process_allocation = 'orbital_sequential'
(PW, PY, PZ, PX)
,nproc_ob
major orderingimproves
nproc_ob
related communication performancecommunicator:
s_parallel_info::icomm_o and icomm_ko
suitable
theory
:'tddft_response', 'tddft_pulse', 'single_scale_maxwell_tddft'
and'multi_scale_maxwell_tddft'
Troubleshooting of the Installation Process¶
Installation of CMake¶
The CMake is a cross-platform build tool. In order to build the SALMON from the source code, the CMake of version 3.14.0 or later is required. You may install it following one of the three instructions below.
Installation by package manager¶
If your system has a built-in package manager, you may conveniently install the CMake tools as below:
Debian/Ubuntu Linux
sudo apt-get install cmake
Fedora Linux/CentOS
sudo yum install cmake
openSUSE Linux
sudo zypper install cmake
Installation from source code¶
You can get the source code distribution from the download page. In
this time, we will use the cmake version 3.16.8 as an example. Download
the archive by wget
comamnd and unpack it as below:
wget https://cmake.org/files/v3.16/cmake-3.16.8.tar.gz
tar -zxvf cmake-3.16.8.tar.gz
And, move to the unpacked directory and build.
cd cmake-3.16.8
./configure --prefix=INSTALLATION_DIRECTORY
make
make install
(replace INSTALLATION_DIRECTORY
to your installation directory.)
Next, to utilize the cmake
command, it is required that the
executable are settled inside the directory specified in your $PATH
.
If you use the bash shell, edit ~/.bashrc
and append the line:
export PATH=INSTALLATION_DIRECTORY/bin:$PATH
and reload the configuration:
source ~/.bashrc
Appendix¶
Additional options in configure.py script¶
Manual specifications of compiler and environment variables¶
In executing configure.py
, you may manually specify compiler and environment variables instead of specifying the architecture, for example:
$ python ../configure.py FC=mpiifort CC=mpiicc FFLAGS="-xAVX" CFLAGS="-restrict -xAVX"
The list of options of configure.py
can be found by:
$ python ../configure.py --help
The major options are as follows:
Commandline switch |
Detail |
---|---|
-a ARCH, --arch=ARCH |
Target architecture |
--enable-mpi, --disable-mpi |
enable/disable MPI parallelization |
--enable-scalapack, --disable-scalapack |
enable/disable computations with ScaLAPACK library |
--enable-eigenexa, --disable-eigenexa |
enable/disable computations with RIKEN R-CCS EigenExa library |
--enable-libxc, --disable-libxc |
enable/disable computations with Libxc library |
--with-lapack |
specified LAPACK/ScaLAPACK installed directory |
--with-libxc |
specified Libxc installed directory |
--debug |
enable debug build |
--release |
enable release build |
FC, FFLAGS |
User-defined Fortran Compiler, and the compiler options |
CC, CFLAGS |
User-defined C Compiler, and the compiler options |
In the build procedure by CMake, they search the following libraries. If the libraries don't found in the path that is specified by environment variables, they will build the required libraries automatically.
Netlib LAPACK (includes BLAS), and ScaLAPACK
We will download and build the Netlib libraries as the typical implementation.
Libxc
EigenExa will download and build automatically even if the library is installed to your machine.
Build for single process calculations¶
When using the --arch
option, MPI parallelization is enabled as default.
If you use a single processor machine, explicitly specify --disable-mpi
in executing the python script:
$ python ../configure.py --arch=<ARCHITECTURE> --disable-mpi
Build by user-specified compiler¶
If you want that specify the compiler, set the FC
and CC
flags in executing the python script:
$ python ../configure.py FC=gfortran CC=gcc
When --arch
option is not used, MPI parallelization is disabled as default.
Build using GNU Makefile¶
If CMake build fails in your environment, we recommend you to try to use Gnu Make for the build process.
First, enter the directory gnumakefiles
:
$ cd SALMON/gnumakefiles
In the directory, Makefile
files are prepared for several architectures:
gnu-mpi
intel-mpi
gnu-without-mpi
intel-without-mpi
Makefile
files with *-without-mpi
indicate that they are for single processor environment.
Choose Makefile
appropriate for your environment, and execute the make command:
$ make -f Makefile.PLATFORM
If the make proceeds successful, a binary file is created in the directory SALMON/bin/
.