Difference between revisions of "SALMON Manual for Beginners"
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Revision as of 17:55, 11 June 2017
Contents
Prerequisites
In this guide, it is assumed that readers have a basic knowledge on Unix. In the following, most works will be done in the command-line interface of Unix. For the installation of SALMON, following packages are required.
- Fortran90/C compiler with MPI support. Our package assumes users have one of the following compilers:
- GCC (Gnu Compiler Collection)
- Intel Fortran/C Compiler
- Fujitsu Compiler (at FX100 / K-Computer)
- One of the following library packages for linear algebra:
- BLAS/LAPACK
- Intel Math Kernel Library (MKL)
- Fujitsu Scientific Subroutine Library 2 (SSL-II)
- One of the following build tools.
- CMake
- Gnu Make
If you use other compilers, you may need to change build scripts (CMake, Makefile). If no numerical library is installed in your computer system, you may need to install BLAS/LAPACK by yourself. See Tips for Installation.
Download
Newest version of the SALMON can be downloaded from Download. 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 |- ARTED Source codes related to periodic systems |- GCEED Source codes related to isolated systems |- src Source codes of core modules |- main Source codes of the main routines |- example Samples |- Makefile Files related to building
Build
To compile SALMON to create executable binary files, two options are prepared, CMake and Gnu Make. If CMake works in your environment, we recommend to use it. If CMake fails in your environment, consider to use Gnu Make.
Build using CMake
First examine whether CMake is usable in your environment or not. Type the following in Unix command-line:
$ cmake --version
If CMake is not installed in your system, error message such as cmake: command not found
will appear.
If CMake is installed in your system, version number will be shown.
To build SALMON, CMake of version 3.0.2 or later is required.
If CMake is not installed or CMake of older version is installed in your system, you need to install the new version by yourself.
The installation of the CMake is simple. A detailed description of the installation is given in Installation of CMake. Here we describe a simple method to use the binary distribution of CMake. First download the binary distribution file appropriate for your system from https://cmake.org/download/. The filename of the downloaded file will be cmake-<VERSION_PLATFORM>.tar.gz. In standard Unix environment, files for the platform of Linux x86_64 will be appropriate. Next extract the binary executable file of CMake, typing in the command-line as
$ tar xvfz cmake-<VERSION_PLATFORM>.tar.gz
Then you will have the cmake binary file in bin directory. For the CMake binary file to be usable, you need to modify the Unix environmental variable $PATH appropriately.
Description how to modify the $PATH should come here
To confirm that CMake of the new version is usable in your environment, type cmake --version
in the command-line.
Build using CMake specifying archtechture
Confirming that CMake of version 3.0.2 or later can be usable in your system, 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=ARCHTECTURE $ make
Here ARCHTECTURE specifies the architecture of the CPU in your computer system such as intel-avx. You need to choose ARCHTECUTRE from the following options:
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 |
fujitsu-fx100 | FX100 Su | Fujitsu Compiler | SSL-II |
fujitsu-k | Fujitsu FX100 / K-computer | Fujitsu Compiler | SSL-II |
If the build is successful, you will get a file salmon.cpu at the directory .salmon/bin. If you specify many-core archtechtures, intel-knl or intel-knc, you find a file salmon.mic or both files salmon.cpu and salmon.mic.
Build using Gnu Make
If CMake build fails in your environment, try Gnu Make for the build process. Gnu Make utilize a file, Makefile, which you can find at the directory SALMON/Makefile. First you need to modify Makefile appropriately according to your environment. Edit the Makefile using a text editor. At least you need to change the line that choose the architecture of the system, from line ?? to ??
# This is a makefile for SALMON program. # please select architecture by deleting “#” #ARCH = gnu ARCH = intel #ARCH = fujitsu #ARCH = intel-knl
Then use make command in the command-line to build the executable file.
$ make
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 of *.inp*, to be read through the standard input, stdin. It 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 either be written in the input file or prepared as a separate file.
pseudopotentials
SALMON utilizes norm-conserving pseudpotentials. You may find pseudopotentials of some elements in Samples. SALMON allows to use several formats of pseudpotentials that can be easily obtained from websites listed below.
pseudopotential | website |
Ab-init FHI | http://www.ab-init |
In the input file, you need to write the filename of the pseudopotential. Use exactly the same filename as that downloaded from the website or that in the Samples.
input file
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 achieved in two steps; first the ground state calculation is carried out and then electron dynamics calculations in real time are achieved. Choice of the calculation mode is specified by the variable calc_mode in the namelist &calculation. For isolated systems, the ground state and the electron dynamics calculations should be carried out in two steps. First the ground state calculation is achieved specifying calc_mode = 'GS' . Then the real-time electron dynamics calculation is achieved specifying calc_mode = 'RT' . For periodic systems, two calculations should be carried out in one step specifying calc_mode = 'GS_RT' .
There are about 20 groups of namelists listed below. A list of variables in each namelist is provided in the file ??? included in the source-file distribution.
name of namelist | description |
&calculation | specify calculation modes |
&control | parameters related to general conditions for the calculation |
&units | specify units of input and output files |
¶llel | parameters related to parallelization |
&system | information related to the system |
&pseudo | information related to pseudopotentials |
&functional | specify density functional to be used |
&rgrid | parameters related to real space grid |
&kgird | parameters related to k-points for periodic systems |
&tgrid | parameters related to time evolution |
&propagation | specify a choice of the propagation method |
&scf | parameters related to ground state calculation |
&emfield | parameters of electric fields applied to the system |
&linear_response | magnitude of the distortion for linear response |
&multiscale | parameters related to coupled multiscale calculations of electron dynamics and light propagations |
&analysis | parameters related to output files |
&hartree | parameters related to Hartree potential calculation of isolated systems |
&ewald | parameters related to Ewald sum that appears in the ground state calculation of periodic systems |
&atomic_coor | Atomic coordinates can be written here |
&group_fundamental | |
&group_file |
In Samples, we prepare six samples that cover typical calculations feasible by using SALMON. We prepare explanations for the input files that will help to prepare input files of your own interests.
Here we briefly explain the format of the namelist.
&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. Between two lines, 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. The description of the variables may appear at any position if they are between &namelist and /. Input files constitute of several blocks of namelists. The blocks can appear in any order.
Run SALMON
To run SALMON, the executable file of salmon.cpu (and salmon.mic if your system is the many-core machine) should be built from the source file of SALMON as described above. An input file inputfile.inp and pseudopotential files should also be prepared as mentioned above. If the command to execute calculations using MPI is mpirun in your system, the calculation will start by typing
$ mpirun salmon.cpu < inputfile.inp > fileout.out
The execution command and the job submission procedure depends much on the local environment. We just summarize the general conditions to execute SALMON:
- salmon runs in parallel environment using MPI.
- executable files are prepared as /salmon/bin/salmon.cpu and/or /salmon/bin/salmon.mic in the standard build procedure.
- to start calculations, inputfile.inp should be read through stdin.
Output files
See Samples.