HPC/Applications/vasp

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Requesting Access

Both VASP-4 and VASP-5 major versions are available on Carbon, and require a license. VASP-5 is a separate license, which includes access to VASP-4 and potpaw_PBE potentials.

You are welcome to use the Carbon binaries, but I (stern) need written or emailed confirmation of your license status. Please kindly ask the vaspmaster to confirm to me that you hold or are covered by a license. You may wish to use the following template.

To: [email protected]
CC: [email protected]
Subject: License confirmation
We are users of the Center for Nanoscale Materials at Argonne National Laboratory.
We would like to use the VASP installation at this site.

Please reply and confirm to Michael Sternberg <[email protected]> that we hold the license numbers

VASP-4   …
VASP-5   …

with the following people in my research group:

…
…


With best regards,
…

Module considerations

module load vasp                # sets $VASP_HOME
module load vasp5               # sets $VASP5_HOME
Each module points to an installation directory using an environment variable corresponding to the module name. Do not hardcode the directory anywhere, as that location is determined by the module and may change in subsequent versions. There should not be a reason to do so, since $PATH will be managed appropriately.
  • Each module provides several binaries (see next section).
  • You do not need to specify a path for vasp for the mpirun statement in the PBS job script.
  • The modules are mutually exclusive.
  • Potentials are available in /opt/soft/vasp-pot.

To access Graeme Henkelman's script suite, load the vasp-vtstscripts module. It works with both the vasp and vasp5 modules above. In either case, choose one of the VTST-patched binaries from the table below. The unpatched vasp binaries will not interoperate with the script suite.

module load vasp-vtstscripts

Binaries

Some options for VASP cannot be configured at runtime (by input data) but must be chosen when compiling. Since no single set of compile-time choices is appropriate for all uses, a number of binaries are provided, distinguished by their name.

The modules from versions vasp/4.6.35-mkl-13 and vasp5/5.2.12a-mkl-4 onwards, respectively, contain several binaries built using different sets of preprocessor flags in the Makefile. Earlier modules only contain two binaries, vasp and vasp-gamma. Additional binaries are provided for useful preprocessor flag combinations after applying patches from the group of Graeme Henkelman (UT Austin) to the source code:

To verify the binaries available for a module, run the appropriate command, once the module has been loaded:

ls $VASP_HOME/bin
ls $VASP5_HOME/bin

Choose a binary appropriate for your task and pass its name to mpirun in the job script. There is no need for full path names. Copy a sample job script from:

$VASP_HOME/vasp.job
$VASP5_HOME/vasp.job

Available binaries and their flags

This table lists the names of the binaries compiled from

  • combinations of preprocessor flags, and
  • variants of the source code, primarily enhancing capabilities of ionic updates.
Versions and capabilities Flags used Binary names
Official source Cell relaxation
along x and y
(z fixed)1
Cell relaxation
along z only
(x and y fixed)1
Patched for VTST2 Patched for Bader-projected DOS3
Conventional
(Versions 4.x–5.3)
(none) vasp vasp-cellz vasp-vtst vasp-baderdos
-DNGZhalf vasp-chargehalf vasp-cellz-chargehalf vasp-vtst-chargehalf vasp-baderdos-chargehalf
-DwNGZhalf vasp-gamma vasp-cellz-gamma vasp-vtst-gamma vasp-baderdos-gamma
-DwNGZhalf -DNGZhalf vasp-gamma-chargehalf vasp-cellz-gamma-chargehalf vasp-vtst-gamma-chargehalf vasp-baderdos-gamma-chargehalf
Advanced
MD techniques4
(Versions 5.2 and 5.3)
-Dtbdyn vasp-tbdyn not useful
-Dtbdyn -DNGZhalf vasp-tbdyn-chargehalf
-Dtbdyn -DwNGZhalf vasp-tbdyn-gamma
-Dtbdyn -DwNGZhalf -DNGZhalf vasp-tbdyn-gamma-chargehalf
Version 5.4 -Dtbdyn vasp_ncl vasp_cellxy_ncl vasp_cellz_ncl vasp_vtst_ncl TBD
-Dtbdyn -DNGZhalf vasp_std vasp_cellxy_std vasp_cellz_std vasp_vtst_std
-Dtbdyn -DwNGZhalf -DNGZhalf vasp_gam vasp_cellxy_gam vasp_cellz_gam vasp_vtst_gam
(none) vasp_gpu_ncl vasp_gpu_cellxy_ncl vasp_gpu_cellz_ncl ? vasp_gpu_vtst_ncl
-DNGZhalf vasp_gpu vasp_gpu_cellxy vasp_gpu_cellz ? vasp_gpu_vtst

1) Stress tensor selectively zeroed in subroutine CONSTR_CELL_RELAX
2) http://theory.cm.utexas.edu/vtsttools/ . The dimer method was broken for vasp5/5.3.3 prior to 5.3.3p3-mkl-2.
3) http://theory.cm.utexas.edu/vtsttools/dos/ (now defunct)
4) http://cms.mpi.univie.ac.at/vasp/vasp/Advanced_MD_techniques.html

Explanation of flags

From file vasp.5.2/makefile.linux_pg in the souce code.

#-----------------------------------------------------------------------
# possible options for CPP:
# NGXhalf             charge density   reduced in X direction
# wNGXhalf            gamma point only reduced in X direction
# avoidalloc          avoid ALLOCATE if possible
# IFC                 work around some IFC bugs
# CACHE_SIZE          1000 for PII,PIII, 5000 for Athlon, 8000 P4
# RPROMU_DGEMV        use DGEMV instead of DGEMM in RPRO (usually  faster)
# RACCMU_DGEMV        use DGEMV instead of DGEMM in RACC (faster on P4)
#  **** definitely use -DRACCMU_DGEMV if you use the mkl library
#-----------------------------------------------------------------------
…
#-----------------------------------------------------------------------
# additional options for CPP in parallel version (see also above):
# NGZhalf               charge density   reduced in Z direction
# wNGZhalf              gamma point only reduced in Z direction
# scaLAPACK             use scaLAPACK (usually slower on 100 Mbit Net)
#-----------------------------------------------------------------------

Common flags

-DIFC -DRPROMU_DGEMV  -DRACCMU_DGEMV -DCACHE_SIZE=16000  -DMPI -DMPI_BLOCK=8000

vdW-DF functional

The vdW-DF functional of Langreth and Lundqvist et al. is implemented in all the *-chargehalf binaries of the vasp5 module.

No specific preparations are needed other than setting the INCAR flags as documented. The binaries will find the required precalculated kernel file vdw_kernel.bindat by means of the environment variable $VASP5_HOME which is set by the module. This is a Carbon-specific extension.

Usage under ASE

VASP calculations can be set up, run, and analyzed using the calculator interface of the ASE package, available on Carbon under both the ase3 and atk modules. ASE is told how to use VASP by means of environment variables which the modules define for you with sensible defaults:

VASP_PP_PATH
VASP_COMMAND
  • The calculator will create and possibly overwrite VASP input files in the current directory, and then run VASP therein. To minimize clutter, consider setting up and changing into a run-specific directory before initializing the calculator.
  • VASP_COMMAND normally uses the vasp binary (see above), and will run in parallel when called under a PBS job. That decision is based on the PBS_NODEFILE environment variable being present.
  • You can supply another executable name or path in the variable VASP_BINARY.
  • The ASE calculator supports an alternative calling interface, a python script named in VASP_SCRIPT. This variable is not set by default on Carbon. If you wish to define a personal VASP_SCRIPT, unset VASP_COMMAND in tandem.
    • VASP_COMMAND takes precendence over VASP_SCRIPT.
    • The stdout stream is redirected to a file under VASP_COMMAND, but will appear on ASE's stdout under VASP_SCRIPT.
    • Inspect the calculator source code for details; see function run(self).

Usage under ATK/VNL

The ATK package (module atk) supports two different ways to interface with VASP.

  1. The ase calculator interface – see previous section.
  2. The VASPScripter AddOn.
    • The scripter "merely" helps you to set up the VASP input files in VNL, the ATK GUI. It does not start or analyze a VASP run.
    • The directory for pseudopotentials is preconfigured to be the same as $VASP_PP_PATH for the ASE calculator.

Node resources for VASP

Consider the follwing to specify PBS node resources (in job files and on the qsub command line).

Single-node jobs

  • When on gen1 nodes use ppn=4 and disallow sharing
#PBS -l nodes=1:ppn=4:gen1
#PBS -l naccesspolicy=SINGLEJOB -n
  • When on gen2, use ppn=7 or 8
#PBS -l nodes=1:ppn=8:gen2

Multi-node jobs

Run on gen2 only, by using the following options for qsub or #PBS:

#PBS -l nodes=__:ppn=__:gen2

See also