CP2K
Versatile ab initio and classical molecular dynamics. CP2K is suited for large parallel quantum chemistry calculations, in particular for AIMD.
Available
- Puhti: 9.1, 2022.2, 2023.1
- Mahti: 8.2, 9.1, 2022.2, 2023.1
- LUMI: 2023.1, 2023.1-gpu
License
CP2K is freely available under the GPL license.
Usage
LUMI
To access CSC modules on LUMI, remember to first load the CSC module tree into use with
module use /appl/local/csc/modulefiles
Check which versions can be loaded directly:
module avail cp2k
You can find all installed versions with:
module spider cp2k
With each new project make sure that your job can efficiently utilize all the cores you request in the batch script. The rule of thumb is that when you double the number of cores the calculation should be at least 1.5 times faster.
Example batch script for Puhti using MPI-only parallelization
#!/bin/bash
#SBATCH --time=00:10:00
#SBATCH --ntasks-per-node=40
#SBATCH --nodes=2
#SBATCH --mem-per-cpu=2GB
#SBATCH --partition=large
#SBATCH --account=<project>
module purge
module load intel-oneapi-compilers-classic/2021.6.0 intel-oneapi-mpi/2021.6.0
module load cp2k/9.1
srun cp2k.popt H2O-64.inp > H2O-64.out
Example batch script for Mahti using mixed MPI-OpenMP parallelization
#!/bin/bash
#SBATCH --time=00:05:00
#SBATCH --ntasks-per-node=32 # 2 - 128
#SBATCH --cpus-per-task=4 # 128 / ntasks-per-node
#SBATCH --nodes=2
#SBATCH --partition=test
#SBATCH --account=<project>
module purge
module load gcc/9.4.0 openmpi/4.1.2
module load cp2k/9.1
export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK
export OMP_PLACES=cores
srun cp2k.psmp H2O-64.inp > H2O-64.out
Performance notes
Mahti:
The following table shows the total execution time [s] for the H2O-64 benchmark in Mahti using cp2k/9.1. The column headers show how many omp-threads were used per mpi-task.
Nodes | d1 | d2 | d4 | d8 |
---|---|---|---|---|
1 | 25.77 | 18.88 | 20.58 | 22.95 |
2 | 17.66 | 15.25 | 13.34 | 17.10 |
- For 64 water molecules, the best performance is obtained with 2 full nodes, 32 mpi-tasks, and 4 OMP-threads per task (like the Mahti example). For this system the performance does not scale beyond 2 nodes.
- Mixed parallization is efficient: choose tasks and threads so that they add up to 128 (physical) cores available per node (or up to 40 on Puhti).
- Test the optimal run parameters for your model system and method.
- Selecting the ELPA diagonalization library instead of ScaLAPACK may significantly accelerate calculations that require large matrix diagonalizations (even up to 50% depending on the system). A good example are metallic systems that may converge poorly with the orbital transformation (OT) method and thus demand a standard diagonalization of the Kohn-Sham matrix.
High-throughput computing with CP2K
High-throughput computations can be run conveniently with CP2K using the built-in
FARMING
program. This is an excellent option for use cases where the aim is to
run a large amount of independent computations, such as when generating data for
AI/ML pipelines. All subjobs are run in parallel within a single Slurm allocation,
thus avoiding excess calls of srun
or sbatch
which decreases the load on the
batch queue system.
Running FARMING
jobs requires an additional input file in which the details of
the workflow, such as the input directories and number of parallel task groups,
are specified. Example farming.inp
and farming.sh
input and batch script files
are provided below. Note that RUN_TYPE
is set to NONE
in the &GLOBAL
section.
&GLOBAL
PROJECT my-farming-job
PROGRAM FARMING
RUN_TYPE NONE
&END GLOBAL
&FARMING
NGROUPS 8
&JOB
DIRECTORY run1
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run2
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run3
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run4
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run5
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run6
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run7
INPUT_FILE_NAME nacl.inp
&END JOB
&JOB
DIRECTORY run8
INPUT_FILE_NAME nacl.inp
&END JOB
&END FARMING
#!/bin/bash -l
#SBATCH --time=00:30:00
#SBATCH --partition=medium
#SBATCH --ntasks-per-node=128
#SBATCH --nodes=1
#SBATCH --account=<project>
module purge
module load gcc/9.4.0 openmpi/4.1.2 cp2k/9.1
srun cp2k.psmp farming.inp >> farming.out
In this particular example, one full Mahti node is requested for running 8 single-point
calculations of a NaCl crystal with different lattice constants. In addition to the
farming.inp
input, each subjob requires its own ordinary input file, which are here
organized into separate subdirectories named run*
. Issuing sbatch farming.sh
in
the parent directory launches all calculations in parallel, allocating 16 cores to
each subjob.
Note that dependencies can also be specified between subjobs using the
DEPENDENCIES
and JOB_ID
keywords under the &JOB
section. This enables the
definition of complex workflows. For further details, see the CP2K
manual and regtest files
for example inputs.
References
CP2K prints out a list of relevant publications towards the end of the log file. Choose and cite the ones relevant to the methods you've used.
More Information
- CP2K online manual: http://manual.cp2k.org/
- CP2K home page: http://www.cp2k.org/
- Regtest inputs can be used as
examples on how to use the different features in CP2K. Note that the convergence
criteria can be quite loose and should be separately tested for production simulations.