GROMACS-Sapelo2: Difference between revisions
(18 intermediate revisions by 3 users not shown) | |||
Line 5: | Line 5: | ||
Sapelo2 | Sapelo2 | ||
===Version=== | ===Version=== | ||
2021.5, 2023.1, 2023.4 | |||
===Author / Distributor=== | ===Author / Distributor=== | ||
Line 12: | Line 12: | ||
Current head authors and project leaders: | Current head authors and project leaders: | ||
Erik Lindahl (Stockholm Center for Biomembrane Research, Stockholm, SE) | Erik Lindahl (Stockholm Center for Biomembrane Research, Stockholm, SE) David van der Spoel (Biomedical Centre, Uppsala, SE) | ||
David van der Spoel (Biomedical Centre, Uppsala, SE) | |||
Berk Hess (Max Planck Institute for Polymer Research, Mainz, DE) | Berk Hess (Max Planck Institute for Polymer Research, Mainz, DE) | ||
. | . | ||
Line 27: | Line 26: | ||
'''Version 2021.5''' | |||
This version was compiled with foss-2021b, CUDA 11.4.1, and PLUMED 2.8.0. It is installed in /apps/eb/GROMACS/2021.5-foss-2021b-CUDA-11.4.1-PLUMED-2.8.0. To use this version of Gromacs, please first load its module with | |||
This version was compiled with | |||
<pre class="gcommand"> | <pre class="gcommand"> | ||
module load GROMACS/ | module load GROMACS/2021.5-foss-2021b-CUDA-11.4.1-PLUMED-2.8.0 | ||
'''Version | </pre>'''Version 2023.1''' | ||
This version was compiled with | This version was compiled with foss-2022a and CUDA 11.7.0. It is installed in /apps/eb/GROMACS/2023.1-foss-2022a-CUDA-11.7.0. To use this version of Gromacs, please first load its module with | ||
<pre class="gcommand"> | <pre class="gcommand"> | ||
module load GROMACS/ | module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0 | ||
</pre> | </pre> | ||
'''Version | '''Version 2023.4''' | ||
This version was compiled with | This version was compiled with foss-2022a and CUDA 11.7.0. It is installed in /apps/eb/GROMACS/2023.4-foss-2022a-CUDA-11.7.0. To use this version of Gromacs, please first load its module with | ||
<pre class="gcommand"> | <pre class="gcommand"> | ||
module load GROMACS/ | module load GROMACS/2023.4-foss-2022a-CUDA-11.7.0 | ||
</pre> | </pre> | ||
This | For each GROMACS module, after version 4.5.6, all of the tools are essentially modules of a binary named "gmx." This is a departure from previous versions, wherein each of the tools was invoked as its own command. On Sapelo2, commands using later versions of GROMACS can be run by first sourcing the file $EBROOTGROMACS/bin/GMXRC. Then running the command gmx followed by the name of the command. For example to print the help output of the mdrun command one would run the following | ||
<pre class="gcommand"> | <pre class="gcommand"> | ||
source $EBROOTGROMACS/bin/GMXRC | |||
</pre> | gmx mdrun --help | ||
</pre> | |||
If using a P100 GPU node, it is advised to request all 32 CPUs there. | |||
Sample job submission script sub.sh to run v. 2023.1 and use 12 CPU cores on one GPU node and 1 A100 GPU card: | |||
<pre class="gscript"> | |||
#!/bin/bash | |||
#SBATCH --job-name=testgromacs # Job name | |||
#SBATCH --partition=gpu_p # Partition (queue) name | |||
#SBATCH --gres=gpu:A100:1 # Request 1 A100 gpu device | |||
#SBATCH --ntasks=1 # Run single task on one GPU node | |||
#SBATCH --cpus-per-task=12 # 12 CPU cores per task | |||
#SBATCH --mem=50gb # Job memory request | |||
#SBATCH --time=4:00:00 # Time limit hrs:min:sec or days-hrs:min:sec | |||
#SBATCH --output=%x.%j.out # Standard output log | |||
#SBATCH --error=%x.%j.err # Standard error log | |||
module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0 | |||
source $EBROOTGROMACS/bin/GMXRC | source $EBROOTGROMACS/bin/GMXRC | ||
export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK | |||
gmx mdrun -ntomp 12 [options] | |||
</pre> | |||
where [options] need to be replaced by the arguments you wish to use. The job name '''testgromacs''' should be replaced by a name that is appropriate for your job. Also, choose an appropriate number of cores per node(--cpus-per-task), a suitable wall time (the example above specifies 4 hours), and a suitable amount of memory. | |||
Sample job submission script | Sample job submission script using MPI and OpenMP to run v. 2023.1 and use 2 GPU nodes to run 4 MPI ranks, 2 MPI ranks per node, 12 CPU cores per task, and 2 A100 GPU cards per node: | ||
<pre class="gscript"> | <pre class="gscript"> | ||
# | #!/bin/bash | ||
# | #SBATCH --job-name=testgromacs # Job name | ||
# | #SBATCH --partition=gpu_p # Partition (queue) name | ||
# | #SBATCH --gres=gpu:A100:2 # Request 2 A100 gpu devices per node | ||
# | #SBATCH --nodes=2 # Request 2 GPU nodes | ||
# | #SBATCH --ntasks=4 # Run 4 MPI ranks | ||
#SBATCH --ntasks-per-node=2 # 2 MPI ranks per node | |||
#SBATCH --cpus-per-task=12 # 12 CPU cores per task | |||
#SBATCH --mem-per-cpu=4gb # Memory request for each CPU core | |||
#SBATCH --time=7-00:00:00 # Time limit hrs:min:sec or days-hrs:min:sec | |||
#SBATCH --output=%x.%j.out # Standard output log | |||
#SBATCH --error=%x.%j.err # Standard error log | |||
module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0 | |||
module load GROMACS/ | |||
source $EBROOTGROMACS/bin/GMXRC | source $EBROOTGROMACS/bin/GMXRC | ||
export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK | |||
srun -n 4 gmx_mpi mdrun -ntomp 12 [options] | |||
</pre> | </pre> | ||
where [options] need to be replaced by the arguments you wish to use. The job name ''' | |||
Also, choose an appropriate number of cores per node ( | where [options] need to be replaced by the arguments you wish to use. Make sure the number of GPUS requested is equal to the number of tasks requested(--ntasks). The job name '''testgromacs''' should be replaced by a name that is appropriate for your job. Also, choose an appropriate number of cores per node(--cpus-per-task), a suitable wall time (the example above specifies 4 hours), and a suitable amount of memory. | ||
=== Documentation === | === Documentation === |
Latest revision as of 12:13, 9 May 2024
Category
Chemistry
Program On
Sapelo2
Version
2021.5, 2023.1, 2023.4
Author / Distributor
First developed in Herman Berendsens group at Groningen University.
Current head authors and project leaders:
Erik Lindahl (Stockholm Center for Biomembrane Research, Stockholm, SE) David van der Spoel (Biomedical Centre, Uppsala, SE) Berk Hess (Max Planck Institute for Polymer Research, Mainz, DE) .
Description
GROMACS is a package to perform molecular dynamics, i.e. simulate the Newtonian equations of motion for systems with hundreds to millions of particles.
Running Program
Also refer to Running Jobs on Sapelo2.
For more information on Environment Modules on Sapelo2 please see the Lmod page.
Version 2021.5
This version was compiled with foss-2021b, CUDA 11.4.1, and PLUMED 2.8.0. It is installed in /apps/eb/GROMACS/2021.5-foss-2021b-CUDA-11.4.1-PLUMED-2.8.0. To use this version of Gromacs, please first load its module with
module load GROMACS/2021.5-foss-2021b-CUDA-11.4.1-PLUMED-2.8.0
Version 2023.1
This version was compiled with foss-2022a and CUDA 11.7.0. It is installed in /apps/eb/GROMACS/2023.1-foss-2022a-CUDA-11.7.0. To use this version of Gromacs, please first load its module with
module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0
Version 2023.4
This version was compiled with foss-2022a and CUDA 11.7.0. It is installed in /apps/eb/GROMACS/2023.4-foss-2022a-CUDA-11.7.0. To use this version of Gromacs, please first load its module with
module load GROMACS/2023.4-foss-2022a-CUDA-11.7.0
For each GROMACS module, after version 4.5.6, all of the tools are essentially modules of a binary named "gmx." This is a departure from previous versions, wherein each of the tools was invoked as its own command. On Sapelo2, commands using later versions of GROMACS can be run by first sourcing the file $EBROOTGROMACS/bin/GMXRC. Then running the command gmx followed by the name of the command. For example to print the help output of the mdrun command one would run the following
source $EBROOTGROMACS/bin/GMXRC gmx mdrun --help
If using a P100 GPU node, it is advised to request all 32 CPUs there.
Sample job submission script sub.sh to run v. 2023.1 and use 12 CPU cores on one GPU node and 1 A100 GPU card:
#!/bin/bash #SBATCH --job-name=testgromacs # Job name #SBATCH --partition=gpu_p # Partition (queue) name #SBATCH --gres=gpu:A100:1 # Request 1 A100 gpu device #SBATCH --ntasks=1 # Run single task on one GPU node #SBATCH --cpus-per-task=12 # 12 CPU cores per task #SBATCH --mem=50gb # Job memory request #SBATCH --time=4:00:00 # Time limit hrs:min:sec or days-hrs:min:sec #SBATCH --output=%x.%j.out # Standard output log #SBATCH --error=%x.%j.err # Standard error log module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0 source $EBROOTGROMACS/bin/GMXRC export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK gmx mdrun -ntomp 12 [options]
where [options] need to be replaced by the arguments you wish to use. The job name testgromacs should be replaced by a name that is appropriate for your job. Also, choose an appropriate number of cores per node(--cpus-per-task), a suitable wall time (the example above specifies 4 hours), and a suitable amount of memory.
Sample job submission script using MPI and OpenMP to run v. 2023.1 and use 2 GPU nodes to run 4 MPI ranks, 2 MPI ranks per node, 12 CPU cores per task, and 2 A100 GPU cards per node:
#!/bin/bash #SBATCH --job-name=testgromacs # Job name #SBATCH --partition=gpu_p # Partition (queue) name #SBATCH --gres=gpu:A100:2 # Request 2 A100 gpu devices per node #SBATCH --nodes=2 # Request 2 GPU nodes #SBATCH --ntasks=4 # Run 4 MPI ranks #SBATCH --ntasks-per-node=2 # 2 MPI ranks per node #SBATCH --cpus-per-task=12 # 12 CPU cores per task #SBATCH --mem-per-cpu=4gb # Memory request for each CPU core #SBATCH --time=7-00:00:00 # Time limit hrs:min:sec or days-hrs:min:sec #SBATCH --output=%x.%j.out # Standard output log #SBATCH --error=%x.%j.err # Standard error log module load GROMACS/2023.1-foss-2022a-CUDA-11.7.0 source $EBROOTGROMACS/bin/GMXRC export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK srun -n 4 gmx_mpi mdrun -ntomp 12 [options]
where [options] need to be replaced by the arguments you wish to use. Make sure the number of GPUS requested is equal to the number of tasks requested(--ntasks). The job name testgromacs should be replaced by a name that is appropriate for your job. Also, choose an appropriate number of cores per node(--cpus-per-task), a suitable wall time (the example above specifies 4 hours), and a suitable amount of memory.
Documentation
Please see http://www.gromacs.org/
Installation
System
64-bit Linux