CalcUA - UAntwerp Tier-2 High Performance Computing Infrastructure (VSC)
NB: You will need an account to use the CalcUA VSC HPC to run the pipeline.
- Quick start
- Step-by-step instructions
- Location of output and work directory
- Availability of Nextflow
- Overview of partitions and resources
- Schedule Nextflow pipeline tasks using Slurm
- Local Nextflow run on a single (interactive) node
- Apptainer / Singularity and Nextflow environment variables for cache and tmp directories
- Troubleshooting
Quick start
To get started with running nf-core pipelines on CalcUA, you can use one of the example templates below. For more detailed info, see the extended explanations further below.
Slurm-scheduled pipeline run
Example job_script.slurm
to run the pipeline using the Slurm job scheduler to queue the individual tasks making up the pipeline. Note that the head Nextflow process used to launch the pipeline does not need to request many resources, 1 CPU and 4 GB should be adequate. The wall clock should be set so that it is long enough for all pipeline tasks to complete.
Single node pipeline run
Example job_script.slurm
to run the pipeline on a single node in local execution mode, only making use of the resources allocated by sbatch
, instead of submitting each Nextflow task as a new Slurm job. Note that in this case we need to request as many resources as are necessary for the pipeline.
Step-by-step instructions
-
Set the
APPTAINER_CACHEDIR
,APPTAINER_TMPDIR
andNXF_APPTAINER_CACHEDIR
environment variables by adding the following lines to your.bashrc
file (or simply add them to your Slurm job script):When using the
~/.bashrc
method, you can ensure that the environment variables are available in your jobs by starting your scripts with the line#! /bin/bash -l
, although this does not always seem to be required (initial testing: required to propagate PATH, but not for other env vars?). See below for more info. -
Load Nextflow in your job script via the command:
module load Nextflow/23.04.2
. Alternatively, when using your own version of Nextflow, usemodule load Java
. -
Choose whether you want to use the Slurm job scheduler to queue individual pipeline tasks (default mode) or if you prefer local execution on a single node.
- For Slurm scheduling, you only need to specify the
vsc_calcua
profile. E.g.,nextflow run pipeline -profile vsc_calcua
. Nextflow tasks will be scheduled as Slurm jobs to your current partition (or the one defined viasbatch --partion=<partition-name>
). - For local execution mode on a single node, you need to append an additional sub-profile. E.g.,
nextflow run pipeline -profile vsc_calcua,single_node
.
Note that the
-profile
option can take multiple values, the first one always beingvsc_calcua
and the secondsingle_node
one being optional. - For Slurm scheduling, you only need to specify the
-
Specify the partition that you want to run the pipeline on using the
sbatch
command’s--partition=<name>
option and how many resources should be allocated. See the overview of partitions and their resources below, or refer to the CalcUA documentation for more info.- For the default Slurm scheduling, the partition on which the head process runs has no effect on the resources allocated to the actual pipeline tasks; these will instead be requested by Nextflow depending on the particular process’ requirements and limited by the maximum thresholds set for each partition in this config.
- For local execution mode on a single node, it is probably convenient to simply request a full node (e.g.,
--cpus-per-task=28
and--mem=112G
for broadwell), but if fewer resources are requested, these limits will be passed on the Nextflow too. - Omitting
--mem-per-cpu
or--mem
will allocate the default memory value, which is the total available memory divided by the number of cores, e.g.,28 * 4 GB = 112 GB
for broadwell (128 GB - 16 GB buffer
).
NB: The head process only requires minimal resources (e.g., 1 CPU and 4 GB RAM).
- Submit the job script containing your full
nextflow run
command viasbatch
or from an an interactivesrun
session launched viascreen
ortmux
(to avoid the process from stopping when you disconnect your SSH session).
For more background info on how Slurm and Nextflow interact, you can read more in the Nextflow training docs and in this Nextflow blog post.
Location of output and work directory
NB: The Nextflow
work
directory is located in$VSC_SCRATCH/work
by default, but this can be changed by using the-work-dir
in yournextflow run
command.
By default, Nextflow stores all of the intermediate files required to run the pipeline in the work
directory. The default work directory is set to $VSC_SCRATCH/work
in this config.
It is generally recommended to delete this directory after the pipeline has finished successfully, because it can grow quite large, and all of the main output files will be saved in the results/
directory anyway. That’s why this config contains a cleanup
command that removes the work
directory automatically once the pipeline has completed successfully.
If the run does not complete successfully, then the work
directory is not deleted and pipelines can be re-submitted using the -resume
flag to re-use any cached files. If runs are abandoned, the directory should be cleaned manually to save storage space.
You can also use the nextflow clean
command to clean up all files related to a specific run (including not just the work
directory, but also log files and the .nextflow
cache directory).
Debug mode
NB: The work directory is cleaned automatically after a successful pipeline run to avoid going over the storage quotas, but the
debug
profile can be provided to retain them in case you need to inspect any intermediate files (e.g.,-profile vsc_calcua,debug
).
Debug mode can be enabled to always retain the work
directory instead of cleaning it. To use it, pass debug
as an additional value to the -profile
option (the order is important, later entries overwrite earlier ones!):
nextflow run <pipeline> -profile vsc_calcua,debug
Note that this is a core config provided by nf-core pipelines, not something built into the VSC CalcUA config directly.
Availability of Nextflow
Nextflow has been made available on CalcUA as a module. You can find out which versions are available by using module av nextflow
.
If you need to use a specific or more recent version of Nextflow that is not available, you can of course manually install it to your home directory and add the executable to your PATH
:
Before it can be used, you will still need to load the Java module in your job scripts: module load Java
. Also make sure that you pass your PATH to your job scripts by starting them with #!/bin/bash -l
or use the full path to the Nextflow binary instead of just calling nextflow
.
Overview of partitions and resources
The CalcUA config is built to work with the following partitions:
Partition | Cluster | Profiles | Type | Max memory | Max CPU | Max wall time | Example usage |
---|---|---|---|---|---|---|---|
zen2 | Vaughan | vsc_calcua | Slurm scheduler | 240 GB (per task) | 64 (per task) | 3 days | nextflow run -profile vsc_calcua |
zen2 | Vaughan | vsc_calcua,single_node | Single node local execution | 240 GB (or as requested) | 64 (or as requested) | 3 days | nextflow run -profile vsc_calcua,single_node |
zen3 | Vaughan | vsc_calcua | Slurm scheduler | 240 GB (per task) | 64 (per task) | 3 days | nextflow run -profile vsc_calcua |
zen3 | Vaughan | vsc_calcua,single_node | Single node local execution | 240 GB (or as requested) | 64 (or as requested) | 3 days | nextflow run -profile vsc_calcua,single_node |
zen3_512 | Vaughan | vsc_calcua | Slurm scheduler | 496 GB (per task) | 64 (per task) | 3 days | nextflow run -profile vsc_calcua |
zen3_512 | Vaughan | vsc_calcua,single_node | Single node local execution | 496 GB (or as requested) | 64 (or as requested) | 3 days | nextflow run -profile vsc_calcua,single_node |
broadwell | Leibniz | vsc_calcua | Slurm scheduler | 112 GB (per task) | 28 (per task) | 3 days | nextflow run -profile vsc_calcua |
broadwell | Leibniz | vsc_calcua,single_node | Single node local execution | 112 GB (or as requested) | 28 (or as requested) | 3 days | nextflow run -profile vsc_calcua,single_node |
broadwell_256 | Leibniz | vsc_calcua | Slurm scheduler | 240 GB (per task) | 28 (per task) | 3 days | nextflow run -profile vsc_calcua |
broadwell_256 | Leibniz | vsc_calcua,single_node | Single node local execution | 240 GB (or as requested) | 28 (or as requested) | 3 days | nextflow run -profile vsc_calcua,single_node |
skylake | Breniac (formerly Hopper) | vsc_calcua | Slurm scheduler | 176 GB (per task) | 28 (per task) | 7 days | nextflow run -profile vsc_calcua |
skylake | Breniac (formerly Hopper) | vsc_calcua,single_node | Single node local execution | 176 GB (or as requested) | 28 (or as requested) | 7 days | nextflow run -profile vsc_calcua,single_node |
For more information on the difference between the Slurm scheduling and Single node local execution mode, see below. Briefly,
- The default
vsc_calcua
profile submits each pipeline task to the Slurm job scheduler using the current partition (where the job was launched or the value supplied tosbatch --partition=<name>
). - The optional
single_node
profile runs pipeline tasks on the same single local node, using only the resource that were requested bysbatch
(orsrun
in interactive mode).
The max memory for the Slurm partitions is set to the available amount of memory for each partition minus 16 GB (which is the amount reserved for the OS and file system buffers, see slide 63 of this CalcUA introduction course). For the local profiles the resources are set dynamically based on those requested by sbatch
.
More information on the hardware differences between the partitions can be found on the CalcUA website and in the VSC documentation. You can also use the sinfo -o "%12P %.10A %.11l %D %c %m"
command to see the available partitions yourself.
NB: Do not launch nextflow jobs directly from a login node. Not only will this occupy considerable resources on the login nodes (the nextflow master process/head job can still use considerable amounts of RAM, see https://nextflow.io/blog/2024/optimizing-nextflow-for-hpc-and-cloud-at-scale.html), but the command might get cancelled (since there is a wall time for the login nodes too).
Schedule Nextflow pipeline tasks using Slurm
The default behaviour of the vsc_calcua
profile allows Nextflow to use the Slurm job scheduler to queue each pipeline task as a separate job. The main job that you manually submit using sbatch
will run the head Nextflow process (nextflow run ...
), which acts as a governor and monitoring job, and spawn new Slurm jobs for the different tasks in the pipeline. Each task will request the appropriate amount of resources defined by the pipeline (up to a threshold set per partition in this config) and will be run as an individual Slurm job. This means that each task will be placed in the scheduling queue individually and all the standard priority rules will apply to each of them.
The nextflow run ...
command that launches the head process, can be invoked either via sbatch
or from an an interactive srun
session launched via screen
or tmux
(to avoid the process from stopping when you disconnect your SSH session), but it does NOT need to request the total amount of resources that would be required by the full pipeline!
NB: When using the default
vsc_calcua
profile, the initial job that launches the master nextflow process does not need many resources to run. Therefore, use the #SBATCH options to limit its requested to a small sensible amount (e.g., 1-2 CPUs and 4 GB RAM), regardless of how computationally intensive the actual pipeline is.
NB: The wall time of the Nextflow head process will ultimately determine how long the pipeline can run for.
Local Nextflow run on a single (interactive) node
By adding the single_node
profile, Nextflow will run in local execution mode, which means that it will not make use of the Slurm job scheduler. Instead, the head Nextflow process (nextflow run ...
) will run on the allocated compute node and spawn all sub-processes for the individual tasks in the pipeline on that same node (i.e., similar to running a pipeline on your own machine). The available resources are determined by the #SBATCH
options passed to Slurm as usual and are shared among all tasks. The thresholds for the amount of resources that can be requested are automatically set to those that were requested during job submission (and will otherwise default to those of the partition).
The nextflow run ...
command that launches the head process, can be invoked either via sbatch
or from an an interactive srun
session launched via screen
or tmux
(to avoid the process from stopping when you disconnect your SSH session) and it DOES need to request the total amount of resources that are required by the full pipeline!
NB:
-profile vsc_calcua,single_node
does not automatically set the pipeline’s CPU/RAM resource limits to those of a full node, but instead dynamically set them based on those allocated by Slurm, i.e. those requested via thesbatch
. However, in many cases, it likely is a good idea to simply request a full node.
Apptainer / Singularity and Nextflow environment variables for cache and tmp directories
NB: The default directory where Nextflow will cache container images is set to
$VSC_SCRATCH/apptainer/nextflow_cache
for this config.
NB: The recommended directories for apptainer/singularity’s cache and tmp directories are
$VSC_SCRATCH/apptainer/cache
(cache directory for images layers) and$VSC_SCRATCH/apptainer/tmp
(temporary directory used during build or docker conversion) respectively, to avoid filling up your home storage and/or job node’s SSDs (since the default locations when unset are$HOME/.apptainer/cache
and/tmp
respectively). These environment variables cannot be set automatically by the config, so warnings will be displayed when launching runs without them being set.
Apptainer is an open-source fork of Singularity, which is an alternative container runtime to Docker. It is more suitable to usage on HPCs because it can be run without root privileges and does not use a dedicated daemon process. More info on the usage of Apptainer/Singularity on the VSC HPC can be found here.
When executing Nextflow pipelines using Apptainer/Singularity, the container image files will by default be cached inside the pipeline work directory. The CalcUA config profile instead sets the singularity.cacheDir setting to a central location on your scratch space ($VSC_SCRATCH/apptainer/nextflow_cache
), in order to reuse them between different pipelines even when cleaning the work directory. If the NXF_APPTAINER_CACHEDIR
/NXF_SINGULARITY_CACHEDIR
environment variables are set manually, they will take precedence over this default setting.
Apptainer/Singularity makes use of two additional environment variables, APPTAINER_CACHEDIR
/SINGULARITY_CACHEDIR
and APPTAINER_TMPDIR
/SINGULARITY_TMPDIR
. As recommended by the VSC documentation on containers, these should be set to a location on the scratch system, to avoid exceeding the quota on your home directory file system.
NB: The cachedir and tmpdir are only used when new images are built or converted from existing docker images. For most nf-core pipelines this does not happen, since they will instead try to directly pull pre-built singularity images from Galaxy Depot
-
The cache directory
APPTAINER_CACHEDIR
/SINGULARITY_CACHEDIR
is used to store files and layers used during image creation (or conversion of Docker/OCI images). Its default location is$HOME/.apptainer/cache
, but we recommended changing it to$VSC_SCRATCH/apptainer/cache
(or another location in scratch) on the CalcUA HPC instead, to avoid exceeding the quota in the home file system. -
The temporary directory
APPTAINER_TMPDIR
/SINGULARITY_TMPDIR
is used to store temporary files when building an image (or converting a Docker/OCI source). The directory must have enough free space to hold the entire uncompressed image during all steps of the build process. Its default location is/tmp
(or more accurately,$TMPDIR
in the environment of the nextflow head process), but we recommended changing it to$VSC_SCRATCH/apptainer/tmp
(or another location in scratch) on the CalcUA HPC instead. The reason being that the default/tmp
would refer to a directory on the the compute node running the nextflow head process, which are small SSDs on CalcUA that could get filled up otherwise.NB: The tmp directory needs to be created manually beforehand, otherwise pipelines that need to pull in and convert docker images, or the manual building of images yourself, will fail.
Currently, Apptainer respects environment variables with either an APPTAINER
or SINGULARITY
prefix, but because support for the latter might be dropped in the future, the former variant is recommended.
These two variables can be set in several different ways:
- Specified in your
~/.bashrc
file (e.g.,echo "export APPTAINER_CACHEDIR=${VSC_SCRATCH}/apptainer/cache APPTAINER_TMPDIR=${VSC_SCRATCH}/apptainer/tmp" >> ~/.bashrc
) - recommended. - Passed to
sbatch
as a parameter or on a#SBATCH
line in the job script (e.g.,--export=APPTAINER_CACHEDIR=${VSC_SCRATCH}/apptainer/cache,APPTAINER_TMPDIR=${VSC_SCRATCH}/apptainer/tmp
). - Directly in your job script (e.g.,
export APPTAINER_CACHEDIR=${VSC_SCRATCH}/apptainer/cache APPTAINER_TMPDIR=${VSC_SCRATCH}/apptainer/tmp
).
However, note that for the .bashrc
option to work, the environment need to be passed on to the slurm jobs. Currently, this seems to happen by default (i.e., variables defined in ~/.bashrc
are propagated, as per the VSC docs), but there also exist methods to enforce this more strictly. E.g., job scripts that start with #!/bin/bash -l
, will ensure that jobs launch using your login environment. Similarly, the sbatch
options --get-user-env
or --export=
can be used. Also see the CalcUA-specific and the general VSC documentation for more info.
Lastly, note that this config file currently uses the Singularity engine rather than the Apptainer one (see singularity
directive: enabled = true
). The reason is that, for the time being, using the apptainer engine in nf-core pipelines will result in docker images being pulled and converted to apptainer ones, rather than making use of pre-built singularity images (see nf-core documentation). Conversely, when making use of the singularity engine, pre-built images are downloaded and Apptainer will still be used in the background for running these, since the installation of apptainer
will by default create an alias for singularity
(and this is also the case on CalcUA).
Troubleshooting
For general errors regarding the pulling of images, try clearing out the existing caches located in $VSC_SCRATCH/apptainer
.
Failed to pull singularity image
Errors similar to the one above can be avoided by first downloading all required container images manually before running the pipeline. It seems like they could be caused by parallel downloads overwhelming the image repository (see issue).
To download a pipeline’s required images, use nf-core download <pipeline> --container-system singularity
. See the nf-core docs for more info.