slurm is albedo's job scheduling system. It is used to submit jobs from the login nodes to the compute nodes.
Jobs
Submitting jobs
- To work interactively on a compute node use salloc.
You can use all options (more CPU, RAM, time, partition, qos, ...) described in the next section.
To enable working with graphical interfaces (X forwarding) add the option --x11 . - Job scripts are submitted via sbatch
You can ssh to a node where a job of yours is running, if (and only if) you have a valid ssh-key pair. (e.g. on a login node: ssh-keygen -t ed25519; ssh-copy-id albedo1)
Make sure your key is secured with a password!
Specifying job resources
Job resources are defined at the header of your job script (or as command line arguments for sbatch
or salloc
). A full list see https://slurm.schedmd.com/sbatch.html#SECTION_OPTIONS. Here is a list of the most common ones:
#SBATCH --account=<account> # Your account #SBATCH --partition=<partition> # Slurm Partition; Default: smp #SBATCH --time=<time> # time limit for job; Default: 0:30:00 #SBATCH --qos=<QOS> # Slurm QOS; Default: 30min #SBATCH --nodes=<#Nodes> # Number of nodes #SBATCH --ntasks=<#Tasks> # Number of tasks (MPI) tasks to be launched #SBATCH --mem=<memory> # If more than the default memory is needed; # Default: <#Cores> * <mem per node>/<cores per node> #SBATCH --ntasks-per-node=<ntasks> # Numer of tasks per node #SBATCH --mail-user=<email adress> # Your mail adress if you want to get notifications #SBATCH --mail-type=<email type> # Valid type values are NONE, BEGIN, END, FAIL, REQUEUE, ALL #SBATCH --job-name=<jobname> # Job name #SBATCH --output=<filename_pattern> # File where the standard output is written to(*) #SBATCH --error=<filename_pattern> # File where the error messages are written to(*)
*) For filename patterns see: https://slurm.schedmd.com/sbatch.html#SECTION_%3CB%3Efilename-pattern%3C/B%3E
Details about specific parameters
Account (-A)
Compute resources are attributed to (primary)sections and projects at AWI. Therefore it is mandatory to specify an account.
This is new on Albedo, compared to ollie
The slurm accounts you may use are listed after login or can be shown via
sacctmgr -s show user name=$USER format=user,account%-30
Note: The account noaccount
is just a dummy account that can not be used for computing.
You can change the default setting on your own:
sacctmgr modify user $USER set DefaultAccount=<account>
Partitions (-p)
Identical compute nodes are combined in partitions. More information about the hardware specification of each node can be found in the System Overview.
Partition | Nodes | Description |
---|---|---|
smp | prod-[001-240] |
|
mpp | prod-[001-240] |
|
fat | fat-00[1-4] |
|
gpu | gpu-00[1-2] |
|
Quality of service (--qos)
A higher priority means your job is scheduled before other jobs. In addition, during working hours 10 nodes are reserved exclusively for jobs using qos=30min (to facilitate development and testing). For longer runs, another QOS (and walltime) has to be specified. Note: long running jobs (longer than 12 hours, up to 48 hours) “cost” more in terms of fairshare (meaning you priority will decrease for further jobs).
QOS | max. walltime | UsageFactor | Priority QOS factor | Notes |
---|---|---|---|---|
30min | 00:30:00 | 1 | 50 | default |
12h | 12:00:00 | 1 | 0 | |
48h | 48:00:00 | 2 | 0 |
Job Scheduling
Priority
For the job scheduling, Slurm assigns each job a priority, which is calculated based on several factors (Multifactor Priority Plugin). Jobs with higher priority, run first. (In principle – the backfill scheduling plugin helps making best use of available resources by filling up resources that are reserved (and thus idle) for large higher priority jobs with small (lower priority) jobs.)
On albedo, the priority is mainly influenced by the
- the fairshare factor (which is based on the user’s recent use of resources) and
- the QOS' priority factor and
- the time your job waits in the queue
Job size (RAM, cores), partitions and/or associations have no influence.
Fairshare
On Albedo all users have the same share of resources, independent of the account used. … TODO…
Accounting
TODO...
Useful Slurm commands
- sinfo shows existing queues
- scontrol show job <JobID> shows information about specific job
- sstat <JobID> shows resources used by a specific job
- squeue shows information about queues and used nodes
- smap curses-graphic of queues and nodes
- sbatch <script> submits a batch job
- salloc <resources> requests access to compute nodes for interactive use
- scancel <JobID> cancels a batch job
- srun <ressources> <executable> starts a (parallel) code
- sshare and sprio give information on fair share value and job priority
Example Scripts
Job arrays
Job arrays in Slurm are an easy way to submit multiple similar jobs (e.g. executing the same script with multiple input data). See here for further details.
#!/bin/bash #SBATCH --account=<account> # Your account #SBATCH --partition=smp #SBATCH --time=0:10:00 #SBATCH --ntasks=1 # run 100 tasks, but only run 10 at a time #SBATCH --array=1-100%10 #SBATCH --output=result_%A_%a.out # gives result_<jobID>_<taskID>.out echo "SLURM_JOBID: $SLURM_JOBID" echo "SLURM_ARRAY_TASK_ID: $SLURM_ARRAY_TASK_ID" echo "SLURM_ARRAY_JOB_ID: $SLURM_ARRAY_JOB_ID" # Here we "translate" the $SLURM_ARRAY_TASK_ID (which takes values from 1-100) # into an input file, that we want to analyze. # Suppose 'input_files.txt' is a text file that has 100 lines, each containing # the respective input file. INPUT_LIST=input_files.txt # Read the (SLURM_ARRAY_TASK_ID)th input file INPUT_FILE=`sed -n "${SLURM_ARRAY_TASK_ID}p" < ${INPUT_LIST}` srun my_executable $INPUT_FILE
How you “translate” your task ID into the srun command line is up to you. You could, for example, also have different scripts that you select in some way and execute.
MPI
#!/bin/bash #SBATCH --account=<account> # Your account #SBATCH --time 0:10:00 #SBATCH -p mpp #SBATCH -N 2 #SBATCH --tasks-per-node 128 #SBATCH --cpus-per-task 1 #SBATCH --hint=nomultithread #SBATCH --job-name=mpi #SBATCH --output=out_%x.%j # disable hyperthreading #SBATCH --hint=nomultithread module purge module load xthi/1.0-intel-oneapi-mpi2021.6.0-oneapi2022.1.0 intel-oneapi-mpi # module load xthi/1.0-openmpi4.1.3-gcc8.5.0 openmpi/4.1.3 ## Uncomment the following line to enlarge the stacksize if needed, ## e.g., if your code crashes with a spurious segmentation fault. # ulimit -s unlimited # To be on the safe side, we emphasize that it is pure MPI, no OpenMP threads export OMP_NUM_THREADS=1 srun xthi | sort -g -k 4
#!/bin/bash #SBATCH --account=<account> # Your account #SBATCH --time 0:10:00 #SBATCH -p mpp #SBATCH -N 2 #SBATCH --tasks-per-node 31 #SBATCH --hint=nomultithread #SBATCH --job-name=mpi_partial_node #SBATCH --output=out_%x.%j # disable hyperthreading #SBATCH --hint=nomultithread module purge module load xthi/1.0-intel-oneapi-mpi2021.6.0-oneapi2022.1.0 intel-oneapi-mpi # module load xthi/1.0-openmpi4.1.3-gcc8.5.0 openmpi/4.1.3 ## Uncomment the following line to enlarge the stacksize if needed, ## e.g., if your code crashes with a spurious segmentation fault. # ulimit -s unlimited # To be on the safe side, we emphasize that it is pure MPI, no OpenMP threads export OMP_NUM_THREADS=1 # The --cpu-bind=rank_ldom distributes the tasks via the node's cores # respecting the node's NUMA domains srun --cpu-bind=rank_ldom xthi | sort -g -k 4
OpenMP
#!/bin/bash #SBATCH --account=<account> # Your account #SBATCH --time 0:10:00 #SBATCH -p smp #SBATCH --tasks-per-node 1 #SBATCH --cpus-per-task 64 #SBATCH --job-name=openMP #SBATCH --output=out_%x.%j # disable hyperthreading #SBATCH --hint=nomultithread module purge module load xthi/1.0-intel-oneapi-mpi2021.6.0-oneapi2022.1.0 intel-oneapi-mpi # module load xthi/1.0-openmpi4.1.3-gcc8.5.0 openmpi/4.1.3 ## Uncomment the following line to enlarge the stacksize if needed, ## e.g., if your code crashes with a spurious segmentation fault. # ulimit -s unlimited # This binds each thread to one core export OMP_PROC_BIND=TRUE # OpenMP and srun, both need to know the number of CPUs per task export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK export SRUN_CPUS_PER_TASK=$SLURM_CPUS_PER_TASK srun xthi | sort -g -k 4
Hybrid (MPI+OpenMP)
#!/bin/bash #SBATCH --account=<account> # Your account #SBATCH --time 0:10:00 #SBATCH -p mpp #SBATCH -N 2 #SBATCH --tasks-per-node 8 #SBATCH --cpus-per-task 16 #SBATCH --job-name=hybrid #SBATCH --output=out_%x.%j # disable hyperthreading #SBATCH --hint=nomultithread module purge module load xthi/1.0-intel-oneapi-mpi2021.6.0-oneapi2022.1.0 intel-oneapi-mpi # module load xthi/1.0-openmpi4.1.3-gcc8.5.0 openmpi/4.1.3 ## Uncomment the following line to enlarge the stacksize if needed, ## e.g., if your code crashes with a spurious segmentation fault. # ulimit -s unlimited # This binds each thread to one core export OMP_PROC_BIND=TRUE # OpenMP and srun, both need to know the number of CPUs per task export OMP_NUM_THREADS=$SLURM_CPUS_PER_TASK export SRUN_CPUS_PER_TASK=$SLURM_CPUS_PER_TASK srun xthi | sort -g -k 4