High Performance Computers ========================== Relevant Machines ----------------- This page includes instructions and guidelines when deploying Dask on high performance supercomputers commonly found in scientific and industry research labs. These systems commonly have the following attributes: 1. Some mechanism to launch MPI applications or use job schedulers like SLURM, SGE, TORQUE, LSF, DRMAA, PBS, or others 2. A shared network file system visible to all machines in the cluster 3. A high performance network interconnect, such as Infiniband 4. Little or no node-local storage Where to start -------------- Most of this page documents various ways and best practices to use Dask on an HPC cluster. This is technical and aimed both at users with some experience deploying Dask and also system administrators. The preferred and simplest way to run Dask on HPC systems today both for new, experienced users or administrator is to use `dask-jobqueue `_. However, dask-jobqueue is slightly oriented toward interactive analysis usage, and it might be better to use tools like dask-mpi in some routine batch production workloads. Dask-jobqueue and Dask-drmaa ---------------------------- `dask-jobqueue `_ provides cluster managers for PBS, SLURM, LSF, SGE and other resource managers. You can launch a Dask cluster on these systems like this. .. code-block:: python from dask_jobqueue import PBSCluster cluster = PBSCluster(cores=36, memory="100GB", project='P48500028', queue='premium', interface='ib0', walltime='02:00:00') cluster.scale(100) # Start 100 workers in 100 jobs that match the description above from dask.distributed import Client client = Client(cluster) # Connect to that cluster Dask-jobqueue provides a lot of possibilities like adaptive dynamic scaling of workers, we recommend reading the `dask-jobqueue documentation `_ first to get a basic system running and then returning to this documentation for fine-tuning if necessary. Using MPI --------- You can launch a Dask cluster using ``mpirun`` or ``mpiexec`` and the `dask-mpi `_ command line tool. .. code-block:: bash mpirun --np 4 dask-mpi --scheduler-file /home/$USER/scheduler.json .. code-block:: python from dask.distributed import Client client = Client(scheduler_file='/path/to/scheduler.json') This depends on the `mpi4py `_ library. It only uses MPI to start the Dask cluster and not for inter-node communication. MPI implementations differ: the use of ``mpirun --np 4`` is specific to the ``mpich`` or ``open-mpi`` MPI implementation installed through conda and linked to mpi4py. .. code-block:: bash conda install mpi4py It is not necessary to use exactly this implementation, but you may want to verify that your ``mpi4py`` Python library is linked against the proper ``mpirun/mpiexec`` executable and that the flags used (like ``--np 4``) are correct for your system. The system administrator of your cluster should be very familiar with these concerns and able to help. In some setups, MPI processes are not allowed to fork other processes. In this case, we recommend using ``--no-nanny`` option in order to prevent dask from using an additional nanny process to manage workers. Run ``dask-mpi --help`` to see more options for the ``dask-mpi`` command. Using a Shared Network File System and a Job Scheduler ------------------------------------------------------ .. note:: This section is not necessary if you use a tool like dask-jobqueue. Some clusters benefit from a shared File System (NFS, GPFS, Lustre or alike), and can use this to communicate the scheduler location to the workers:: dask-scheduler --scheduler-file /path/to/scheduler.json # writes address to file dask-worker --scheduler-file /path/to/scheduler.json # reads file for address dask-worker --scheduler-file /path/to/scheduler.json # reads file for address .. code-block:: python >>> client = Client(scheduler_file='/path/to/scheduler.json') This can be particularly useful when deploying ``dask-scheduler`` and ``dask-worker`` processes using a job scheduler like SGE/SLURM/Torque/etc. Here is an example using SGE's ``qsub`` command:: # Start a dask-scheduler somewhere and write the connection information to a file qsub -b y /path/to/dask-scheduler --scheduler-file /home/$USER/scheduler.json # Start 100 dask-worker processes in an array job pointing to the same file qsub -b y -t 1-100 /path/to/dask-worker --scheduler-file /home/$USER/scheduler.json Note, the ``--scheduler-file`` option is *only* valuable if your scheduler and workers share a network file system. High Performance Network ------------------------ Many HPC systems have both standard Ethernet networks as well as high-performance networks capable of increased bandwidth. You can instruct Dask to use the high-performance network interface by using the ``--interface`` keyword with the ``dask-worker``, ``dask-scheduler``, or ``dask-mpi`` commands or the ``interface=`` keyword with the dask-jobqueue ``Cluster`` objects: .. code-block:: bash mpirun --np 4 dask-mpi --scheduler-file /home/$USER/scheduler.json --interface ib0 In the code example above, we have assumed that your cluster has an Infiniband network interface called ``ib0``. You can check this by asking your system administrator or by inspecting the output of ``ifconfig`` .. code-block:: bash $ ifconfig lo Link encap:Local Loopback # Localhost inet addr:127.0.0.1 Mask:255.0.0.0 inet6 addr: ::1/128 Scope:Host eth0 Link encap:Ethernet HWaddr XX:XX:XX:XX:XX:XX # Ethernet inet addr:192.168.0.101 ... ib0 Link encap:Infiniband # Fast InfiniBand inet addr:172.42.0.101 https://stackoverflow.com/questions/43881157/how-do-i-use-an-infiniband-network-with-dask Local Storage ------------- Users often exceed memory limits available to a specific Dask deployment. In normal operation, Dask spills excess data to disk, often to the default temporary directory. However, in HPC systems this default temporary directory may point to an network file system (NFS) mount which can cause problems as Dask tries to read and write many small files. *Beware, reading and writing many tiny files from many distributed processes is a good way to shut down a national supercomputer*. If available, it's good practice to point Dask workers to local storage, or hard drives that are physically on each node. Your IT administrators will be able to point you to these locations. You can do this with the ``--local-directory`` or ``local_directory=`` keyword in the ``dask-worker`` command:: dask-mpi ... --local-directory /path/to/local/storage or any of the other Dask Setup utilities, or by specifying the following :doc:`configuration value <../../configuration>`: .. code-block:: yaml temporary-directory: /path/to/local/storage However, not all HPC systems have local storage. If this is the case then you may want to turn off Dask's ability to spill to disk altogether. See :doc:`this page ` for more information on Dask's memory policies. Consider changing the following values in your ``~/.config/dask/distributed.yaml`` file to disable spilling data to disk: .. code-block:: yaml distributed: worker: memory: target: false # don't spill to disk spill: false # don't spill to disk pause: 0.80 # pause execution at 80% memory use terminate: 0.95 # restart the worker at 95% use This stops Dask workers from spilling to disk, and instead relies entirely on mechanisms to stop them from processing when they reach memory limits. As a reminder, you can set the memory limit for a worker using the ``--memory-limit`` keyword:: dask-mpi ... --memory-limit 10GB Launch Many Small Jobs ---------------------- .. note:: This section is not necessary if you use a tool like dask-jobqueue. HPC job schedulers are optimized for large monolithic jobs with many nodes that all need to run as a group at the same time. Dask jobs can be quite a bit more flexible: workers can come and go without strongly affecting the job. If we split our job into many smaller jobs, we can often get through the job scheduling queue much more quickly than a typical job. This is particularly valuable when we want to get started right away and interact with a Jupyter notebook session rather than waiting for hours for a suitable allocation block to become free. So, to get a large cluster quickly, we recommend allocating a dask-scheduler process on one node with a modest wall time (the intended time of your session) and then allocating many small single-node dask-worker jobs with shorter wall times (perhaps 30 minutes) that can easily squeeze into extra space in the job scheduler. As you need more computation, you can add more of these single-node jobs or let them expire. Use Dask to co-launch a Jupyter server -------------------------------------- Dask can help you by launching other services alongside it. For example, you can run a Jupyter notebook server on the machine running the ``dask-scheduler`` process with the following commands .. code-block:: python from dask.distributed import Client client = Client(scheduler_file='scheduler.json') import socket host = client.run_on_scheduler(socket.gethostname) def start_jlab(dask_scheduler): import subprocess proc = subprocess.Popen(['/path/to/jupyter', 'lab', '--ip', host, '--no-browser']) dask_scheduler.jlab_proc = proc client.run_on_scheduler(start_jlab)