PyTorch
Machine learning framework for Python.
News
1.3.2024 PyTorch 2.2 added to Puhti, Mahti and LUMI. The LUMI module includes ROCm versions of FlashAttention-2 and bitsandbytes as these are difficult for users to add themselves. xFormers has been added to all three systems.
17.11.2023 PyTorch 2.1 added to Puhti, Mahti and LUMI. Horovod has been removed, we recommend using PyTorch DDP instead. PyTorch Geometric was added to the Puhti and Mahti version.
5.10.2022 Due to Puhti's update to Red Hat Enterprise Linux 8 (RHEL8), the number of fully supported PyTorch versions has been reduced. Previously deprecated conda-based versions have been removed. Please contact our servicedesk if you really need access to older versions.
5.5.2022 Due to Mahti's update to Red Hat Enterprise Linux 8 (RHEL8), the number of fully supported PyTorch versions has been reduced. Please contact our servicedesk if you really need access to other versions.
4.2.2022 All old PyTorch versions which were based on direct Conda installations have been deprecated, and we encourage users to move to newer versions. Read more on our separate Conda deprecation page.
Available
Currently supported PyTorch versions:
Version | Module | Puhti | Mahti | LUMI | Notes |
---|---|---|---|---|---|
2.2.2 | pytorch/2.2 |
- | - | X | default version |
2.2.1 | pytorch/2.2 |
X | X | - | default version |
2.1.2 | pytorch/2.1 |
- | - | X | |
2.1.0 | pytorch/2.1 |
X | X | - | |
2.0.1 | pytorch/2.0 |
- | - | X | |
2.0.0 | pytorch/2.0 |
X | X | - | |
1.13.1 | pytorch/1.13 |
- | - | X | limited multi-node support |
1.13.0 | pytorch/1.13 |
X | X | - | |
1.12.0 | pytorch/1.12 |
X | X | - | |
1.11.0 | pytorch/1.11 |
X | X | - | |
1.10.0 | pytorch/1.10 |
(x) | (x) | - | |
1.9.0 | pytorch/1.9 |
(x) | (x) | - | |
1.8.1 | pytorch/1.8 |
(x) | (x) | - | |
1.7.1 | pytorch/1.7 |
(x) | - | - |
Includes PyTorch and related libraries with GPU support via CUDA/ROCm.
Versions marked with "(x)" are based on old Red Hat Enterprise Linux 7
(RHEL7) images, and are no longer fully supported. In particular MPI
and Horovod are not expected to work anymore with these modules. If
you still wish to access these versions, you need to enable old RHEL7
modules by module use /appl/soft/ai/rhel7/modulefiles/
.
If you find that some package is missing, you can often install it yourself with
pip install --user
. See our Python
documentation for
more information on how to install packages yourself. If you think that some
important PyTorch-related package should be included in the module provided by
CSC, please contact our servicedesk.
It is also possible to use Python virtual
environments. To
create a virtual environment use the command python3 -m venv
--system-site-packages venv
.
All modules are based on containers using Apptainer (previously known
as Singularity). Wrapper scripts have been provided so that common
commands such as python
, python3
, pip
and pip3
should work as
normal. For other commands, you need to prefix them with
apptainer_wrapper exec
, for example apptainer_wrapper exec
huggingface-cli
. For more information, see CSC's general
instructions on how to run Apptainer
containers.
New users
If you are new to using machine learning on CSC's supercomputers, please read our new tutorial Getting started with machine learning at CSC, which covers how to run a simple PyTorch project on Puhti using the web user interface.
License
PyTorch is BSD-style licensed, as found in the LICENSE file.
Usage
To use the default version of PyTorch on Puhti or Mahti, initialize it with:
module load pytorch
To access PyTorch on LUMI:
module use /appl/local/csc/modulefiles/
module load pytorch
If you wish to have a specific version (see above for available versions), use:
module load pytorch/1.13
Please note that the module already includes CUDA and cuDNN libraries, so there is no need to load cuda and cudnn modules separately!
This command will also show all available versions:
module avail pytorch
To check the exact packages and versions included in the loaded module you can run:
list-packages
Warning
Note that login nodes are not intended for heavy computing, please use slurm batch jobs instead. See our instructions on how to use the batch job system.
Example batch script
Example batch script for reserving one GPU and a corresponding proportion of the available CPU cores in a single node:
#!/bin/bash
#SBATCH --account=<project>
#SBATCH --partition=gpu
#SBATCH --ntasks=1
#SBATCH --cpus-per-task=10
#SBATCH --mem=80G
#SBATCH --time=1:00:00
#SBATCH --gres=gpu:v100:1
module load pytorch/2.1
srun python3 myprog.py <options>
#!/bin/bash
#SBATCH --account=<project>
#SBATCH --partition=gpusmall
#SBATCH --ntasks=1
#SBATCH --cpus-per-task=32
#SBATCH --time=1:00:00
#SBATCH --gres=gpu:a100:1
module load pytorch/2.1
srun python3 myprog.py <options>
#!/bin/bash
#SBATCH --account=<project>
#SBATCH --partition=small-g
#SBATCH --ntasks=1
#SBATCH --cpus-per-task=7
#SBATCH --gpus-per-node=1
#SBATCH --mem=60G
#SBATCH --time=1:00:00
module use /appl/local/csc/modulefiles/
module load pytorch/2.1
srun python3 myprog.py <options>
Please read the section on Efficient GPU utilization in our Machine learning guide to learn how to use the GPU efficiently.
Big datasets, multi-GPU and multi-node jobs
If you are working with big datasets, or datasets that contain a lot of files, please read the data section of our Machine learning guide. In particular, please do not read a huge number of files from the shared file system, use fast local disk or package your data into larger files instead!
For multi-GPU and multi-node jobs we recommend using the PyTorch Distributed Data-Parallel framework. You can read more about this and find examples of how to use PyTorch DDP on CSC's supercomputers in the Multi-GPU and multi-node section of our Machine learning guide
PyTorch profiler
If your PyTorch program is slow, or you notice that it has a low GPU utilization you can use the PyTorch profiler to analyze the time and memory consumption of your program.
The PyTorch profiler can be taken into use by adding a few lines of code to your existing PyTorch program:
from torch.profiler import profile, ProfilerActivity
prof = profile(
schedule=torch.profiler.schedule(
skip_first=10,
wait=5,
warmup=1,
active=3,
repeat=1)
on_trace_ready=torch.profiler.tensorboard_trace_handler('./logs/profiler'),
activities=[ProfilerActivity.CPU, ProfilerActivity.CUDA],
record_shapes=True, # record shapes of operator inputs
profile_memory=True, # track tensor memory allocation/deallocation
with_stack=True # record source code information
)
In this example we opt to skip the first 10 batches and record only a
few batches for profiling. The profiling trace is saved into
TensorBoard format into the directory logs/profiler
. To see all the
options, check the PyTorch API documentation for
profiler.
Next you need to start and stop the profiler, and record the individual steps (typically the batches). This would typically be around your training loop:
prof.start()
for batch in train_loader:
# normal forward and backprop stuff here
prof.step()
prof.stop()
In our GitHub
repository we gave a
full example with profiling:
mnist_ddp_profiler.py
with a corresponding Slurm batch job
script.
After running the job you can view the output of the profiler using TensorBoard. Start a TensorBoard session in the web interface of the supercomputer you are using. If the PyTorch profiler isn't opened automatically you may be able to find it as PYTORCH_PROFILER in the tab bar. If the tab isn't visible by default, it can be found at the pull-down menu on the right-hand side of the interface.
A particularly useful view is the Trace view (select "Trace" from the "Views" pull-down menu). Below is an example screenshot of a run of the example linked to above.
The Trace view can be zoomed in and panned using the small toolbar to the upper right, or using the 'a' and 'd' keys to pan, and 'w' and 's' for zooming in and out.
In the screenshot we can see:
- Area 1, marked with red, shows the data loading (can be seen by zooming in and reading the function names shown. This is run entirely in the CPU as it's only colored in the top part of the screen under regular python CPU threads.
- Area 2, marked with blue, shows the forward and back propagation steps. Part of this is done on the GPU, as seen by the coloring in the bottom part, in the "GPU 0" area.
Clearly this job is not utilizing the GPU well as a majority of the time is used in CPU processing. In general one could try adding more CPU cores to handle the data loading more efficiently, and increase the batch size to increase the GPU processing load. In this particular case, however, the problem is that the network is so small that it cannot really utilize the GPU fully.
More hints on how to view and interpret the output of the profiler can be found in the PyTorch profiler with TensorBoard tutorial.