RAPIDS: Difference between revisions
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=Overview= <!--T:1--> | |||
<!--T:2--> | |||
[https://rapids.ai/ RAPIDS] is a suite of open source software libraries from NVIDIA mainly for executing data science and analytics pipelines in Python on GPUs. It relies on NVIDIA CUDA primitives for low-level compute optimization and provides friendly Python APIs, similar to those in Pandas or Scikit-learn. | |||
<!--T:3--> | |||
The main components are: | |||
* '''cuDF''', a Python GPU DataFrame library (built on the Apache Arrow columnar memory format) for loading, joining, aggregating, filtering, and otherwise manipulating data. | |||
<!--T:38--> | |||
* '''cuML''', a suite of libraries that implement machine learning algorithms and mathematical primitive functions that share compatible APIs with other RAPIDS projects. | |||
To build | <!--T:39--> | ||
* '''cuGraph''', a GPU accelerated graph analytics library, with functionality like NetworkX, which is seamlessly integrated into the RAPIDS data science platform. | |||
<!--T:40--> | |||
* '''Cyber Log Accelerators (CLX or ''clicks'')''', a collection of RAPIDS examples for security analysts, data scientists, and engineers to quickly get started applying RAPIDS and GPU acceleration to real-world cybersecurity use cases. | |||
<!--T:41--> | |||
* '''cuxFilter''', a connector library, which provides the connections between different visualization libraries and a GPU dataframe without much hassle. This also allows you to use charts from different libraries in a single dashboard, while also providing the interaction. | |||
<!--T:42--> | |||
* '''cuSpatial''', a GPU accelerated C++/Python library for accelerating GIS workflows including point-in-polygon, spatial join, coordinate systems, shape primitives, distances, and trajectory analysis. | |||
<!--T:43--> | |||
* '''cuSignal''', which leverages CuPy, Numba, and the RAPIDS ecosystem for GPU accelerated signal processing. In some cases, cuSignal is a direct port of Scipy Signal to leverage GPU compute resources via CuPy but also contains Numba CUDA kernels for additional speedups for selected functions. | |||
<!--T:44--> | |||
* '''cuCIM''', an extensible toolkit designed to provide GPU accelerated I/O, computer vision & image processing primitives for N-Dimensional images with a focus on biomedical imaging. | |||
<!--T:45--> | |||
* '''RAPIDS Memory Manager (RMM)''', a central place for all device memory allocations in cuDF (C++ and Python) and other RAPIDS libraries. In addition, it is a replacement allocator for CUDA Device Memory (and CUDA Managed Memory) and a pool allocator to make CUDA device memory allocation / deallocation faster and asynchronous. | |||
= Apptainer images= <!--T:4--> | |||
<!--T:5--> | |||
To build an Apptainer (formerly called [[Singularity#Please_use_Apptainer_instead|Singularity]]) image for RAPIDS, the first thing to do is to find and select a Docker image provided by NVIDIA. | |||
==Finding a Docker image== <!--T:6--> | |||
There are three types of RAPIDS Docker images: ''base'', ''runtime'', and ''devel''. For each type, multiple images are provided for different combinations of RAPIDS and CUDA versions, either on Ubuntu or on CentOS. You can find the Docker <tt>pull</tt> command for a selected image under the '''Tags''' tab on each site. | |||
<!--T:7--> | |||
* [https://ngc.nvidia.com/catalog/containers/nvidia:rapidsai:rapidsai NVIDIA GPU Cloud (NGC)] | |||
** '''base''' images contain a RAPIDS environment ready for use. Use this type of image if you want to submit a job to the Slurm scheduler. | |||
** '''runtime''' images extend the base image by adding a Jupyter notebook server and example notebooks. Use this type of image if you want to interactively work with RAPIDS through notebooks and examples. | |||
* [https://hub.docker.com/r/rapidsai/rapidsai-dev Docker Hub] | |||
** '''devel''' images contain the full RAPIDS source tree, the compiler toolchain, the debugging tools, the headers and the static libraries for RAPIDS development. Use this type of image if you want to implement customized operations with low-level access to cuda-based processes. | |||
<!--T:46--> | |||
'''NOTE:''' Starting with the RAPIDS v23.08 release, '''base''' type images are available [https://catalog.ngc.nvidia.com/orgs/nvidia/teams/rapidsai/containers/base here], '''runtime''' type images are replaced by `notebooks` images and available [https://catalog.ngc.nvidia.com/orgs/nvidia/teams/rapidsai/containers/notebooks here], and '''devel''' type images are no longer supported. | |||
== | ==Building an Apptainer image== <!--T:8--> | ||
For example, if a | <!--T:9--> | ||
For example, if a Docker <tt>pull</tt> command for a selected image is given as | |||
<source lang="console"> docker pull nvcr.io/nvidia/rapidsai/rapidsai:cuda11.0-runtime-centos7</source> | <!--T:10--> | ||
<source lang="console">docker pull nvcr.io/nvidia/rapidsai/rapidsai:cuda11.0-runtime-centos7</source> | |||
on a computer that supports Apptainer, you can build an Apptainer image (here ''rapids.sif'') with the following command based on the <tt>pull</tt> tag: | |||
<source lang="console">[name@server ~]$ apptainer build rapids.sif docker://nvcr.io/nvidia/rapidsai/rapidsai:cuda11.0-runtime-centos7</source> | |||
It usually takes | <!--T:11--> | ||
It usually takes from thirty to sixty minutes to complete the image-building process. Since the image size is relatively large, you need to have enough memory and disk space on the server to build such an image. | |||
= | =Working on clusters with an Apptainer image= <!--T:12--> | ||
Once you have | Once you have an Apptainer image for RAPIDS ready in your account, you can request an interactive session on a GPU node or submit a batch job to Slurm if you have your RAPIDS code ready. | ||
==Working interactively on a GPU node== <!--T:13--> | |||
<!--T: | <!--T:14--> | ||
If an Apptainer image was built based on a runtime or a devel type of Docker image, it includes a Jupyter Notebook server and can be used to explore RAPIDS interactively on a compute node with a GPU.<br> | |||
To request an interactive session on a compute node with a single GPU, e.g. a T4 type of GPU on Graham, run | |||
<source lang="console">[name@ | <source lang="console">[name@gra-login ~]$ salloc --ntasks=1 --cpus-per-task=2 --mem=10G --gres=gpu:t4:1 --time=1:0:0 --account=def-someuser</source> | ||
<!--T: | <!--T:15--> | ||
Once the requested resource is granted, start the RAPIDS shell on the GPU node with | |||
<!--T:16--> | |||
<!--T: | <source lang="console">[name@gra#### ~]$ module load apptainer | ||
<source lang="console"> | [name@gra#### ~]$ apptainer shell --nv -B /home -B /project -B /scratch rapids.sif | ||
</source> | </source> | ||
* the <tt>--nv</tt> option binds the GPU driver on the host to the container, so the GPU device can be accessed from inside the Apptainer container; | |||
* the <tt>-B</tt> option binds any filesystem that you would like to access from inside the container. | |||
<!--T:17--> | |||
After the shell prompt changes to <tt>Apptainer></tt>, you can check the GPU stats in the container to make sure the GPU device is accessible with | |||
<source lang="console">Apptainer> nvidia-smi</source> | |||
<!--T:18--> | |||
<!--T: | Then to initiate Conda and activate the RAPIDS environment, run | ||
<source lang="console"> | <source lang="console">Apptainer> source /opt/conda/etc/profile.d/conda.sh | ||
Apptainer> conda activate rapids | |||
</source> | </source> | ||
<!--T: | |||
<source lang="console">(rapids) | <!--T:19--> | ||
After the shell prompt changes to <tt>(rapids) Apptainer></tt>, you can launch the Jupyter Notebook server in the RAPIDS environment with the following command, and the URL of the Notebook server will be displayed after it starts successfully. | |||
<source lang="console">(rapids) Apptainer> jupyter-lab --ip $(hostname -f) --no-browser | |||
</source> | </source> | ||
<!--T:47--> | |||
<!--T: | '''NOTE:''' Starting with the RAPIDS v23.08 release, after initiating Conda, there is no need to activate rapids as all packages are included in the base conda environment, e.g. you can launch the Jupyter Notebook server in the base environment with the following commands. | ||
<!--T:48--> | |||
<!--T: | <source lang="console">Apptainer> source /opt/conda/etc/profile.d/conda.sh | ||
<source lang="console"> | Apptainer> jupyter-lab --ip $(hostname -f) --no-browser | ||
</source> | </source> | ||
<!--T:20--> | |||
As there is no direct Internet connection on a compute node on Graham, you would need to set up an SSH tunnel with port forwarding between your local computer and the GPU node. See [[Advanced_Jupyter_configuration#Connecting_to_JupyterLab|detailed instructions for connecting to Jupyter Notebook]]. | |||
== | ==Submitting a RAPIDS job to the Slurm scheduler== <!--T:21--> | ||
<!--T:22--> | |||
Once you have your RAPIDS code ready and want to submit a job execution request to the Slurm scheduler, you need to prepare two script files, i.e. a job submission script and a job execution script. | |||
<!--T:23--> | |||
'''Submission script''' | |||
{{File | {{File | ||
|name=submit.sh | |name=submit.sh | ||
Line 91: | Line 129: | ||
|contents= | |contents= | ||
#!/bin/bash | #!/bin/bash | ||
#SBATCH --gres=gpu:t4:1 | #SBATCH --gres=gpu:t4:1 | ||
#SBATCH --cpus-per-task=2 | #SBATCH --cpus-per-task=2 | ||
Line 97: | Line 134: | ||
#SBATCH --time=dd:hh:mm | #SBATCH --time=dd:hh:mm | ||
#SBATCH --account=def-someuser | #SBATCH --account=def-someuser | ||
module load apptainer | |||
module load | apptainer exec --nv -B /home -B /scratch rapids.sif /path/to/run_script.sh | ||
}} | }} | ||
<!--T:24--> | |||
'''Execution script''' | |||
{{File | {{File | ||
|name=run_script.sh | |name=run_script.sh | ||
Line 111: | Line 146: | ||
#!/bin/bash | #!/bin/bash | ||
source /opt/conda/etc/profile.d/conda.sh | source /opt/conda/etc/profile.d/conda.sh | ||
conda activate rapids | conda activate rapids # only needed if working with RAPIDS v.23.06 or under | ||
nvidia-smi | nvidia-smi | ||
python /path/to/my_rapids_code.py | python /path/to/my_rapids_code.py | ||
}} | }} | ||
=Helpful | =Helpful links= <!--T:25--> | ||
< | <!--T:26--> | ||
* [https://docs.rapids.ai/ RAPIDS Docs]: a collection of all the documentation for RAPIDS, how to stay connected and report issues; | |||
* [https://github.com/rapidsai/notebooks RAPIDS Notebooks]: a collection of example notebooks on GitHub for getting started quickly; | |||
* [https://medium.com/rapids-ai RAPIDS on Medium]: a collection of use cases and blogs for RAPIDS applications. | |||
</translate> |
Latest revision as of 20:12, 1 November 2023
Overview
RAPIDS is a suite of open source software libraries from NVIDIA mainly for executing data science and analytics pipelines in Python on GPUs. It relies on NVIDIA CUDA primitives for low-level compute optimization and provides friendly Python APIs, similar to those in Pandas or Scikit-learn.
The main components are:
- cuDF, a Python GPU DataFrame library (built on the Apache Arrow columnar memory format) for loading, joining, aggregating, filtering, and otherwise manipulating data.
- cuML, a suite of libraries that implement machine learning algorithms and mathematical primitive functions that share compatible APIs with other RAPIDS projects.
- cuGraph, a GPU accelerated graph analytics library, with functionality like NetworkX, which is seamlessly integrated into the RAPIDS data science platform.
- Cyber Log Accelerators (CLX or clicks), a collection of RAPIDS examples for security analysts, data scientists, and engineers to quickly get started applying RAPIDS and GPU acceleration to real-world cybersecurity use cases.
- cuxFilter, a connector library, which provides the connections between different visualization libraries and a GPU dataframe without much hassle. This also allows you to use charts from different libraries in a single dashboard, while also providing the interaction.
- cuSpatial, a GPU accelerated C++/Python library for accelerating GIS workflows including point-in-polygon, spatial join, coordinate systems, shape primitives, distances, and trajectory analysis.
- cuSignal, which leverages CuPy, Numba, and the RAPIDS ecosystem for GPU accelerated signal processing. In some cases, cuSignal is a direct port of Scipy Signal to leverage GPU compute resources via CuPy but also contains Numba CUDA kernels for additional speedups for selected functions.
- cuCIM, an extensible toolkit designed to provide GPU accelerated I/O, computer vision & image processing primitives for N-Dimensional images with a focus on biomedical imaging.
- RAPIDS Memory Manager (RMM), a central place for all device memory allocations in cuDF (C++ and Python) and other RAPIDS libraries. In addition, it is a replacement allocator for CUDA Device Memory (and CUDA Managed Memory) and a pool allocator to make CUDA device memory allocation / deallocation faster and asynchronous.
Apptainer images
To build an Apptainer (formerly called Singularity) image for RAPIDS, the first thing to do is to find and select a Docker image provided by NVIDIA.
Finding a Docker image
There are three types of RAPIDS Docker images: base, runtime, and devel. For each type, multiple images are provided for different combinations of RAPIDS and CUDA versions, either on Ubuntu or on CentOS. You can find the Docker pull command for a selected image under the Tags tab on each site.
- NVIDIA GPU Cloud (NGC)
- base images contain a RAPIDS environment ready for use. Use this type of image if you want to submit a job to the Slurm scheduler.
- runtime images extend the base image by adding a Jupyter notebook server and example notebooks. Use this type of image if you want to interactively work with RAPIDS through notebooks and examples.
- Docker Hub
- devel images contain the full RAPIDS source tree, the compiler toolchain, the debugging tools, the headers and the static libraries for RAPIDS development. Use this type of image if you want to implement customized operations with low-level access to cuda-based processes.
NOTE: Starting with the RAPIDS v23.08 release, base type images are available here, runtime type images are replaced by `notebooks` images and available here, and devel type images are no longer supported.
Building an Apptainer image
For example, if a Docker pull command for a selected image is given as
docker pull nvcr.io/nvidia/rapidsai/rapidsai:cuda11.0-runtime-centos7
on a computer that supports Apptainer, you can build an Apptainer image (here rapids.sif) with the following command based on the pull tag:
[name@server ~]$ apptainer build rapids.sif docker://nvcr.io/nvidia/rapidsai/rapidsai:cuda11.0-runtime-centos7
It usually takes from thirty to sixty minutes to complete the image-building process. Since the image size is relatively large, you need to have enough memory and disk space on the server to build such an image.
Working on clusters with an Apptainer image
Once you have an Apptainer image for RAPIDS ready in your account, you can request an interactive session on a GPU node or submit a batch job to Slurm if you have your RAPIDS code ready.
Working interactively on a GPU node
If an Apptainer image was built based on a runtime or a devel type of Docker image, it includes a Jupyter Notebook server and can be used to explore RAPIDS interactively on a compute node with a GPU.
To request an interactive session on a compute node with a single GPU, e.g. a T4 type of GPU on Graham, run
[name@gra-login ~]$ salloc --ntasks=1 --cpus-per-task=2 --mem=10G --gres=gpu:t4:1 --time=1:0:0 --account=def-someuser
Once the requested resource is granted, start the RAPIDS shell on the GPU node with
[name@gra#### ~]$ module load apptainer
[name@gra#### ~]$ apptainer shell --nv -B /home -B /project -B /scratch rapids.sif
- the --nv option binds the GPU driver on the host to the container, so the GPU device can be accessed from inside the Apptainer container;
- the -B option binds any filesystem that you would like to access from inside the container.
After the shell prompt changes to Apptainer>, you can check the GPU stats in the container to make sure the GPU device is accessible with
Apptainer> nvidia-smi
Then to initiate Conda and activate the RAPIDS environment, run
Apptainer> source /opt/conda/etc/profile.d/conda.sh
Apptainer> conda activate rapids
After the shell prompt changes to (rapids) Apptainer>, you can launch the Jupyter Notebook server in the RAPIDS environment with the following command, and the URL of the Notebook server will be displayed after it starts successfully.
(rapids) Apptainer> jupyter-lab --ip $(hostname -f) --no-browser
NOTE: Starting with the RAPIDS v23.08 release, after initiating Conda, there is no need to activate rapids as all packages are included in the base conda environment, e.g. you can launch the Jupyter Notebook server in the base environment with the following commands.
Apptainer> source /opt/conda/etc/profile.d/conda.sh
Apptainer> jupyter-lab --ip $(hostname -f) --no-browser
As there is no direct Internet connection on a compute node on Graham, you would need to set up an SSH tunnel with port forwarding between your local computer and the GPU node. See detailed instructions for connecting to Jupyter Notebook.
Submitting a RAPIDS job to the Slurm scheduler
Once you have your RAPIDS code ready and want to submit a job execution request to the Slurm scheduler, you need to prepare two script files, i.e. a job submission script and a job execution script.
Submission script
#!/bin/bash
#SBATCH --gres=gpu:t4:1
#SBATCH --cpus-per-task=2
#SBATCH --mem=10G
#SBATCH --time=dd:hh:mm
#SBATCH --account=def-someuser
module load apptainer
apptainer exec --nv -B /home -B /scratch rapids.sif /path/to/run_script.sh
Execution script
#!/bin/bash
source /opt/conda/etc/profile.d/conda.sh
conda activate rapids # only needed if working with RAPIDS v.23.06 or under
nvidia-smi
python /path/to/my_rapids_code.py
Helpful links
- RAPIDS Docs: a collection of all the documentation for RAPIDS, how to stay connected and report issues;
- RAPIDS Notebooks: a collection of example notebooks on GitHub for getting started quickly;
- RAPIDS on Medium: a collection of use cases and blogs for RAPIDS applications.