gpu-jupyter/README.md

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Gitea fork of
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# GPU-Jupyter
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#### Leverage Jupyter Notebooks with the power of your NVIDIA GPU and perform GPU calculations using Tensorflow and Pytorch in collaborative notebooks.
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![Jupyterlab Overview](https://raw.githubusercontent.com/iot-salzburg/gpu-jupyter/master/extra/jupyterlab-overview.png)
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First of all, thanks to [docker-stacks](https://github.com/jupyter/docker-stacks)
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for creating and maintaining a robost Python, R and Julia toolstack for Data Analytics/Science
applications. This project uses the NVIDIA CUDA image as the base image and installs their
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toolstack on top of it to enable GPU calculations in the Jupyter notebooks.
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The image of this repository is available on [Dockerhub](https://hub.docker.com/r/cschranz/gpu-jupyter).
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## Contents
1. [Quickstart](#quickstart)
2. [Build your own image](#build-your-own-image)
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3. [Tracing](#tracing)
4. [Configuration](#configuration)
5. [Deployment](#deployment-in-the-docker-swarm)
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6. [Issues and Contributing](#issues-and-contributing)
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## Quickstart
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1. A computer with an NVIDIA GPU is required.
2. Install [Docker](https://www.docker.com/community-edition#/download) version **1.10.0+**
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and [Docker Compose](https://docs.docker.com/compose/install/) version **1.6.0+**.
3. Get access to your GPU via CUDA drivers within Docker containers.
You can be sure that you can access your GPU within Docker,
if the command `docker run --gpus all nvidia/cuda:10.1-cudnn7-runtime-ubuntu18.04 nvidia-smi`
returns a result similar to this one:
```bash
Tue Jan 5 09:38:21 2021
+-----------------------------------------------------------------------------+
| NVIDIA-SMI 450.80.02 Driver Version: 450.80.02 CUDA Version: 10.1 |
|-------------------------------+----------------------+----------------------+
| GPU Name Persistence-M| Bus-Id Disp.A | Volatile Uncorr. ECC |
| Fan Temp Perf Pwr:Usage/Cap| Memory-Usage | GPU-Util Compute M. |
| | | MIG M. |
|===============================+======================+======================|
| 0 GeForce RTX 207... Off | 00000000:01:00.0 On | N/A |
| 0% 40C P8 7W / 215W | 360MiB / 7974MiB | 1% Default |
| | | N/A |
+-------------------------------+----------------------+----------------------+
+-----------------------------------------------------------------------------+
| Processes: |
| GPU GI CI PID Type Process name GPU Memory |
| ID ID Usage |
|=============================================================================|
+-----------------------------------------------------------------------------+
```
If you don't get an output similar than this one, follow the installation steps in this
[medium article](https://medium.com/@christoph.schranz/set-up-your-own-gpu-based-jupyterlab-e0d45fcacf43).
The CUDA toolkit is not required on the host system, as it will be
installed within the Docker containers using [NVIDIA-docker](https://github.com/NVIDIA/nvidia-docker).
It is also important to keep your installed CUDA version in mind, when you pull images.
**You can't run images based on `nvidia/cuda:11.1` if you have only CUDA version 10.1 installed.**
Check your host's CUDA-version with `nvcc --version` and update to at least
the same version you want to pull.
4. Pull and run the image. This can last some hours, as a whole data-science
environment will be downloaded:
```bash
cd your-working-directory
docker run --gpus all -d -it -p 8848:8888 -v $(pwd)/data:/home/jovyan/work -e GRANT_SUDO=yes -e JUPYTER_ENABLE_LAB=yes --user root cschranz/gpu-jupyter:v1.3_cuda-10.1_ubuntu-18.04_python-only
```
This starts an instance with of *GPU-Jupyter* the tag `v1.3_cuda-10.1_ubuntu-18.04_python-only` at [http://localhost:8848](http://localhost:8848) (port `8484`).
The default password is `gpu-jupyter` (previously `asdf`) which should be changed as described [below](#set-password).
Furthermore, data within the host's `data` directory is shared with the container.
Other versions of GPU-Jupyter are available and listed on Dockerhub under [Tags](https://hub.docker.com/r/cschranz/gpu-jupyter/tags?page=1&ordering=last_updated).
Within the Jupyterlab instance, you can check if you can access your GPU by opening a new terminal window and running
`nvidia-smi`. In terminal windows, you can also install new packages for your own projects.
Some example code can be found in the repository under `extra/Getting_Started`.
If you want to learn more about Jupyterlab, check out this [tutorial](https://www.youtube.com/watch?v=7wfPqAyYADY).
## Build your own Image
First, it is necessary to generate the `Dockerfile` in `.build`, that is based on
the NIVIDA base image and the [docker-stacks](https://github.com/jupyter/docker-stacks).
As soon as you have access to your GPU within Docker containers
(make sure the command `docker run --gpus all nvidia/cuda:10.1-cudnn7-runtime-ubuntu18.04 nvidia-smi`
shows your GPU statistics), you can generate the Dockerfile, build and run it.
The following commands will start *GPU-Jupyter* on [localhost:8848](http://localhost:8848)
with the default password `gpu-jupyter` (previously `asdf`).
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```bash
git clone https://github.com/iot-salzburg/gpu-jupyter.git
cd gpu-jupyter
# generate a Dockerfile with python and without Julia and R
./generate-Dockerfile.sh --python-only
docker build -t gpu-jupyter .build/ # will take a while
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docker run --gpus all -d -it -p 8848:8888 -v $(pwd)/data:/home/jovyan/work -e GRANT_SUDO=yes -e JUPYTER_ENABLE_LAB=yes -e NB_UID="$(id -u)" -e NB_GID="$(id -g)" --user root --restart always --name gpu-jupyter_1 gpu-jupyter
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```
This starts a container WITH GPU support, a shared local data volume `data`
and some other configurations like root permissions which are necessary to install packages within the container.
For more configurations, scroll down to [Configuration of the Dockerfile-Generation](#configuration-of-the-dockerfile-generation).
### Start via Docker Compose
The script `start-local.sh` is a wrapper for a quick configuration of the
underlying `docker-compose.yml`:
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```bash
./start-local.sh -p 8848 # the default port is 8888
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```
## Tracing
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With these commands we can see if everything worked well:
```bash
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docker ps
docker logs [service-name] # or
bash show-local.sh # a env-var safe wrapper for 'docker-compose logs -f'
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```
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In order to stop the local deployment, run:
```bash
docker ps
docker rm -f [service-name] # or
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./stop-local.sh
```
## Configuration
### Configuration of the Dockerfile-Generation
The script `generate-Dockerfile.sh` generates a Dockerfile within the `.build/`
directory.
This implies that this Dockerfile is overwritten by each generation.
The Dockerfile-generation script `generate-Dockerfile.sh`
has the following parameters (note that 2, 3 and 4 are exclusive):
* `-c|--commit`: specify a commit or `"latest"` for the `docker-stacks`,
the default commit is a working one.
* `-s|--slim`: Generate a slim Dockerfile.
As some installations are not needed by everyone, there is the possibility to skip some
installations to reduce the size of the image.
Here the `docker-stack` `scipy-notebook` is used instead of `datascience-notebook`
that comes with Julia and R.
Moreover, none of the packages within `src/Dockerfile.usefulpackages` is installed.
* `--python-only|--no-datascience-notebook`: As the name suggests, the `docker-stack` `datascience-notebook`
is not installed
on top of the `scipy-notebook`, but the packages within `src/Dockerfile.usefulpackages` are.
* `--no-useful-packages`: On top of the `docker-stack` `datascience-notebook` (Julia and R),
the essential `gpulibs` are installed, but not the packages within `src/Dockerfile.usefulpackages`.
### Custom Installations
Custom packages can be installed within a container, or by modifying the file
`src/Dockerfile.usefulpackages`.
**As `.build/Dockerfile` is overwritten each time a Dockerfile is generated,
it is suggested to append custom installations either
within `src/Dockerfile.usefulpackages` or in `generate-Dockerfile.sh`.**
If an essential package is missing in the default stack, please let us know!
### Set Password
Please set a new password using `src/jupyter_notebook_config.json`.
Therefore, hash your password in the form (password)(salt) using a sha1 hash generator, e.g., the sha1 generator of [sha1-online.com](http://www.sha1-online.com/).
The input with the default password `gpu-jupyter` (previously `asdf`) is concatenated by an arbitrary salt `3b4b6378355` to `gpu-jupyter3b4b6378355` and is hashed to `642693b20f0a33bcad27b94293d0ed7db3408322`.
**Never give away your own unhashed password!**
Then update the config file as shown below and restart the service.
```json
{
"NotebookApp": {
"password": "sha1:3b4b6378355:642693b20f0a33bcad27b94293d0ed7db3408322"
}
}
```
### Updates
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#### Update CUDA to another version
The host's CUDA-version must be equal or higher than that of the
container itself (in `Dockerfile.header`).
Check the host's version with `nvcc --version` and the version compatibilities
for CUDA-dependent packages as [Pytorch](https://pytorch.org/get-started/locally/)
respectively [Tensorflow](https://www.tensorflow.org/install/gpu) previously.
Then modify, if supported, the CUDA-version in `Dockerfile.header` to, e.g.:
the line:
FROM nvidia/cuda:11.1-base-ubuntu20.04
and in the `Dockerfile.pytorch` the line:
cudatoolkit=11.1
Then re-generate, re-build and run the updated image, as closer described above:
Note that a change in the first line of the Dockerfile will re-build the whole image.
```bash
./generate-Dockerfile.sh
docker build -t gpu-jupyter .build/ # will take a while
docker run --gpus all -d -it -p 8848:8888 -v $pwd/data:/home/jovyan/work -e GRANT_SUDO=yes -e JUPYTER_ENABLE_LAB=yes --user root --restart always --name gpu-jupyter_1 gpu-jupyter
```
#### Update Docker-Stack
The [docker-stacks](https://github.com/jupyter/docker-stacks) are used as a
submodule within `.build/docker-stacks`. Per default, the head of the commit is reset to a commit on which `gpu-jupyter` runs stable.
To update the generated Dockerfile to a specific commit, run:
```bash
./generate-Dockerfile.sh --commit c1c32938438151c7e2a22b5aa338caba2ec01da2
```
To update the generated Dockerfile to the latest commit, run:
```bash
./generate-Dockerfile.sh --commit latest
```
A new build can last some time and may consume a lot of data traffic. Note, that the latest version may result in
a version conflict!
More info to submodules can be found in
[this tutorial](https://www.vogella.com/tutorials/GitSubmodules/article.html).
## Deployment in the Docker Swarm
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A Jupyter instance often requires data from other services.
If that data-source is containerized in Docker and sharing a port for communication shouldn't be allowed, e.g., for security reasons,
then connecting the data-source with *GPU-Jupyter* within a Docker Swarm is a great option!
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### Set up Docker Swarm and Registry
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This step requires a running [Docker Swarm](https://www.youtube.com/watch?v=x843GyFRIIY) on a cluster or at least on this node.
In order to register custom images in a local Docker Swarm cluster,
a registry instance must be deployed in advance.
Note that the we are using the port 5001, as many services use the default port 5000.
```bash
sudo docker service create --name registry --publish published=5001,target=5000 registry:2
curl 127.0.0.1:5001/v2/
```
This should output `{}`. \
Afterwards, check if the registry service is available using `docker service ls`.
### Configure the shared Docker network
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Additionally, *GPU-Jupyter* is connected to the data-source via the same *docker-network*. Therefore, This network must be set to **attachable** in the source's `docker-compose.yml`:
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```yml
services:
data-source-service:
...
networks:
- default
- datastack
...
networks:
datastack:
driver: overlay
attachable: true
```
In this example,
* the docker stack was deployed in Docker swarm with the name **elk** (`docker stack deploy ... elk`),
* the docker network has the name **datastack** within the `docker-compose.yml` file,
* this network is configured to be attachable in the `docker-compose.yml` file
* and the docker network has the name **elk_datastack**, see the following output:
```bash
sudo docker network ls
# ...
# [UID] elk_datastack overlay swarm
# ...
```
The docker network name **elk_datastack** is used in the next step as a parameter.
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### Start GPU-Jupyter in Docker Swarm
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Finally, *GPU-Jupyter* can be deployed in the Docker Swarm with the shared network, using:
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```bash
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./generate-Dockerfile.sh
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./add-to-swarm.sh -p [port] -n [docker-network] -r [registry-port]
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# e.g. ./add-to-swarm.sh -p 8848 -n elk_datastack -r 5001
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```
where:
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* **-p:** port specifies the port on which the service will be available.
* **-n:** docker-network is the name of the attachable network from the previous step,
e.g., here it is **elk_datastack**.
* **-r:** registry port is the port that is published by the registry service, default is `5000`.
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Now, *gpu-jupyter* will be accessible here on [localhost:8848](http://localhost:8848)
with the default password `gpu-jupyter` (previously `asdf`) and shares the network with the other data-source, i.e.,
all ports of the data-source will be accessible within *GPU-Jupyter*,
even if they aren't routed it the source's `docker-compose` file.
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Check if everything works well using:
```bash
sudo docker service ps gpu_gpu-jupyter
docker service ps gpu_gpu-jupyter
```
In order to remove the service from the swarm, use:
```bash
./remove-from-swarm.sh
```
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## Issues and Contributing
This project has the intention to create a robust image for CUDA-based GPU-applications,
which is built on top of the [docker-stacks](https://github.com/jupyter/docker-stacks).
You are free to help to improve this project, by:
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* [filing a new issue](https://github.com/iot-salzburg/gpu-jupyter/issues/new)
* [open a pull request](https://help.github.com/articles/using-pull-requests/)