title | keywords | description |
---|---|---|
Get Started, Part 2: Containers |
containers, python, code, coding, build, push, run |
Learn how to write, build, and run a simple app -- the Docker way. |
{% include_relative nav.html selected="2" %}
-
Read the orientation in Part 1.
-
Give your environment a quick test run to make sure you're all set up:
docker run hello-world
It's time to begin building an app the Docker way. We start at the bottom of the hierarchy of such app, a container, which this page covers. Above this level is a service, which defines how containers behave in production, covered in Part 3. Finally, at the top level is the stack, defining the interactions of all the services, covered in Part 5.
- Stack
- Services
- Container (you are here)
In the past, if you were to start writing a Python app, your first order of business was to install a Python runtime onto your machine. But, that creates a situation where the environment on your machine needs to be perfect for your app to run as expected, and also needs to match your production environment.
With Docker, you can just grab a portable Python runtime as an image, no installation necessary. Then, your build can include the base Python image right alongside your app code, ensuring that your app, its dependencies, and the runtime, all travel together.
These portable images are defined by something called a Dockerfile
.
Dockerfile
defines what goes on in the environment inside your
container. Access to resources like networking interfaces and disk drives is
virtualized inside this environment, which is isolated from the rest of your
system, so you need to map ports to the outside world, and
be specific about what files you want to "copy in" to that environment. However,
after doing that, you can expect that the build of your app defined in this
Dockerfile
behaves exactly the same wherever it runs.
Create an empty directory on your local machine. Change directories (cd
) into the new directory,
create a file called Dockerfile
, copy-and-paste the following content into
that file, and save it. Take note of the comments that explain each statement in
your new Dockerfile.
# Use an official Python runtime as a parent image
FROM python:2.7-slim
# Set the working directory to /app
WORKDIR /app
# Copy the current directory contents into the container at /app
COPY . /app
# Install any needed packages specified in requirements.txt
RUN pip install --trusted-host pypi.python.org -r requirements.txt
# Make port 80 available to the world outside this container
EXPOSE 80
# Define environment variable
ENV NAME World
# Run app.py when the container launches
CMD ["python", "app.py"]
This Dockerfile
refers to a couple of files we haven't created yet, namely
app.py
and requirements.txt
. Let's create those next.
Create two more files, requirements.txt
and app.py
, and put them in the same
folder with the Dockerfile
. This completes our app, which as you can see is
quite simple. When the above Dockerfile
is built into an image, app.py
and
requirements.txt
is present because of that Dockerfile
's COPY
command,
and the output from app.py
is accessible over HTTP thanks to the EXPOSE
command.
Flask
Redis
from flask import Flask
from redis import Redis, RedisError
import os
import socket
# Connect to Redis
redis = Redis(host="redis", db=0, socket_connect_timeout=2, socket_timeout=2)
app = Flask(__name__)
@app.route("/")
def hello():
try:
visits = redis.incr("counter")
except RedisError:
visits = "<i>cannot connect to Redis, counter disabled</i>"
html = "<h3>Hello {name}!</h3>" \
"<b>Hostname:</b> {hostname}<br/>" \
"<b>Visits:</b> {visits}"
return html.format(name=os.getenv("NAME", "world"), hostname=socket.gethostname(), visits=visits)
if __name__ == "__main__":
app.run(host='0.0.0.0', port=80)
Now we see that pip install -r requirements.txt
installs the Flask and Redis
libraries for Python, and the app prints the environment variable NAME
, as
well as the output of a call to socket.gethostname()
. Finally, because Redis
isn't running (as we've only installed the Python library, and not Redis
itself), we should expect that the attempt to use it here fails and produces
the error message.
Note: Accessing the name of the host when inside a container retrieves the container ID, which is like the process ID for a running executable.
That's it! You don't need Python or anything in requirements.txt
on your
system, nor does building or running this image install them on your system. It
doesn't seem like you've really set up an environment with Python and Flask, but
you have.
We are ready to build the app. Make sure you are still at the top level of your
new directory. Here's what ls
should show:
$ ls
Dockerfile app.py requirements.txt
Now run the build command. This creates a Docker image, which we're going to
name using the --tag
option. Use -t
if you want to use the shorter option.
docker build --tag=friendlyhello .
Where is your built image? It's in your machine's local Docker image registry:
$ docker image ls
REPOSITORY TAG IMAGE ID
friendlyhello latest 326387cea398
Note how the tag defaulted to latest
. The full syntax for the tag option would
be something like --tag=friendlyhello:v0.0.1
.
Troubleshooting for Linux users
Proxy server settings
Proxy servers can block connections to your web app once it's up and running. If you are behind a proxy server, add the following lines to your Dockerfile, using the
ENV
command to specify the host and port for your proxy servers:# Set proxy server, replace host:port with values for your servers ENV http_proxy host:port ENV https_proxy host:port
DNS settings
DNS misconfigurations can generate problems with
pip
. You need to set your own DNS server address to makepip
work properly. You might want to change the DNS settings of the Docker daemon. You can edit (or create) the configuration file at/etc/docker/daemon.json
with thedns
key, as following:{ "dns": ["your_dns_address", "8.8.8.8"] }In the example above, the first element of the list is the address of your DNS server. The second item is Google's DNS which can be used when the first one is not available.
Before proceeding, save
daemon.json
and restart the docker service.
sudo service docker restart
Once fixed, retry to run the
build
command.
Run the app, mapping your machine's port 4000 to the container's published port
80 using -p
:
docker run -p 4000:80 friendlyhello
You should see a message that Python is serving your app at http://0.0.0.0:80
.
But that message is coming from inside the container, which doesn't know you
mapped port 80 of that container to 4000, making the correct URL
http://localhost:4000
.
Go to that URL in a web browser to see the display content served up on a web page.
Note: If you are using Docker Toolbox on Windows 7, use the Docker Machine IP instead of
localhost
. For example, http://192.168.99.100:4000/. To find the IP address, use the commanddocker-machine ip
.
You can also use the curl
command in a shell to view the same content.
$ curl http://localhost:4000
<h3>Hello World!</h3><b>Hostname:</b> 8fc990912a14<br/><b>Visits:</b> <i>cannot connect to Redis, counter disabled</i>
This port remapping of 4000:80
demonstrates the difference
between EXPOSE
within the Dockerfile
and what the publish
value is set to when running
docker run -p
. In later steps, map port 4000 on the host to port 80
in the container and use http://localhost
.
Hit CTRL+C
in your terminal to quit.
On Windows, explicitly stop the container
On Windows systems,
CTRL+C
does not stop the container. So, first typeCTRL+C
to get the prompt back (or open another shell), then typedocker container ls
to list the running containers, followed bydocker container stop <Container NAME or ID>
to stop the container. Otherwise, you get an error response from the daemon when you try to re-run the container in the next step.
Now let's run the app in the background, in detached mode:
docker run -d -p 4000:80 friendlyhello
You get the long container ID for your app and then are kicked back to your
terminal. Your container is running in the background. You can also see the
abbreviated container ID with docker container ls
(and both work interchangeably when
running commands):
$ docker container ls
CONTAINER ID IMAGE COMMAND CREATED
1fa4ab2cf395 friendlyhello "python app.py" 28 seconds ago
Notice that CONTAINER ID
matches what's on http://localhost:4000
.
Now use docker container stop
to end the process, using the CONTAINER ID
, like so:
docker container stop 1fa4ab2cf395
To demonstrate the portability of what we just created, let's upload our built image and run it somewhere else. After all, you need to know how to push to registries when you want to deploy containers to production.
A registry is a collection of repositories, and a repository is a collection of
images—sort of like a GitHub repository, except the code is already built.
An account on a registry can create many repositories. The docker
CLI uses
Docker's public registry by default.
Note: We use Docker's public registry here just because it's free and pre-configured, but there are many public ones to choose from, and you can even set up your own private registry using Docker Trusted Registry.
If you don't have a Docker account, sign up for one at hub.docker.com{: target="blank" class="" }. Make note of your username.
Log in to the Docker public registry on your local machine.
$ docker login
The notation for associating a local image with a repository on a registry is
username/repository:tag
. The tag is optional, but recommended, since it is
the mechanism that registries use to give Docker images a version. Give the
repository and tag meaningful names for the context, such as
get-started:part2
. This puts the image in the get-started
repository and
tag it as part2
.
Now, put it all together to tag the image. Run docker tag image
with your
username, repository, and tag names so that the image uploads to your
desired destination. The syntax of the command is:
docker tag image username/repository:tag
For example:
docker tag friendlyhello gordon/get-started:part2
Run docker image ls to see your newly tagged image.
$ docker image ls
REPOSITORY TAG IMAGE ID CREATED SIZE
friendlyhello latest d9e555c53008 3 minutes ago 195MB
gordon/get-started part2 d9e555c53008 3 minutes ago 195MB
python 2.7-slim 1c7128a655f6 5 days ago 183MB
...
Upload your tagged image to the repository:
docker push username/repository:tag
Once complete, the results of this upload are publicly available. If you log in to Docker Hub, you see the new image there, with its pull command.
From now on, you can use docker run
and run your app on any machine with this
command:
docker run -p 4000:80 username/repository:tag
If the image isn't available locally on the machine, Docker pulls it from the repository.
$ docker run -p 4000:80 gordon/get-started:part2
Unable to find image 'gordon/get-started:part2' locally
part2: Pulling from gordon/get-started
10a267c67f42: Already exists
f68a39a6a5e4: Already exists
9beaffc0cf19: Already exists
3c1fe835fb6b: Already exists
4c9f1fa8fcb8: Already exists
ee7d8f576a14: Already exists
fbccdcced46e: Already exists
Digest: sha256:0601c866aab2adcc6498200efd0f754037e909e5fd42069adeff72d1e2439068
Status: Downloaded newer image for gordon/get-started:part2
* Running on http://0.0.0.0:80/ (Press CTRL+C to quit)
No matter where docker run
executes, it pulls your image, along with Python
and all the dependencies from requirements.txt
, and runs your code. It all
travels together in a neat little package, and you don't need to install
anything on the host machine for Docker to run it.
That's all for this page. In the next section, we learn how to scale our application by running this container in a service.
Continue to Part 3 >>{: class="button outline-btn"}
Or, learn how to launch your container on your own machine using Digital Ocean{: target="blank" class="" }.
Here's a terminal recording of what was covered on this page:
<script type="text/javascript" src="https://asciinema.org/a/blkah0l4ds33tbe06y4vkme6g.js" id="asciicast-blkah0l4ds33tbe06y4vkme6g" speed="2" async></script>Here is a list of the basic Docker commands from this page, and some related ones if you'd like to explore a bit before moving on.
docker build -t friendlyhello . # Create image using this directory's Dockerfile
docker run -p 4000:80 friendlyhello # Run "friendlyhello" mapping port 4000 to 80
docker run -d -p 4000:80 friendlyhello # Same thing, but in detached mode
docker container ls # List all running containers
docker container ls -a # List all containers, even those not running
docker container stop <hash> # Gracefully stop the specified container
docker container kill <hash> # Force shutdown of the specified container
docker container rm <hash> # Remove specified container from this machine
docker container rm $(docker container ls -a -q) # Remove all containers
docker image ls -a # List all images on this machine
docker image rm <image id> # Remove specified image from this machine
docker image rm $(docker image ls -a -q) # Remove all images from this machine
docker login # Log in this CLI session using your Docker credentials
docker tag <image> username/repository:tag # Tag <image> for upload to registry
docker push username/repository:tag # Upload tagged image to registry
docker run username/repository:tag # Run image from a registry