PHP applications are usually composed by a webserver, a relational database system and the language interpreter itself. In this tutorial we will be leveraging a full PHP application stack using docker. This is an in-depth tutorial in which we are going to build and orchestrate containers for Nginx (the webserver), MySQL (the database system) and PHP.
For the sake of this tutorial, we will write a simple application that reads a list of cities from a database and displays it on a web page, this way we will demonstrate a basic, but working, PHP application.
This guide assumes that you have Docker-CE already installed and at least a minimal working knowledge of docker. For that matter you may review the following tutorials:
Configuring our working environment
A real life docker-based application will typically be composed of several containers. Managing these manually can easily become quite messy and cumbersome. That’s where docker-compose comes into play. It helps you to manage a number of containers through a simple yaml
configuration file.
Install docker-compose.
curl -L https://github.com/docker/compose/releases/download/1.19.0/docker-compose-`uname -s`-`uname -m` -o /usr/local/bin/docker-compose
chmod +x /usr/local/bin/docker-compose
Create a folder to hold all the necessary files of this example and then cd
into it. From now on, this is our working directory and every command will be executed inside this folder and every path will be referenced relative to it. This folder may be referenced later as WORKING_DIR
.
mkdir ~/docker
cd ~/docker
Now create three more folders.
mkdir php nginx app
The php
folder is where we will build our custom PHP image, the nginx
folder will hold the necessary files for our custom nginx image and the app
folder is where we will be putting the source code and configuration of our sample application.
Configuring the PHP container
In this example, we are going to use php-fpm
to connect to the Nginx webserver. We will be using the official PHP base image. However, we also need to install and enable some extensions so that we may access the database. Inside the php
folder create a file named Dockerfile
and put the following contents into it.
FROM php:7.1-fpm-alpine3.4
RUN apk update --no-cache \
&& apk add --no-cache $PHPIZE_DEPS \
&& apk add --no-cache mysql-dev \
&& docker-php-ext-install pdo pdo_mysql
Note that we are using the Alpine version of the official PHP image. Alpine is a very tiny distribution targeted towards containers by providing much smaller footprints. Also, note the use of the command docker-php-ext-install
, the official PHP image provides this command to ease the process of installing and configuring PHP extensions.
Now, let’s build this Docker image by issuing the following (inside our WORKING_DIR
):
docker build -t aklwebhost-php php/
The docker-compose.yml
file
As already mentioned, docker-compose
allows you to manage a number of containers through a simple configuration file. This configuration file is typically named docker-compose.yml
. Create this file inside the app
folder.
touch app/docker-compose.yml
Now put the following contents into this file.
version: '2'
services:
php:
image: aklwebhost-php
volumes:
- ./:/app
working_dir: /app
We will explain this syntax. First, note the first line.
version: '2'
This specifies the version of the docker-compose.yml
configuration file used. The next line specifies the services, or in other words, the containers to be provisioned.
services:
php:
image: aklwebhost-php
volumes:
- ./:/app
working_dir: /app
Note that every service has a specific key inside the services
block. The name specified here will be used to reference this specific container later. Also note that inside the php
configuration, we define the image used to run the container (this is the image we built previously). We also define a volume mapping.
volumes:
- ./:/app
This tells docker-compose
to map the current directory (./
) to the /app
directory inside the container. The last line sets the /app
folder inside the container as the working directory, which means that this is the folder where all future commands inside a container are by default executed from.
We can now orchestrate our containers.
cd ~/docker/app
docker-compose up -d
You can run the following command to make sure that the PHP container was executed:
docker ps
How to execute commands inside the containers
Still inside the app
folder, we can run any command inside a defined service container with the help of the docker-compose
command.
docker-compose exec [service] [command]
The [service]
placeholder refers to the service key. In our case, this was php
. Let’s run a command inside the container to check our PHP version.
docker-compose exec php php -v
You will see the following output.
PHP 7.1.14 (cli) (built: Feb 7 2018 00:40:45) ( NTS )
Copyright (c) 1997-2018 The PHP Group
Zend Engine v3.1.0, Copyright (c) 1998-2018 Zend Technologies
Configuring the Nginx container
Just like the PHP container, we need to create a custom image for the webserver. But in this case, we just need to provide a configuration for our virtual host
. Make sure you are inside our WORKING_DIR
and create a Dockerfile
inside the nginx
folder:
cd ~/docker
touch nginx/Dockerfile
Now put the following contents into this Dockerfile
:
FROM nginx:1.13.8-alpine
COPY ./default.conf /etc/nginx/conf.d/default.conf
We are using the default Nginx image based on Alpine. On this Docker file we simply copy a configuration file into our application setup. Before building this image, create a configuration file.
touch nginx/default.conf
Now populate it with this content.
server {
listen 80 default_server;
listen [::]:80 default_server ipv6only=on;
root /app;
index index.php;
#server_name server_domain_or_IP;
location / {
try_files $uri $uri/ /index.php?$query_string;
}
location ~ \.php$ {
try_files $uri /index.php =404;
fastcgi_split_path_info ^(.+\.php)(/.+)$;
fastcgi_pass php:9000;
fastcgi_index index.php;
fastcgi_param SCRIPT_FILENAME $document_root$fastcgi_script_name;
include fastcgi_params;
}
}
Note that at the fastcgi_pass php:9000
line we are referencing the PHP container by it’s name inside the service
block of the docker-compose.yml
configuration file. Internally docker-compose
creates a network and assigns the service name as the host name to each of the services defined. We can now build the Nginx image.
docker build -t aklwebhost-nginx nginx/
Updating docker-compose.yml
Now update the app/docker-compose.yml
file.
version: '2'
services:
php:
image: aklwebhost-php
volumes:
- ./:/app
working_dir: /app
web:
image: aklwebhost-nginx
volumes:
- ./:/app
depends_on:
- php
ports:
- 80:80
We have only added a new service. The configuration is nearly the same, except for the following.
depends_on:
- php
ports:
- 80:80
Once the Nginx container needs the PHP service to be fully initialized, we force this requirement in the depends_on
option. The ports
configuration key maps a host port to a container port, here we map the port 80
in the host to the port 80
in the container.
Now create a file called index.php
inside the app
folder and put the following in it.
<?php phpinfo();
Make sure the port 80
is accessible through your firewall and execute the following.
cd ~/docker/app
docker-compose up -d
Once again, double check that the service is up.
docker ps
Open a browser and access [aklwebhost-instance-ip]
. You may find out your AKLWEB HOST instance IP address by running the following.
hostname -I
You will see the PHP info page.
Configuring the MySQL container
The official MySQL image allows you to configure the container through simple environment variables. This can be done with an environment
option inside the service block definition. Update the ~/docker/app/docker-compose.yml
file to the following.
version: '2'
services:
php:
image: aklwebhost-php
volumes:
- ./:/app
working_dir: /app
web:
image: aklwebhost-nginx
volumes:
- ./:/app
depends_on:
- php
ports:
- 80:80
mysql:
image: mysql:5.7.21
volumes:
- ./:/app
- dbdata:/var/lib/mysql
environment:
- MYSQL_DATABASE=world
- MYSQL_ROOT_PASSWORD=root
working_dir: /app
volumes:
dbdata:
Now we’ve defined a new service for the database. Notice the line dbdata:/var/lib/mysql
. This mounts the path on the container /var/lib/mysql
to a persistent volume managed by Docker, this way the database data persists after the container is removed. This volume needs to be defined in a top-level block as you can see in the end of the file.
Before orchestrating our new configuration, let’s download a sample MySQL database. The official MySQL documentation provides some sample databases. We will be using the well-known world database. This database provides a listing of countries and cities. To download this sample, execute the following inside our app folder.
curl -L http://downloads.mysql.com/docs/world.sql.gz -o world.sql.gz
gunzip world.sql.gz
Now lets orchestrate our containers.
docker-compose up -d
As you may have already noticed, the docker-compose up
command starts only the containers that are not already started. It checks for the differences between your docker-compose.yml
file and the current configuration of running containers.
One more time, check that the MySQL container was started.
docker ps
Now populate the world database.
docker-compose exec -T mysql mysql -uroot -proot world < world.sql
You can verify that the database was populated by selecting data directly from the database. First access the MySQL prompt inside the container.
docker-compose exec mysql mysql -uroot -proot world
In the MySQL prompt, run the following.
select * from city limit 10;
You will see a list of cities. Now quit the MySQL prompt.
mysql> exit
Building our application
Now that all of the necessary containers are up and running, we can focus on our sample application. Update the app/index.php
file to the following.
<?php
$pdo = new PDO('mysql:host=mysql;dbname=world;charset=utf8', 'root', 'root');
$stmt = $pdo->prepare("
select city.Name, city.District, country.Name as Country, city.Population
from city
left join country on city.CountryCode = country.Code
order by Population desc
limit 10
");
$stmt->execute();
$cities = $stmt->fetchAll(PDO::FETCH_ASSOC);
?>
<!doctype html>
<html>
<head>
<meta charset="UTF-8">
<title>AKLWEB HOST Rocks!</title>
</head>
<body>
<h2>Most Populous Cities In The World</h2>
<table>
<thead>
<tr>
<th>Name</th>
<th>Country</th>
<th>District</th>
<th>Population</th>
</tr>
</thead>
<tbody>
<?php foreach($cities as $city): ?>
<tr>
<td><?=$city['Name']?></td>
<td><?=$city['Country']?></td>
<td><?=$city['District']?></td>
<td><?=number_format($city['Population'], 0)?></td>
</tr>
<?php endforeach ?>
</tbody>
</table>
</body>
</html>
If you access [aklwebhost-instance-ip]
in a web browser, you will see a list of the most populous cities in the world. Congratulations, you have deployed a fully working PHP application using docker.
Conclusion
In this tutorial, I have demonstrated step by step how to configuring a fully working PHP application. We built custom images for PHP and Nginx, and configured docker-compose to orchestrate our containers. Despite being very basic and simple, this setup reflects a real life scenario.
In this guide, we have built and tagged our images locally. For a more flexible setup, you can push these images to a docker registry. You may push to the official docker registry or even setup your own docker registry. In any case, this will allow you to build your images on one host and use them on another.
For a more detailed usage of docker-compose
, you should refer to the official documentation.
Depending on your application requirements and the PHP framework you use, you may want to add more extensions. This can easily be done by modifying the Dockerfile
used to build our custom PHP image. However, some extensions need extra dependencies to be installed in the container. You should refer to the list of extensions in the PHP official documentation to review the basic requirements of each extension.