In my last post, I showed how to refactor the Dockerfile in your project. I didn’t want to make the previous post too long, so I didn’t touch the multistage builds. Here is the post where I will show you how to improve the Dockerfile even more, using multistage builds. Using stages in your builds is not hard to use, but there are some things where the below knowledge may help you ๐Ÿ˜ƒ

Let’s take the result of the last article:

FROM php:7.4.25-fpm
WORKDIR /app

COPY --from=composer:2.1.11 /usr/bin/composer /usr/bin/composer

RUN apt update && \
    apt install -y \
    libicu-dev=67.1-7 \
    libgd-dev=2.3.0-2 \
    libonig-dev=6.9.6-1.1 \
    unzip=6.0-26 && \
    apt purge -y --auto-remove

RUN docker-php-ext-install \
    exif \
    gd \
    intl \
    mbstring \
    mysqli \
    opcache \
    pdo_mysql \
    sockets

ENV COMPOSER_ALLOW_SUPERUSER 1

COPY composer.json .
COPY composer.lock .
RUN composer install --no-dev --no-scripts

COPY . .
RUN composer dumpautoload --optimize

Don’t keep not necessary dependencies

Every dependency in your image is potentially the source of vulnerabilities, and you should keep them up to date. So, it’s good practice to keep only a minimum of really required dependencies.
So let’s try to get rid of the composer from our final image. Composer is required to install our backend dependencies, but it’s not required in the runtime of our app. Actually, you shouldn’t keep it in your final image, because every change, like for example composer update is removed after the container restart, so it’s presence may be even confusing.

You can get rid of this dependency using multistage builds:

FROM composer:2.1.11 AS build
WORKDIR /app

COPY composer.json .
COPY composer.lock .
RUN composer install --no-dev --no-scripts --ignore-platform-reqs

COPY . .
RUN composer dumpautoload --optimize

FROM php:7.4.25-fpm
WORKDIR /app

RUN apt update && \
    apt install -y \
    libicu-dev=67.1-7 \
    libgd-dev=2.3.0-2 \
    libonig-dev=6.9.6-1.1 \
    unzip=6.0-26 && \
    apt purge -y --auto-remove

RUN docker-php-ext-install \
    exif \
    gd \
    intl \
    mbstring \
    mysqli \
    opcache \
    pdo_mysql \
    sockets

COPY --from=build /app /app

So, what happened here? As you can see, I’ve added a new FROM instruction before the PHP stage. In this way, we can add multiple stages to our docker image. The AS word is an alias for our stage, that we can use to refer to it. Referring to the stage is helpful if we need to copy something between stages, or use the previous stage as a base image for another stage.

In this case, I’ve added a build stage using a composer image, that will install all my dependencies and generate autoload files of my project. Now, when you start building this image, docker will create the build container first. When the build stage is finished, docker will start building the next stage. For the docker build process, those stages are recognized as different images, so the final image will keep only layers from the latest stage of build.

Also as you can see, I had added the --ignore-platform-reqs flag. This flag will allow you to install your dependencies even if you don’t have the required PHP extensions installed. Otherwise, compose may stop installing process if some packages require extensions that do not exist in the base composer image.

Cache

As I’ve explained before, for docker build our stages are like different images. That makes a small problem for the building process that had confused me when I’ve tried the first time to build this image using cache from the previously built image. When I tried to build this image a few times in CI/CD adding --cache-from flag, the docker didn’t use the cache. On my first time trying to get it working with using cache, I’ve spent a lot of time debugging the pipeline, I’ve even looked for problems in my runner. The problem wasn’t in my runner, and what’s more that’s behavior is expected.

Because the final image keeps only the layers that belong to the target stage (default the latest target), the final image doesn’t have layers of different stages than the target. That’s obvious when you think about it because that helps you to make your images smaller. It may be confusing when you create the CI/CD pipeline when you probably don’t have this thinking in your mind.

So how to resolve this problem? The goal is to keep all stage layers to use later as a cache. So we need to keep them during the build and then push them to our registry, to be able to get them on the next builds.
To achieve that, we can use the --target flag:

docker pull myimage:latest-build | true
docker pull myimage:latest | true

docker build . --target=build --cache-from=myimage:latest-build -t myimage:latest-build
docker build . --cache-from=myimage:latest-build --cache-from=myimage:latest -t myimage:latest

docker push myimage:latest-build
docker push myimage:latest

In this way, our application will always use the cache when building your images if it’s available of course.
The first two lines will pull your previous builds images. The ... | true makes that commands always returning the 0 code for shell, even if the image doesn’t exist that happens during the very first build. Another return code may stop your pipeline.

Image for local environment

The next thing that I had a problem with, was creating a single Dockerfile for local and running environments. The answer to my need was just to add another stage in Dockerfile.

I’m using the docker-compose to create the local development environment to work on my applications. In my case I had two Dockerfiles in my source code. The first of the files was the PHP with all extensions required to run the app. The second one was the runtime image that contains configured PHP same as the previous one, but with my application code installed in it. The PHP with extensions was the common part of both of those images. It’s stupid to make the same changes in two separated Dockerfiles like I had to do it.

There is a way to solve this problem using stages:

FROM php:7.4.25-fpm AS base
WORKDIR /app

RUN apt update && \
    apt install -y \
    libicu-dev=67.1-7 \
    libgd-dev=2.3.0-2 \
    libonig-dev=6.9.6-1.1 \
    unzip=6.0-26 && \
    apt purge -y --auto-remove

RUN docker-php-ext-install \
    exif \
    gd \
    intl \
    mbstring \
    mysqli \
    opcache \
    pdo_mysql \
    sockets

FROM composer:2.1.11 AS build
WORKDIR /app

COPY composer.json .
COPY composer.lock .
RUN composer install --no-dev --no-scripts --ignore-platform-reqs

COPY . .
RUN composer dumpautoload --optimize

FROM base AS final

COPY --from=build /app /app

The first change is to move the part that prepares my base PHP image and name this target as base. The next part is the same as before. The last part is the target created from the base stage result, named final, that also copies our application from the build stage.
Now to build this image for your running environment like production, you need to build the final stage, which automatically builds all previous stages. For using that Dockerfile in your docker-compose you need to specify which stage you need to run your local environment:

services:
  web:
    #...
    port:
      - 8080:80

  php:
    build:
      context: .
      dockerfile: Dockerfile
      target: base
    ports:
      - "9000"
    volumes:
      - .:/app

And since now, we have had the same Dockerfile for the local and running environments.

So that’s all what I want to show you in this article.
Have a nice day, and keep taking care of your Dockerfiles ๐Ÿ˜ƒ