page_title: Best Practices for Writing Dockerfiles page_description: Hints, tips and guidelines for writing clean, reliable Dockerfiles page_keywords: Examples, Usage, base image, docker, documentation, dockerfile, best practices, hub, official repo # Best practices for writing Dockerfiles ## Overview Docker can build images automatically by reading the instructions from a `Dockerfile`, a text file that contains all the commands, in order, needed to build a given image. `Dockerfile`s adhere to a specific format and use a specific set of instructions. You can learn the basics on the [Dockerfile Reference](https://docs.docker.com/reference/builder/) page. If you’re new to writing `Dockerfile`s, you should start there. This document covers the best practices and methods recommended by Docker, Inc. and the Docker community for creating easy-to-use, effective `Dockerfile`s. We strongly suggest you follow these recommendations (in fact, if you’re creating an Official Image, you *must* adhere to these practices). You can see many of these practices and recommendations in action in the [buildpack-deps `Dockerfile`](https://github.com/docker-library/buildpack-deps/blob/master/jessie/Dockerfile). > Note: for more detailed explanations of any of the Dockerfile commands >mentioned here, visit the [Dockerfile Reference](https://docs.docker.com/reference/builder/) page. ## General guidelines and recommendations ### Containers should be ephemeral The container produced by the image your `Dockerfile` defines should be as ephemeral as possible. By “ephemeral,” we mean that it can be stopped and destroyed and a new one built and put in place with an absolute minimum of set-up and configuration. ### Use [a .dockerignore file](https://docs.docker.com/reference/builder/#the-dockerignore-file) For faster uploading and efficiency during `docker build`, you should use a `.dockerignore` file to exclude files or directories from the build context and final image. For example, unless`.git` is needed by your build process or scripts, you should add it to `.dockerignore`, which can save many megabytes worth of upload time. ### Avoid installing unnecessary packages In order to reduce complexity, dependencies, file sizes, and build times, you should avoid installing extra or unnecessary packages just because they might be “nice to have.” For example, you don’t need to include a text editor in a database image. ### Run only one process per container In almost all cases, you should only run a single process in a single container. Decoupling applications into multiple containers makes it much easier to scale horizontally and reuse containers. If that service depends on another service, make use of [container linking](https://docs.docker.com/userguide/dockerlinks/). ### Minimize the number of layers You need to find the balance between readability (and thus long-term maintainability) of the `Dockerfile` and minimizing the number of layers it uses. Be strategic and cautious about the number of layers you use. ### Sort multi-line arguments Whenever possible, ease later changes by sorting multi-line arguments alphanumerically. This will help you avoid duplication of packages and make the list much easier to update. This also makes PRs a lot easier to read and review. Adding a space before a backslash (`\`) helps as well. Here’s an example from the [`buildpack-deps` image](https://github.com/docker-library/buildpack-deps): RUN apt-get update && apt-get install -y \ bzr \ cvs \ git \ mercurial \ subversion ### Build cache During the process of building an image Docker will step through the instructions in your `Dockerfile` executing each in the order specified. As each instruction is examined Docker will look for an existing image in its cache that it can reuse, rather than creating a new (duplicate) image. If you do not want to use the cache at all you can use the ` --no-cache=true` option on the `docker build` command. However, if you do let Docker use its cache then it is very important to understand when it will, and will not, find a matching image. The basic rules that Docker will follow are outlined below: * Starting with a base image that is already in the cache, the next instruction is compared against all child images derived from that base image to see if one of them was built using the exact same instruction. If not, the cache is invalidated. * In most cases simply comparing the instruction in the `Dockerfile` with one of the child images is sufficient. However, certain instructions require a little more examination and explanation. * In the case of the `ADD` and `COPY` instructions, the contents of the file(s) being put into the image are examined. Specifically, a checksum is done of the file(s) and then that checksum is used during the cache lookup. If anything has changed in the file(s), including its metadata, then the cache is invalidated. * Aside from the `ADD` and `COPY` commands cache checking will not look at the files in the container to determine a cache match. For example, when processing a `RUN apt-get -y update` command the files updated in the container will not be examined to determine if a cache hit exists. In that case just the command string itself will be used to find a match. Once the cache is invalidated, all subsequent `Dockerfile` commands will generate new images and the cache will not be used. ## The Dockerfile instructions Below you'll find recommendations for the best way to write the various instructions available for use in a `Dockerfile`. ### [`FROM`](https://docs.docker.com/reference/builder/#from) Whenever possible, use current Official Repositories as the basis for your image. We recommend the [Debian image](https://registry.hub.docker.com/_/debian/) since it’s very tightly controlled and kept extremely minimal (currently under 100 mb), while still being a full distribution. ### [`RUN`](https://docs.docker.com/reference/builder/#run) As always, to make your `Dockerfile` more readable, understandable, and maintainable, put long or complex `RUN` statements on multiple lines separated with backslashes. Probably the most common use-case for `RUN` is an application of `apt-get`. When using `apt-get`, here are a few things to keep in mind: * Don’t do `RUN apt-get update` on a single line. This will cause caching issues if the referenced archive gets updated, which will make your subsequent `apt-get install` fail without comment. * Avoid `RUN apt-get upgrade` or `dist-upgrade`, since many of the “essential” packages from the base images will fail to upgrade inside an unprivileged container. If a base package is out of date, you should contact its maintainers. If you know there’s a particular package, `foo`, that needs to be updated, use `apt-get install -y foo` and it will update automatically. * Do write instructions like: RUN apt-get update && apt-get install -y package-bar package-foo package-baz Writing the instruction this way not only makes it easier to read and maintain, but also, by including `apt-get update`, ensures that the cache will naturally be busted and the latest versions will be installed with no further coding or manual intervention required. * Further natural cache-busting can be realized by version-pinning packages (e.g., `package-foo=1.3.*`). This will force retrieval of that version regardless of what’s in the cache. Writing your `apt-get` code this way will greatly ease maintenance and reduce failures due to unanticipated changes in required packages. #### Example Below is a well-formed `RUN` instruction that demonstrates the above recommendations. Note that the last package, `s3cmd`, specifies a version `1.1.0*`. If the image previously used an older version, specifying the new one will cause a cache bust of `apt-get update` and ensure the installation of the new version (which in this case had a new, required feature). RUN apt-get update && apt-get install -y \ aufs-tools \ automake \ btrfs-tools \ build-essential \ curl \ dpkg-sig \ git \ iptables \ libapparmor-dev \ libcap-dev \ libsqlite3-dev \ lxc=1.0* \ mercurial \ parallel \ reprepro \ ruby1.9.1 \ ruby1.9.1-dev \ s3cmd=1.1.0* Writing the instruction this way also helps you avoid potential duplication of a given package because it is much easier to read than an instruction like: RUN apt-get install -y package-foo && apt-get install -y package-bar ### [`CMD`](https://docs.docker.com/reference/builder/#cmd) The `CMD` instruction should be used to run the software contained by your image, along with any arguments. `CMD` should almost always be used in the form of `CMD [“executable”, “param1”, “param2”…]`. Thus, if the image is for a service (Apache, Rails, etc.), you would run something like `CMD ["apache2","-DFOREGROUND"]`. Indeed, this form of the instruction is recommended for any service-based image. In most other cases, `CMD` should be given an interactive shell (bash, python, perl, etc), for example, `CMD ["perl", "-de0"]`, `CMD ["python"]`, or `CMD [“php”, “-a”]`. Using this form means that when you execute something like `docker run -it python`, you’ll get dropped into a usable shell, ready to go. `CMD` should rarely be used in the manner of `CMD [“param”, “param”]` in conjunction with [`ENTRYPOINT`](https://docs.docker.com/reference/builder/#entrypoint), unless you and your expected users are already quite familiar with how `ENTRYPOINT` works. ### [`EXPOSE`](https://docs.docker.com/reference/builder/#expose) The `EXPOSE` instruction indicates the ports on which a container will listen for connections. Consequently, you should use the common, traditional port for your application. For example, an image containing the Apache web server would use `EXPOSE 80`, while an image containing MongoDB would use `EXPOSE 27017` and so on. For external access, your users can execute `docker run` with a flag indicating how to map the specified port to the port of their choice. For container linking, Docker provides environment variables for the path from the recipient container back to the source (ie, `MYSQL_PORT_3306_TCP`). ### [`ENV`](https://docs.docker.com/reference/builder/#env) In order to make new software easier to run, you can use `ENV` to update the `PATH` environment variable for the software your container installs. For example, `ENV PATH /usr/local/nginx/bin:$PATH` will ensure that `CMD [“nginx”]` just works. The `ENV` instruction is also useful for providing required environment variables specific to services you wish to containerize, such as Postgres’s `PGDATA`. Lastly, `ENV` can also be used to set commonly used version numbers so that version bumps are easier to maintain, as seen in the following example: ENV PG_MAJOR 9.3 ENV PG_VERSION 9.3.4 RUN curl -SL http://example.com/postgres-$PG_VERSION.tar.xz | tar -xJC /usr/src/postgress && … ENV PATH /usr/local/postgres-$PG_MAJOR/bin:$PATH Similar to having constant variables in a program (as opposed to hard-coding values), this approach lets you change a single `ENV` instruction to auto-magically bump the version of the software in your container. ### [`ADD`](https://docs.docker.com/reference/builder/#add) or [`COPY`](https://docs.docker.com/reference/builder/#copy) Although `ADD` and `COPY` are functionally similar, generally speaking, `COPY` is preferred. That’s because it’s more transparent than `ADD`. `COPY` only supports the basic copying of local files into the container, while `ADD` has some features (like local-only tar extraction and remote URL support) that are not immediately obvious. Consequently, the best use for `ADD` is local tar file auto-extraction into the image, as in `ADD rootfs.tar.xz /`. If you have multiple `Dockerfile` steps that use different files from your context, `COPY` them individually, rather than all at once. This will ensure that each step's build cache is only invalidated (forcing the step to be re-run) if the specifically required files change. For example: COPY requirements.txt /tmp/ RUN pip install /tmp/requirements.txt COPY . /tmp/ Results in fewer cache invalidations for the `RUN` step, than if you put the `COPY . /tmp/` before it. Because image size matters, using `ADD` to fetch packages from remote URLs is strongly discouraged; you should use `curl` or `wget` instead. That way you can delete the files you no longer need after they've been extracted and you won't have to add another layer in your image. For example, you should avoid doing things like: ADD http://example.com/big.tar.xz /usr/src/things/ RUN tar -xJf /usr/src/things/big.tar.xz -C /usr/src/things RUN make -C /usr/src/things all And instead, do something like: RUN mkdir -p /usr/src/things \ && curl -SL http://example.com/big.tar.gz \ | tar -xJC /usr/src/things \ && make -C /usr/src/things all For other items (files, directories) that do not require `ADD`’s tar auto-extraction capability, you should always use `COPY`. ### [`ENTRYPOINT`](https://docs.docker.com/reference/builder/#entrypoint) The best use for `ENTRYPOINT` is as a helper script. Using `ENTRYPOINT` for other tasks can make your code harder to understand. For example, ....docker run -it official-image bash is much easier to understand than ....docker run -it --entrypoint bash official-image -i This is especially true for new Docker users, who might naturally assume the above command will work fine. In cases where an image uses `ENTRYPOINT` for anything other than just a wrapper script, the command will fail and the beginning user will then be forced to learn about `ENTRYPOINT` and `--entrypoint`. In order to avoid a situation where commands are run without clear visibility to the user, make sure your script ends with something like `exec "$@"` (see [the exec builtin command](http://wiki.bash-hackers.org/commands/builtin/exec)). After the entrypoint completes, the script will transparently bootstrap the command invoked by the user, making what has been run clear to the user (for example, `docker run -it mysql mysqld --some --flags` will transparently run `mysqld --some --flags` after `ENTRYPOINT` runs `initdb`). For example, let’s look at the `Dockerfile` for the [Postgres Official Image](https://github.com/docker-library/postgres). It refers to the following script: ```bash #!/bin/bash set -e if [ "$1" = 'postgres' ]; then chown -R postgres "$PGDATA" if [ -z "$(ls -A "$PGDATA")" ]; then gosu postgres initdb fi exec gosu postgres "$@" fi exec "$@" ``` That script then gets copied into the container and run via `ENTRYPOINT` on container startup: COPY ./docker-entrypoint.sh / ENTRYPOINT ["/docker-entrypoint.sh"] ### [`VOLUME`](https://docs.docker.com/reference/builder/#volume) The `VOLUME` instruction should be used to expose any database storage area, configuration storage, or files/folders created by your docker container. You are strongly encouraged to use `VOLUME` for any mutable and/or user-serviceable parts of your image. ### [`USER`](https://docs.docker.com/reference/builder/#user) If a service can run without privileges, use `USER` to change to a non-root user. Start by creating the user and group in the `Dockerfile` with something like `RUN groupadd -r postgres && useradd -r -g postgres postgres`. > **Note:** Users and groups in an image get a non-deterministic > UID/GID in that the “next” UID/GID gets assigned regardless of image > rebuilds. So, if it’s critical, you should assign an explicit UID/GID. You should avoid installing or using `sudo` since it has unpredictable TTY and signal-forwarding behavior that can cause more more problems than it solves. If you absolutely need functionality similar to `sudo` (e.g., initializing the daemon as root but running it as non-root), you may be able to use [“gosu”](https://github.com/tianon/gosu). Lastly, to reduce layers and complexity, avoid switching `USER` back and forth frequently. ### [`WORKDIR`](https://docs.docker.com/reference/builder/#workdir) For clarity and reliability, you should always use absolute paths for your `WORKDIR`. Also, you should use `WORKDIR` instead of proliferating instructions like `RUN cd … && do-something`, which are hard to read, troubleshoot, and maintain. ### [`ONBUILD`](https://docs.docker.com/reference/builder/#onbuild) `ONBUILD` is only useful for images that are going to be built `FROM` a given image. For example, you would use `ONBUILD` for a language stack image that builds arbitrary user software written in that language within the `Dockerfile`, as you can see in [Ruby’s `ONBUILD` variants](https://github.com/docker-library/ruby/blob/master/2.1/onbuild/Dockerfile). Images built from `ONBUILD` should get a separate tag, for example: `ruby:1.9-onbuild` or `ruby:2.0-onbuild`. Be careful when putting `ADD` or `COPY` in `ONBUILD`. The “onbuild” image will fail catastrophically if the new build's context is missing the resource being added. Adding a separate tag, as recommended above, will help mitigate this by allowing the `Dockerfile` author to make a choice. ## Examples For Official Repositories These Official Repos have exemplary `Dockerfile`s: * [Go](https://registry.hub.docker.com/_/golang/) * [Perl](https://registry.hub.docker.com/_/perl/) * [Hy](https://registry.hub.docker.com/_/hylang/) * [Rails](https://registry.hub.docker.com/_/rails) ## Additional Resources: * [Dockerfile Reference](https://docs.docker.com/reference/builder/#onbuild) * [More about Base Images](https://docs.docker.com/articles/baseimages/) * [More about Automated Builds](https://docs.docker.com/docker-hub/builds/) * [Guidelines for Creating Official Repositories](https://docs.docker.com/docker-hub/official_repos/)