There are two main categories of data — persistent and non-persistent.
Persistent is the data you need to keep. Things like; customer records, financial data, research results, audit logs, and even some types of application log data. Non-persistent is the data you don’t need to keep.
Both are important, and Docker has solutions for both.
To deal with non-persistent data, every Docker container gets its own non-persistent storage. This is automatically created for every container and is tightly coupled to the lifecycle of the container. As a result, deleting the container will delete the storage and any data on it.
To deal with persistent data, a container needs to store it in a volume. Volumes are separate objects that have their lifecycles decoupled from containers. This means you can create and manage volumes independently, and they’re not tied to the lifecycle of any container. Net result, you can delete a container that’s using a volume, and the volume won’t be deleted.
This writable layer of local storage is managed on every Docker host by a storage driver (not to be confused with a volume driver). If you’re running Docker in production on Linux, you’ll need to make sure you match the right storage driver with the Linux distribution on your Docker host. Use the following list as a guide:
Red Hat Enterprise Linux: Use the overlay2 driver with modern
versions of RHEL running Docker 17.06 or higher. Use the devicemapper
driver with older versions. This applies to Oracle Linux and other
Red Hat related upstream and downstream distros.
Ubuntu: Use the overlay2 or aufs drivers. If you’re using a Linux 4.x
kernel or higher you should go with overlay2.
SUSE Linux Enterprise Server: Use the btrfs storage driver.
Windows Windows only has one driver and it is configured by default.
By default, Docker creates new volumes with the built-in local driver. As the name suggests, volumes created with the local driver are only available to containers on the same node as the volume. You can use the -d flag to specify a different driver. Third-party volume drivers are available as plugins. These provide Docker with seamless access external storage systems such as cloud storage services and on-premises storage systems including SAN or NAS.
$ docker volume inspect myvol
Notice that the Driver and Scope are both local. This means the volume was created with the local driver and is only available to containers on this Docker host. The Mountpoint property tells us where in the Docker host’s filesystem the volume exists.
With bind mounts
With volume mount
- type: volume
Bind mounts explanation
Bind mounts have been around since the early days of Docker. Bind mounts have limited functionality compared to volumes. When you use a bind mount, a file or directory on the host machine is mounted into a container. The file or directory is referenced by its full or relative path on the host machine. By contrast, when you use a volume, a new directory is created within Docker’s storage directory on the host machine, and Docker manages that directory’s contents.
tmpfs mounts explanation
Volumes and bind mounts let you share files between the host machine and container so that you can persist data even after the container is stopped. If you’re running Docker on Linux, you have a third option: tmpfs mounts. When you create a container with a tmpfs mount, the container can create files outside the container’s writable layer. As opposed to volumes and bind mounts, a tmpfs mount is temporary and only persisted in the host memory. When the container stops, the tmpfs mount is removed, and files are written there won’t be persisted.
Volumes are the preferred mechanism for persisting data generated by and used by Docker containers. While bind mounts are dependent on the directory structure of the host machine, volumes are completely managed by Docker.