Estimated reading time:
4 minutes
One of the reasons Docker containers and services are so powerful is that
you can connect them together, or connect them to non-Docker workloads. Docker
containers and services do not even need to be aware that they are deployed on
Docker, or whether their peers are also Docker workloads or not. Whether your
Docker hosts run Linux, Windows, or a mix of the two, you can use Docker to
manage them in a platform-agnostic way.
This topic defines some basic Docker networking concepts and prepares you to
design and deploy your applications to take full advantage of these
capabilities.
Most of this content applies to all Docker installations. However,
a few advanced features are only available to
Docker EE customers.
Scope of this topic
This topic does not go into OS-specific details about how Docker networks
work, so you will not find information about how Docker manipulates iptables
rules on Linux or how it manipulates routing rules on Windows servers, and you
will not find detailed information about how Docker forms and encapsulates
packets or handles encryption. See Docker and iptables
and
Docker Reference Architecture: Designing Scalable, Portable Docker Container Networks
for a much greater depth of technical detail.
In addition, this topic does not provide any tutorials for how to create,
manage, and use Docker networks. Each section includes links to relevant
tutorials and command references.
Network drivers
Docker’s networking subsystem is pluggable, using drivers. Several drivers
exist by default, and provide core networking functionality:
-
bridge: The default network driver. If you don’t specify a driver, this is
the type of network you are creating. Bridge networks are usually used when
your applications run in standalone containers that need to communicate. See
bridge networks. -
host: For standalone containers, remove network isolation between the
container and the Docker host, and use the host’s networking directly. host
is only available for swarm services on Docker 17.06 and higher. See
use the host network. -
overlay: Overlay networks connect multiple Docker daemons together and
enable swarm services to communicate with each other. You can also use overlay
networks to facilitate communication between a swarm service and a standalone
container, or between two standalone containers on different Docker daemons.
This strategy removes the need to do OS-level routing between these
containers. See overlay networks. -
macvlan: Macvlan networks allow you to assign a MAC address to a container,
making it appear as a physical device on your network. The Docker daemon
routes traffic to containers by their MAC addresses. Using the macvlan
driver is sometimes the best choice when dealing with legacy applications that
expect to be directly connected to the physical network, rather than routed
through the Docker host’s network stack. See
Macvlan networks. -
none: For this container, disable all networking. Usually used in
conjunction with a custom network driver. none is not available for swarm
services. See
disable container networking. -
Network plugins: You can install and use
third-party network plugins with Docker. These plugins are available from
Docker Store
or from third-party vendors. See the vendor’s documentation for installing and
using a given network plugin.
Network driver summary
- User-defined bridge networks are best when you need multiple containers to
communicate on the same Docker host. - Host networks are best when the network stack should not be isolated from
the Docker host, but you want other aspects of the container to be isolated. - Overlay networks are best when you need containers running on different
Docker hosts to communicate, or when multiple applications work together using
swarm services. - Macvlan networks are best when you are migrating from a VM setup or
need your containers to look like physical hosts on your network, each with a
unique MAC address. - Third-party network plugins allow you to integrate Docker with specialized
network stacks.
Docker EE networking features
The following two features are only possible when using Docker EE and managing
your Docker services using Universal Control Plane (UCP):
-
The HTTP routing mesh
allows you to share the same network IP address and port among multiple
services. UCP routes the traffic to the appropriate service using the
combination of hostname and port, as requested from the client. -
Session stickiness allows you to specify information in the HTTP header
which UCP uses to route subsequent requests to the same service task, for
applications which require stateful sessions.
Networking tutorials
Now that you understand the basics about Docker networks, deepen your
understanding using the following tutorials:
- Standalone networking tutorial
- Host networking tutorial
- Overlay networking tutorial
- Macvlan networking tutorial
networking, bridge, routing, routing mesh, overlay, ports
Leave a Reply