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276 lines
13 KiB
Markdown
276 lines
13 KiB
Markdown
<!--[metadata]>
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+++
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aliases = ["/engine/articles/security/"]
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title = "Docker security"
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description = "Review of the Docker Daemon attack surface"
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keywords = ["Docker, Docker documentation, security"]
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[menu.main]
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parent = "smn_secure_docker"
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weight =-99
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+++
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<![end-metadata]-->
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# Docker security
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There are three major areas to consider when reviewing Docker security:
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- the intrinsic security of the kernel and its support for
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namespaces and cgroups;
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- the attack surface of the Docker daemon itself;
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- loopholes in the container configuration profile, either by default,
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or when customized by users.
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- the "hardening" security features of the kernel and how they
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interact with containers.
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## Kernel namespaces
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Docker containers are very similar to LXC containers, and they have
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similar security features. When you start a container with
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`docker run`, behind the scenes Docker creates a set of namespaces and control
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groups for the container.
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**Namespaces provide the first and most straightforward form of
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isolation**: processes running within a container cannot see, and even
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less affect, processes running in another container, or in the host
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system.
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**Each container also gets its own network stack**, meaning that a
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container doesn't get privileged access to the sockets or interfaces
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of another container. Of course, if the host system is setup
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accordingly, containers can interact with each other through their
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respective network interfaces — just like they can interact with
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external hosts. When you specify public ports for your containers or use
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[*links*](../userguide/networking/default_network/dockerlinks.md)
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then IP traffic is allowed between containers. They can ping each other,
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send/receive UDP packets, and establish TCP connections, but that can be
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restricted if necessary. From a network architecture point of view, all
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containers on a given Docker host are sitting on bridge interfaces. This
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means that they are just like physical machines connected through a
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common Ethernet switch; no more, no less.
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How mature is the code providing kernel namespaces and private
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networking? Kernel namespaces were introduced [between kernel version
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2.6.15 and
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2.6.26](http://man7.org/linux/man-pages/man7/namespaces.7.html).
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This means that since July 2008 (date of the 2.6.26 release
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), namespace code has been exercised and scrutinized on a large
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number of production systems. And there is more: the design and
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inspiration for the namespaces code are even older. Namespaces are
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actually an effort to reimplement the features of [OpenVZ](
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http://en.wikipedia.org/wiki/OpenVZ) in such a way that they could be
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merged within the mainstream kernel. And OpenVZ was initially released
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in 2005, so both the design and the implementation are pretty mature.
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## Control groups
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Control Groups are another key component of Linux Containers. They
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implement resource accounting and limiting. They provide many
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useful metrics, but they also help ensure that each container gets
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its fair share of memory, CPU, disk I/O; and, more importantly, that a
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single container cannot bring the system down by exhausting one of those
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resources.
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So while they do not play a role in preventing one container from
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accessing or affecting the data and processes of another container, they
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are essential to fend off some denial-of-service attacks. They are
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particularly important on multi-tenant platforms, like public and
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private PaaS, to guarantee a consistent uptime (and performance) even
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when some applications start to misbehave.
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Control Groups have been around for a while as well: the code was
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started in 2006, and initially merged in kernel 2.6.24.
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## Docker daemon attack surface
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Running containers (and applications) with Docker implies running the
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Docker daemon. This daemon currently requires `root` privileges, and you
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should therefore be aware of some important details.
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First of all, **only trusted users should be allowed to control your
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Docker daemon**. This is a direct consequence of some powerful Docker
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features. Specifically, Docker allows you to share a directory between
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the Docker host and a guest container; and it allows you to do so
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without limiting the access rights of the container. This means that you
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can start a container where the `/host` directory will be the `/` directory
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on your host; and the container will be able to alter your host filesystem
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without any restriction. This is similar to how virtualization systems
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allow filesystem resource sharing. Nothing prevents you from sharing your
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root filesystem (or even your root block device) with a virtual machine.
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This has a strong security implication: for example, if you instrument Docker
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from a web server to provision containers through an API, you should be
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even more careful than usual with parameter checking, to make sure that
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a malicious user cannot pass crafted parameters causing Docker to create
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arbitrary containers.
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For this reason, the REST API endpoint (used by the Docker CLI to
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communicate with the Docker daemon) changed in Docker 0.5.2, and now
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uses a UNIX socket instead of a TCP socket bound on 127.0.0.1 (the
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latter being prone to cross-site request forgery attacks if you happen to run
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Docker directly on your local machine, outside of a VM). You can then
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use traditional UNIX permission checks to limit access to the control
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socket.
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You can also expose the REST API over HTTP if you explicitly decide to do so.
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However, if you do that, being aware of the above mentioned security
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implication, you should ensure that it will be reachable only from a
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trusted network or VPN; or protected with e.g., `stunnel` and client SSL
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certificates. You can also secure them with [HTTPS and
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certificates](https.md).
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The daemon is also potentially vulnerable to other inputs, such as image
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loading from either disk with 'docker load', or from the network with
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'docker pull'. This has been a focus of improvement in the community,
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especially for 'pull' security. While these overlap, it should be noted
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that 'docker load' is a mechanism for backup and restore and is not
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currently considered a secure mechanism for loading images. As of
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Docker 1.3.2, images are now extracted in a chrooted subprocess on
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Linux/Unix platforms, being the first-step in a wider effort toward
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privilege separation.
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Eventually, it is expected that the Docker daemon will run restricted
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privileges, delegating operations well-audited sub-processes,
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each with its own (very limited) scope of Linux capabilities,
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virtual network setup, filesystem management, etc. That is, most likely,
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pieces of the Docker engine itself will run inside of containers.
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Finally, if you run Docker on a server, it is recommended to run
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exclusively Docker in the server, and move all other services within
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containers controlled by Docker. Of course, it is fine to keep your
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favorite admin tools (probably at least an SSH server), as well as
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existing monitoring/supervision processes (e.g., NRPE, collectd, etc).
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## Linux kernel capabilities
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By default, Docker starts containers with a restricted set of
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capabilities. What does that mean?
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Capabilities turn the binary "root/non-root" dichotomy into a
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fine-grained access control system. Processes (like web servers) that
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just need to bind on a port below 1024 do not have to run as root: they
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can just be granted the `net_bind_service` capability instead. And there
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are many other capabilities, for almost all the specific areas where root
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privileges are usually needed.
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This means a lot for container security; let's see why!
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Your average server (bare metal or virtual machine) needs to run a bunch
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of processes as root. Those typically include SSH, cron, syslogd;
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hardware management tools (e.g., load modules), network configuration
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tools (e.g., to handle DHCP, WPA, or VPNs), and much more. A container is
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very different, because almost all of those tasks are handled by the
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infrastructure around the container:
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- SSH access will typically be managed by a single server running on
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the Docker host;
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- `cron`, when necessary, should run as a user
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process, dedicated and tailored for the app that needs its
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scheduling service, rather than as a platform-wide facility;
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- log management will also typically be handed to Docker, or by
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third-party services like Loggly or Splunk;
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- hardware management is irrelevant, meaning that you never need to
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run `udevd` or equivalent daemons within
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containers;
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- network management happens outside of the containers, enforcing
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separation of concerns as much as possible, meaning that a container
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should never need to perform `ifconfig`,
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`route`, or ip commands (except when a container
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is specifically engineered to behave like a router or firewall, of
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course).
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This means that in most cases, containers will not need "real" root
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privileges *at all*. And therefore, containers can run with a reduced
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capability set; meaning that "root" within a container has much less
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privileges than the real "root". For instance, it is possible to:
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- deny all "mount" operations;
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- deny access to raw sockets (to prevent packet spoofing);
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- deny access to some filesystem operations, like creating new device
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nodes, changing the owner of files, or altering attributes (including
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the immutable flag);
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- deny module loading;
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- and many others.
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This means that even if an intruder manages to escalate to root within a
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container, it will be much harder to do serious damage, or to escalate
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to the host.
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This won't affect regular web apps; but malicious users will find that
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the arsenal at their disposal has shrunk considerably! By default Docker
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drops all capabilities except [those
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needed](https://github.com/docker/docker/blob/master/oci/defaults_linux.go#L64-L79),
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a whitelist instead of a blacklist approach. You can see a full list of
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available capabilities in [Linux
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manpages](http://man7.org/linux/man-pages/man7/capabilities.7.html).
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One primary risk with running Docker containers is that the default set
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of capabilities and mounts given to a container may provide incomplete
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isolation, either independently, or when used in combination with
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kernel vulnerabilities.
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Docker supports the addition and removal of capabilities, allowing use
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of a non-default profile. This may make Docker more secure through
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capability removal, or less secure through the addition of capabilities.
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The best practice for users would be to remove all capabilities except
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those explicitly required for their processes.
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## Other kernel security features
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Capabilities are just one of the many security features provided by
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modern Linux kernels. It is also possible to leverage existing,
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well-known systems like TOMOYO, AppArmor, SELinux, GRSEC, etc. with
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Docker.
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While Docker currently only enables capabilities, it doesn't interfere
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with the other systems. This means that there are many different ways to
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harden a Docker host. Here are a few examples.
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- You can run a kernel with GRSEC and PAX. This will add many safety
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checks, both at compile-time and run-time; it will also defeat many
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exploits, thanks to techniques like address randomization. It doesn't
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require Docker-specific configuration, since those security features
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apply system-wide, independent of containers.
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- If your distribution comes with security model templates for
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Docker containers, you can use them out of the box. For instance, we
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ship a template that works with AppArmor and Red Hat comes with SELinux
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policies for Docker. These templates provide an extra safety net (even
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though it overlaps greatly with capabilities).
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- You can define your own policies using your favorite access control
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mechanism.
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Just like there are many third-party tools to augment Docker containers
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with e.g., special network topologies or shared filesystems, you can
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expect to see tools to harden existing Docker containers without
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affecting Docker's core.
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As of Docker 1.10 User Namespaces are supported directly by the docker
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daemon. This feature allows for the root user in a container to be mapped
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to a non uid-0 user outside the container, which can help to mitigate the
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risks of container breakout. This facility is available but not enabled
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by default.
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Refer to the [daemon command](../reference/commandline/dockerd.md#daemon-user-namespace-options)
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in the command line reference for more information on this feature.
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Additional information on the implementation of User Namespaces in Docker
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can be found in <a href="https://integratedcode.us/2015/10/13/user-namespaces-have-arrived-in-docker/" target="_blank">this blog post</a>.
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## Conclusions
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Docker containers are, by default, quite secure; especially if you take
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care of running your processes inside the containers as non-privileged
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users (i.e., non-`root`).
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You can add an extra layer of safety by enabling AppArmor, SELinux,
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GRSEC, or your favorite hardening solution.
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Last but not least, if you see interesting security features in other
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containerization systems, these are simply kernels features that may
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be implemented in Docker as well. We welcome users to submit issues,
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pull requests, and communicate via the mailing list.
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## Related Information
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* [Use trusted images](../security/trust/index.md)
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* [Seccomp security profiles for Docker](../security/seccomp.md)
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* [AppArmor security profiles for Docker](../security/apparmor.md)
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* [On the Security of Containers (2014)](https://medium.com/@ewindisch/on-the-security-of-containers-2c60ffe25a9e)
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