In Kubernetes, rather than individual application containers, pods are the smallest deployable units that can be created, scheduled, and managed.
A pod (as in a pod of whales or pea pod) corresponds to a colocated group of applications running with a shared context. Within that context, the applications may also have individual cgroup isolations applied. A pod models an application-specific "logical host" in a containerized environment. It may contain one or more applications which are relatively tightly coupled -- in a pre-container world, they would have executed on the same physical or virtual host.
The context of the pod can be defined as the conjunction of several Linux namespaces:
- PID namespace (applications within the pod can see each other's processes)
- network namespace (applications within the pod have access to the same IP and port space)
- IPC namespace (applications within the pod can use SystemV IPC or POSIX message queues to communicate)
- UTS namespace (applications within the pod share a hostname)
Applications within a pod also have access to shared volumes, which are defined at the pod level and made available in each application's filesystem. Additionally, a pod may define top-level cgroup isolations which form an outer bound to any individual isolation applied to constituent applications.
In terms of Docker constructs, a pod consists of a colocated group of Docker containers with shared volumes. PID namespace sharing is not yet implemented with Docker.
Like individual application containers, pods are considered to be relatively ephemeral rather than durable entities. As discussed in life of a pod, pods are scheduled to nodes and remain there until termination (according to restart policy) or deletion. When a node dies, the pods scheduled to that node are deleted. Specific pods are never rescheduled to new nodes; instead, they must be replaced (see replication controller for more details). (In the future, a higher-level API may support pod migration.)
Pods facilitate data sharing and communication among their constituents.
The applications in the pod all use the same network namespace/IP and port space, and can find and communicate with each other using localhost. Each pod has an IP address in a flat shared networking namespace that has full communication with other physical computers and containers across the network. The hostname is set to the pod's Name for the application containers within the pod. More details on networking.
In addition to defining the application containers that run in the pod, the pod specifies a set of shared storage volumes. Volumes enable data to survive container restarts and to be shared among the applications within the pod.
Pods also simplify application deployment and management by providing a higher-level abstraction than the raw, low-level container interface. Pods serve as units of deployment and horizontal scaling/replication. Co-location, fate sharing, coordinated replication, resource sharing, and dependency management are handled automatically.
Pods can be used to host vertically integrated application stacks, but their primary motivation is to support co-located, co-managed helper programs, such as:
- content management systems, file and data loaders, local cache managers, etc.
- log and checkpoint backup, compression, rotation, snapshotting, etc.
- data change watchers, log tailers, logging and monitoring adapters, event publishers, etc.
- proxies, bridges, and adapters
- controllers, managers, configurators, and updaters
Individual pods are not intended to run multiple instances of the same application, in general.
Why not just run multiple programs in a single (Docker) container?
- Transparency. Making the containers within the pod visible to the infrastructure enables the infrastructure to provide services to those containers, such as process management and resource monitoring. This facilitates a number of conveniences for users.
- Decoupling software dependencies. The individual containers may be rebuilt and redeployed independently. Kubernetes may even support live updates of individual containers someday.
- Ease of use. Users don't need to run their own process managers, worry about signal and exit-code propagation, etc.
- Efficiency. Because the infrastructure takes on more responsibility, containers can be lighterweight.
Why not support affinity-based co-scheduling of containers?
That approach would provide co-location, but would not provide most of the benefits of pods, such as resource sharing, IPC, guaranteed fate sharing, and simplified management.
Pods aren't intended to be treated as durable pets. They won't survive scheduling failures, node failures, or other evictions, such as due to lack of resources, or in the case of node maintenance.
In general, users shouldn't need to create pods directly. They should almost always use controllers (e.g., replication controller), even for singletons. Controllers provide self-healing with a cluster scope, as well as replication and rollout management.
Pod is exposed as a primitive in order to facilitate:
- scheduler and controller pluggability
- support for pod-level operations without the need to "proxy" them via controller APIs
- decoupling of pod lifetime from controller lifetime, such as for bootstrapping
- decoupling of controllers and services -- the endpoint controller just watches pods
- clean composition of Kubelet-level functionality with cluster-level functionality -- Kubelet is effectively the "pod controller"
- high-availability applications, which will expect pods to be replaced in advance of their termination and certainly in advance of deletion, such as in the case of planned evictions, image prefetching, or live pod migration #3949
The current best practice for pets is to create a replication controller with replicas
equal to 1
and a corresponding service. If you find this cumbersome, please comment on issue #260.