Kubernetes Pods
are mortal. They are born and they die, and they
are not resurrected. ReplicationControllers
in
particular create and destroy Pods
dynamically (e.g. when scaling up or down
or when doing rolling updates). While each Pod
gets its own IP address, even
those IP addresses cannot be relied upon to be stable over time. This leads to
a problem: if some set of Pods
(let’s call them backends) provides
functionality to other Pods
(let’s call them frontends) inside the Kubernetes
cluster, how do those frontends find out and keep track of which backends are
in that set?
Enter Services
.
A Kubernetes Service
is an abstraction which defines a logical set of Pods
and a policy by which to access them - sometimes called a micro-service. The
set of Pods
targeted by a Service
is (usually) determined by a Label
Selector
(see below for why you might want a
Service
without a selector).
As an example, consider an image-processing backend which is running with 3
replicas. Those replicas are fungible - frontends do not care which backend
they use. While the actual Pods
that compose the backend set may change, the
frontend clients should not need to be aware of that or keep track of the list
of backends themselves. The Service
abstraction enables this decoupling.
For Kubernetes-native applications, Kubernetes offers a simple Endpoints
API
that is updated whenever the set of Pods
in a Service
changes. For
non-native applications, Kubernetes offers a virtual-IP-based bridge to Services
which redirects to the backend Pods
.
A Service
in Kubernetes is a REST object, similar to a Pod
. Like all of the
REST objects, a Service
definition can be POSTed to the apiserver to create a
new instance. For example, suppose you have a set of Pods
that each expose
port 9376 and carry a label "app=MyApp"
.
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"spec": {
"selector": {
"app": "MyApp"
},
"ports": [
{
"protocol": "TCP",
"port": 80,
"targetPort": 9376
}
]
}
}
This specification will create a new Service
object named “my-service” which
targets TCP port 9376 on any Pod
with the "app=MyApp"
label. This Service
will also be assigned an IP address (sometimes called the “cluster IP”), which
is used by the service proxies (see below). The Service
’s selector will be
evaluated continuously and the results will be POSTed to an Endpoints
object
also named “my-service”.
Note that a Service
can map an incoming port to any targetPort
. By default
the targetPort
will be set to the same value as the port
field. Perhaps
more interesting is that targetPort
can be a string, referring to the name of
a port in the backend Pods
. The actual port number assigned to that name can
be different in each backend Pod
. This offers a lot of flexibility for
deploying and evolving your Services
. For example, you can change the port
number that pods expose in the next version of your backend software, without
breaking clients.
Kubernetes Services
support TCP
and UDP
for protocols. The default
is TCP
.
Services generally abstract access to Kubernetes Pods
, but they can also
abstract other kinds of backends. For example:
Namespace
or on another cluster.In any of these scenarios you can define a service without a selector:
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"spec": {
"ports": [
{
"protocol": "TCP",
"port": 80,
"targetPort": 9376
}
]
}
}
Because this service has no selector, the corresponding Endpoints
object will not be
created. You can manually map the service to your own specific endpoints:
{
"kind": "Endpoints",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"subsets": [
{
"addresses": [
{ "ip": "1.2.3.4" }
],
"ports": [
{ "port": 9376 }
]
}
]
}
NOTE: Endpoint IPs may not be loopback (127.0.0.0/8), link-local (169.254.0.0/16), or link-local multicast (224.0.0.0/24).
Accessing a Service
without a selector works the same as if it had selector.
The traffic will be routed to endpoints defined by the user (1.2.3.4:9376
in
this example).
Every node in a Kubernetes cluster runs a kube-proxy
. This application
is responsible for implementing a form of virtual IP for Service
s. In
Kubernetes v1.0 the proxy was purely in userspace. In Kubernetes v1.1 an
iptables proxy was added, but was not the default operating mode. In
Kubernetes v1.2 we expect the iptables proxy to be the default.
As of Kubernetes v1.0, Services
are a “layer 3” (TCP/UDP over IP) construct.
In Kubernetes v1.1 the Ingress
API was added (beta) to represent “layer 7”
(HTTP) services.
In this mode, kube-proxy watches the Kubernetes master for the addition and
removal of Service
and Endpoints
objects. For each Service
it opens a
port (randomly chosen) on the local node. Any connections to this “proxy port”
will be proxied to one of the Service
’s backend Pods
(as reported in
Endpoints
). Which backend Pod
to use is decided based on the
SessionAffinity
of the Service
. Lastly, it installs iptables rules which
capture traffic to the Service
’s clusterIP
(which is virtual) and Port
and redirects that traffic to the proxy port which proxies the a backend Pod
.
The net result is that any traffic bound for the Service
’s IP:Port is proxied
to an appropriate backend without the clients knowing anything about Kubernetes
or Services
or Pods
.
By default, the choice of backend is round robin. Client-IP based session affinity
can be selected by setting service.spec.sessionAffinity
to "ClientIP"
(the
default is "None"
).
In this mode, kube-proxy watches the Kubernetes master for the addition and
removal of Service
and Endpoints
objects. For each Service
it installs
iptables rules which capture traffic to the Service
’s clusterIP
(which is
virtual) and Port
and redirects that traffic to one of the Service
’s
backend sets. For each Endpoints
object it installs iptables rules which
select a backend Pod
.
By default, the choice of backend is random. Client-IP based session affinity
can be selected by setting service.spec.sessionAffinity
to "ClientIP"
(the
default is "None"
).
As with the userspace proxy, the net result is that any traffic bound for the
Service
’s IP:Port is proxied to an appropriate backend without the clients
knowing anything about Kubernetes or Services
or Pods
. This should be
faster and more reliable than the userspace proxy.
Many Services
need to expose more than one port. For this case, Kubernetes
supports multiple port definitions on a Service
object. When using multiple
ports you must give all of your ports names, so that endpoints can be
disambiguated. For example:
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"spec": {
"selector": {
"app": "MyApp"
},
"ports": [
{
"name": "http",
"protocol": "TCP",
"port": 80,
"targetPort": 9376
},
{
"name": "https",
"protocol": "TCP",
"port": 443,
"targetPort": 9377
}
]
}
}
You can specify your own cluster IP address as part of a Service
creation
request. To do this, set the spec.clusterIP
field. For example, if you
already have an existing DNS entry that you wish to replace, or legacy systems
that are configured for a specific IP address and difficult to re-configure.
The IP address that a user chooses must be a valid IP address and within the
service-cluster-ip-range
CIDR range that is specified by flag to the API
server. If the IP address value is invalid, the apiserver returns a 422 HTTP
status code to indicate that the value is invalid.
A question that pops up every now and then is why we do all this stuff with virtual IPs rather than just use standard round-robin DNS. There are a few reasons:
We try to discourage users from doing things that hurt themselves. That said, if enough people ask for this, we may implement it as an alternative.
Kubernetes supports 2 primary modes of finding a Service
- environment
variables and DNS.
When a Pod
is run on a Node
, the kubelet adds a set of environment variables
for each active Service
. It supports both Docker links
compatible variables (see
makeLinkVariables)
and simpler {SVCNAME}_SERVICE_HOST
and {SVCNAME}_SERVICE_PORT
variables,
where the Service name is upper-cased and dashes are converted to underscores.
For example, the Service "redis-master"
which exposes TCP port 6379 and has been
allocated cluster IP address 10.0.0.11 produces the following environment
variables:
REDIS_MASTER_SERVICE_HOST=10.0.0.11
REDIS_MASTER_SERVICE_PORT=6379
REDIS_MASTER_PORT=tcp://10.0.0.11:6379
REDIS_MASTER_PORT_6379_TCP=tcp://10.0.0.11:6379
REDIS_MASTER_PORT_6379_TCP_PROTO=tcp
REDIS_MASTER_PORT_6379_TCP_PORT=6379
REDIS_MASTER_PORT_6379_TCP_ADDR=10.0.0.11
This does imply an ordering requirement - any Service
that a Pod
wants to
access must be created before the Pod
itself, or else the environment
variables will not be populated. DNS does not have this restriction.
An optional (though strongly recommended) cluster
add-on is a DNS server. The
DNS server watches the Kubernetes API for new Services
and creates a set of
DNS records for each. If DNS has been enabled throughout the cluster then all
Pods
should be able to do name resolution of Services
automatically.
For example, if you have a Service
called "my-service"
in Kubernetes
Namespace
"my-ns"
a DNS record for "my-service.my-ns"
is created. Pods
which exist in the "my-ns"
Namespace
should be able to find it by simply doing
a name lookup for "my-service"
. Pods
which exist in other Namespaces
must
qualify the name as "my-service.my-ns"
. The result of these name lookups is the
cluster IP.
Kubernetes also supports DNS SRV (service) records for named ports. If the
"my-service.my-ns"
Service
has a port named "http"
with protocol TCP
, you
can do a DNS SRV query for "_http._tcp.my-service.my-ns"
to discover the port
number for "http"
.
Sometimes you don’t need or want load-balancing and a single service IP. In
this case, you can create “headless” services by specifying "None"
for the
cluster IP (spec.clusterIP
).
For such Services
, a cluster IP is not allocated. DNS is configured to return
multiple A records (addresses) for the Service
name, which point directly to
the Pods
backing the Service
. Additionally, the kube proxy does not handle
these services and there is no load balancing or proxying done by the platform
for them. The endpoints controller will still create Endpoints
records in
the API.
This option allows developers to reduce coupling to the Kubernetes system, if they desire, but leaves them freedom to do discovery in their own way. Applications can still use a self-registration pattern and adapters for other discovery systems could easily be built upon this API.
For some parts of your application (e.g. frontends) you may want to expose a Service onto an external (outside of your cluster, maybe public internet) IP address, other services should be visible only from inside of the cluster.
Kubernetes ServiceTypes
allow you to specify what kind of service you want.
The default and base type is ClusterIP
, which exposes a service to connection
from inside the cluster. NodePort
and LoadBalancer
are two types that expose
services to external traffic.
Valid values for the ServiceType
field are:
ClusterIP
: use a cluster-internal IP only - this is the default and is
discussed above. Choosing this value means that you want this service to be
reachable only from inside of the cluster.NodePort
: on top of having a cluster-internal IP, expose the service on a
port on each node of the cluster (the same port on each node). You’ll be able
to contact the service on any <NodeIP>:NodePort
address.LoadBalancer
: on top of having a cluster-internal IP and exposing service
on a NodePort also, ask the cloud provider for a load balancer
which forwards to the Service
exposed as a <NodeIP>:NodePort
for each Node.If you set the type
field to "NodePort"
, the Kubernetes master will
allocate a port from a flag-configured range (default: 30000-32767), and each
Node will proxy that port (the same port number on every Node) into your Service
.
That port will be reported in your Service
’s spec.ports[*].nodePort
field.
If you want a specific port number, you can specify a value in the nodePort
field, and the system will allocate you that port or else the API transaction
will fail (i.e. you need to take care about possible port collisions yourself).
The value you specify must be in the configured range for node ports.
This gives developers the freedom to set up their own load balancers, to configure cloud environments that are not fully supported by Kubernetes, or even to just expose one or more nodes’ IPs directly.
Note that this Service will be visible as both <NodeIP>:spec.ports[*].nodePort
and spec.clusterIp:spec.ports[*].port
.
On cloud providers which support external load balancers, setting the type
field to "LoadBalancer"
will provision a load balancer for your Service
.
The actual creation of the load balancer happens asynchronously, and
information about the provisioned balancer will be published in the Service
’s
status.loadBalancer
field. For example:
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"spec": {
"selector": {
"app": "MyApp"
},
"ports": [
{
"protocol": "TCP",
"port": 80,
"targetPort": 9376,
"nodePort": 30061
}
],
"clusterIP": "10.0.171.239",
"loadBalancerIP": "78.11.24.19",
"type": "LoadBalancer"
},
"status": {
"loadBalancer": {
"ingress": [
{
"ip": "146.148.47.155"
}
]
}
}
}
Traffic from the external load balancer will be directed at the backend Pods
,
though exactly how that works depends on the cloud provider. Some cloud providers allow
the loadBalancerIP
to be specified. In those cases, the load-balancer will be created
with the user-specified loadBalancerIP
. If the loadBalancerIP
field is not specified,
an ephemeral IP will be assigned to the loadBalancer. If the loadBalancerIP
is specified, but the
cloud provider does not support the feature, the field will be ignored.
If there are external IPs that route to one or more cluster nodes, Kubernetes services can be exposed on those
externalIPs
. Traffic that ingresses into the cluster with the external IP (as destination IP), on the service port,
will be routed to one of the service endpoints. externalIPs
are not managed by Kubernetes and are the responsibility
of the cluster administrator.
In the ServiceSpec, externalIPs
can be specified along with any of the ServiceTypes
.
In the example below, my-service can be accessed by clients on 80.11.12.10:80 (externalIP:port)
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "my-service"
},
"spec": {
"selector": {
"app": "MyApp"
},
"ports": [
{
"name": "http",
"protocol": "TCP",
"port": 80,
"targetPort": 9376
}
],
"externalIPs" : [
"80.11.12.10"
]
}
}
Using the userspace proxy for VIPs will work at small to medium scale, but will not scale to very large clusters with thousands of Services. See the original design proposal for portals for more details.
Using the userspace proxy obscures the source-IP of a packet accessing a Service
.
This makes some kinds of firewalling impossible. The iptables proxier does not
obscure in-cluster source IPs, but it does still impact clients coming through
a load-balancer or node-port.
The Type
field is designed as nested functionality - each level adds to the
previous. This is not strictly required on all cloud providers (e.g. Google Compute Engine does
not need to allocate a NodePort
to make LoadBalancer
work, but AWS does)
but the current API requires it.
In the future we envision that the proxy policy can become more nuanced than
simple round robin balancing, for example master-elected or sharded. We also
envision that some Services
will have “real” load balancers, in which case the
VIP will simply transport the packets there.
We intend to improve our support for L7 (HTTP) Services
.
We intend to have more flexible ingress modes for Services
which encompass
the current ClusterIP
, NodePort
, and LoadBalancer
modes and more.
The previous information should be sufficient for many people who just want to
use Services
. However, there is a lot going on behind the scenes that may be
worth understanding.
One of the primary philosophies of Kubernetes is that users should not be exposed to situations that could cause their actions to fail through no fault of their own. In this situation, we are looking at network ports - users should not have to choose a port number if that choice might collide with another user. That is an isolation failure.
In order to allow users to choose a port number for their Services
, we must
ensure that no two Services
can collide. We do that by allocating each
Service
its own IP address.
To ensure each service receives a unique IP, an internal allocator atomically updates a global allocation map in etcd prior to each service. The map object must exist in the registry for services to get IPs, otherwise creations will fail with a message indicating an IP could not be allocated. A background controller is responsible for creating that map (to migrate from older versions of Kubernetes that used in memory locking) as well as checking for invalid assignments due to administrator intervention and cleaning up any IPs that were allocated but which no service currently uses.
Unlike Pod
IP addresses, which actually route to a fixed destination,
Service
IPs are not actually answered by a single host. Instead, we use
iptables
(packet processing logic in Linux) to define virtual IP addresses
which are transparently redirected as needed. When clients connect to the
VIP, their traffic is automatically transported to an appropriate endpoint.
The environment variables and DNS for Services
are actually populated in
terms of the Service
’s VIP and port.
We support two proxy modes - userspace and iptables, which operate slightly differently.
As an example, consider the image processing application described above.
When the backend Service
is created, the Kubernetes master assigns a virtual
IP address, for example 10.0.0.1. Assuming the Service
port is 1234, the
Service
is observed by all of the kube-proxy
instances in the cluster.
When a proxy sees a new Service
, it opens a new random port, establishes an
iptables redirect from the VIP to this new port, and starts accepting
connections on it.
When a client connects to the VIP the iptables rule kicks in, and redirects
the packets to the Service proxy
’s own port. The Service proxy
chooses a
backend, and starts proxying traffic from the client to the backend.
This means that Service
owners can choose any port they want without risk of
collision. Clients can simply connect to an IP and port, without being aware
of which Pods
they are actually accessing.
Again, consider the image processing application described above.
When the backend Service
is created, the Kubernetes master assigns a virtual
IP address, for example 10.0.0.1. Assuming the Service
port is 1234, the
Service
is observed by all of the kube-proxy
instances in the cluster.
When a proxy sees a new Service
, it installs a series of iptables rules which
redirect from the VIP to per-Service
rules. The per-Service
rules link to
per-Endpoint
rules which redirect (Destination NAT) to the backends.
When a client connects to the VIP the iptables rule kicks in. A backend is chosen (either based on session affinity or randomly) and packets are redirected to the backend. Unlike the userspace proxy, packets are never copied to userspace, the kube-proxy does not have to be running for the VIP to work, and the client IP is not altered.
This same basic flow executes when traffic comes in through a node-port or through a load-balancer, though in those cases the client IP does get altered.
Service is a top-level resource in the kubernetes REST API. More details about the API object can be found at: Service API object.
Read Service Operations.