This page explains how to configure your DNS Pod and customize the DNS resolution process. In Kubernetes version 1.11 and later, CoreDNS is at GA and is installed by default with kubeadm. See CoreDNS ConfigMap options and Using CoreDNS for Service Discovery.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. If you do not already have a cluster, you can create one by using Minikube, or you can use one of these Kubernetes playgrounds:
To check the version, enter kubectl version
.
DNS is a built-in Kubernetes service launched automatically using the addon manager cluster add-on.
As of Kubernetes v1.12, CoreDNS is the recommended DNS Server, replacing kube-dns. However, kube-dns may still be installed by default with certain Kubernetes installer tools. Refer to the documentation provided by your installer to know which DNS server is installed by default.
The CoreDNS Deployment is exposed as a Kubernetes Service with a static IP.
Both the CoreDNS and kube-dns Service are named kube-dns
in the metadata.name
field. This is done so that there is greater interoperability with workloads that relied on the legacy kube-dns
Service name to resolve addresses internal to the cluster. It abstracts away the implementation detail of which DNS provider is running behind that common endpoint.
The kubelet passes DNS to each container with the --cluster-dns=<dns-service-ip>
flag.
DNS names also need domains. You configure the local domain in the kubelet
with the flag --cluster-domain=<default-local-domain>
.
The DNS server supports forward lookups (A records), port lookups (SRV records), reverse IP address lookups (PTR records), and more. For more information see DNS for Services and Pods.
If a Pod’s dnsPolicy
is set to “default
”, it inherits the name resolution
configuration from the node that the Pod runs on. The Pod’s DNS resolution
should behave the same as the node.
But see Known issues.
If you don’t want this, or if you want a different DNS config for pods, you can
use the kubelet’s --resolv-conf
flag. Set this flag to “” to prevent Pods from
inheriting DNS. Set it to a valid file path to specify a file other than
/etc/resolv.conf
for DNS inheritance.
CoreDNS is a general-purpose authoritative DNS server that can serve as cluster DNS, complying with the dns specifications.
CoreDNS is a DNS server that is modular and pluggable, and each plugin adds new functionality to CoreDNS. This can be configured by maintaining a Corefile, which is the CoreDNS configuration file. A cluster administrator can modify the ConfigMap for the CoreDNS Corefile to change how service discovery works.
In Kubernetes, CoreDNS is installed with the following default Corefile configuration.
apiVersion: v1
kind: ConfigMap
metadata:
name: coredns
namespace: kube-system
data:
Corefile: |
.:53 {
errors
health
kubernetes cluster.local in-addr.arpa ip6.arpa {
pods insecure
fallthrough in-addr.arpa ip6.arpa
}
prometheus :9153
forward . /etc/resolv.conf
cache 30
loop
reload
loadbalance
}
The Corefile configuration includes the following plugins of CoreDNS:
The
pods insecure
option is provided for backward compatibility with kube-dns. You can use thepods verified
option, which returns an A record only if there exists a pod in same namespace with matching IP. Thepods disabled
option can be used if you don’t use pod records.
You can modify the default CoreDNS behavior by modifying the ConfigMap.
CoreDNS has the ability to configure stubdomains and upstream nameservers using the forward plugin.
If a cluster operator has a Consul domain server located at 10.150.0.1, and all Consul names have the suffix .consul.local. To configure it in CoreDNS, the cluster administrator creates the following stanza in the CoreDNS ConfigMap.
consul.local:53 {
errors
cache 30
forward . 10.150.0.1
}
To explicitly force all non-cluster DNS lookups to go through a specific nameserver at 172.16.0.1, point the forward
to the nameserver instead of /etc/resolv.conf
forward . 172.16.0.1
The final ConfigMap along with the default Corefile
configuration looks like:
apiVersion: v1
kind: ConfigMap
metadata:
name: coredns
namespace: kube-system
data:
Corefile: |
.:53 {
errors
health
kubernetes cluster.local in-addr.arpa ip6.arpa {
pods insecure
fallthrough in-addr.arpa ip6.arpa
}
prometheus :9153
forward . 172.16.0.1
cache 30
loop
reload
loadbalance
}
consul.local:53 {
errors
cache 30
forward . 10.150.0.1
}
In Kubernetes version 1.10 and later, kubeadm supports automatic translation of the CoreDNS ConfigMap from the kube-dns ConfigMap. Note: While kube-dns accepts an FQDN for stubdomain and nameserver (eg: ns.foo.com), CoreDNS does not support this feature. During translation, all FQDN nameservers will be omitted from the CoreDNS config.
Kube-dns is now available as an optional DNS server since CoreDNS is now the default. The running DNS Pod holds 3 containers:
kubedns
“: watches the Kubernetes master for changes
in Services and Endpoints, and maintains in-memory lookup structures to serve
DNS requests.dnsmasq
“: adds DNS caching to improve performance.sidecar
“: provides a single health check endpoint
to perform healthchecks for dnsmasq
and kubedns
.Cluster administrators can specify custom stub domains and upstream nameservers
by providing a ConfigMap for kube-dns (kube-system:kube-dns
).
For example, the following ConfigMap sets up a DNS configuration with a single stub domain and two upstream nameservers:
apiVersion: v1
kind: ConfigMap
metadata:
name: kube-dns
namespace: kube-system
data:
stubDomains: |
{"acme.local": ["1.2.3.4"]}
upstreamNameservers: |
["8.8.8.8", "8.8.4.4"]
DNS requests with the “.acme.local” suffix are forwarded to a DNS listening at 1.2.3.4. Google Public DNS serves the upstream queries.
The table below describes how queries with certain domain names map to their destination DNS servers:
Domain name | Server answering the query |
---|---|
kubernetes.default.svc.cluster.local | kube-dns |
foo.acme.local | custom DNS (1.2.3.4) |
widget.com | upstream DNS (one of 8.8.8.8, 8.8.4.4) |
See ConfigMap options for details about the configuration option format.
Custom upstream nameservers and stub domains do not affect Pods with a
dnsPolicy
set to “Default
” or “None
”.
If a Pod’s dnsPolicy
is set to “ClusterFirst
”, its name resolution is
handled differently, depending on whether stub-domain and upstream DNS servers
are configured.
Without custom configurations: Any query that does not match the configured cluster domain suffix, such as “www.kubernetes.io”, is forwarded to the upstream nameserver inherited from the node.
With custom configurations: If stub domains and upstream DNS servers are configured, DNS queries are routed according to the following flow:
The query is first sent to the DNS caching layer in kube-dns.
From the caching layer, the suffix of the request is examined and then forwarded to the appropriate DNS, based on the following cases:
Names with the cluster suffix, for example “.cluster.local”: The request is sent to kube-dns.
Names with the stub domain suffix, for example “.acme.local”: The request is sent to the configured custom DNS resolver, listening for example at 1.2.3.4.
Names without a matching suffix, for example “widget.com”: The request is forwarded to the upstream DNS, for example Google public DNS servers at 8.8.8.8 and 8.8.4.4.
Options for the kube-dns kube-system:kube-dns
ConfigMap:
Field | Format | Description |
---|---|---|
stubDomains (optional) |
A JSON map using a DNS suffix key such as “acme.local”, and a value consisting of a JSON array of DNS IPs. | The target nameserver can itself be a Kubernetes Service. For instance, you can run your own copy of dnsmasq to export custom DNS names into the ClusterDNS namespace. |
upstreamNameservers (optional) |
A JSON array of DNS IPs. | If specified, the values replace the nameservers taken by default from the node’s /etc/resolv.conf . Limits: a maximum of three upstream nameservers can be specified. |
In this example, the user has a Consul DNS service discovery system they want to
integrate with kube-dns. The consul domain server is located at 10.150.0.1, and
all consul names have the suffix .consul.local
. To configure Kubernetes, the
cluster administrator creates the following ConfigMap:
apiVersion: v1
kind: ConfigMap
metadata:
name: kube-dns
namespace: kube-system
data:
stubDomains: |
{"consul.local": ["10.150.0.1"]}
Note that the cluster administrator does not want to override the node’s
upstream nameservers, so they did not specify the optional
upstreamNameservers
field.
In this example the cluster administrator wants to explicitly force all
non-cluster DNS lookups to go through their own nameserver at 172.16.0.1.
In this case, they create a ConfigMap with the
upstreamNameservers
field specifying the desired nameserver:
apiVersion: v1
kind: ConfigMap
metadata:
name: kube-dns
namespace: kube-system
data:
upstreamNameservers: |
["172.16.0.1"]
CoreDNS supports the features of kube-dns and more.
A ConfigMap created for kube-dns to support StubDomains
and upstreamNameservers
translates to the forward
plugin in CoreDNS.
Similarly, the Federations
plugin in kube-dns translates to the federation
plugin in CoreDNS.
This example ConfigMap for kubedns specifies federations, stubdomains and upstreamnameservers:
apiVersion: v1
data:
federations: |
{"foo" : "foo.feddomain.com"}
stubDomains: |
{"abc.com" : ["1.2.3.4"], "my.cluster.local" : ["2.3.4.5"]}
upstreamNameservers: |
["8.8.8.8", "8.8.4.4"]
kind: ConfigMap
The equivalent configuration in CoreDNS creates a Corefile:
For federations:
federation cluster.local {
foo foo.feddomain.com
}
For stubDomains:
abc.com:53 {
errors
cache 30
forward . 1.2.3.4
}
my.cluster.local:53 {
errors
cache 30
forward . 2.3.4.5
}
The complete Corefile with the default plugins:
.:53 {
errors
health
kubernetes cluster.local in-addr.arpa ip6.arpa {
pods insecure
fallthrough in-addr.arpa ip6.arpa
}
federation cluster.local {
foo foo.feddomain.com
}
prometheus :9153
forward . 8.8.8.8 8.8.4.4
cache 30
}
abc.com:53 {
errors
cache 30
forward . 1.2.3.4
}
my.cluster.local:53 {
errors
cache 30
forward . 2.3.4.5
}
To migrate from kube-dns to CoreDNS, a detailed blog is available to help users adapt CoreDNS in place of kube-dns. A cluster administrator can also migrate using the deploy script.
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