Deploy a TiDB Cluster across Multiple Kubernetes Clusters
To deploy a TiDB cluster across multiple Kubernetes clusters refers to deploying one TiDB cluster on multiple interconnected Kubernetes clusters. Each component of the cluster is distributed on multiple Kubernetes clusters to achieve disaster recovery among Kubernetes clusters. The interconnected network of Kubernetes clusters means that Pod IP can be accessed in any cluster and between clusters, and Pod FQDN records can be looked up by querying the DNS service in any cluster and between clusters.
Prerequisites
You need to configure the Kubernetes network and DNS so that the Kubernetes cluster meets the following conditions:
- The TiDB components on each Kubernetes cluster can access the Pod IP of all TiDB components in and between clusters.
- The TiDB components on each Kubernetes cluster can look up the Pod FQDN of all TiDB components in and between clusters.
To build multiple connected EKS or GKE clusters, refer to Build Multiple Interconnected AWS EKS Clusters or Build Multiple Interconnected GCP GKE Clusters.
Supported scenarios
Currently supported scenarios:
- Deploy a new TiDB cluster across multiple Kubernetes clusters.
- Deploy new TiDB clusters that enable this feature on other Kubernetes clusters and join the initial TiDB cluster.
Experimentally supported scenarios:
- Enable this feature for a cluster that already has data. If you need to perform this action in a production environment, it is recommended to complete this requirement through data migration.
Unsupported scenarios:
- You cannot interconnect two clusters that already have data. You might perform this action through data migration.
Deploy a cluster across multiple Kubernetes clusters
Before you deploy a TiDB cluster across multiple Kubernetes clusters, you need to first deploy the Kubernetes clusters required for this operation. The following deployment assumes that you have completed Kubernetes deployment.
The following takes the deployment of one TiDB cluster across two Kubernetes clusters as an example. One TidbCluster is deployed in each Kubernetes cluster.
In the following sections, ${tc_name_1}
and ${tc_name_2}
refer to the name of TidbCluster that will be deployed in each Kubernetes cluster. ${namespace_1}
and ${namespace_2}
refer to the namespace of TidbCluster. ${cluster_domain_1}
and ${cluster_domain_2}
refer to the Cluster Domain of each Kubernetes cluster.
Step 1. Deploy the initial TidbCluster
Create and deploy the initial TidbCluster.
cat << EOF | kubectl apply -n ${namespace_1} -f -
apiVersion: pingcap.com/v1alpha1
kind: TidbCluster
metadata:
name: "${tc_name_1}"
spec:
version: v7.5.0
timezone: UTC
pvReclaimPolicy: Delete
enableDynamicConfiguration: true
configUpdateStrategy: RollingUpdate
clusterDomain: "${cluster_domain_1}"
acrossK8s: true
discovery: {}
pd:
baseImage: pingcap/pd
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config: {}
tikv:
baseImage: pingcap/tikv
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config: {}
tidb:
baseImage: pingcap/tidb
maxFailoverCount: 0
replicas: 1
service:
type: ClusterIP
config: {}
EOF
The descriptions of the related fields are as follows:
spec.acrossK8s
: Specifies whether the TiDB cluster is deployed across Kubernetes clusters. In this example, this field must be set totrue
.spec.clusterDomain
: If this field is set, the Pod FQDN which contains the cluster domain is used as the address for inter-component access.Take Pod
${tc_name}-pd-0
as an example: Pods in other Kubernetes clusters access this Pod using the${tc_name}-pd-0.${tc_name}-pd-peer.${ns}.svc.${cluster_domain}
address.If the cluster domain is required when Pods access the Pod FQDB of another Kubernetes cluster, you must set this field.
Step 2. Deploy the new TidbCluster to join the TiDB cluster
After the initial cluster completes the deployment, you can deploy the new TidbCluster to join the TiDB cluster. You can create a new TidbCluster to join any existing TidbCluster.
cat << EOF | kubectl apply -n ${namespace_2} -f -
apiVersion: pingcap.com/v1alpha1
kind: TidbCluster
metadata:
name: "${tc_name_2}"
spec:
version: v7.5.0
timezone: UTC
pvReclaimPolicy: Delete
enableDynamicConfiguration: true
configUpdateStrategy: RollingUpdate
clusterDomain: "${cluster_domain_2}"
acrossK8s: true
cluster:
name: "${tc_name_1}"
namespace: "${namespace_1}"
clusterDomain: "${cluster_domain_1}"
discovery: {}
pd:
baseImage: pingcap/pd
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config: {}
tikv:
baseImage: pingcap/tikv
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config: {}
tidb:
baseImage: pingcap/tidb
maxFailoverCount: 0
replicas: 1
service:
type: ClusterIP
config: {}
EOF
Deploy the TLS-enabled TiDB cluster across multiple Kubernetes clusters
You can follow the steps below to enable TLS between TiDB components for TiDB clusters deployed across multiple Kubernetes clusters.
The following takes the deployment of a TiDB cluster across two Kubernetes clusters as an example. One TidbCluster is deployed in each Kubernetes cluster.
In the following sections, ${tc_name_1}
and ${tc_name_2}
refer to the name of TidbCluster that will be deployed in each Kubernetes cluster. ${namespace_1}
and ${namespace_2}
refer to the namespace of TidbCluster. ${cluster_domain_1}
and ${cluster_domain_2}
refer to the Cluster Domain of each Kubernetes cluster.
Step 1. Issue the root certificate
Use cfssl
If you use cfssl
, the CA certificate issue process is the same as the general issue process. You need to save the CA certificate created for the first time, and use this CA certificate when you issue certificates for TiDB components later.
In other words, when you create a component certificate in a cluster, you do not need to create a CA certificate again. Complete step 1 ~ 4 in Enabling TLS between TiDB components once to issue the CA certificate. After that, start from step 5 to issue certificates between other cluster components.
Use cert-manager
If you use cert-manager
, you only need to create a CA Issuer
and a CA Certificate
in the initial cluster, and export the CA Secret
to other new clusters that want to join.
For other clusters, you only need to create a component certificate Issuer
(refers to ${cluster_name}-tidb-issuer
in the TLS document) and configure the Issuer
to use the CA
. The detailed process is as follows:
Create a
CA Issuer
and aCA Certificate
in the initial Kubernetes cluster.Run the following command:
cat <<EOF | kubectl apply -f - apiVersion: cert-manager.io/v1 kind: Issuer metadata: name: ${tc_name_1}-selfsigned-ca-issuer namespace: ${namespace} spec: selfSigned: {} --- apiVersion: cert-manager.io/v1 kind: Certificate metadata: name: ${tc_name_1}-ca namespace: ${namespace_1} spec: secretName: ${tc_name_1}-ca-secret commonName: "TiDB" isCA: true duration: 87600h # 10yrs renewBefore: 720h # 30d issuerRef: name: ${tc_name_1}-selfsigned-ca-issuer kind: Issuer EOFExport the CA and delete irrelevant information.
First, you need to export the
Secret
that stores the CA. The name of theSecret
can be obtained from.spec.secretName
of theCertificate
YAML file in the first step.kubectl get secret ${tc_name_1}-ca-secret -n ${namespace_1} -o yaml > ca.yamlDelete irrelevant information in the Secret YAML file. After the deletion, the YAML file is as follows (the information in
data
is omitted):apiVersion: v1 data: ca.crt: LS0...LQo= tls.crt: LS0t....LQo= tls.key: LS0t...tCg== kind: Secret metadata: name: ${tc_name_2}-ca-secret type: kubernetes.io/tlsImport the exported CA to other clusters.
You need to configure the
namespace
so that related components can access the CA certificate:kubectl apply -f ca.yaml -n ${namespace_2}Create a component certificate
Issuer
in all Kubernetes clusters and configure it to use this CA.In the initial Kubernetes cluster, create an
Issuer
that issues certificates between TiDB components.Run the following command:
cat << EOF | kubectl apply -f - apiVersion: cert-manager.io/v1 kind: Issuer metadata: name: ${tc_name_1}-tidb-issuer namespace: ${namespace_1} spec: ca: secretName: ${tc_name_1}-ca-secret EOFIn other Kubernetes clusters, create an
Issuer
that issues certificates between TiDB components.Run the following command:
cat << EOF | kubectl apply -f - apiVersion: cert-manager.io/v1 kind: Issuer metadata: name: ${tc_name_2}-tidb-issuer namespace: ${namespace_2} spec: ca: secretName: ${tc_name_2}-ca-secret EOF
Step 2. Issue certificates for the TiDB components of each Kubernetes cluster
You need to issue a component certificate for each TiDB component on the Kubernetes cluster. When issuing a component certificate, you need to add an authorization record ending with .${cluster_domain}
to the hosts, for example, the record of the initial TidbCluster is ${tc_name_1}-pd.${namespace_1}.svc.${cluster_domain_1}
.
Use the cfssl
system to issue certificates for TiDB components
The following example shows how to use cfssl
to create a certificate used by PD. Run the following command to create the pd-server.json
file for the initial TidbCluster.
cat << EOF > pd-server.json
{
"CN": "TiDB",
"hosts": [
"127.0.0.1",
"::1",
"${tc_name_1}-pd",
"${tc_name_1}-pd.${namespace_1}",
"${tc_name_1}-pd.${namespace_1}.svc",
"${tc_name_1}-pd.${namespace_1}.svc.${cluster_domain_1}",
"${tc_name_1}-pd-peer",
"${tc_name_1}-pd-peer.${namespace_1}",
"${tc_name_1}-pd-peer.${namespace_1}.svc",
"${tc_name_1}-pd-peer.${namespace_1}.svc.${cluster_domain_1}",
"*.${tc_name_1}-pd-peer",
"*.${tc_name_1}-pd-peer.${namespace_1}",
"*.${tc_name_1}-pd-peer.${namespace_1}.svc",
"*.${tc_name_1}-pd-peer.${namespace_1}.svc.${cluster_domain_1}"
],
"key": {
"algo": "ecdsa",
"size": 256
},
"names": [
{
"C": "US",
"L": "CA",
"ST": "San Francisco"
}
]
}
EOF
Use the cert-manager
system to issue certificates for TiDB components
The following example shows how to use cert-manager
to create a certificate used by PD for the initial TidbCluster. Certifcates
is shown below.
cat << EOF | kubectl apply -f -
apiVersion: cert-manager.io/v1
kind: Certificate
metadata:
name: ${tc_name_1}-pd-cluster-secret
namespace: ${namespace_1}
spec:
secretName: ${tc_name_1}-pd-cluster-secret
duration: 8760h # 365d
renewBefore: 360h # 15d
subject:
organizations:
- PingCAP
commonName: "TiDB"
usages:
- server auth
- client auth
dnsNames:
- "${tc_name_1}-pd"
- "${tc_name_1}-pd.${namespace_1}"
- "${tc_name_1}-pd.${namespace_1}.svc"
- "${tc_name_1}-pd.${namespace_1}.svc.${cluster_domain_1}"
- "${tc_name_1}-pd-peer"
- "${tc_name_1}-pd-peer.${namespace_1}"
- "${tc_name_1}-pd-peer.${namespace_1}.svc"
- "${tc_name_1}-pd-peer.${namespace_1}.svc.${cluster_domain_1}"
- "*.${tc_name_1}-pd-peer"
- "*.${tc_name_1}-pd-peer.${namespace_1}"
- "*.${tc_name_1}-pd-peer.${namespace_1}.svc"
- "*.${tc_name_1}-pd-peer.${namespace_1}.svc.${cluster_domain_1}"
ipAddresses:
- 127.0.0.1
- ::1
issuerRef:
name: ${tc_name_1}-tidb-issuer
kind: Issuer
group: cert-manager.io
EOF
You need to refer to the TLS-related documents, issue the corresponding certificates for the components, and create the Secret
in the corresponding Kubernetes clusters.
For other TLS-related information, refer to the following documents:
Step 3. Deploy the initial TidbCluster
Run the following commands to deploy the initial TidbCluster. The following YAML
file enables the TLS feature and configures cert-allowed-cn
, which makes each component start to verify the certificates issued by the CN
for the CA
of TiDB
.
cat << EOF | kubectl apply -n ${namespace_1} -f -
apiVersion: pingcap.com/v1alpha1
kind: TidbCluster
metadata:
name: "${tc_name_1}"
spec:
version: v7.5.0
timezone: UTC
tlsCluster:
enabled: true
pvReclaimPolicy: Delete
enableDynamicConfiguration: true
configUpdateStrategy: RollingUpdate
clusterDomain: "${cluster_domain_1}"
acrossK8s: true
discovery: {}
pd:
baseImage: pingcap/pd
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config:
security:
cert-allowed-cn:
- TiDB
tikv:
baseImage: pingcap/tikv
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config:
security:
cert-allowed-cn:
- TiDB
tidb:
baseImage: pingcap/tidb
maxFailoverCount: 0
replicas: 1
service:
type: ClusterIP
tlsClient:
enabled: true
config:
security:
cert-allowed-cn:
- TiDB
EOF
Step 4. Deploy a new TidbCluster to join the TiDB cluster
After the initial cluster completes the deployment, you can deploy the new TidbCluster to join the TiDB cluster. You can create a new TidbCluster to join any existing TidbCluster.
cat << EOF | kubectl apply -n ${namespace_2} -f -
apiVersion: pingcap.com/v1alpha1
kind: TidbCluster
metadata:
name: "${tc_name_2}"
spec:
version: v7.5.0
timezone: UTC
tlsCluster:
enabled: true
pvReclaimPolicy: Delete
enableDynamicConfiguration: true
configUpdateStrategy: RollingUpdate
clusterDomain: "${cluster_domain_2}"
acrossK8s: true
cluster:
name: "${tc_name_1}"
namespace: "${namespace_1}"
clusterDomain: "${cluster_domain_1}"
discovery: {}
pd:
baseImage: pingcap/pd
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config:
security:
cert-allowed-cn:
- TiDB
tikv:
baseImage: pingcap/tikv
maxFailoverCount: 0
replicas: 1
requests:
storage: "10Gi"
config:
security:
cert-allowed-cn:
- TiDB
tidb:
baseImage: pingcap/tidb
maxFailoverCount: 0
replicas: 1
service:
type: ClusterIP
tlsClient:
enabled: true
config:
security:
cert-allowed-cn:
- TiDB
EOF
Upgrade TiDB Cluster
For a TiDB cluster deployed across Kubernetes clusters, to perform a rolling upgrade for each component Pod of the TiDB cluster, take the following steps in sequence to modify the version
configuration of each component in the TidbCluster spec for each Kubernetes cluster.
Upgrade PD versions for all Kubernetes clusters.
Modify the
spec.pd.version
field in the spec for the initial TidbCluster.apiVersion: pingcap.com/v1alpha1 kind: TidbCluster # ... spec: pd: version: ${version}Watch the status of PD Pods and wait for PD Pods in the initial TidbCluster to finish recreation and become
Running
.Repeat the first two substeps to upgrade all PD Pods in other TidbCluster.
Take step 1 as an example, perform the following upgrade operations in sequence:
- If TiFlash is deployed in clusters, upgrade the TiFlash versions for all the Kubernetes clusters that have TiFlash deployed.
- Upgrade TiKV versions for all Kubernetes clusters.
- If Pump is deployed in clusters, upgrade the Pump versions for all the Kubernetes clusters that have Pump deployed.
- Upgrade TiDB versions for all Kubernetes clusters.
- If TiCDC is deployed in clusters, upgrade the TiCDC versions for all the Kubernetes clusters that have TiCDC deployed.
Exit and reclaim TidbCluster that already join a cross-Kubernetes cluster
When you need to make a cluster exit from the joined TiDB cluster deployed across Kubernetes and reclaim resources, you can perform the operation by scaling in the cluster. In this scenario, the following requirements of scaling-in need to be met.
- After scaling in the cluster, the number of TiKV replicas in the cluster should be greater than the number of
max-replicas
set in PD. By default, the number of TiKV replicas needs to be greater than three.
Take the second TidbCluster created in the last section as an example. First, set the number of replicas of PD, TiKV, and TiDB to 0
. If you have enabled other components such as TiFlash, TiCDC, and Pump, set the number of these replicas to 0
:
kubectl patch tc ${tc_name_2} -n ${namespace_2} --type merge -p '{"spec":{"pd":{"replicas":0},"tikv":{"replicas":0},"tidb":{"replicas":0}}}'
Wait for the status of the second TidbCluster to become Ready
, and scale in related components to 0
replica:
kubectl get pods -l app.kubernetes.io/instance=${tc_name_2} -n ${namespace_2}
The Pod list shows No resources found
. At this time, all Pods have been scaled in, and the second TidbCluster exits the cluster. Check the cluster status of the second TidbCluster:
kubectl get tc ${tc_name_2} -n ${namespace_2}
The result shows that the second TidbCluster is in the Ready
status. At this time, you can delete the object and reclaim related resources.
kubectl delete tc ${tc_name_2} -n ${namespace_2}
Through the above steps, you can complete exit and resources reclaim of the joined clusters.
Enable the feature for a cluster with existing data and make it the initial TiDB cluster
A cluster with existing data refer to a deployed TiDB cluster with the configuration spec.acrossK8s: false
.
Depending on the network between multiple Kubernetes clusters, there are different methods.
If all Kubernetes have the same Cluster Domain, you only need to update the spec.crossK8s
configuration of TidbCluster. Run the following command:
kubectl patch tidbcluster cluster1 --type merge -p '{"spec":{"acrossK8s": true}}'
After the modification, wait for the TiDB cluster to complete rolling update.
If each Kubernetes have different Cluster Domain, you need to update the spec.clusterDomain
and spec.acrossK8s
fields. Take the following steps:
Update the
spec.clusterDomain
andspec.acrossK8s
fields:Configure the following parameters according to the
clusterDomain
in your Kubernetes cluster information:kubectl patch tidbcluster cluster1 --type merge -p '{"spec":{"clusterDomain":"cluster1.com", "acrossK8s": true}}'After completing the modification, the TiDB cluster performs the rolling update.
Update the
PeerURL
information of PD:After completing the rolling update, you need to use
port-forward
to expose PD's API, and use API of PD to updatePeerURL
of PD.Use
port-forward
to expose API of PD:kubectl port-forward pods/cluster1-pd-0 2380:2380 2379:2379 -n pingcapAccess
PD API
to obtainmembers
information. Note that after usingport-forward
, the terminal session is occupied. You need to perform the following operations in another terminal session:curl http://127.0.0.1:2379/v2/membersAfter running the command, the output is as follows:
{"members":[{"id":"6ed0312dc663b885","name":"cluster1-pd-0.cluster1-pd-peer.pingcap.svc.cluster1.com","peerURLs":["http://cluster1-pd-0.cluster1-pd-peer.pingcap.svc:2380"],"clientURLs":["http://cluster1-pd-0.cluster1-pd-peer.pingcap.svc.cluster1.com:2379"]},{"id":"bd9acd3d57e24a32","name":"cluster1-pd-1.cluster1-pd-peer.pingcap.svc.cluster1.com","peerURLs":["http://cluster1-pd-1.cluster1-pd-peer.pingcap.svc:2380"],"clientURLs":["http://cluster1-pd-1.cluster1-pd-peer.pingcap.svc.cluster1.com:2379"]},{"id":"e04e42cccef60246","name":"cluster1-pd-2.cluster1-pd-peer.pingcap.svc.cluster1.com","peerURLs":["http://cluster1-pd-2.cluster1-pd-peer.pingcap.svc:2380"],"clientURLs":["http://cluster1-pd-2.cluster1-pd-peer.pingcap.svc.cluster1.com:2379"]}]}Record the
id
of each PD instance, and use theid
to update thepeerURL
of each member in turn:member_ID="6ed0312dc663b885" member_peer_url="http://cluster1-pd-0.cluster1-pd-peer.pingcap.svc.cluster1.com:2380" curl http://127.0.0.1:2379/v2/members/${member_ID} -XPUT \ -H "Content-Type: application/json" -d '{"peerURLs":["${member_peer_url}"]}'
After completing the above steps, this TidbCluster can be used as the initial TidbCluster for TiDB cluster deployment across Kubernetes clusters. You can refer the section to deploy other TidbCluster.
For more examples and development information, refer to multi-cluster
.
Deploy TiDB monitoring components
Refer to Deploy TiDB Monitor across Multiple Kubernetes Clusters.