kubernetes之StorageClass+NFS详解
1.什么是StorageClass
Kubernetes提供了一套可以自动创建PV的机制,即:Dynamic Provisioning.而这个机制的核心在于:StorageClass这个API对象. StorageClass对象会定义下面两部分内容: 1,PV的属性.比如,存储类型,Volume的大小等. 2,创建这种PV需要用到的存储插件 有了这两个信息之后,Kubernetes就能够根据用户提交的PVC,找到一个对应的StorageClass,之后Kubernetes就会调用该StorageClass声明的存储插件,进而创建出需要的PV. 但是其实使用起来是一件很简单的事情,你只需要根据自己的需求,编写YAML文件即可,然后使用kubectl create命令执行即可
2.为什么需要StorageClass
在一个大规模的Kubernetes集群里,可能有成千上万个PVC,这就意味着运维人员必须实现创建出这个多个PV,此外,随着项目的需要,会有新的PVC不断被提交,那么运维人员就需要不断的添加新的,满足要求的PV,否则新的Pod就会因为PVC绑定不到PV而导致创建失败.而且通过 PVC 请求到一定的存储空间也很有可能不足以满足应用对于存储设备的各种需求
而且不同的应用程序对于存储性能的要求可能也不尽相同,比如读写速度、并发性能等,为了解决这一问题,Kubernetes 又为我们引入了一个新的资源对象:StorageClass,通过 StorageClass 的定义,管理员可以将存储资源定义为某种类型的资源,比如快速存储、慢速存储等,用户根据 StorageClass 的描述就可以非常直观的知道各种存储资源的具体特性了,这样就可以根据应用的特性去申请合适的存储资源了。
3.StorageClass运行原理及部署流程
要使用 StorageClass,我们就得安装对应的自动配置程序,比如我们这里存储后端使用的是 nfs,那么我们就需要使用到一个 nfs-client 的自动配置程序,我们也叫它 Provisioner,这个程序使用我们已经配置好的 nfs 服务器,来自动创建持久卷,也就是自动帮我们创建 PV。
1.自动创建的 PV 以${namespace}-${pvcName}-${pvName}这样的命名格式创建在 NFS 服务器上的共享数据目录中
2.而当这个 PV 被回收后会以archieved-${namespace}-${pvcName}-${pvName}这样的命名格式存在 NFS 服务器上。
1)详细的运作流程可以参考下图:
2)搭建StorageClass+NFS,大致有以下几个步骤:
1.创建一个可用的NFS Serve
2.创建Service Account.这是用来管控NFS provisioner在k8s集群中运行的权限
3.创建StorageClass.负责建立PVC并调用NFS provisioner进行预定的工作,并让PV与PVC建立管理
4.创建NFS provisioner.有两个功能,一个是在NFS共享目录下创建挂载点(volume),另一个则是建了PV并将PV与NFS的挂载点建立关联
4.创建StorageClass
4.1创建NFS共享服务
该步骤比较简单不在赘述,大家可以自行百度搭建,当前环境NFS server及共享目录信息
IP: 10.3.104.51
Export PATH: /data/volumes/
4.2使用以下文档配置account及相关权限
1)rbac.yaml: #唯一需要修改的地方只有namespace,根据实际情况定义
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat rbac.yaml apiVersion: v1 kind: ServiceAccount metadata: name: nfs-client-provisioner namespace: default #根据实际环境设定namespace,下面类同 --- kind: ClusterRole apiVersion: rbac.authorization.k8s.io/v1 metadata: name: nfs-client-provisioner-runner rules: - apiGroups: [""] resources: ["persistentvolumes"] verbs: ["get", "list", "watch", "create", "delete"] - apiGroups: [""] resources: ["persistentvolumeclaims"] verbs: ["get", "list", "watch", "update"] - apiGroups: ["storage.k8s.io"] resources: ["storageclasses"] verbs: ["get", "list", "watch"] - apiGroups: [""] resources: ["events"] verbs: ["create", "update", "patch"] --- kind: ClusterRoleBinding apiVersion: rbac.authorization.k8s.io/v1 metadata: name: run-nfs-client-provisioner subjects: - kind: ServiceAccount name: nfs-client-provisioner namespace: default roleRef: kind: ClusterRole name: nfs-client-provisioner-runner apiGroup: rbac.authorization.k8s.io --- kind: Role apiVersion: rbac.authorization.k8s.io/v1 metadata: name: leader-locking-nfs-client-provisioner namespace: default rules: - apiGroups: [""] resources: ["endpoints"] verbs: ["get", "list", "watch", "create", "update", "patch"] --- kind: RoleBinding apiVersion: rbac.authorization.k8s.io/v1 metadata: name: leader-locking-nfs-client-provisioner subjects: - kind: ServiceAccount name: nfs-client-provisioner namespace: default roleRef: kind: Role name: leader-locking-nfs-client-provisioner apiGroup: rbac.authorization.k8s.io
2)创建rbac
[root@k8s-master storageclass]# kubectl apply -f rbac.yaml serviceaccount/nfs-client-provisioner created clusterrole.rbac.authorization.k8s.io/nfs-client-provisioner-runner created clusterrolebinding.rbac.authorization.k8s.io/run-nfs-client-provisioner created role.rbac.authorization.k8s.io/leader-locking-nfs-client-provisioner created rolebinding.rbac.authorization.k8s.io/leader-locking-nfs-client-provisioner created [root@k8s-master storageclass]# kubectl get role,rolebinding NAME CREATED AT role.rbac.authorization.k8s.io/leader-locking-nfs-client-provisioner 2021-09-14T03:15:03Z NAME ROLE AGE rolebinding.rbac.authorization.k8s.io/leader-locking-nfs-client-provisioner Role/leader-locking-nfs-client-provisioner 5m36s
4.3创建NFS资源的StorageClass
1)nfs-StorageClass.yaml
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat nfs-StorageClass.yaml apiVersion: storage.k8s.io/v1 kind: StorageClass metadata: name: managed-nfs-storage provisioner: wxc-nfs-storage #这里的名称要和provisioner配置文件中的环境变量PROVISIONER_NAME保持一致 parameters: archiveOnDelete: "false"
2)创建nfs-StorageClass
[root@k8s-master storageclass]# kubectl apply -f nfs-StorageClass.yaml storageclass.storage.k8s.io/managed-nfs-storage created [root@k8s-master storageclass]# kubectl get sc NAME PROVISIONER RECLAIMPOLICY VOLUMEBINDINGMODE ALLOWVOLUMEEXPANSION AGE managed-nfs-storage wxc-nfs-storage Delete Immediate false 8s
4.4创建NFS provisioner
1)nfs-provisioner.yaml
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat nfs-provisioner.yaml apiVersion: apps/v1 kind: Deployment metadata: name: nfs-client-provisioner labels: app: nfs-client-provisioner namespace: default #与RBAC文件中的namespace保持一致 spec: replicas: 1 selector: matchLabels: app: nfs-client-provisioner strategy: type: Recreate selector: matchLabels: app: nfs-client-provisioner template: metadata: labels: app: nfs-client-provisioner spec: serviceAccountName: nfs-client-provisioner containers: - name: nfs-client-provisioner image: quay.io/external_storage/nfs-client-provisioner:latest volumeMounts: - name: nfs-client-root mountPath: /persistentvolumes env: - name: PROVISIONER_NAME value: wxc-nfs-storage #provisioner名称,请确保该名称与 nfs-StorageClass.yaml文件中的provisioner名称保持一致 - name: NFS_SERVER value: 10.3.104.51 #NFS Server IP地址 - name: NFS_PATH value: /nfsdata/volumes #NFS挂载卷 volumes: - name: nfs-client-root nfs: server: 10.3.104.51 #NFS Server IP地址 path: /nfsdata/volumes #NFS 挂载卷
2)创建nfs-provisioner
[root@k8s-master storageclass]# kubectl apply -f nfs-provisioner.yaml deployment.apps/nfs-client-provisioner created [root@k8s-master storageclass]# kubectl get deploy NAME READY UP-TO-DATE AVAILABLE AGE nfs-client-provisioner 1/1 1 1 11s [root@k8s-master storageclass]# kubectl get pods NAME READY STATUS RESTARTS AGE nfs-client-provisioner-677fc9c97c-9cj92 1/1 Running 0 18s
5.创建测试pod,检查是否部署成功
5.1创建Pod+PVC
1)test-claim.yaml
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat test-claim.yaml kind: PersistentVolumeClaim apiVersion: v1 metadata: name: test-claim annotations: volume.beta.kubernetes.io/storage-class: "managed-nfs-storage" #与nfs-StorageClass.yaml metadata.name保持一致,关联storageclass进行后续动态撞见PV spec: accessModes: - ReadWriteMany resources: requests: storage: 1Mi [root@k8s-master storageclass]# kubectl apply -f test-claim.yaml persistentvolumeclaim/test-claim created
2)确保PVC状态为Bound(默认自动创建PV且Bound状态)
[root@k8s-master storageclass]# kubectl get pvc NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE test-claim Bound pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92 1Mi RWX managed-nfs-storage 8s [root@k8s-master storageclass]# kubectl get pv NAME CAPACITY ACCESS MODES RECLAIM POLICY STATUS CLAIM STORAGECLASS REASON AGE pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92 1Mi RWX Delete Bound default/test-claim managed-nfs-storage 18s
3)创建测试pod,查看是否可以正常挂载
test-pod.yaml
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat test-pod.yaml kind: Pod apiVersion: v1 metadata: name: test-pod spec: containers: - name: test-pod image: busybox:1.24 command: - "/bin/sh" args: - "-c" - "touch /mnt/SUCCESS && exit 0 || exit 1" #创建一个SUCCESS文件后退出 volumeMounts: - name: nfs-pvc mountPath: "/mnt" restartPolicy: "Never" volumes: - name: nfs-pvc persistentVolumeClaim: claimName: test-claim #与PVC名称保持一致 [root@k8s-master storageclass]# kubectl apply -f test-pod.yaml pod/test-pod created
4)检查结果
[root@k8s-master storageclass]# ll /nfsdata/volumes/default-test-claim-pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92/ #文件规则是按照${namespace}-${pvcName}-${pvName}创建的
total 0
-rw-r--r-- 1 nfsnobody nfsnobody 0 Sep 14 11:34 SUCCESS #下面有一个 SUCCESS 的文件,证明我们上面的验证是成功
5.2StateFulDet+volumeClaimTemplates自动创建PV
1)创建无头服务及statefulset
nginx-statefulset.yaml
[root@k8s-master storageclass]# pwd /root/k8s_practice/storageclass [root@k8s-master storageclass]# cat nginx-statefulset.yaml apiVersion: v1 kind: Service metadata: name: nginx-headless labels: app: nginx spec: ports: - port: 80 name: web clusterIP: None #注意此处的值,None表示无头服务 selector: app: nginx --- apiVersion: apps/v1beta1 kind: StatefulSet metadata: name: web spec: serviceName: "nginx-headless" #与service名称保持一致 replicas: 2 #两个副本 template: metadata: labels: app: nginx spec: containers: - name: nginx image: ikubernetes/myapp:v1 ports: - containerPort: 80 name: web volumeMounts: - name: www mountPath: /usr/share/nginx/html volumeClaimTemplates: - metadata: name: www annotations: volume.beta.kubernetes.io/storage-class: "managed-nfs-storage" #managed-nfs-storage为我们创建的storage-class名称 spec: accessModes: [ "ReadWriteOnce" ] resources: requests: storage: 1Gi
2)检查结果
集群节点上
[root@k8s-master storageclass]# kubectl get pod -l app=nginx NAME READY STATUS RESTARTS AGE web-0 1/1 Running 0 19s web-1 0/1 ContainerCreating 0 12s [root@k8s-master storageclass]# kubectl get pvc NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE test-claim Bound pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92 1Mi RWX managed-nfs-storage 148m www-web-0 Bound pvc-5c8e5883-3d67-43f7-b63c-b7e76f02fb2b 1Gi RWO managed-nfs-storage 34s www-web-1 Bound pvc-67780cda-dd3b-4f3c-9802-0dedc45d57f3 1Gi RWO managed-nfs-storage 27s [root@k8s-master storageclass]# kubectl get pv NAME CAPACITY ACCESS MODES RECLAIM POLICY STATUS CLAIM STORAGECLASS REASON AGE pvc-5c8e5883-3d67-43f7-b63c-b7e76f02fb2b 1Gi RWO Delete Bound default/www-web-0 managed-nfs-storage 38s pvc-67780cda-dd3b-4f3c-9802-0dedc45d57f3 1Gi RWO Delete Bound default/www-web-1 managed-nfs-storage 31s pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92 1Mi RWX Delete Bound default/test-claim managed-nfs-storage 148m
3)NFS Server上:
[root@k8s-master storageclass]# cd /nfsdata/volumes/ [root@k8s-master volumes]# ll total 12 drwxrwxrwx 2 nfsnobody nfsnobody 4096 Sep 14 11:34 default-test-claim-pvc-f2aa9a85-dcff-49d0-a0a8-549e2d8c9f92 drwxrwxrwx 2 nfsnobody nfsnobody 4096 Sep 14 13:56 default-www-web-0-pvc-5c8e5883-3d67-43f7-b63c-b7e76f02fb2b drwxrwxrwx 2 nfsnobody nfsnobody 4096 Sep 14 13:56 default-www-web-1-pvc-67780cda-dd3b-4f3c-9802-0dedc45d57f3 [root@k8s-master volumes]# echo "web-00" > default-www-web-0-pvc-5c8e5883-3d67-43f7-b63c-b7e76f02fb2b/index.html [root@k8s-master volumes]# echo "web-01" > default-www-web-1-pvc-67780cda-dd3b-4f3c-9802-0dedc45d57f3/index.html
4)集群任意节点上:
[root@k8s-master volumes]# kubectl get pod -o wide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES nfs-client-provisioner-677fc9c97c-9cj92 1/1 Running 0 156m 10.244.1.18 k8s-node1 <none> <none> recycler-for-pv-nfs2 0/1 Completed 0 4d22h 10.244.2.11 k8s-node2 <none> <none> recycler-for-pv-nfs6 0/1 Completed 0 4d22h 10.244.1.16 k8s-node1 <none> <none> test-pod 0/1 Completed 0 148m 10.244.2.13 k8s-node2 <none> <none> web-0 1/1 Running 0 6m14s 10.244.2.14 k8s-node2 <none> <none> web-1 1/1 Running 0 6m7s 10.244.1.19 k8s-node1 <none> <none> [root@k8s-master volumes]# kubectl get svc -o wide NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE SELECTOR kubernetes ClusterIP 10.96.0.1 <none> 443/TCP 7d2h <none> nginx-headless ClusterIP None <none> 80/TCP 6m25s app=nginx [root@k8s-master volumes]# kubectl exec -it nfs-client-provisioner-677fc9c97c-9cj92 sh #进入集群中任意pod中,解析nginx-headless 服务 kubectl exec [POD] [COMMAND] is DEPRECATED and will be removed in a future version. Use kubectl exec [POD] -- [COMMAND] instead. / # nslookup nginx-headless nslookup: can't resolve '(null)': Name does not resolve Name: nginx-headless Address 1: 10.244.1.19 web-0.nginx-headless.default.svc.cluster.local #可以看到有两个地址 Address 2: 10.244.2.14 web-1.nginx-headless.default.svc.cluster.local [root@k8s-master volumes]# curl 10.244.2.14 web-00 [root@k8s-master volumes]# curl 10.244.1.19 web-01
#对于statefulset我们可以通过添加/删除pod副本的数量,观察PV/PVC的状态及变化.
6.关于StorageClass回收策略对数据的影响
6.1第一种配置
archiveOnDelete: "false" reclaimPolicy: Delete #默认没有配置,默认值为Delete
测试结果:
1.pod删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 2.sc删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 3.删除PVC后,PV被删除且NFS Server对应数据被删除
6.2第二种配置
archiveOnDelete: "false" reclaimPolicy: Retain
测试结果:
1.pod删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 2.sc删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 3.删除PVC后,PV不会别删除,且状态由Bound变为Released,NFS Server对应数据被保留 4.重建sc后,新建PVC会绑定新的pv,旧数据可以通过拷贝到新的PV中
6.3第三种配置
archiveOnDelete: "ture" reclaimPolicy: Retain
结果:
1.pod删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 2.sc删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 3.删除PVC后,PV不会别删除,且状态由Bound变为Released,NFS Server对应数据被保留 4.重建sc后,新建PVC会绑定新的pv,旧数据可以通过拷贝到新的PV中
6.4第四种配置
archiveOnDelete: "ture" reclaimPolicy: Delete
结果:
1.pod删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 2.sc删除重建后数据依然存在,旧pod名称及数据依然保留给新pod使用 3.删除PVC后,PV不会别删除,且状态由Bound变为Released,NFS Server对应数据被保留 4.重建sc后,新建PVC会绑定新的pv,旧数据可以通过拷贝到新的PV中
总结:除以第一种配置外,其他三种配置在PV/PVC被删除后数据依然保留
7.常见问题
7.1如何设置默认的StorageClass
1)命令kubectl patch 来更新:
#查看当前sc [root@k8s-master storageclass]# kubectl get sc NAME PROVISIONER RECLAIMPOLICY VOLUMEBINDINGMODE ALLOWVOLUMEEXPANSION AGE managed-nfs-storage wxc-nfs-storage Delete Immediate false 171m #设置managed-nfs-storage为默认后端存储 [root@k8s-master storageclass]# kubectl patch storageclass managed-nfs-storage -p '{"metadata": {"annotations":{"storageclass.kubernetes.io/is-default-class":"true"}}}' storageclass.storage.k8s.io/managed-nfs-storage patched #再次查看,注意是否有default标识 [root@k8s-master storageclass]# kubectl get sc NAME PROVISIONER RECLAIMPOLICY VOLUMEBINDINGMODE ALLOWVOLUMEEXPANSION AGE managed-nfs-storage (default) wxc-nfs-storage Delete Immediate false 171m #取消默认存储后端 [root@k8s-master storageclass]# kubectl patch storageclass managed-nfs-storage -p '{"metadata": {"annotations":{"storageclass.kubernetes.io/is-default-class":"false"}}}' storageclass.storage.k8s.io/managed-nfs-storage patched [root@k8s-master storageclass]# kubectl get sc NAME PROVISIONER RECLAIMPOLICY VOLUMEBINDINGMODE ALLOWVOLUMEEXPANSION AGE managed-nfs-storage wxc-nfs-storage Delete Immediate false 172m
2)修改YAML文件更新
apiVersion: storage.k8s.io/v1 kind: StorageClass metadata: name: managed-nfs-storage annotations: "storageclass.kubernetes.io/is-default-class": "true" #添加此注释 provisioner: wxc-nfs-storage #or choose another name, must match deployment's env PROVISIONER_NAME' parameters: archiveOnDelete: "false"
7.2如何使用默认的StorageClass
如果集群有一个默认的StorageClass能够满足我们的需求,那么剩下所有需要做的就是创建PersistentVolumeClaim(PVC),剩下的都有默认的动态配置搞定,包括无需去指定storageClassName:
apiVersion: v1 kind: PersistentVolumeClaim metadata: name: mypvc namespace: testns spec: accessModes: - ReadWriteOnce resources: requests: storage: 10Gi
7.3修改默回收策略(默认为Delete)
apiVersion: storage.k8s.io/v1 kind: StorageClass metadata: name: managed-nfs-storage annotations: provisioner: qgg-nfs-storage #or choose another name, must match deployment's env PROVISIONER_NAME' parameters: archiveOnDelete: "ture" #暂时不清楚该值对回收策略产生什么影响 reclaimPolicy: Retain #只有NFS 和hostPth支持两种回收策略
7.4能过删除/关闭默认的StorageClass
不能删除默认的StorageClass,因为它是作为集群的add-on安装的,如果它被删除,会被重新安装。 当然,可以停掉默认的StorageClass行为,通过删除annotation:storageclass.beta.kubernetes.io/is-default-class,或者设置为false。 如果没有StorageClass对象标记默认的annotation,那么PersistentVolumeClaim对象(在不指定StorageClass情况下)将不自动触发动态配置。相反,它们将回到绑定可用的*PersistentVolume(PV)*的状态。
7.5当删除PersistentVolumeClaim(PVC)会发生什么
如果一个卷是动态配置的卷,则默认的回收策略为“删除”。这意味着,在默认的情况下,当PVC被删除时,基础的PV和对应的存储也会被删除。如果需要保留存储在卷上的数据,则必须在PV被设置之后将回收策略从delete更改为retain。
参考文档:https://github.com/kubernetes-incubator/external-storage/tree/master/nfs-client
作者:杰宏唯一
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