Using an OBS Bucket Through a Dynamic PV¶
This section describes how to automatically create an OBS bucket. It is applicable when no underlying storage volume is available.
Constraints¶
If OBS volumes are used, the owner group and permission of the mount point cannot be modified.
CCE allows parallel file systems to be mounted using OBS SDKs or PVCs. If PVC mounting is used, the obsfs tool provided by OBS must be used. An obsfs resident process is generated each time an object storage volume generated from the parallel file system is mounted to a node, as shown in the following figure.
Figure 1 obsfs resident process¶
Reserve 1 GiB of memory for each obsfs process. For example, for a node with 4 vCPUs and 8 GiB of memory, an obsfs parallel file system should be mounted to no more than eight pods.
Note
An obsfs resident process runs on a node. If the consumed memory exceeds the upper limit of the node, the node malfunctions. On a node with 4 vCPUs and 8 GiB of memory, if more than 100 pods are mounted to a parallel file system, the node will be unavailable. Control the number of pods mounted to a parallel file system on a single node.
Kata containers do not support OBS volumes.
OBS allows a single user to create a maximum of 100 buckets. If a large number of dynamic PVCs are created, the number of buckets may exceed the upper limit, and no more OBS buckets can be created. In this case, use OBS by calling its API or SDK and do not mount OBS buckets to workloads.
Automatically Creating an OBS Volume on the Console¶
Log in to the CCE console and click the cluster name to access the cluster console.
Dynamically create a PVC and PV.
Choose Storage in the navigation pane and click the PersistentVolumeClaims (PVCs) tab. Click Create PVC in the upper right corner. In the dialog box displayed, configure the PVC parameters.
Parameter
Description
PVC Type
In this example, select OBS.
PVC Name
Enter the PVC name, which must be unique in the same namespace.
Creation Method
If no underlying storage is available, select Dynamically provision to create a PVC, PV, and underlying storage on the console in cascading mode.
If underlying storage is available, create a storage volume or use an existing storage volume to statically create a PVC based on whether a PV has been created. For details, see Using an Existing OBS Bucket Through a Static PV.
In this example, select Dynamically provision.
Storage Classes
The storage class of OBS volumes is csi-obs.
Instance Type
Parallel file system: a high-performance file system provided by OBS. It provides millisecond-level access latency, TB/s-level bandwidth, and million-level IOPS. Parallel file systems are recommended.
Object bucket: a container that stores objects in OBS. All objects in a bucket are at the same logical level.
OBS Class
You can select the following object bucket types:
Standard: Applicable when a large number of hotspot files or small-sized files need to be accessed frequently (multiple times per month on average) and require fast access response.
Infrequent access: Applicable when data is not frequently accessed (fewer than 12 times per year on average) but requires fast access response.
Access Mode
OBS volumes support only ReadWriteMany, indicating that a storage volume can be mounted to multiple nodes in read/write mode. For details, see Volume Access Modes.
Access Key (AK/SK)
Custom: Customize a secret if you want to assign different user permissions to different OBS storage devices. For details, see Using a Custom Access Key (AK/SK) to Mount an OBS Volume.
Only secrets with the secret.kubernetes.io/used-by = csi label can be selected. The secret type is cfe/secure-opaque. If no secret is available, click Create Secret to create one.
Name: Enter a secret name.
Namespace: Select the namespace where the secret is.
Access Key (AK/SK): Upload a key file in .csv format. For details, see Obtaining an Access Key.
Click Create to create a PVC and a PV.
You can choose Storage in the navigation pane and view the created PVC and PV on the PersistentVolumeClaims (PVCs) and PersistentVolumes (PVs) tab pages, respectively.
Create an application.
In the navigation pane on the left, click Workloads. In the right pane, click the Deployments tab.
Click Create Workload in the upper right corner. On the displayed page, click Data Storage in the Container Settings area and click Add Volume to select PVC.
Mount and use storage volumes, as shown in Table 1. For details about other parameters, see Workloads.
Table 1 Mounting a storage volume¶ Parameter
Description
PVC
Select an existing object storage volume.
Mount Path
Enter a mount path, for example, /tmp.
This parameter indicates the container path to which a data volume will be mounted. Do not mount the volume to a system directory such as / or /var/run. Otherwise, containers will be malfunctional. Mount the volume to an empty directory. If the directory is not empty, ensure that there are no files that affect container startup. Otherwise, the files will be replaced, causing container startup failures or workload creation failures.
Important
NOTICE: If a volume is mounted to a high-risk directory, use an account with minimum permissions to start the container. Otherwise, high-risk files on the host machine may be damaged.
Subpath
Enter the subpath of the storage volume and mount a path in the storage volume to the container. In this way, different folders of the same storage volume can be used in a single pod. tmp, for example, indicates that data in the mount path of the container is stored in the tmp folder of the storage volume. If this parameter is left blank, the root path is used by default.
Permission
Read-only: You can only read the data in the mounted volumes.
Read/Write: You can modify the data volumes mounted to the path. Newly written data will not be migrated if the container is migrated, which may cause data loss.
In this example, the disk is mounted to the /data path of the container. The container data generated in this path is stored in the OBS volume.
After the configuration, click Create Workload.
After the workload is created, the data in the container mount directory will be persistently stored. Verify the storage by referring to PV Reclaim Policy.
(kubectl) Automatically Creating an OBS Volume¶
Use kubectl to connect to the cluster.
Use StorageClass to dynamically create a PVC and PV.
Create the pvc-obs-auto.yaml file.
apiVersion: v1 kind: PersistentVolumeClaim metadata: name: pvc-obs-auto namespace: default annotations: everest.io/obs-volume-type: STANDARD # Object storage type. csi.storage.k8s.io/fstype: obsfs # Instance type. csi.storage.k8s.io/node-publish-secret-name: <your_secret_name> # Custom secret name. csi.storage.k8s.io/node-publish-secret-namespace: <your_namespace> # Namespace of the custom secret. spec: accessModes: - ReadWriteMany # The value must be ReadWriteMany for object storage. resources: requests: storage: 1Gi # OBS volume capacity. storageClassName: csi-obs # The storage class type is OBS.
Table 2 Key parameters¶ Parameter
Mandatory
Description
everest.io/obs-volume-type
Yes
OBS storage class.
If fsType is set to s3fs, STANDARD (standard bucket) and WARM (infrequent access bucket) are supported.
This parameter is invalid when fsType is set to obsfs.
csi.storage.k8s.io/fstype
Yes
Instance type. The value can be obsfs or s3fs.
obsfs: Parallel file system, which is mounted using obsfs (recommended).
s3fs: Object bucket, which is mounted using s3fs.
csi.storage.k8s.io/node-publish-secret-name
No
Custom secret name.
(Recommended) Select this option if you want to assign different user permissions to different OBS storage devices. For details, see Using a Custom Access Key (AK/SK) to Mount an OBS Volume.
csi.storage.k8s.io/node-publish-secret-namespace
No
Namespace of a custom secret.
storage
Yes
Requested capacity in the PVC, in Gi.
For OBS buckets, this field is used only for verification (cannot be empty or 0). Its value is fixed at 1, and any value you set does not take effect for OBS buckets.
storageClassName
Yes
Storage class name. The storage class name of OBS volumes is csi-obs.
Run the following command to create a PVC:
kubectl apply -f pvc-obs-auto.yaml
Create an application.
Create a file named web-demo.yaml. In this example, the OBS volume is mounted to the /data path.
apiVersion: apps/v1 kind: Deployment metadata: name: web-demo namespace: default spec: replicas: 2 selector: matchLabels: app: web-demo template: metadata: labels: app: web-demo spec: containers: - name: container-1 image: nginx:latest volumeMounts: - name: pvc-obs-volume #Volume name, which must be the same as the volume name in the volumes field. mountPath: /data #Location where the storage volume is mounted. imagePullSecrets: - name: default-secret volumes: - name: pvc-obs-volume #Volume name, which can be customized. persistentVolumeClaim: claimName: pvc-obs-auto #Name of the created PVC.
Run the following command to create a workload to which the OBS volume is mounted:
kubectl apply -f web-demo.yaml
After the workload is created, you can try Verifying Data Persistence and Sharing.
Verifying Data Persistence and Sharing¶
View the deployed application and files.
Run the following command to view the created pod:
kubectl get pod | grep web-demo
Expected output:
web-demo-846b489584-mjhm9 1/1 Running 0 46s web-demo-846b489584-wvv5s 1/1 Running 0 46s
Run the following commands in sequence to view the files in the /data path of the pods:
kubectl exec web-demo-846b489584-mjhm9 -- ls /data kubectl exec web-demo-846b489584-wvv5s -- ls /data
If no result is returned for both pods, no file exists in the /data path.
Run the following command to create a file named static in the /data path:
kubectl exec web-demo-846b489584-mjhm9 -- touch /data/static
Run the following command to view the files in the /data path:
kubectl exec web-demo-846b489584-mjhm9 -- ls /data
Expected output:
staticVerify data persistence.
Run the following command to delete the pod named web-demo-846b489584-mjhm9:
kubectl delete pod web-demo-846b489584-mjhm9
Expected output:
pod "web-demo-846b489584-mjhm9" deleted
After the deletion, the Deployment controller automatically creates a replica.
Run the following command to view the created pod:
kubectl get pod | grep web-demo
The expected output is as follows, in which web-demo-846b489584-d4d4j is the newly created pod:
web-demo-846b489584-d4d4j 1/1 Running 0 110s web-demo-846b489584-wvv5s 1/1 Running 0 7m50s
Run the following command to check whether the files in the /data path of the new pod have been modified:
kubectl exec web-demo-846b489584-d4d4j -- ls /data
Expected output:
staticIf the static file still exists, the data can be stored persistently.
Verify data sharing.
Run the following command to view the created pod:
kubectl get pod | grep web-demo
Expected output:
web-demo-846b489584-d4d4j 1/1 Running 0 7m web-demo-846b489584-wvv5s 1/1 Running 0 13m
Run the following command to create a file named share in the /data path of either pod: In this example, select the pod named web-demo-846b489584-d4d4j.
kubectl exec web-demo-846b489584-d4d4j -- touch /data/share
Check the files in the /data path of the pod.
kubectl exec web-demo-846b489584-d4d4j -- ls /data
Expected output:
share static
Check whether the share file exists in the /data path of another pod (web-demo-846b489584-wvv5s) as well to verify data sharing.
kubectl exec web-demo-846b489584-wvv5s -- ls /data
Expected output:
share static
After you create a file in the /data path of a pod, if the file is also created in the /data path of the other pod, the two pods share the same volume.