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Autoscaling the Compute Resource of a MongoDB Standalone Database
This guide will show you how to use KubeDB
to autoscale compute resources i.e. cpu and memory of a MongoDB standalone database.
Before You Begin
At first, you need to have a Kubernetes cluster, and the
kubectl
command-line tool must be configured to communicate with your cluster.Install
KubeDB
Provisioner, Ops-manager and Autoscaler operator in your cluster following the steps here.Install
Metrics Server
from hereYou should be familiar with the following
KubeDB
concepts:
To keep everything isolated, we are going to use a separate namespace called demo
throughout this tutorial.
$ kubectl create ns demo
namespace/demo created
Note: YAML files used in this tutorial are stored in docs/examples/mongodb directory of kubedb/docs repository.
Autoscaling of Standalone Database
Here, we are going to deploy a MongoDB
standalone using a supported version by KubeDB
operator. Then we are going to apply MongoDBAutoscaler
to set up autoscaling.
Deploy MongoDB standalone
In this section, we are going to deploy a MongoDB standalone database with version 4.4.26
. Then, in the next section we will set up autoscaling for this database using MongoDBAutoscaler
CRD. Below is the YAML of the MongoDB
CR that we are going to create,
apiVersion: kubedb.com/v1
kind: MongoDB
metadata:
name: mg-standalone
namespace: demo
spec:
version: "4.4.26"
storageType: Durable
storage:
resources:
requests:
storage: 1Gi
podTemplate:
spec:
containers:
- name: mongo
resources:
requests:
cpu: "200m"
memory: "300Mi"
limits:
cpu: "200m"
memory: "300Mi"
deletionPolicy: WipeOut
Let’s create the MongoDB
CRO we have shown above,
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.11.18/docs/examples/mongodb/autoscaling/compute/mg-standalone.yaml
mongodb.kubedb.com/mg-standalone created
Now, wait until mg-standalone
has status Ready
. i.e,
$ kubectl get mg -n demo
NAME VERSION STATUS AGE
mg-standalone 4.4.26 Ready 2m53s
Let’s check the Pod containers resources,
$ kubectl get pod -n demo mg-standalone-0 -o json | jq '.spec.containers[].resources'
{
"limits": {
"cpu": "200m",
"memory": "300Mi"
},
"requests": {
"cpu": "200m",
"memory": "300Mi"
}
}
Let’s check the MongoDB resources,
$ kubectl get mongodb -n demo mg-standalone -o json | jq '.spec.podTemplate.spec.containers[] | select(.name == "mongodb") | .resources'
{
"limits": {
"cpu": "200m",
"memory": "300Mi"
},
"requests": {
"cpu": "200m",
"memory": "300Mi"
}
}
You can see from the above outputs that the resources are same as the one we have assigned while deploying the mongodb.
We are now ready to apply the MongoDBAutoscaler
CRO to set up autoscaling for this database.
Compute Resource Autoscaling
Here, we are going to set up compute (cpu and memory) autoscaling using a MongoDBAutoscaler Object.
Create MongoDBAutoscaler Object
In order to set up compute resource autoscaling for this standalone database, we have to create a MongoDBAutoscaler
CRO with our desired configuration. Below is the YAML of the MongoDBAutoscaler
object that we are going to create,
apiVersion: autoscaling.kubedb.com/v1alpha1
kind: MongoDBAutoscaler
metadata:
name: mg-as
namespace: demo
spec:
databaseRef:
name: mg-standalone
opsRequestOptions:
timeout: 3m
apply: IfReady
compute:
standalone:
trigger: "On"
podLifeTimeThreshold: 5m
resourceDiffPercentage: 20
minAllowed:
cpu: 400m
memory: 400Mi
maxAllowed:
cpu: 1
memory: 1Gi
controlledResources: ["cpu", "memory"]
containerControlledValues: "RequestsAndLimits"
Here,
spec.databaseRef.name
specifies that we are performing compute resource autoscaling onmg-standalone
database.spec.compute.standalone.trigger
specifies that compute resource autoscaling is enabled for this database.spec.compute.standalone.podLifeTimeThreshold
specifies the minimum lifetime for at least one of the pod to initiate a vertical scaling.spec.compute.replicaset.resourceDiffPercentage
specifies the minimum resource difference in percentage. The default is 10%. If the difference between current & recommended resource is less than ResourceDiffPercentage, Autoscaler Operator will ignore the updating.spec.compute.standalone.minAllowed
specifies the minimum allowed resources for the database.spec.compute.standalone.maxAllowed
specifies the maximum allowed resources for the database.spec.compute.standalone.controlledResources
specifies the resources that are controlled by the autoscaler.spec.compute.standalone.containerControlledValues
specifies which resource values should be controlled. The default is “RequestsAndLimits”.spec.opsRequestOptions
contains the options to pass to the created OpsRequest. It has 3 fields. Know more about them here : readinessCriteria, timeout, apply.
If it was an InMemory database
, we could also autoscaler the inMemory resources using MongoDB compute autoscaler, like below.
Autoscale inMemory database
To autoscale inMemory databases, you need to specify the spec.compute.standalone.inMemoryStorage
section.
...
inMemoryStorage:
usageThresholdPercentage: 80
scalingFactorPercentage: 30
...
It has two fields inside it.
usageThresholdPercentage
. If db uses more than usageThresholdPercentage of the total memory, memoryStorage should be increased. Default usage threshold is 70%.scalingFactorPercentage
. If db uses more than usageThresholdPercentage of the total memory, memoryStorage should be increased by this given scaling percentage. Default scaling percentage is 50%.
Note: To inform you, We use
db.serverStatus().inMemory.cache["bytes currently in the cache"]
&db.serverStatus().inMemory.cache["maximum bytes configured"]
to calculate the used & maximum inMemory storage respectively.
Let’s create the MongoDBAutoscaler
CR we have shown above,
$ kubectl apply -f https://github.com/kubedb/docs/raw/v2024.11.18/docs/examples/mongodb/autoscaling/compute/mg-as-standalone.yaml
mongodbautoscaler.autoscaling.kubedb.com/mg-as created
Verify Autoscaling is set up successfully
Let’s check that the mongodbautoscaler
resource is created successfully,
$ kubectl get mongodbautoscaler -n demo
NAME AGE
mg-as 102s
$ kubectl describe mongodbautoscaler mg-as -n demo
Name: mg-as
Namespace: demo
Labels: <none>
Annotations: <none>
API Version: autoscaling.kubedb.com/v1alpha1
Kind: MongoDBAutoscaler
Metadata:
Creation Timestamp: 2022-10-27T09:54:35Z
Generation: 1
Managed Fields:
API Version: autoscaling.kubedb.com/v1alpha1
Fields Type: FieldsV1
fieldsV1:
f:metadata:
f:annotations:
.:
f:kubectl.kubernetes.io/last-applied-configuration:
f:spec:
.:
f:compute:
.:
f:standalone:
.:
f:containerControlledValues:
f:controlledResources:
f:maxAllowed:
.:
f:cpu:
f:memory:
f:minAllowed:
.:
f:cpu:
f:memory:
f:podLifeTimeThreshold:
f:resourceDiffPercentage:
f:trigger:
f:databaseRef:
f:opsRequestOptions:
.:
f:apply:
f:timeout:
Manager: kubectl-client-side-apply
Operation: Update
Time: 2022-10-27T09:54:35Z
API Version: autoscaling.kubedb.com/v1alpha1
Fields Type: FieldsV1
fieldsV1:
f:status:
.:
f:checkpoints:
f:conditions:
f:vpas:
Manager: kubedb-autoscaler
Operation: Update
Subresource: status
Time: 2022-10-27T09:55:08Z
Resource Version: 656164
UID: 439c148f-7c22-456f-a4b4-758cead29932
Spec:
Compute:
Standalone:
Container Controlled Values: RequestsAndLimits
Controlled Resources:
cpu
memory
Max Allowed:
Cpu: 1
Memory: 1Gi
Min Allowed:
Cpu: 400m
Memory: 400Mi
Pod Life Time Threshold: 5m0s
Resource Diff Percentage: 20
Trigger: On
Database Ref:
Name: mg-standalone
Ops Request Options:
Apply: IfReady
Timeout: 3m0s
Status:
Checkpoints:
Cpu Histogram:
Bucket Weights:
Index: 6
Weight: 10000
Reference Timestamp: 2022-10-27T00:00:00Z
Total Weight: 0.133158834498727
First Sample Start: 2022-10-27T09:54:56Z
Last Sample Start: 2022-10-27T09:54:56Z
Last Update Time: 2022-10-27T09:55:07Z
Memory Histogram:
Reference Timestamp: 2022-10-28T00:00:00Z
Ref:
Container Name: mongodb
Vpa Object Name: mg-standalone
Total Samples Count: 1
Version: v3
Conditions:
Last Transition Time: 2022-10-27T09:55:08Z
Message: Successfully created mongoDBOpsRequest demo/mops-mg-standalone-57huq2
Observed Generation: 1
Reason: CreateOpsRequest
Status: True
Type: CreateOpsRequest
Vpas:
Conditions:
Last Transition Time: 2022-10-27T09:55:07Z
Status: True
Type: RecommendationProvided
Recommendation:
Container Recommendations:
Container Name: mongodb
Lower Bound:
Cpu: 400m
Memory: 400Mi
Target:
Cpu: 400m
Memory: 400Mi
Uncapped Target:
Cpu: 93m
Memory: 262144k
Upper Bound:
Cpu: 1
Memory: 1Gi
Vpa Name: mg-standalone
Events: <none>
So, the mongodbautoscaler
resource is created successfully.
you can see in the Status.VPAs.Recommendation
section, that recommendation has been generated for our database. Our autoscaler operator continuously watches the recommendation generated and creates an mongodbopsrequest
based on the recommendations, if the database pods are needed to scaled up or down.
Let’s watch the mongodbopsrequest
in the demo namespace to see if any mongodbopsrequest
object is created. After some time you’ll see that a mongodbopsrequest
will be created based on the recommendation.
$ watch kubectl get mongodbopsrequest -n demo
Every 2.0s: kubectl get mongodbopsrequest -n demo
NAME TYPE STATUS AGE
mops-mg-standalone-57huq2 VerticalScaling Progressing 10s
Let’s wait for the ops request to become successful.
$ watch kubectl get mongodbopsrequest -n demo
Every 2.0s: kubectl get mongodbopsrequest -n demo
NAME TYPE STATUS AGE
mops-mg-standalone-57huq2 VerticalScaling Successful 68s
We can see from the above output that the MongoDBOpsRequest
has succeeded. If we describe the MongoDBOpsRequest
we will get an overview of the steps that were followed to scale the database.
$ kubectl describe mongodbopsrequest -n demo mops-mg-standalone-57huq2
Name: mops-mg-standalone-57huq2
Namespace: demo
Labels: <none>
Annotations: <none>
API Version: ops.kubedb.com/v1alpha1
Kind: MongoDBOpsRequest
Metadata:
Creation Timestamp: 2022-10-27T09:55:08Z
Generation: 1
Managed Fields:
API Version: ops.kubedb.com/v1alpha1
Fields Type: FieldsV1
fieldsV1:
f:metadata:
f:ownerReferences:
.:
k:{"uid":"439c148f-7c22-456f-a4b4-758cead29932"}:
f:spec:
.:
f:apply:
f:databaseRef:
f:timeout:
f:type:
f:verticalScaling:
.:
f:standalone:
.:
f:limits:
.:
f:cpu:
f:memory:
f:requests:
.:
f:cpu:
f:memory:
Manager: kubedb-autoscaler
Operation: Update
Time: 2022-10-27T09:55:08Z
API Version: ops.kubedb.com/v1alpha1
Fields Type: FieldsV1
fieldsV1:
f:status:
.:
f:conditions:
f:observedGeneration:
f:phase:
Manager: kubedb-ops-manager
Operation: Update
Subresource: status
Time: 2022-10-27T09:55:33Z
Owner References:
API Version: autoscaling.kubedb.com/v1alpha1
Block Owner Deletion: true
Controller: true
Kind: MongoDBAutoscaler
Name: mg-as
UID: 439c148f-7c22-456f-a4b4-758cead29932
Resource Version: 656279
UID: 29908a23-7cba-4f81-b787-3f9d226993f8
Spec:
Apply: IfReady
Database Ref:
Name: mg-standalone
Timeout: 3m0s
Type: VerticalScaling
Vertical Scaling:
Standalone:
Limits:
Cpu: 400m
Memory: 400Mi
Requests:
Cpu: 400m
Memory: 400Mi
Status:
Conditions:
Last Transition Time: 2022-10-27T09:55:08Z
Message: MongoDB ops request is vertically scaling database
Observed Generation: 1
Reason: VerticalScaling
Status: True
Type: VerticalScaling
Last Transition Time: 2022-10-27T09:55:33Z
Message: Successfully Vertically Scaled Standalone Resources
Observed Generation: 1
Reason: UpdateStandaloneResources
Status: True
Type: UpdateStandaloneResources
Last Transition Time: 2022-10-27T09:55:33Z
Message: Successfully Vertically Scaled Database
Observed Generation: 1
Reason: Successful
Status: True
Type: Successful
Observed Generation: 1
Phase: Successful
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal PauseDatabase 2m40s KubeDB Ops-manager Operator Pausing MongoDB demo/mg-standalone
Normal PauseDatabase 2m40s KubeDB Ops-manager Operator Successfully paused MongoDB demo/mg-standalone
Normal Starting 2m40s KubeDB Ops-manager Operator Updating Resources of PetSet: mg-standalone
Normal UpdateStandaloneResources 2m40s KubeDB Ops-manager Operator Successfully updated standalone Resources
Normal Starting 2m40s KubeDB Ops-manager Operator Updating Resources of PetSet: mg-standalone
Normal UpdateStandaloneResources 2m40s KubeDB Ops-manager Operator Successfully updated standalone Resources
Normal UpdateStandaloneResources 2m15s KubeDB Ops-manager Operator Successfully Vertically Scaled Standalone Resources
Normal ResumeDatabase 2m15s KubeDB Ops-manager Operator Resuming MongoDB demo/mg-standalone
Normal ResumeDatabase 2m15s KubeDB Ops-manager Operator Successfully resumed MongoDB demo/mg-standalone
Normal Successful 2m15s KubeDB Ops-manager Operator Successfully Vertically Scaled Database
Now, we are going to verify from the Pod, and the MongoDB yaml whether the resources of the standalone database has updated to meet up the desired state, Let’s check,
$ kubectl get pod -n demo mg-standalone-0 -o json | jq '.spec.containers[].resources'
{
"limits": {
"cpu": "400m",
"memory": "400Mi"
},
"requests": {
"cpu": "400m",
"memory": "400Mi"
}
}
$ kubectl get mongodb -n demo mg-standalone -o json | jq '.spec.podTemplate.spec.containers[] | select(.name == "mongodb") | .resources'
{
"limits": {
"cpu": "400m",
"memory": "400Mi"
},
"requests": {
"cpu": "400m",
"memory": "400Mi"
}
}
The above output verifies that we have successfully auto scaled the resources of the MongoDB standalone database.
Cleaning Up
To clean up the Kubernetes resources created by this tutorial, run:
kubectl delete mg -n demo mg-standalone
kubectl delete mongodbautoscaler -n demo mg-as