Using HPA and CA for Auto Scaling of Workloads and Nodes
Application Scenarios
The best way to handle surging traffic is to automatically adjust the number of machines based on the traffic volume or resource usage, which is called scaling.
When deploying applications in pods, you can configure requested resources and resource limits for the pods to prevent unlimited usage of resources during peak hours. However, after the upper limit is reached, an application error may occur. Pod scaling can effectively resolve this issue. If the resource usage on the node increases to a certain extent, newly added pods cannot be scheduled to this node. In this case, CCE will add nodes accordingly.
Solution
Two major auto scaling policies are HPA (Horizontal Pod Autoscaling) and CA (Cluster AutoScaling). HPA is for workload auto scaling and CA is for node auto scaling.
HPA and CA work with each other. HPA requires sufficient cluster resources for successful scaling. When the cluster resources are insufficient, CA is needed to add nodes. If HPA reduces workloads, the cluster will have a large number of idle resources. In this case, CA needs to release nodes to avoid resource waste.
Using HPA and CA enables automatic scaling for most scenarios while also providing monitoring capabilities.
This section uses an example to describe the auto scaling process using HPA and CA policies together.
Preparations
- Create a cluster with one node. The node should have 2 cores of vCPUs and 4 GiB of memory, or a higher specification, as well as an EIP to allow external access. If no EIP is bound to the node during node creation, you can manually bind one on the ECS console after creating the node.
- Install add-ons for the cluster.
- autoscaler: node scaling add-on
- metrics-server: an aggregator of resource usage data in a Kubernetes cluster. It can collect measurement data of major Kubernetes resources, such as pods, nodes, containers, and Services.
- Log in to the cluster node and run a computing-intensive application. When a user sends a request, the result needs to be calculated before being returned to the user.
- Create a PHP file named index.php to calculate the square root of the request for 1,000,000 times before returning OK!.
vi index.php
The file content is as follows:<?php $x = 0.0001; for ($i = 0; $i <= 1000000; $i++) { $x += sqrt($x); } echo "OK!"; ?>
- Compile a Dockerfile file to build an image.
vi Dockerfile
The content is as follows:FROM php:5-apache COPY index.php /var/www/html/index.php RUN chmod a+rx index.php
- Run the following command to build an image named hpa-example with the tag latest.
docker build -t hpa-example:latest .
- (Optional) Log in to the SWR console, choose Organizations in the navigation pane, and click Create Organization in the upper right corner.
Skip this step if you already have an organization.
- In the navigation pane, choose My Images and then click Upload Through Client. On the page displayed, click Generate a temporary login command and click to copy the command.
- Run the login command copied in the previous step on the cluster node. If the login is successful, the message "Login Succeeded" is displayed.
- Tag the hpa-example image.
docker tag {Image name 1:Tag 1}/{Image repository address}/{Organization name}/{Image name 2:Tag 2}
- {Image name 1:Tag 1}: name and tag of the local image to be uploaded.
- {Image repository address}: the domain name at the end of the login command in login command. It can be obtained on the SWR console.
- {Organization name}: name of the created organization.
- {Image name 2:Tag 2}: desired image name and tag to be displayed on the SWR console.
The following is an example:
docker tag hpa-example:latest swr.ap-southeast-1.myhuaweicloud.com/cloud-develop/hpa-example:latest
- Push the image to the image repository.
docker push {Image repository address}/{Organization name}/{Image name 2:Tag 2}
The following is an example:
docker push swr.ap-southeast-1.myhuaweicloud.com/cloud-develop/hpa-example:latest
The following information will be returned upon a successful push:
6d6b9812c8ae: Pushed ... fe4c16cbf7a4: Pushed latest: digest: sha256:eb7e3bbd*** size: **
To view the pushed image, go to the SWR console and refresh the My Images page.
- Create a PHP file named index.php to calculate the square root of the request for 1,000,000 times before returning OK!.
Creating a Node Pool and a Node Scaling Policy
- Log in to the CCE console, access the created cluster, click Nodes on the left, click the Node Pools tab, and click Create Node Pool in the upper right corner.
- Configure the node pool.
- Node Type: Select a node type.
- Specifications: 2 vCPUs | 4 GiB
Retain the defaults for other parameters. For details, see Creating a Node Pool.
- Locate the row containing the newly created node pool and click Auto Scaling in the upper right corner. For details, see Creating a Node Scaling Policy.
If the CCE Cluster Autoscaler add-on is not installed in the cluster, install it first. For details, see CCE Cluster Autoscaler.
- Customize scale-out rules.: Click Add Rule. In the dialog box displayed, configure parameters. If the CPU allocation rate is greater than 70%, a node is added to each associated node pool. A node scaling policy needs to be associated with a node pool. Multiple node pools can be associated. When you need to scale nodes, node with proper specifications will be added or reduced from the node pool based on the minimum waste principle.
- Nodes: Modify the node quantity range. The number of nodes in a node pool will always be within the range during auto scaling.
- Cooldown Period: a period during which the nodes added in the current node pool cannot be scaled in
- Click OK.
Creating a Workload
Use the hpa-example image to create a Deployment with one replica. The image path is related to the organization uploaded to the SWR repository and needs to be replaced with the actual value.
kind: Deployment apiVersion: apps/v1 metadata: name: hpa-example spec: replicas: 1 selector: matchLabels: app: hpa-example template: metadata: labels: app: hpa-example spec: containers: - name: container-1 image: 'hpa-example:latest' # Replace it with the address of the image you uploaded to SWR. resources: limits: # The value of limits must be the same as that of requests to prevent flapping during scaling. cpu: 500m memory: 200Mi requests: cpu: 500m memory: 200Mi imagePullSecrets: - name: default-secret
Then, create a NodePort Service for the workload so that the workload can be accessed from external networks.
To allow external access to NodePort Services, allocate an EIP for the node in the cluster. After the allocation, synchronize node data. For details, see Synchronizing Data with Cloud Servers. If the node has already bound with an EIP, you do not need to create one.
Alternatively, you can create a Service with an ELB load balancer for external access. For details, see Using kubectl to Create a Service (Automatically Creating a Load Balancer).
kind: Service
apiVersion: v1
metadata:
name: hpa-example
spec:
ports:
- name: cce-service-0
protocol: TCP
port: 80
targetPort: 80
nodePort: 31144
selector:
app: hpa-example
type: NodePort
Creating an HPA Policy
Create an HPA policy. As shown below, the policy is associated with the hpa-example workload, and the target CPU usage is 50%.
There are two other annotations. One annotation defines the CPU thresholds, indicating that scaling is not performed when the CPU usage is between 30% and 70% to prevent impact caused by slight fluctuation. The other is the scaling time window, indicating that after the policy is successfully executed, a scaling operation will not be triggered again in this cooling interval to prevent impact caused by short-term fluctuation.
apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: hpa-policy annotations: extendedhpa.metrics: '[{"type":"Resource","name":"cpu","targetType":"Utilization","targetRange":{"low":"30","high":"70"}}]' extendedhpa.option: '{"downscaleWindow":"5m","upscaleWindow":"3m"}' spec: scaleTargetRef: kind: Deployment name: hpa-example apiVersion: apps/v1 minReplicas: 1 maxReplicas: 100 metrics: - type: Resource resource: name: cpu target: type: Utilization averageUtilization: 50
Configure the parameters as follows if you are using the console.
Observing the Auto Scaling Process
- Check the cluster node status. In the following example, there are two nodes.
# kubectl get node NAME STATUS ROLES AGE VERSION 192.168.0.183 Ready <none> 2m20s v1.17.9-r0-CCE21.1.1.3.B001-17.36.8 192.168.0.26 Ready <none> 55m v1.17.9-r0-CCE21.1.1.3.B001-17.36.8
Check the HPA policy. The CPU usage of the target workload is 0%.
# kubectl get hpa hpa-policy NAME REFERENCE TARGETS MINPODS MAXPODS REPLICAS AGE hpa-policy Deployment/hpa-example 0%/50% 1 100 1 4m
- Run the following command to access the workload. In the following command, {ip:port} indicates the access address of the workload, which can be queried on the workload details page.
while true;do wget -q -O- http://{ip:port}; done
If no EIP is displayed, the cluster node has not been assigned any EIP. Allocate one, bind it to the node, and synchronize node data. For details, see Synchronizing Data with Cloud Servers.
Observe the scaling process of the workload.
# kubectl get hpa hpa-policy --watch NAME REFERENCE TARGETS MINPODS MAXPODS REPLICAS AGE hpa-policy Deployment/hpa-example 0%/50% 1 100 1 4m hpa-policy Deployment/hpa-example 190%/50% 1 100 1 4m23s hpa-policy Deployment/hpa-example 190%/50% 1 100 4 4m31s hpa-policy Deployment/hpa-example 200%/50% 1 100 4 5m16s hpa-policy Deployment/hpa-example 200%/50% 1 100 4 6m16s hpa-policy Deployment/hpa-example 85%/50% 1 100 4 7m16s hpa-policy Deployment/hpa-example 81%/50% 1 100 4 8m16s hpa-policy Deployment/hpa-example 81%/50% 1 100 7 8m31s hpa-policy Deployment/hpa-example 57%/50% 1 100 7 9m16s hpa-policy Deployment/hpa-example 51%/50% 1 100 7 10m hpa-policy Deployment/hpa-example 58%/50% 1 100 7 11m
You can see that the CPU usage of the workload is 190% at 4m23s, which exceeds the target value. In this case, scaling is triggered to expand the workload to four replicas/pods. In the subsequent several minutes, the CPU usage does not decrease until 7m16s. This is because the new pods may not be successfully created. The possible cause is that resources are insufficient and the pods are in the pending state. During this period, nodes are being scaled out.
At 7m16s, the CPU usage decreases, indicating that the pods are successfully created and start to bear traffic. The CPU usage decreases to 81% at 8m, still greater than the target value (50%) and the high threshold (70%). Therefore, 7 pods are added at 9m16s, and the CPU usage decreases to 51%, which is within the range of 30% to 70%. From then on, the number of pods remains 7.
In the following output, you can see the workload scaling process and the time when the HPA policy takes effect.
# kubectl describe deploy hpa-example ... Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal ScalingReplicaSet 25m deployment-controller Scaled up replica set hpa-example-79dd795485 to 1 Normal ScalingReplicaSet 20m deployment-controller Scaled up replica set hpa-example-79dd795485 to 4 Normal ScalingReplicaSet 16m deployment-controller Scaled up replica set hpa-example-79dd795485 to 7 # kubectl describe hpa hpa-policy ... Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal SuccessfulRescale 20m horizontal-pod-autoscaler New size: 4; reason: cpu resource utilization (percentage of request) above target Normal SuccessfulRescale 16m horizontal-pod-autoscaler New size: 7; reason: cpu resource utilization (percentage of request) above target
Check the number of nodes. The following output shows that two nodes are added.
# kubectl get node NAME STATUS ROLES AGE VERSION 192.168.0.120 Ready <none> 3m5s v1.17.9-r0-CCE21.1.1.3.B001-17.36.8 192.168.0.136 Ready <none> 6m58s v1.17.9-r0-CCE21.1.1.3.B001-17.36.8 192.168.0.183 Ready <none> 18m v1.17.9-r0-CCE21.1.1.3.B001-17.36.8 192.168.0.26 Ready <none> 71m v1.17.9-r0-CCE21.1.1.3.B001-17.36.8
You can also view the scaling history on the console. For example, the CA policy is executed once when the CPU allocation rate in the cluster is greater than 70%, and the number of nodes in the node pool is increased from 2 to 3. The new node is automatically added by autoscaler based on the pending state of pods in the initial phase of HPA.
The node scaling process is as follows:
- After the number of pods changes to 4, the pods are in Pending state due to insufficient resources. As a result, the default scale-out policy of the autoscaler add-on is triggered, and the number of nodes is increased by one.
- The second node scale-out is triggered because the CPU allocation rate in the cluster is greater than 70%. As a result, the number of nodes is increased by one, which is recorded in the scaling history on the console. Scaling based on the allocation rate ensures that the cluster has sufficient resources.
- Stop accessing the workload and check the number of pods.
# kubectl get hpa hpa-policy --watch NAME REFERENCE TARGETS MINPODS MAXPODS REPLICAS AGE hpa-policy Deployment/hpa-example 50%/50% 1 100 7 12m hpa-policy Deployment/hpa-example 21%/50% 1 100 7 13m hpa-policy Deployment/hpa-example 0%/50% 1 100 7 14m hpa-policy Deployment/hpa-example 0%/50% 1 100 7 18m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 18m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 19m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 19m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 19m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 19m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 23m hpa-policy Deployment/hpa-example 0%/50% 1 100 3 23m hpa-policy Deployment/hpa-example 0%/50% 1 100 1 23m
You can see that the CPU usage is 21% at 13m. The number of pods is reduced to 3 at 18m, and then reduced to 1 at 23m.
In the following output, you can see the workload scaling process and the time when the HPA policy takes effect.
# kubectl describe deploy hpa-example ... Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal ScalingReplicaSet 25m deployment-controller Scaled up replica set hpa-example-79dd795485 to 1 Normal ScalingReplicaSet 20m deployment-controller Scaled up replica set hpa-example-79dd795485 to 4 Normal ScalingReplicaSet 16m deployment-controller Scaled up replica set hpa-example-79dd795485 to 7 Normal ScalingReplicaSet 6m28s deployment-controller Scaled down replica set hpa-example-79dd795485 to 3 Normal ScalingReplicaSet 72s deployment-controller Scaled down replica set hpa-example-79dd795485 to 1 # kubectl describe hpa hpa-policy ... Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal SuccessfulRescale 20m horizontal-pod-autoscaler New size: 4; reason: cpu resource utilization (percentage of request) above target Normal SuccessfulRescale 16m horizontal-pod-autoscaler New size: 7; reason: cpu resource utilization (percentage of request) above target Normal SuccessfulRescale 6m45s horizontal-pod-autoscaler New size: 3; reason: All metrics below target Normal SuccessfulRescale 90s horizontal-pod-autoscaler New size: 1; reason: All metrics below target
You can also view the HPA policy execution history on the console. Wait until the one node is reduced.
The reason why the other two nodes in the node pool are not reduced is that they both have pods in the kube-system namespace (and these pods are not created by DaemonSets). For details, see Node Scaling Mechanisms.
Summary
By using HPA and CA, auto scaling can be effortlessly implemented in various scenarios. Additionally, the scaling process of nodes and pods can be conveniently tracked.
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