基于kubernetes部署Prometheus和Grafana

------ ## 一:环境准备 #### 1.kubernetes集群正常 ```shell [root@master ~]# kubectl get node NAME STATUS ROLES AGE VERSION master Ready control-plane,master 36d v1.23.1 node-1 Ready 36d v1.23.1 node-2 Ready 36d v1.23.1 node-3 Ready 36d v1.23.1 ``` #### 2.harbor仓库正常 ![image-20220602010601512](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602010601512.png) ## 二:Prometheus部署 #### 1.node-exporter部署 ​ node-exporter可以采集机器(物理机、虚拟机、云主机等)的监控指标数据,能够采集到的指标包括CPU, 内存,磁盘,网络,文件数等信息 创建监控namespace: ```shell [root@master ~]# kubectl create ns monitor-sa ``` 创建node-export.yaml: ```shell [root@master ~]# vim node-export.yaml apiVersion: apps/v1 kind: DaemonSet # 可以保证k8s集群的每个节点都运行完全一样的pod metadata: name: node-exporter namespace: monitor-sa labels: name: node-exporter spec: selector: matchLabels: name: node-exporter template: metadata: labels: name: node-exporter spec: hostPID: true hostIPC: true hostNetwork: true containers: - name: node-exporter image: prom/node-exporter:v0.16.0 #image: 10.0.0.230/xingdian/node-exporter:v0.16.0 ports: - containerPort: 9100 resources: requests: cpu: 0.15 # 这个容器运行至少需要0.15核cpu securityContext: privileged: true # 开启特权模式 args: - --path.procfs - /host/proc - --path.sysfs - /host/sys - --collector.filesystem.ignored-mount-points - '"^/(sys|proc|dev|host|etc)($|/)"' volumeMounts: - name: dev mountPath: /host/dev - name: proc mountPath: /host/proc - name: sys mountPath: /host/sys - name: rootfs mountPath: /rootfs tolerations: - key: "node-role.kubernetes.io/master" operator: "Exists" effect: "NoSchedule" volumes: - name: proc hostPath: path: /proc - name: dev hostPath: path: /dev - name: sys hostPath: path: /sys - name: rootfs hostPath: path: / ``` 注意: ​ hostNetwork、hostIPC、hostPID都为True时,表示这个Pod里的所有容器,会直接使用宿主机的网络,直接与宿主机进行IPC(进程间通信)通信,可以看到宿主机里正在运行的所有进程。加入了hostNetwork:true会直接将我们的宿主机的9100端口映射出来,从而不需要创建service 在我们的宿主机上就会有一个9100的端口 创建: ```shell [root@master ~]# kubectl apply -f node-export.yaml ``` 查看node-exporter是否部署成功: ```shell [root@master ~]# kubectl get pods -n monitor-sa -o wide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES node-exporter-2cbrg 1/1 Running 0 34m 10.0.0.220 master node-exporter-7rrbh 1/1 Running 0 34m 10.0.0.222 node-2 node-exporter-96v29 1/1 Running 0 34m 10.0.0.221 node-1 node-exporter-bf2j8 1/1 Running 0 34m 10.0.0.223 node-3 ``` 注意: ​ node-export默认的监听端口是9100,可以看到当前主机获取到的所有监控数据 ```shell [root@master ~]# curl http://10.0.0.220:9100/metrics | grep node_cpu_seconds % Total % Received % Xferd Average Speed Time Time Time Current Dload Upload Total Spent Left Speed 0 0 0 0 0 0 0 0 --:--:-- --:--:-- --:--:-- 0# HELP node_cpu_seconds_total Seconds the cpus spent in each mode. # TYPE node_cpu_seconds_total counter node_cpu_seconds_total{cpu="0",mode="idle"} 8398.49 node_cpu_seconds_total{cpu="0",mode="iowait"} 1.54 node_cpu_seconds_total{cpu="0",mode="irq"} 0 node_cpu_seconds_total{cpu="0",mode="nice"} 0 node_cpu_seconds_total{cpu="0",mode="softirq"} 17.2 node_cpu_seconds_total{cpu="0",mode="steal"} 0 node_cpu_seconds_total{cpu="0",mode="system"} 70.61 node_cpu_seconds_total{cpu="0",mode="user"} 187.04 node_cpu_seconds_total{cpu="1",mode="idle"} 8403.82 node_cpu_seconds_total{cpu="1",mode="iowait"} 4.95 node_cpu_seconds_total{cpu="1",mode="irq"} 0 node_cpu_seconds_total{cpu="1",mode="nice"} 0 node_cpu_seconds_total{cpu="1",mode="softirq"} 16.75 node_cpu_seconds_total{cpu="1",mode="steal"} 0 node_cpu_seconds_total{cpu="1",mode="system"} 71.26 node_cpu_seconds_total{cpu="1",mode="user"} 190.27 100 74016 100 74016 0 0 5878k 0 --:--:-- --:--:-- --:--:-- 6023k [root@master ~]# curl http://10.0.0.220:9100/metrics | grep node_load % Total % Received % Xferd Average Speed Time Time Time Current Dload Upload Total Spent Left Speed 0 0 0 0 0 0 0 0 --:--:-- --:--:-- --:--:-- 0# HELP node_loa 1 1m load average. # TYPE node_load1 gauge node_load1 0.2 # HELP node_load15 15m load average. # TYPE node_load15 gauge node_load15 0.22 # HELP node_load5 5m load average. # TYPE node_load5 gauge node_load5 0.2 100 74044 100 74044 0 0 8604k 0 --:--:-- --:--:-- --:--:-- 9038k ``` #### 2.Prometheus安装 创建sa账号,对sa做rbac授权: ```shell # 创建一个sa账号monitor [root@master ~]# kubectl create serviceaccount monitor -n monitor-sa # 把sa账号monitor通过clusterrolebing绑定到clusterrole上 [root@master ~]# kubectl create clusterrolebinding monitor-clusterrolebinding -n monitor-sa --clusterrole=cluster-admin --serviceaccount=monitor-sa:monitor ``` 创建prometheus数据存储目录: ```shell # 将prometheus调度到node-1节点 [root@node-1 ~]# mkdir /data && chmod 777 /data ``` 创建一个configmap存储卷,用来存放prometheus配置信息: ```shell [root@master ~]# vim prometheus-cfg.yaml --- kind: ConfigMap apiVersion: v1 metadata: labels: app: prometheus name: prometheus-config namespace: monitor-sa data: prometheus.yml: | global: scrape_interval: 15s scrape_timeout: 10s evaluation_interval: 1m scrape_configs: - job_name: 'kubernetes-node' kubernetes_sd_configs: - role: node relabel_configs: - source_labels: [__address__] regex: '(.*):10250' replacement: '${1}:9100' target_label: __address__ action: replace - action: labelmap regex: __meta_kubernetes_node_label_(.+) - job_name: 'kubernetes-node-cadvisor' kubernetes_sd_configs: - role: node scheme: https tls_config: ca_file: /var/run/secrets/kubernetes.io/serviceaccount/ca.crt bearer_token_file: /var/run/secrets/kubernetes.io/serviceaccount/token relabel_configs: - action: labelmap regex: __meta_kubernetes_node_label_(.+) - target_label: __address__ replacement: kubernetes.default.svc:443 - source_labels: [__meta_kubernetes_node_name] regex: (.+) target_label: __metrics_path__ replacement: /api/v1/nodes/${1}/proxy/metrics/cadvisor - job_name: 'kubernetes-apiserver' kubernetes_sd_configs: - role: endpoints scheme: https tls_config: ca_file: /var/run/secrets/kubernetes.io/serviceaccount/ca.crt bearer_token_file: /var/run/secrets/kubernetes.io/serviceaccount/token relabel_configs: - source_labels: [__meta_kubernetes_namespace, __meta_kubernetes_service_name, __meta_kubernetes_endpoint_port_name] action: keep regex: default;kubernetes;https - job_name: 'kubernetes-service-endpoints' kubernetes_sd_configs: - role: endpoints relabel_configs: - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_scrape] action: keep regex: true - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_scheme] action: replace target_label: __scheme__ regex: (https?) - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_path] action: replace target_label: __metrics_path__ regex: (.+) - source_labels: [__address__, __meta_kubernetes_service_annotation_prometheus_io_port] action: replace target_label: __address__ regex: ([^:]+)(?::\d+)?;(\d+) replacement: $1:$2 - action: labelmap regex: __meta_kubernetes_service_label_(.+) - source_labels: [__meta_kubernetes_namespace] action: replace target_label: kubernetes_namespace - source_labels: [__meta_kubernetes_service_name] action: replace target_label: kubernetes_name ``` 创建: ```shell [root@master ~]# kubectl apply -f prometheus-cfg.yaml configmap/prometheus-config created ``` 配置详解: ```shell --- kind: ConfigMap apiVersion: v1 metadata: labels: app: prometheus name: prometheus-config namespace: monitor-sa data: prometheus.yml: | global: scrape_interval: 15s #采集目标主机监控据的时间间隔 scrape_timeout: 10s # 数据采集超时时间,默认10s evaluation_interval: 1m #触发告警检测的时间,默认是1m scrape_configs: # 配置数据源,称为target,每个target用job_name命名。又分为静态配置和服务发现 - job_name: 'kubernetes-node' kubernetes_sd_configs: # 使用的是k8s的服务发现 - role: node # 使用node角色,它使用默认的kubelet提供的http端口来发现集群中每个node节点 relabel_configs: # 重新标记 - source_labels: [__address__] # 配置的原始标签,匹配地址 regex: '(.*):10250' #匹配带有10250端口的url replacement: '${1}:9100' #把匹配到的ip:10250的ip保留 target_label: __address__ #新生成的url是${1}获取到的ip:9100 action: replace # 动作替换 - action: labelmap regex: __meta_kubernetes_node_label_(.+) #匹配到下面正则表达式的标签会被保留,如果不做regex正则的话,默认只是会显示instance标签 - job_name: 'kubernetes-node-cadvisor' # 抓取cAdvisor数据,是获取kubelet上/metrics/cadvisor接口数据来获取容器的资源使用情况 kubernetes_sd_configs: - role: node scheme: https tls_config: ca_file: /var/run/secrets/kubernetes.io/serviceaccount/ca.crt bearer_token_file: /var/run/secrets/kubernetes.io/serviceaccount/token relabel_configs: - action: labelmap # 把匹配到的标签保留 regex: __meta_kubernetes_node_label_(.+) #保留匹配到的具有__meta_kubernetes_node_label的标签 - target_label: __address__ # 获取到的地址:__address__="192.168.40.180:10250" replacement: kubernetes.default.svc:443 # 把获取到的地址替换成新的地址kubernetes.default.svc:443 - source_labels: [__meta_kubernetes_node_name] regex: (.+) # 把原始标签中__meta_kubernetes_node_name值匹配到 target_label: __metrics_path__ #获取__metrics_path__对应的值 replacement: /api/v1/nodes/${1}/proxy/metrics/cadvisor # 把metrics替换成新的值api/v1/nodes/k8s-master1/proxy/metrics/cadvisor # ${1}是__meta_kubernetes_node_name获取到的值 # 新的url就是https://kubernetes.default.svc:443/api/v1/nodes/k8s-master1/proxy/metrics/cadvisor - job_name: 'kubernetes-apiserver' kubernetes_sd_configs: - role: endpoints # 使用k8s中的endpoint服务发现,采集apiserver 6443端口获取到的数据 scheme: https tls_config: ca_file: /var/run/secrets/kubernetes.io/serviceaccount/ca.crt bearer_token_file: /var/run/secrets/kubernetes.io/serviceaccount/token relabel_configs: - source_labels: [__meta_kubernetes_namespace, __meta_kubernetes_service_name, __meta_kubernetes_endpoint_port_name] # endpoint这个对象的名称空间,endpoint对象的服务名,exnpoint的端口名称 action: keep # 采集满足条件的实例,其他实例不采集 regex: default;kubernetes;https #正则匹配到的默认空间下的service名字是kubernetes,协议是https的endpoint类型保留下来 - job_name: 'kubernetes-service-endpoints' kubernetes_sd_configs: - role: endpoints relabel_configs: - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_scrape] action: keep regex: true # 重新打标仅抓取到的具有 "prometheus.io/scrape: true" 的annotation的端点,意思是说如果某个service具有prometheus.io/scrape = true annotation声明则抓取,annotation本身也是键值结构,所以这里的源标签设置为键,而regex设置值true,当值匹配到regex设定的内容时则执行keep动作也就是保留,其余则丢弃。 - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_scheme] action: replace target_label: __scheme__ regex: (https?) # 重新设置scheme,匹配源标签__meta_kubernetes_service_annotation_prometheus_io_scheme也就是prometheus.io/scheme annotation,如果源标签的值匹配到regex,则把值替换为__scheme__对应的值。 - source_labels: [__meta_kubernetes_service_annotation_prometheus_io_path] action: replace target_label: __metrics_path__ regex: (.+) # 应用中自定义暴露的指标,也许你暴露的API接口不是/metrics这个路径,那么你可以在这个POD对应的service中做一个"prometheus.io/path = /mymetrics" 声明,上面的意思就是把你声明的这个路径赋值给__metrics_path__,其实就是让prometheus来获取自定义应用暴露的metrices的具体路径,不过这里写的要和service中做好约定,如果service中这样写 prometheus.io/app-metrics-path: '/metrics' 那么你这里就要__meta_kubernetes_service_annotation_prometheus_io_app_metrics_path这样写。 - source_labels: [__address__, __meta_kubernetes_service_annotation_prometheus_io_port] action: replace target_label: __address__ regex: ([^:]+)(?::\d+)?;(\d+) replacement: $1:$2 # 暴露自定义的应用的端口,就是把地址和你在service中定义的 "prometheus.io/port = " 声明做一个拼接,然后赋值给__address__,这样prometheus就能获取自定义应用的端口,然后通过这个端口再结合__metrics_path__来获取指标,如果__metrics_path__值不是默认的/metrics那么就要使用上面的标签替换来获取真正暴露的具体路径。 - action: labelmap #保留下面匹配到的标签 regex: __meta_kubernetes_service_label_(.+) - source_labels: [__meta_kubernetes_namespace] action: replace # 替换__meta_kubernetes_namespace变成kubernetes_namespace target_label: kubernetes_namespace - source_labels: [__meta_kubernetes_service_name] action: replace target_label: kubernetes_name ``` 通过deployment部署prometheus: ```shell [root@master ~]# cat prometheus-deploy.yaml --- apiVersion: apps/v1 kind: Deployment metadata: name: prometheus-server namespace: monitor-sa labels: app: prometheus spec: replicas: 1 selector: matchLabels: app: prometheus component: server #matchExpressions: #- {key: app, operator: In, values: [prometheus]} #- {key: component, operator: In, values: [server]} template: metadata: labels: app: prometheus component: server annotations: prometheus.io/scrape: 'false' spec: nodeName: node-1 # 指定pod调度到哪个节点上 serviceAccountName: monitor containers: - name: prometheus image: prom/prometheus:v2.2.1 #image: 10.0.0.230/xingdian/prometheus:v2.2.1 imagePullPolicy: IfNotPresent command: - prometheus - --config.file=/etc/prometheus/prometheus.yml - --storage.tsdb.path=/prometheus # 数据存储目录 - --storage.tsdb.retention=720h # 数据保存时长 - --web.enable-lifecycle # 开启热加载 ports: - containerPort: 9090 protocol: TCP volumeMounts: - mountPath: /etc/prometheus/prometheus.yml name: prometheus-config subPath: prometheus.yml - mountPath: /prometheus/ name: prometheus-storage-volume volumes: - name: prometheus-config configMap: name: prometheus-config items: - key: prometheus.yml path: prometheus.yml mode: 0644 - name: prometheus-storage-volume hostPath: path: /data type: Directory ``` 创建: ```shell [root@master ~]# kubectl apply -f prometheus-deploy.yaml deployment.apps/prometheus-server created ``` 查看: ```shell [root@master ~]# kubectl get pods -o wide -n monitor-sa NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES prometheus-server-59cb5d648-bxwrb 1/1 Running 0 14m 10.244.2.100 node-1 ``` #### 3.prometheus pod创建service ```shell [root@master ~]# cat prometheus-svc.yaml apiVersion: v1 kind: Service metadata: name: prometheus namespace: monitor-sa labels: app: prometheus spec: type: NodePort ports: - port: 9090 targetPort: 9090 protocol: TCP selector: app: prometheus component: server ``` 创建: ```shell [root@master ~]# kubectl apply -f prometheus-svc.yaml service/prometheus created ``` 查看service在物理机映射的端口: ```shell [root@master ~]# kubectl get svc -n monitor-sa NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE prometheus NodePort 10.106.61.80 9090:32169/TCP 32m ``` #### 4.web界面查看 ![image-20220602011956600](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602011956600.png) ![image-20220602012012382](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602012012382.png) #### 5.Prometheus热加载 ```shell # 为了每次修改配置文件可以热加载prometheus,也就是不停止prometheus,就可以使配置生效,想要使配置生效可用如下热加载命令: [root@master ~]# kubectl get pods -n monitor-sa -o wide -l app=prometheus NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES prometheus-server-689fb8cdbc-kcsw2 1/1 Running 0 5m39s 10.244.36.70 k8s-node1 # 想要使配置生效可用如下命令热加载: [root@master ~]# curl -X POST http://10.244.36.70:9090/-/reload # 查看log [root@master ~]# kubectl logs -n monitor-sa prometheus-server-689fb8cdbc-kcsw2 ``` 注意: ```shell # 热加载速度比较慢,可以暴力重启prometheus,如修改上面的prometheus-cfg.yaml文件之后,可执行如下强制删除: [root@master ~]# kubectl delete -f prometheus-cfg.yaml [root@master ~]# kubectl delete -f prometheus-deploy.yaml # 然后再通过apply更新: [root@master ~]# kubectl apply -f prometheus-cfg.yaml [root@master ~]# kubectl apply -f prometheus-deploy.yaml #注意:线上最好热加载,暴力删除可能造成监控数据的丢失 ``` ## 三:Grafana的部署 #### 1.Grafana介绍 Grafana是一个跨平台的开源的度量分析和可视化工具,可以将采集的数据可视化的展示,并及时通知给告警接收方 它主要有以下六大特点: 1)展示方式:快速灵活的客户端图表,面板插件有许多不同方式的可视化指标和日志,官方库中具有丰富的仪表盘插件,比如热图、折线图、图表等多种展示方式 2)数据源:Graphite,InfluxDB,OpenTSDB,Prometheus,Elasticsearch,CloudWatch和KairosDB等 3)通知提醒:以可视方式定义最重要指标的警报规则,Grafana将不断计算并发送通知,在数据达到阈值时通过Slack、PagerDuty等获得通知 4)混合展示:在同一图表中混合使用不同的数据源,可以基于每个查询指定数据源,甚至自定义数据源 5)注释:使用来自不同数据源的丰富事件注释图表,将鼠标悬停在事件上会显示完整的事件元数据和标记 #### 2.Grafana安装 ```shell [root@master prome]# cat grafana.yaml apiVersion: apps/v1 kind: Deployment metadata: name: monitoring-grafana namespace: kube-system spec: replicas: 1 selector: matchLabels: task: monitoring k8s-app: grafana template: metadata: labels: task: monitoring k8s-app: grafana spec: containers: - name: grafana image: 10.0.0.230/xingdian/heapster-grafana-amd64:v5.0.4 #heleicool/heapster-grafana-amd64:v5.0.4 ports: - containerPort: 3000 protocol: TCP volumeMounts: - mountPath: /etc/ssl/certs name: ca-certificates readOnly: true - mountPath: /var name: grafana-storage env: - name: INFLUXDB_HOST value: monitoring-influxdb - name: GF_SERVER_HTTP_PORT value: "3000" # The following env variables are required to make Grafana accessible via # the kubernetes api-server proxy. On production clusters, we recommend # removing these env variables, setup auth for grafana, and expose the grafana # service using a LoadBalancer or a public IP. - name: GF_AUTH_BASIC_ENABLED value: "false" - name: GF_AUTH_ANONYMOUS_ENABLED value: "true" - name: GF_AUTH_ANONYMOUS_ORG_ROLE value: Admin - name: GF_SERVER_ROOT_URL # If you're only using the API Server proxy, set this value instead: # value: /api/v1/namespaces/kube-system/services/monitoring-grafana/proxy value: / volumes: - name: ca-certificates hostPath: path: /etc/ssl/certs - name: grafana-storage emptyDir: {} --- apiVersion: v1 kind: Service metadata: labels: # For use as a Cluster add-on (https://github.com/kubernetes/kubernetes/tree/master/cluster/addons) # If you are NOT using this as an addon, you should comment out this line. kubernetes.io/cluster-service: 'true' kubernetes.io/name: monitoring-grafana name: monitoring-grafana namespace: kube-system spec: # In a production setup, we recommend accessing Grafana through an external Loadbalancer # or through a public IP. # type: LoadBalancer # You could also use NodePort to expose the service at a randomly-generated port # type: NodePort ports: - port: 80 targetPort: 3000 selector: k8s-app: grafana type: NodePort ``` 创建: ```shell [root@master prome]# kubectl apply -f grafana.yaml deployment.apps/monitoring-grafana created service/monitoring-grafana created ``` 查看: ```shell [root@master prome]# kubectl get pods -n kube-system -l task=monitoring -o wide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES monitoring-grafana-7c5c6c7486-rbt62 1/1 Running 0 9s 10.244.1.83 node-3 ``` ```shell [root@master prome]# kubectl get svc -n kube-system | grep grafana monitoring-grafana NodePort 10.101.77.194 80:30919/TCP 76s ``` ## 四:配置Grafana 浏览器访问: ![image-20220602013222284](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602013222284.png) 添加数据源: ![image-20220602013322234](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602013322234.png) 指定Prometheus地址: ![image-20220602013441712](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602013441712.png) 导入监控模板: ![image-20220602013943317](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602013943317.png) ![image-20220602014027197](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014027197.png) 注意: 官方下载监控模板:https://grafana.com/dashboards?dataSource=prometheus&search=kubernetes ![image-20220602014152927](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014152927.png) ![image-20220602014212551](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014212551.png) 展示: ![image-20220602014306247](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014306247.png) ![image-20220602014321106](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014321106.png) ![image-20220602014337431](%E5%9F%BA%E4%BA%8Ekubernetes%E9%83%A8%E7%BD%B2Prometheus%E5%92%8CGrafana.assets/image-20220602014337431.png)