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prometheus基于kubernetes监控
prometheus对kubernetes的监控
对于Kubernetes而言,我们可以把当中所有的资源分为几类:
- 基础设施层(Node):集群节点,为整个集群和应用提供运行时资源
- 容器基础设施(Container):为应用提供运行时环境
- 用户应用(Pod):Pod中会包含一组容器,它们一起工作,并且对外提供一个(或者一组)功能
- 内部服务负载均衡(Service):在集群内,通过Service在集群暴露应用功能,集群内应用和应用之间访问时提供内部的负载均衡
- 外部访问入口(Ingress):通过Ingress提供集群外的访问入口,从而可以使外部客户端能够访问到部署在Kubernetes集群内的服务
因此,如果要构建一个完整的监控体系,我们应该考虑,以下5个方面:
- 集群节点状态监控:从集群中各节点的kubelet服务获取节点的基本运行状态
- 集群节点资源用量监控:通过Daemonset的形式在集群中各节点部署Node Exporter采集节点的资源使用情况
- 节点中运行的容器监控:通过各个节点中kubelet内置的cAdvisor中获取各节点中所有容器的运行状态和资源使用状态
- 如果在集群中部署的应用程序本身内置了对prometheus的监控支持,那么我们还应该找到相应的pod实例,并从该pod实例中获取其内部运行状态的监控指标
- 对k8s本身的组件做监控:apiserver、scheduler、controller-manager、kubelet、kube-proxy
我的机器规划
master节点 | node节点 | |
---|---|---|
数量 | 1 | 2 |
hostname | wentaomaster1 | wentaonode1|wentaonode2 |
IP | 192.168.184.10 | 192.168.184.20|192.168.184.30 |
k8s版本 | 1.25.0 | 1.25.0 |
node_exporter组件安装和配置
node_exporter介绍
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
安装node_exporter
[root@wentaomaster1]#kubectl create ns monitor-sa
[root@wentaomaster1]#ctr -n k8s.io images import node-exporter.tar.gz
[root@wentaonode1]#ctr -n k8s.io images import node-exporter.tar.gz
[root@wentaonode2]#ctr -n k8s.io images import node-exporter.tar.gz
[root@wentaomaster1]#cat 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# 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
containers:
- name: node-exporter
image: prom/node-exporter:v0.16.0
imagePullPolicy: IfNotPresent
ports:
- containerPort: 9100
resources:
requests:
cpu: 0.15
securityContext:
privileged: true #开启特权模式
args:
- --path.procfs#配置挂载宿主机(node节点)的路径
- /host/proc
- --path.sysfs#配置挂载宿主机(node节点)的路径
- /host/sys
- --collector.filesystem.ignored-mount-points
- '"^/(sys|proc|dev|host|etc)($|/)"'#通过正则表达式忽略某些文件系统挂载点的信息收集
volumeMounts:
- name: dev
mountPath: /host/dev
- name: proc
mountPath: /host/proc
- name: sys
mountPath: /host/sys
- name: rootfs
mountPath: /rootfs#将主机/dev、/proc、/sys这些目录挂在到容器中,这是因为我们采集的很多节点数据都是通过这些文件来获取系统信息的。
tolerations:
- key: ""
operator: "Exists"
effect: "NoSchedule" #对污点为NoSchedule的节点定义容忍度
volumes:
- name: proc
hostPath:
path: /proc
- name: dev
hostPath:
path: /dev
- name: sys
hostPath:
path: /sys
- name: rootfs
hostPath:
path: /
[root@wentaomaster1]#kubectl apply -f node-export.yaml
#通过kubectl apply更新node-exporter.yaml文件
[root@wentaomaster1]#kubectl get pod -n monitor-sa
#查看node-exporter是否部署成功
#显示如下,看到pod的状态都是running,说明部署成功
[root@wentaomaster1]# curl http://192.168.184.20:9100/metrics
#通过node-exporter采集数据
#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
[root@wentaomaster1]# curl http://192.168.184.20:9100/metrics | grep node_cpu_seconds
#显示192.168.184.20主机cpu的使用情况
prometheus server安装和配置
创建serviceaccount账号,对其做RBAC授权
#创建一个sa账号monitor
[root@wentaomaster1 ~]# kubectl create serviceaccount monitor -n monitor-sa
#把sa账号monitor通过clusterrolebing绑定到clusterrole上
[root@wentaomaster1 ~]# kubectl create clusterrolebinding monitor-clusterrolebinding -n monitor-sa --clusterrole=cluster-admin --serviceaccount=monitor-sa:monitor
[root@wentaomaster1~]# kubectl create clusterrolebinding monitor-clusterrolebinding-1 -n monitor-sa --clusterrole=cluster-admin --user=system:serviceaccount:monitor:monitor-sa
创建prometheus数据存储目录
#在k8s集群的两个node节点上创建数据存储目录
[root@wentaonode1 ~]# mkdir /data
[root@wentaonode1 ~]# chmod 777 /data/
[root@wentaonode2 ~]# mkdir /data
[root@wentaonode2 ~]# chmod 777 /data/
安装prometheus server服务
创建一个configmap存储卷,用来存放prometheus配置信息
[root@wentaomaster1]# cat 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
[root@wentaomaster1]#kubectl apply -f prometheus-cfg.yaml
通过deployment部署prometheus
[root@wentaonode1 ~]# ctr -n=k8s.io images import prometheus-2-2-1.tar.gz
[root@wentaonode2 ~]# ctr -n=k8s.io images import prometheus-2-2-1.tar.gz
[root@wentaomaster1 ~]# cat prometheus-deploy.yaml
---
apiVersion: apps/v1
kind: Deployment
metadata:
name: prometheus-server
namespace: monitor-sa
labels:
app: prometheus
spec:
replicas: 2
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:
serviceAccountName: monitor
containers:
- name: prometheus
image: prom/prometheus:v2.2.1
imagePullPolicy: IfNotPresent
command:
- prometheus
- --config.file=/etc/prometheus/prometheus.yml
- --storage.tsdb.path=/prometheus #旧数据存储目录
- --storage.tsdb.retention=720h #何时删除旧数据,默认为15天。
- --web.enable-lifecycle #开启热加载
ports:
- containerPort: 9090
protocol: TCP
volumeMounts:
- mountPath: /etc/prometheus
name: prometheus-config
- mountPath: /prometheus/
name: prometheus-storage-volume
volumes:
- name: prometheus-config
configMap:
name: prometheus-config
- name: prometheus-storage-volume
hostPath:
path: /data
type: Directory
[root@xianchaomaster1]# kubectl apply -f prometheus-deploy.yaml
#查看prometheus是否部署成功
[root@xianchaomaster1]# kubectl get pods -n monitor-sa
#显示如下,可看到pod状态是running,说明prometheus部署成功
给prometheus pod创建一个service
[root@wentaomaster1 ~]# 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
[root@wentaomaster1 ~]# kubectl apply -f prometheus-svc.yaml
[root@wentaomaster1 ~]# kubectl get svc -n monitor-sa
#查看service在物理机映射的端口
通过上面可以看到service在宿主机上映射的端口是30065,这样我们访问k8s集群的node1节点的ip:30065,就可以访问到prometheus的web ui界面了
点击页面的Status->Targets,可看到如下,说明我们配置的服务发现可以正常采集数据
prometheus热加载
#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@wentaomaster1 ~]# kubectl get pod -n monitor-sa -o wide
#10.244.166.172/10.244.105.15是k8s内部的prometheus的pod的ip地址
#想要使配置热生效可用如下命令热加载:
[root@wentaomaster1 ~]# curl -X POST http://10.244.166.172:9090/-/reload
#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:
kubectl delete -f prometheus-cfg.yaml
kubectl delete -f prometheus-deploy.yaml
然后再通过apply更新:
kubectl apply -f prometheus-cfg.yaml
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
可视化UI界面Grafana的安装和配置
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。
安装Grafana
[root@wentaonode1 ~]# ctr -n=k8s.io images import heapster-grafana-amd64_v5_0_4.tar.gz
[root@wentaonode2 ~]# ctr -n=k8s.io images import heapster-grafana-amd64_v5_0_4.tar.gz
[root@wentaomaster1 ~]# cat grafana.yaml
apiVersion: apps/v1
kind: Deployment
metadata:
name: monitoring-grafana
namespace: kube-system
spec:
replicas: 2
selector:
matchLabels:
task: monitoring
k8s-app: grafana
template:
metadata:
labels:
task: monitoring
k8s-app: grafana
spec:
containers:
- name: grafana
image: k8s.gcr.io/heapster-grafana-amd64:v5.0.4
imagePullPolicy: IfNotPresent
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/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
#更新yaml文件:
[root@wentaomaster1 ~]# kubectl apply -f grafana.yaml
#查看grafana是否创建成功:
[root@wentaomaster1 ~]# kubectl get pod -n kube-system -l task=monitoring
#显示如下,说明部署成功
Grafana界面接入prometheus数据源
#查看grafana前端的service
[root@wentaomaster1 ~]# kubectl get svc -n kube-system
- 登录grafana,在浏览器访问192.168.184.10:32562 ,可看到如下页面
- 配置grafana界面:
- 开始配置grafana的web界面:
选择Create your first data source
- 开始配置grafana的web界面:
- 出现如下:
#注:
#Name: Prometheus
#Type: Prometheus
#HTTP 处的URL写 如下:
#http://prometheus.monitor-sa.svc:9090
- 点击左下角Save & Test,出现如下Data source is working,说明prometheus数据源成功的被grafana接入了
-
导入的监控模板,可在如下链接搜索
https://grafana/dashboards?dataSource=prometheus&search=kubernetes -
导入监控模板,按如下步骤:
上面Save & Test测试没问题之后,就可以返回Grafana主页面
点击左侧+号下面的import,如下:
选择Upload json file,然后选择一个本地的json文件
这里选择的是node_exporter.json这个文件,选择之后出现如下:
Prometheus后面需要变成Prometheus,然后再点击Import,就可以出现如下界面:
导入docker_rev1.json监控模板,步骤和上面导入node_exporter.json步骤一样,导入之后显示如下:
安装kube-state-metrics组件
kube-state-metrics是什么?
kube-state-metrics通过监听API Server生成有关资源对象的状态指标,比如Node、Pod,需要注意的是kube-state-metrics只是简单的提供一个metrics数据,并不会存储这些指标数据,所以我们可以使用Prometheus来抓取这些数据然后存储,主要关注的是业务相关的一些元数据,比如Pod副本状态等;调度了多少个replicas?现在可用的有几个?多少个Pod是running/stopped/terminated状态?Pod重启了多少次?我有多少job在运行中。
安装kube-state-metrics组件
- 创建sa,并对sa授权
[root@wentaomaster1 ~]# cat kube-state-metrics-rbac.yaml
---
apiVersion: v1
kind: ServiceAccount
metadata:
name: kube-state-metrics
namespace: kube-system
---
apiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: kube-state-metrics
rules:
- apiGroups: [""]
resources: ["nodes", "pods", "services", "resourcequotas", "replicationcontrollers", "limitranges", "persistentvolumeclaims", "persistentvolumes", "namespaces", "endpoints"]
verbs: ["list", "watch"]
- apiGroups: ["extensions"]
resources: ["daemonsets", "deployments", "replicasets"]
verbs: ["list", "watch"]
- apiGroups: ["apps"]
resources: ["statefulsets"]
verbs: ["list", "watch"]
- apiGroups: ["batch"]
resources: ["cronjobs", "jobs"]
verbs: ["list", "watch"]
- apiGroups: ["autoscaling"]
resources: ["horizontalpodautoscalers"]
verbs: ["list", "watch"]
---
apiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
name: kube-state-metrics
roleRef:
apiGroup: rbac.authorization.k8s.io
kind: ClusterRole
name: kube-state-metrics
subjects:
- kind: ServiceAccount
name: kube-state-metrics
namespace: kube-system
[root@wentaomaster1 ~]# kubectl apply -f kube-state-metrics-rbac.yaml
- 安装kube-state-metrics组件
[root@wentaonode1 ~]#ctr -n=k8s.io images import kube-state-metrics_1_9_0.tar.gz
[root@wentaonode2 ~]#ctr -n=k8s.io images import kube-state-metrics_1_9_0.tar.gz
- 通过kubectl apply更新yaml文件
[root@wentaomaster1 ~]# cat kube-state-metrics-deploy.yaml
apiVersion: apps/v1
kind: Deployment
metadata:
name: kube-state-metrics
namespace: kube-system
spec:
replicas: 2
selector:
matchLabels:
app: kube-state-metrics
template:
metadata:
labels:
app: kube-state-metrics
spec:
serviceAccountName: kube-state-metrics
containers:
- name: kube-state-metrics
image: quay.io/coreos/kube-state-metrics:v1.9.0
imagePullPolicy: IfNotPresent
ports:
- containerPort: 8080
[root@wentaomaster1 ~]# kubectl apply -f kube-state-metrics-deploy.yaml
#查看kube-state-metrics是否部署成功
[root@wentaomaster1 ~]# kubectl get pod -n kube-system -l app=kube-state-metrics
#显示如下,看到pod处于running状态,说明部署成功
- 创建service
在k8s的控制节点生成一个kube-state-metrics-svc.yaml文件
[root@wentaomaster1 ~]# cat kube-state-metrics-svc.yaml
apiVersion: v1
kind: Service
metadata:
annotations:
prometheus.io/scrape: 'true'
name: kube-state-metrics
namespace: kube-system
labels:
app: kube-state-metrics
spec:
ports:
- name: kube-state-metrics
port: 8080
protocol: TCP
selector:
app: kube-state-metrics
[root@wentaomaster1 ~]# kubectl apply -f kube-state-metrics-svc.yaml
#查看service是否创建成功
[root@wentaomaster1 ~]# kubectl get svc -n kube-system
#显示如下,说明创建成功
- 在grafana web界面导入Kubernetes Cluster (Prometheus)-1577674936972.json和Kubernetes cluster monitoring (via Prometheus) (k8s 1.16)-1577691996738.json
基于Alertmanager发送报警到多个接收方
配置alertmanager发送报警到QQ邮箱
- 报警:指prometheus将监测到的异常事件发送给alertmanager
- 通知:alertmanager将报警信息发送到邮件、企业微信、钉钉等
创建alertmanager-configmap文件
#先提前看一下要创建alertmanager配置文件
#在k8s的可直接点创建alertmanager-cm.yaml文件
[root@wentaomaster1 prometheus]# cat alertmanager-cm.yaml
kind: ConfigMap
apiVersion: v1
metadata:
name: alertmanager
namespace: monitor-sa
data:
alertmanager.yml: |-
global:
resolve_timeout: 1m
smtp_smarthost: 'smtp.163:25' #这是网易的邮箱,可以自己注册一个,地址mail.163,'smtp.163:25'这是默认发送系统,填的都一样
smtp_from: '177****8421@163' #这是你自己在网易注册的邮箱,是你发送报警信息的邮箱
smtp_auth_username: '177****8421@163' #username同上
smtp_auth_password: 'PU*********ZIBR'
smtp_require_tls: false
route:
group_by: [alertname]
group_wait: 10s
group_interval: 10s
repeat_interval: 5m
receiver: default-receiver
receivers:
- name: 'default-receiver'
email_configs:
- to: '2580***386@qq' #这是你接收报警的邮箱
send_resolved: true
注册后在设置中找到POP3/SMTP/IMAP:
开启IMAP/SMTP服务和POP3/SMTP服务,然后会得到一个授权密码(注意:这个授权密码只会出现一次,一定要截图/复制下来,写配置文件alertmanager-cm.yaml要用):
#创建alertmanager配置文件
#在k8s的可直接点创建alertmanager-cm.yaml文件
[root@wentaomaster1 prometheus]# cat alertmanager-cm.yaml
kind: ConfigMap
apiVersion: v1
metadata:
name: alertmanager
namespace: monitor-sa
data:
alertmanager.yml: |-
global:
resolve_timeout: 1m
smtp_smarthost: 'smtp.163:25' #这是网易的邮箱,可以自己注册一个,地址mail.163,'smtp.163:25'这是默认发送系统,填的都一样
smtp_from: '177****8421@163' #这是你自己在网易注册的邮箱,是你发送报警信息的邮箱
smtp_auth_username: '177****8421@163' #username同上
smtp_auth_password: 'PU*********ZIBR'
smtp_require_tls: false
route:
group_by: [alertname]
group_wait: 10s
group_interval: 10s
repeat_interval: 5m
receiver: default-receiver
receivers:
- name: 'default-receiver'
email_configs:
- to: '2580***386@qq' #这是你接收报警的qq邮箱
send_resolved: true
alertmanager配置文件解释说明:
smtp_smarthost: 'smtp.163:25'
#163邮箱的SMTP服务器地址+端口
smtp_from: '177****8421@163'
#这是指定从哪个邮箱发送报警
smtp_auth_username: '177****8421@163'
smtp_auth_password: ' PU*********ZIBR'
#这是发送邮箱的授权码而不是登录密码
email_configs:
- to: '2580***386@qq'
#to后面指定发送到哪个邮箱,我发送到我的qq邮箱
route: #用于设置告警的分发策略
group_by: [alertname]
#alertmanager会根据group_by配置将Alert分组
group_wait: 10s
# 分组等待时间。也就是告警产生后等待10s,如果有同组告警一起发出
group_interval: 10s # 上下两组发送告警的间隔时间
repeat_interval: 5m # 重复发送告警的时间,减少相同邮件的发送频率,默认是1h
receiver: default-receiver #定义谁来收告警
- Prometheus 一条告警的触发流程、等待时间
- 报警处理流程如下:
-
Prometheus Server监控目标主机上暴露的http接口(这里假设接口A),通过Promethes配置的’scrape_interval’定义的时间间隔,定期采集目标主机上监控数据。
-
当接口A不可用的时候,Server端会持续的尝试从接口中取数据,直到"scrape_timeout"时间后停止尝试。这时候把接口的状态变为“DOWN”。
-
Prometheus同时根据配置的"evaluation_interval"的时间间隔,定期(默认1min)的对Alert Rule进行评估;当到达评估周期的时候,发现接口A为DOWN,即UP=0为真,激活Alert,进入“PENDING”状态,并记录当前active的时间;
-
当下一个alert rule的评估周期到来的时候,发现UP=0继续为真,然后判断警报Active的时间是否已经超出rule里的‘for’ 持续时间,如果未超出,则进入下一个评估周期;如果时间超出,则alert的状态变为“FIRING”;同时调用Alertmanager接口,发送相关报警数据。
-
AlertManager收到报警数据后,会将警报信息进行分组,然后根据alertmanager配置的“group_wait”时间先进行等待。等wait时间过后再发送报警信息。
-
属于同一个Alert Group的警报,在等待的过程中可能进入新的alert,如果之前的报警已经成功发出,那么间隔“group_interval”的时间间隔后再重新发送报警信息。比如配置的是邮件报警,那么同属一个group的报警信息会汇总在一个邮件里进行发送。
-
如果Alert Group里的警报一直没发生变化并且已经成功发送,等待‘repeat_interval’时间间隔之后再重复发送相同的报警邮件;如果之前的警报没有成功发送,则相当于触发第6条条件,则需要等待group_interval时间间隔后重复发送。
同时最后至于警报信息具体发给谁,满足什么样的条件下指定警报接收人,设置不同报警发送频率,这里由alertmanager的route路由规则进行配置。
创建prometheus和告警规则配置文件
#安装prometheus和alertmanager,需要把alertmanager.tar.gz镜像包上传的k8s的各个工作节点,手动解压:
[root@wentaonode1 ~]# ctr -n=k8s.io images import alertmanager.tar.gz
[root@wentaonode2 ~]# ctr -n=k8s.io images import alertmanager.tar.gz
#生成一个etcd-certs,这个在部署prometheus需要
[root@wentaomaster1 ~]#kubectl -n monitor-sa create secret generic etcd-certs --from-file=/etc/kubernetes/pki/etcd/server.key --from-file=/etc/kubernetes/pki/etcd/server.crt --from-file=/etc/kubernetes/pki/etcd/ca.crt
#在k8s的控制节点生成一个prometheus-alertmanager-cfg.yaml文件
[root@wentaomaster1 ~]# cat prometheus-alertmanager-cfg.yaml
kind: ConfigMap
apiVersion: v1
metadata:
labels:
app: prometheus
name: prometheus-config
namespace: monitor-sa
data:
prometheus.yml: |
rule_files:
- /etc/prometheus/rules.yml
alerting:
alertmanagers:
- static_configs:
- targets: ["localhost:9093"]
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
- job_name: 'kubernetes-pods'
kubernetes_sd_configs:
- role: pod
relabel_configs:
- action: keep
regex: true
source_labels:
- __meta_kubernetes_pod_annotation_prometheus_io_scrape
- action: replace
regex: (.+)
source_labels:
- __meta_kubernetes_pod_annotation_prometheus_io_path
target_label: __metrics_path__
- action: replace
regex: ([^:]+)(?::\d+)?;(\d+)
replacement: $1:$2
source_labels:
- __address__
- __meta_kubernetes_pod_annotation_prometheus_io_port
target_label: __address__
- action: labelmap
regex: __meta_kubernetes_pod_label_(.+)
- action: replace
source_labels:
- __meta_kubernetes_namespace
target_label: kubernetes_namespace
- action: replace
source_labels:
- __meta_kubernetes_pod_name
target_label: kubernetes_pod_name
- job_name: 'kubernetes-etcd'
scheme: https
tls_config:
ca_file: /var/run/secrets/kubernetes.io/k8s-certs/etcd/ca.crt
cert_file: /var/run/secrets/kubernetes.io/k8s-certs/etcd/server.crt
key_file: /var/run/secrets/kubernetes.io/k8s-certs/etcd/server.key
scrape_interval: 5s
static_configs:
- targets: ['192.168.184.10:2379']
rules.yml: |
groups:
- name: example
rules:
- alert: apiserver的cpu使用率大于80%
expr: rate(process_cpu_seconds_total{job=~"kubernetes-apiserver"}[1m]) * 100 > 80
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}组件的cpu使用率超过80%"
- alert: apiserver的cpu使用率大于90%
expr: rate(process_cpu_seconds_total{job=~"kubernetes-apiserver"}[1m]) * 100 > 90
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}组件的cpu使用率超过90%"
- alert: etcd的cpu使用率大于80%
expr: rate(process_cpu_seconds_total{job=~"kubernetes-etcd"}[1m]) * 100 > 80
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}组件的cpu使用率超过80%"
- alert: etcd的cpu使用率大于90%
expr: rate(process_cpu_seconds_total{job=~"kubernetes-etcd"}[1m]) * 100 > 90
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}组件的cpu使用率超过90%"
- alert: kube-state-metrics的cpu使用率大于80%
expr: rate(process_cpu_seconds_total{k8s_app=~"kube-state-metrics"}[1m]) * 100 > 80
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.k8s_app}}组件的cpu使用率超过80%"
value: "{{ $value }}%"
threshold: "80%"
- alert: kube-state-metrics的cpu使用率大于90%
expr: rate(process_cpu_seconds_total{k8s_app=~"kube-state-metrics"}[1m]) * 100 > 0
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.k8s_app}}组件的cpu使用率超过90%"
value: "{{ $value }}%"
threshold: "90%"
- alert: coredns的cpu使用率大于80%
expr: rate(process_cpu_seconds_total{k8s_app=~"kube-dns"}[1m]) * 100 > 80
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.k8s_app}}组件的cpu使用率超过80%"
value: "{{ $value }}%"
threshold: "80%"
- alert: coredns的cpu使用率大于90%
expr: rate(process_cpu_seconds_total{k8s_app=~"kube-dns"}[1m]) * 100 > 90
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.k8s_app}}组件的cpu使用率超过90%"
value: "{{ $value }}%"
threshold: "90%"
- alert: kube-proxy打开句柄数>600
expr: process_open_fds{job=~"kubernetes-kube-proxy"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>600"
value: "{{ $value }}"
- alert: kube-proxy打开句柄数>1000
expr: process_open_fds{job=~"kubernetes-kube-proxy"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>1000"
value: "{{ $value }}"
- alert: kubernetes-schedule打开句柄数>600
expr: process_open_fds{job=~"kubernetes-schedule"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>600"
value: "{{ $value }}"
- alert: kubernetes-schedule打开句柄数>1000
expr: process_open_fds{job=~"kubernetes-schedule"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>1000"
value: "{{ $value }}"
- alert: kubernetes-controller-manager打开句柄数>600
expr: process_open_fds{job=~"kubernetes-controller-manager"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>600"
value: "{{ $value }}"
- alert: kubernetes-controller-manager打开句柄数>1000
expr: process_open_fds{job=~"kubernetes-controller-manager"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>1000"
value: "{{ $value }}"
- alert: kubernetes-apiserver打开句柄数>600
expr: process_open_fds{job=~"kubernetes-apiserver"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>600"
value: "{{ $value }}"
- alert: kubernetes-apiserver打开句柄数>1000
expr: process_open_fds{job=~"kubernetes-apiserver"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>1000"
value: "{{ $value }}"
- alert: kubernetes-etcd打开句柄数>600
expr: process_open_fds{job=~"kubernetes-etcd"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>600"
value: "{{ $value }}"
- alert: kubernetes-etcd打开句柄数>1000
expr: process_open_fds{job=~"kubernetes-etcd"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "{{$labels.instance}}的{{$labels.job}}打开句柄数>1000"
value: "{{ $value }}"
- alert: coredns
expr: process_open_fds{k8s_app=~"kube-dns"} > 600
for: 2s
labels:
severity: warnning
annotations:
description: "插件{{$labels.k8s_app}}({{$labels.instance}}): 打开句柄数超过600"
value: "{{ $value }}"
- alert: coredns
expr: process_open_fds{k8s_app=~"kube-dns"} > 1000
for: 2s
labels:
severity: critical
annotations:
description: "插件{{$labels.k8s_app}}({{$labels.instance}}): 打开句柄数超过1000"
value: "{{ $value }}"
- alert: kube-proxy
expr: process_virtual_memory_bytes{job=~"kubernetes-kube-proxy"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: scheduler
expr: process_virtual_memory_bytes{job=~"kubernetes-schedule"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: kubernetes-controller-manager
expr: process_virtual_memory_bytes{job=~"kubernetes-controller-manager"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: kubernetes-apiserver
expr: process_virtual_memory_bytes{job=~"kubernetes-apiserver"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: kubernetes-etcd
expr: process_virtual_memory_bytes{job=~"kubernetes-etcd"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: kube-dns
expr: process_virtual_memory_bytes{k8s_app=~"kube-dns"} > 2000000000
for: 2s
labels:
severity: warnning
annotations:
description: "插件{{$labels.k8s_app}}({{$labels.instance}}): 使用虚拟内存超过2G"
value: "{{ $value }}"
- alert: HttpRequestsAvg
expr: sum(rate(rest_client_requests_total{job=~"kubernetes-kube-proxy|kubernetes-kubelet|kubernetes-schedule|kubernetes-control-manager|kubernetes-apiservers"}[1m])) > 1000
for: 2s
labels:
team: admin
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): TPS超过1000"
value: "{{ $value }}"
threshold: "1000"
- alert: Pod_restarts
expr: kube_pod_container_status_restarts_total{namespace=~"kube-system|default|monitor-sa"} > 0
for: 2s
labels:
severity: warnning
annotations:
description: "在{{$labels.namespace}}名称空间下发现{{$labels.pod}}这个pod下的容器{{$labels.container}}被重启,这个监控指标是由{{$labels.instance}}采集的"
value: "{{ $value }}"
threshold: "0"
- alert: Pod_waiting
expr: kube_pod_container_status_waiting_reason{namespace=~"kube-system|default"} == 1
for: 2s
labels:
team: admin
annotations:
description: "空间{{$labels.namespace}}({{$labels.instance}}): 发现{{$labels.pod}}下的{{$labels.container}}启动异常等待中"
value: "{{ $value }}"
threshold: "1"
- alert: Pod_terminated
expr: kube_pod_container_status_terminated_reason{namespace=~"kube-system|default|monitor-sa"} == 1
for: 2s
labels:
team: admin
annotations:
description: "空间{{$labels.namespace}}({{$labels.instance}}): 发现{{$labels.pod}}下的{{$labels.container}}被删除"
value: "{{ $value }}"
threshold: "1"
- alert: Etcd_leader
expr: etcd_server_has_leader{job="kubernetes-etcd"} == 0
for: 2s
labels:
team: admin
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 当前没有leader"
value: "{{ $value }}"
threshold: "0"
- alert: Etcd_leader_changes
expr: rate(etcd_server_leader_changes_seen_total{job="kubernetes-etcd"}[1m]) > 0
for: 2s
labels:
team: admin
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 当前leader已发生改变"
value: "{{ $value }}"
threshold: "0"
- alert: Etcd_failed
expr: rate(etcd_server_proposals_failed_total{job="kubernetes-etcd"}[1m]) > 0
for: 2s
labels:
team: admin
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}): 服务失败"
value: "{{ $value }}"
threshold: "0"
- alert: Etcd_db_total_size
expr: etcd_debugging_mvcc_db_total_size_in_bytes{job="kubernetes-etcd"} > 10000000000
for: 2s
labels:
team: admin
annotations:
description: "组件{{$labels.job}}({{$labels.instance}}):db空间超过10G"
value: "{{ $value }}"
threshold: "10G"
- alert: Endpoint_ready
expr: kube_endpoint_address_not_ready{namespace=~"kube-system|default"} == 1
for: 2s
labels:
team: admin
annotations:
description: "空间{{$labels.namespace}}({{$labels.instance}}): 发现{{$labels.endpoint}}不可用"
value: "{{ $value }}"
threshold: "1"
- name: 物理节点状态-监控告警
rules:
- alert: 物理节点cpu使用率
expr: 100-avg(irate(node_cpu_seconds_total{mode="idle"}[5m])) by(instance)*100 > 90
for: 2s
labels:
severity: ccritical
annotations:
summary: "{{ $labels.instance }}cpu使用率过高"
description: "{{ $labels.instance }}的cpu使用率超过90%,当前使用率[{{ $value }}],需要排查处理"
- alert: 物理节点内存使用率
expr: (node_memory_MemTotal_bytes - (node_memory_MemFree_bytes + node_memory_Buffers_bytes + node_memory_Cached_bytes)) / node_memory_MemTotal_bytes * 100 > 90
for: 2s
labels:
severity: critical
annotations:
summary: "{{ $labels.instance }}内存使用率过高"
description: "{{ $labels.instance }}的内存使用率超过90%,当前使用率[{{ $value }}],需要排查处理"
- alert: InstanceDown
expr: up == 0
for: 2s
labels:
severity: critical
annotations:
summary: "{{ $labels.instance }}: 服务器宕机"
description: "{{ $labels.instance }}: 服务器延时超过2分钟"
- alert: 物理节点磁盘的IO性能
expr: 100-(avg(irate(node_disk_io_time_seconds_total[1m])) by(instance)* 100) < 60
for: 2s
labels:
severity: critical
annotations:
summary: "{{$labels.mountpoint}} 流入磁盘IO使用率过高!"
description: "{{$labels.mountpoint }} 流入磁盘IO大于60%(目前使用:{{$value}})"
- alert: 入网流量带宽
expr: ((sum(rate (node_network_receive_bytes_total{device!~'tap.*|veth.*|br.*|docker.*|virbr*|lo*'}[5m])) by (instance)) / 100) > 102400
for: 2s
labels:
severity: critical
annotations:
summary: "{{$labels.mountpoint}} 流入网络带宽过高!"
description: "{{$labels.mountpoint }}流入网络带宽持续5分钟高于100M. RX带宽使用率{{$value}}"
- alert: 出网流量带宽
expr: ((sum(rate (node_network_transmit_bytes_total{device!~'tap.*|veth.*|br.*|docker.*|virbr*|lo*'}[5m])) by (instance)) / 100) > 102400
for: 2s
labels:
severity: critical
annotations:
summary: "{{$labels.mountpoint}} 流出网络带宽过高!"
description: "{{$labels.mountpoint }}流出网络带宽持续5分钟高于100M. RX带宽使用率{{$value}}"
- alert: TCP会话
expr: node_netstat_Tcp_CurrEstab > 1000
for: 2s
labels:
severity: critical
annotations:
summary: "{{$labels.mountpoint}} TCP_ESTABLISHED过高!"
description: "{{$labels.mountpoint }} TCP_ESTABLISHED大于1000%(目前使用:{{$value}}%)"
- alert: 磁盘容量
expr: 100-(node_filesystem_free_bytes{fstype=~"ext4|xfs"}/node_filesystem_size_bytes {fstype=~"ext4|xfs"}*100) > 80
for: 2s
labels:
severity: critical
annotations:
summary: "{{$labels.mountpoint}} 磁盘分区使用率过高!"
description: "{{$labels.mountpoint }} 磁盘分区使用大于80%(目前使用:{{$value}}%)"
[root@wentaomaster1 ~]# kubectl apply -f prometheus-alertmanager-cfg.yaml
[root@wentaomaster1 ~]# cat prometheus-alertmanager-deploy.yaml
---
apiVersion: apps/v1
kind: Deployment
metadata:
name: prometheus-server
namespace: monitor-sa
labels:
app: prometheus
spec:
replicas: 2
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:
serviceAccountName: monitor
containers:
- name: prometheus
image: prom/prometheus:v2.2.1
imagePullPolicy: IfNotPresent
command:
- "/bin/prometheus"
args:
- "--config.file=/etc/prometheus/prometheus.yml"
- "--storage.tsdb.path=/prometheus"
- "--storage.tsdb.retention=24h"
- "--web.enable-lifecycle"
ports:
- containerPort: 9090
protocol: TCP
volumeMounts:
- mountPath: /etc/prometheus
name: prometheus-config
- mountPath: /prometheus/
name: prometheus-storage-volume
- name: k8s-certs
mountPath: /var/run/secrets/kubernetes.io/k8s-certs/etcd/
- name: alertmanager
image: prom/alertmanager:v0.14.0
imagePullPolicy: IfNotPresent
args:
- "--config.file=/etc/alertmanager/alertmanager.yml"
- "--log.level=debug"
ports:
- containerPort: 9093
protocol: TCP
name: alertmanager
volumeMounts:
- name: alertmanager-config
mountPath: /etc/alertmanager
- name: alertmanager-storage
mountPath: /alertmanager
- name: localtime
mountPath: /etc/localtime
volumes:
- name: prometheus-config
configMap:
name: prometheus-config
- name: prometheus-storage-volume
hostPath:
path: /data
type: Directory
- name: k8s-certs
secret:
secretName: etcd-certs
- name: alertmanager-config
configMap:
name: alertmanager
- name: alertmanager-storage
hostPath:
path: /data/alertmanager
type: DirectoryOrCreate
- name: localtime
hostPath:
path: /usr/share/zoneinfo/Asia/Shanghai
[root@wentaomaster1 ~]# kubectl apply -f prometheus-alertmanager-deploy.yaml
#查看prometheus是否部署成功
[root@wentaomaster1 ~]# kubectl get pod -n monitor-sa -owide
#显示如下,说明创建成功:
#部署alertmanager的service,方便在浏览器访问
#在k8s的控制节点生成一个alertmanager-svc.yaml文件
[root@wentaomaster1 ~]# cat alertmanager-svc.yaml
---
apiVersion: v1
kind: Service
metadata:
labels:
name: prometheus
kubernetes.io/cluster-service: 'true'
name: alertmanager
namespace: monitor-sa
spec:
ports:
- name: alertmanager
nodePort: 30066
port: 9093
protocol: TCP
targetPort: 9093
selector:
app: prometheus
sessionAffinity: None
type: NodePort
通过kubectl apply更新yaml文件
[root@wentaomaster1 ~]# kubectl apply -f alertmanager-svc.yaml
#查看service在物理机映射的端口
[root@wentaomaster1 ~]# kubectl get svc -n monitor-sa
可以看到alertmanager的service在物理机映射的端口是30066
访问http://192.168.184.10:30066/#/alerts
访问prometheus的web界面,可看到:
点击Alerts:
把Pod_restarts展开,可看到如下:
可以看到QQ邮箱已经一大堆报警了哈哈哈
扩展:暴力更新配置文件
修改prometheus任何一个配置文件之后,可通过kubectl apply使配置生效,执行顺序如下:
kubectl delete -f alertmanager-cm.yaml
kubectl apply -f alertmanager-cm.yaml
kubectl delete -f prometheus-alertmanager-cfg.yaml
kubectl apply -f prometheus-alertmanager-cfg.yaml
kubectl delete -f prometheus-alertmanager-deploy.yaml
kubectl apply -f prometheus-alertmanager-deploy.yaml
本文标签: 邮箱prometheusKubernetesGrafanaqq
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