kubernetes二进制集群部署三——负载均衡调度器部-创新互联
内容要点:
1、实验环境
2、负载均衡调度器部署
一、实验环境:
基于之前部署好的多 Master 集群架构的基础上,部署两台调度器服务器(这边我用的是 nginx),实现负载均衡:
kubernetes二进制集群部署一——etcd存储组件、flannel网络组件部署:
https://blog.51cto.com/14475876/2470049
kubernetes二进制集群部署一——单master集群部署+多master群及部署:
https://blog.51cto.com/14475876/2470063
服务器信息
角色 | IP地址 |
master01 | 192.168.109.138 |
master02 | 192.168.109.230 |
调度器1(nginx01) | 192.168.109.131 |
调度器1(nginx02) | 192.168.109.132 |
node01节点 | 192.168.109.133 |
node02节点 | 192.168.109.137 |
虚拟 ip | 192.168.109.100 |
需要两个的脚本:
第一个:keepalived.conf ! Configuration File for keepalived global_defs { # 接收邮件地址 notification_email { acassen@firewall.loc failover@firewall.loc sysadmin@firewall.loc } # 邮件发送地址 notification_email_from Alexandre.Cassen@firewall.loc smtp_server 127.0.0.1 smtp_connect_timeout 30 router_id NGINX_MASTER } vrrp_script check_nginx { script "/usr/local/nginx/sbin/check_nginx.sh" } vrrp_instance VI_1 { state MASTER interface eth0 virtual_router_id 51 # VRRP 路由 ID实例,每个实例是唯一的 priority 100 # 优先级,备服务器设置 90 advert_int 1 # 指定VRRP 心跳包通告间隔时间,默认1秒 authentication { auth_type PASS auth_pass 1111 } virtual_ipaddress { 10.0.0.188/24 } track_script { check_nginx } } mkdir /usr/local/nginx/sbin/ -p vim /usr/local/nginx/sbin/check_nginx.sh count=$(ps -ef |grep nginx |egrep -cv "grep|$$") if [ "$count" -eq 0 ];then /etc/init.d/keepalived stop fi chmod +x /usr/local/nginx/sbin/check_nginx.sh 第二个:nginx cat > /etc/yum.repos.d/nginx.repo << EOF [nginx] name=nginx repo baseurl=http://nginx.org/packages/centos/7/$basearch/ gpgcheck=0 EOF stream { log_format main '$remote_addr $upstream_addr - [$time_local] $status $upstream_bytes_sent'; access_log /var/log/nginx/k8s-access.log main; upstream k8s-apiserver { server 10.0.0.3:6443; server 10.0.0.8:6443; } server { listen 6443; proxy_pass k8s-apiserver; } }
二、负载均衡调度器部署
//首先关闭防火墙: [root@localhost ~]# systemctl stop firewalld.service [root@localhost ~]# setenforce 0 //将这个脚本文件放进家目录中: [root@localhost ~]# ls anaconda-ks.cfg initial-setup-ks.cfg keepalived.conf nginx.sh 公共 模板 视频 图片 文档 下载 音乐 桌面 //建立本地yum仓库: [root@localhost ~]# vim /etc/yum.repos.d/nginx.repo [nginx] name=nginx repo baseurl=http://nginx.org/packages/centos/7/$basearch/ gpgcheck=0 [root@localhost ~]# yum list [root@localhost ~]# yum install nginx -y //下载nginx //接下来是添加四层转发: [root@localhost ~]# vim /etc/nginx/nginx.conf 添加以下模块: stream { log_format main '$remote_addr $upstream_addr - [$time_local] $status $upstream_bytes_sent'; access_log /var/log/nginx/k8s-access.log main; upstream k8s-apiserver { server 192.168.109.138:6443; //master01的IP地址 server 192.168.109.230:6443; //master02的IP地址 } server { listen 6443; proxy_pass k8s-apiserver; } } [root@localhost ~]# systemctl start nginx //开启服务 //接下来是部署 keepalived服务: [root@localhost ~]# yum install keepalived -y //修改配置文件(nginx01是master): [root@localhost ~]# cp keepalived.conf /etc/keepalived/keepalived.conf cp:是否覆盖"/etc/keepalived/keepalived.conf"? yes [root@localhost ~]# vim /etc/keepalived/keepalived.conf //做如下删改: ! Configuration File for keepalived global_defs { # 接收邮件地址 notification_email { acassen@firewall.loc failover@firewall.loc sysadmin@firewall.loc } # 邮件发送地址 notification_email_from Alexandre.Cassen@firewall.loc smtp_server 127.0.0.1 smtp_connect_timeout 30 router_id NGINX_MASTER } vrrp_script check_nginx { script "/etc/nginx/check_nginx.sh" ##检测脚本的路径,稍后会创建 } vrrp_instance VI_1 { state MASTER interface ens33 virtual_router_id 51 priority 100 ##优先级 advert_int 1 authentication { auth_type PASS auth_pass 1111 } virtual_ipaddress { 192.168.109.100/24 ##虚拟IP地址 } track_script { check_nginx } } //nginx02(是backup),配置如下: ! Configuration File for keepalived global_defs { # 接收邮件地址 notification_email { acassen@firewall.loc failover@firewall.loc sysadmin@firewall.loc } # 邮件发送地址 notification_email_from Alexandre.Cassen@firewall.loc smtp_server 127.0.0.1 smtp_connect_timeout 30 router_id NGINX_MASTER } vrrp_script check_nginx { script "/etc/nginx/check_nginx.sh" ##检测脚本的路径,稍后会创建 } vrrp_instance VI_1 { state BACKUP interface ens33 virtual_router_id 51 priority 90 ##优先级低于master advert_int 1 authentication { auth_type PASS auth_pass 1111 } virtual_ipaddress { 192.168.109.100/24 ##虚拟IP地址 } track_script { check_nginx } } //创建检测脚本 [root@localhost ~]# vim /etc/nginx/check_nginx.sh count=$(ps -ef |grep nginx |egrep -cv "grep|$$") if [ "$count" -eq 0 ];then systemctl stop keepalived fi [root@localhost ~]# chmod +x /etc/nginx/check_nginx.sh //授权 [root@localhost ~]# systemctl start keepalived.service //开启服务 [root@localhost ~]# ip a //查看ip地址
2、实验结果验证
验证一:漂移地址是否起作用(高可用是否实现)
1、此时 虚拟ip在 nginx01 上,验证地址漂移,可以在 lb01 中使用 pkill nginx 停止nginx服务,再在 lb02 上使用 ip a 命令查看地址是否进行了漂移。
2、恢复,此时,在 nginx02上,我们先启动 nginx服务,再启动 keepalived服务,再用 ip a命令查看,地址又漂移回来了,而 nginx02上没有虚拟ip。
验证二:验证负载均衡是否实现<此时VIP在bl2上>
1、修改nginx01(master)的首页内容:
[root@localhost ~]# vim /usr/share/nginx/html/index.htmlWelcome to master nginx!
2、修改nginx02(backup)的首页内容:
[root@localhost ~]# vim /usr/share/nginx/html/index.htmlWelcome to backup nginx!
3、用浏览器访问:http://192.168.109.100/
此时,负载均衡和高可用功能都已经完全实现了!!!
3、部署 node节点:
//开始修改 node节点配置文件统一的 VIP(bootstrap.kubeconfig,kubelet.kubeconfig) 修改内容:server: https://192.168.109.100:6443(都改成vip) [root@localhost cfg]# vim /opt/kubernetes/cfg/bootstrap.kubeconfig [root@localhost cfg]# vim /opt/kubernetes/cfg/kubelet.kubeconfig [root@localhost cfg]# vim /opt/kubernetes/cfg/kube-proxy.kubeconfig //重启服务: [root@localhost cfg]# systemctl restart kubelet.service [root@localhost cfg]# systemctl restart kube-proxy.service //检查修改内容: [root@localhost cfg]# grep 100 * bootstrap.kubeconfig: server: https://192.168.109.100:6443 kubelet.kubeconfig: server: https://192.168.109.100:6443 kube-proxy.kubeconfig: server: https://192.109.220.100:6443 //接下来在 调度器1 上查看 nginx的k8s日志: [root@localhost ~]# tail /var/log/nginx/k8s-access.log 192.168.109.131 192.168.109.138:6443 - [09/Feb/2020:13:14:45 +0800] 200 1122 192.168.109.131 192.168.109.230:6443 - [09/Feb/2020:13:14:45 +0800] 200 1121 192.168.109.132 192.168.109.138:6443 - [09/Feb/2020:13:18:14 +0800] 200 1120 192.168.109.132 192.168.109.230:6443 - [09/Feb/2020:13:18:14 +0800] 200 1121 可以看出是以轮询调度的算法,将请求流量分发给两台master ———— 接下来是测试创建 Pod: 在 master01 上操作: [root@localhost kubeconfig]# kubectl run nginx --image=nginx //查看状态: [root@localhost kubeconfig]# kubectl get pods NAME READY STATUS RESTARTS AGE nginx-dbddb74b8-zbhhr 1/1 Running 0 47s 此时已经创建完成,正在运行中 *** 注意日志问题 ***: [root@localhost kubeconfig]# kubectl logs nginx-dbddb74b8-zbhhr Error from server (Forbidden): Forbidden (user=system:anonymous, verb=get, resource=nodes, subresource=proxy) ( pods/log nginx-dbddb74b8-zbhhr) 此时,由于权限问题查看日志,会出现报错 解决办法(提升权限): [root@localhost kubeconfig]# kubectl create clusterrolebinding cluster-system-anonymous --clusterrole=cluster-admin --user=system:anonymous clusterrolebinding.rbac.authorization.k8s.io/cluster-system-anonymous created 此时,再次查看日志,就不会出现报错: //查看 Pod网络: [root@localhost kubeconfig]# kubectl get pods -o wide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE nginx-dbddb74b8-zbhhr 1/1 Running 0 7m11s 172.17.93.2 192.168.109.131可以看出,这个在master01上创建的pod被分配到了node01上了。 我们可以在对应网络的 node节点上操作就可以直接访问: 在node01上操作: [root@localhost cfg]# curl 172.17.93.2
此时,由于 flannel网络组件的作用下,都可以在node01和node02的浏览器上访问这个地址:172.17.93.2
由于刚刚访问了网页,我们也可以在 master01上查看到日志信息:
网页题目:kubernetes二进制集群部署三——负载均衡调度器部-创新互联
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