二进制安装Kubernetes(k8s) v1.27.3 IPv4/IPv6双栈 可脱离互联网
https://github.com/cby-chen/Kubernetes 开源不易,帮忙点个star,谢谢了
介绍
kubernetes(k8s)二进制高可用安装部署,支持IPv4+IPv6双栈。
我使用IPV6的目的是在公网进行访问,所以我配置了IPV6静态地址。
若您没有IPV6环境,或者不想使用IPv6,不对主机进行配置IPv6地址即可。
不配置IPV6,不影响后续,不过集群依旧是支持IPv6的。为后期留有扩展可能性。
若不要IPv6 ,不给网卡配置IPv6即可,不要对IPv6相关配置删除或操作,否则会出问题。
强烈建议在Github上查看文档 !!!
Github出问题会更新文档,并且后续尽可能第一时间更新新版本文档 !!!
手动项目地址:https://github.com/cby-chen/Kubernetes
1.环境
主机名称 | IP地址 | 说明 | 软件 |
---|---|---|---|
192.168.1.60 | 外网节点 | 下载各种所需安装包 | |
Master01 | 192.168.0.31 | master节点 | kube-apiserver、kube-controller-manager、kube-scheduler、etcd、kubelet、kube-proxy、nfs-client、haproxy、keepalived、nginx |
Master02 | 192.168.0.32 | master节点 | kube-apiserver、kube-controller-manager、kube-scheduler、etcd、kubelet、kube-proxy、nfs-client、haproxy、keepalived、nginx |
Master03 | 192.168.0.33 | master节点 | kube-apiserver、kube-controller-manager、kube-scheduler、etcd、kubelet、kube-proxy、nfs-client、haproxy、keepalived、nginx |
Node01 | 192.168.0.34 | node节点 | kubelet、kube-proxy、nfs-client、nginx |
Node02 | 192.168.0.35 | node节点 | kubelet、kube-proxy、nfs-client、nginx |
192.168.0.36 | VIP |
网段
物理主机:192.168.0.0/24
service:10.96.0.0/12
pod:172.16.0.0/12
安装包已经整理好:https://github.com/cby-chen/Kubernetes/releases/download/v1.27.3/kubernetes-v1.27.3.tar
1.1.k8s基础系统环境配置
1.2.配置IP
# 注意! # 若虚拟机是进行克隆的那么网卡的UUID会重复 # 若UUID重复需要重新生成新的UUID # UUID重复无法获取到IPV6地址 # # 查看当前的网卡列表和 UUID: # nmcli con show # 删除要更改 UUID 的网络连接: # nmcli con delete uuid <原 UUID> # 重新生成 UUID: # nmcli con add type ethernet ifname <接口名称> con-name <新名称> # 重新启用网络连接: # nmcli con up <新名称> # 更改网卡的UUID ssh root@192.168.0.31 "nmcli con delete uuid 708a1497-2192-43a5-9f03-2ab936fb3c44;nmcli con add type ethernet ifname eth0 con-name eth0;nmcli con up eth0" ssh root@192.168.0.32 "nmcli con delete uuid 708a1497-2192-43a5-9f03-2ab936fb3c44;nmcli con add type ethernet ifname eth0 con-name eth0;nmcli con up eth0" ssh root@192.168.0.33 "nmcli con delete uuid 708a1497-2192-43a5-9f03-2ab936fb3c44;nmcli con add type ethernet ifname eth0 con-name eth0;nmcli con up eth0" ssh root@192.168.0.34 "nmcli con delete uuid 708a1497-2192-43a5-9f03-2ab936fb3c44;nmcli con add type ethernet ifname eth0 con-name eth0;nmcli con up eth0" ssh root@192.168.0.35 "nmcli con delete uuid 708a1497-2192-43a5-9f03-2ab936fb3c44;nmcli con add type ethernet ifname eth0 con-name eth0;nmcli con up eth0" # 修改静态的IPv4地址 ssh root@192.168.0.154 "nmcli con mod eth0 ipv4.addresses 192.168.0.31/24; nmcli con mod eth0 ipv4.gateway 192.168.0.1; nmcli con mod eth0 ipv4.method manual; nmcli con mod eth0 ipv4.dns "8.8.8.8"; nmcli con up eth0" ssh root@192.168.0.156 "nmcli con mod eth0 ipv4.addresses 192.168.0.32/24; nmcli con mod eth0 ipv4.gateway 192.168.0.1; nmcli con mod eth0 ipv4.method manual; nmcli con mod eth0 ipv4.dns "8.8.8.8"; nmcli con up eth0" ssh root@192.168.0.164 "nmcli con mod eth0 ipv4.addresses 192.168.0.33/24; nmcli con mod eth0 ipv4.gateway 192.168.0.1; nmcli con mod eth0 ipv4.method manual; nmcli con mod eth0 ipv4.dns "8.8.8.8"; nmcli con up eth0" ssh root@192.168.0.166 "nmcli con mod eth0 ipv4.addresses 192.168.0.34/24; nmcli con mod eth0 ipv4.gateway 192.168.0.1; nmcli con mod eth0 ipv4.method manual; nmcli con mod eth0 ipv4.dns "8.8.8.8"; nmcli con up eth0" ssh root@192.168.0.167 "nmcli con mod eth0 ipv4.addresses 192.168.0.35/24; nmcli con mod eth0 ipv4.gateway 192.168.0.1; nmcli con mod eth0 ipv4.method manual; nmcli con mod eth0 ipv4.dns "8.8.8.8"; nmcli con up eth0" # 没有IPv6选择不配置即可 ssh root@192.168.0.31 "nmcli con mod eth0 ipv6.addresses fc00:43f4:1eea:1::10; nmcli con mod eth0 ipv6.gateway fc00:43f4:1eea:1::1; nmcli con mod eth0 ipv6.method manual; nmcli con mod eth0 ipv6.dns "2400:3200::1"; nmcli con up eth0" ssh root@192.168.0.32 "nmcli con mod eth0 ipv6.addresses fc00:43f4:1eea:1::20; nmcli con mod eth0 ipv6.gateway fc00:43f4:1eea:1::1; nmcli con mod eth0 ipv6.method manual; nmcli con mod eth0 ipv6.dns "2400:3200::1"; nmcli con up eth0" ssh root@192.168.0.33 "nmcli con mod eth0 ipv6.addresses fc00:43f4:1eea:1::30; nmcli con mod eth0 ipv6.gateway fc00:43f4:1eea:1::1; nmcli con mod eth0 ipv6.method manual; nmcli con mod eth0 ipv6.dns "2400:3200::1"; nmcli con up eth0" ssh root@192.168.0.34 "nmcli con mod eth0 ipv6.addresses fc00:43f4:1eea:1::40; nmcli con mod eth0 ipv6.gateway fc00:43f4:1eea:1::1; nmcli con mod eth0 ipv6.method manual; nmcli con mod eth0 ipv6.dns "2400:3200::1"; nmcli con up eth0" ssh root@192.168.0.35 "nmcli con mod eth0 ipv6.addresses fc00:43f4:1eea:1::50; nmcli con mod eth0 ipv6.gateway fc00:43f4:1eea:1::1; nmcli con mod eth0 ipv6.method manual; nmcli con mod eth0 ipv6.dns "2400:3200::1"; nmcli con up eth0" # 查看网卡配置 # nmcli device show eth0 # nmcli con show eth0 [root@localhost ~]# cat /etc/sysconfig/network-scripts/ifcfg-eth0 TYPE=Ethernet PROXY_METHOD=none BROWSER_ONLY=no BOOTPROTO=none DEFROUTE=yes IPV4_FAILURE_FATAL=no IPV6INIT=yes IPV6_AUTOCONF=no IPV6_DEFROUTE=yes IPV6_FAILURE_FATAL=no IPV6_ADDR_GEN_MODE=stable-privacy NAME=eth0 UUID=424fd260-c480-4899-97e6-6fc9722031e8 DEVICE=eth0 ONBOOT=yes IPADDR=192.168.0.31 PREFIX=24 GATEWAY=192.168.8.1 DNS1=8.8.8.8 IPV6ADDR=fc00:43f4:1eea:1::10/128 IPV6_DEFAULTGW=fc00:43f4:1eea:1::1 DNS2=2400:3200::1 [root@localhost ~]#
1.3.设置主机名
hostnamectl set-hostname k8s-master01 hostnamectl set-hostname k8s-master02 hostnamectl set-hostname k8s-master03 hostnamectl set-hostname k8s-node01 hostnamectl set-hostname k8s-node02
1.4.配置yum源
# 其他系统的源地址 # https://mirrors.tuna.tsinghua.edu.cn/help/ # 对于 Ubuntu sed -i 's/cn.archive.ubuntu.com/mirrors.ustc.edu.cn/g' /etc/apt/sources.list # 对于 CentOS 7 sudo sed -e 's|^mirrorlist=|#mirrorlist=|g' \ -e 's|^#baseurl=http://mirror.centos.org/centos|baseurl=https://mirrors.tuna.tsinghua.edu.cn/centos|g' \ -i.bak \ /etc/yum.repos.d/CentOS-*.repo # 对于 CentOS 8 sudo sed -e 's|^mirrorlist=|#mirrorlist=|g' \ -e 's|^#baseurl=http://mirror.centos.org/$contentdir|baseurl=https://mirrors.tuna.tsinghua.edu.cn/centos|g' \ -i.bak \ /etc/yum.repos.d/CentOS-*.repo # 对于私有仓库 sed -e 's|^mirrorlist=|#mirrorlist=|g' -e 's|^#baseurl=http://mirror.centos.org/\$contentdir|baseurl=http://192.168.1.123/centos|g' -i.bak /etc/yum.repos.d/CentOS-*.repo
1.5.安装一些必备工具
# 对于 Ubuntu apt update && apt upgrade -y && apt install -y wget psmisc vim net-tools nfs-kernel-server telnet lvm2 git tar curl # 对于 CentOS 7 yum update -y && yum -y install wget psmisc vim net-tools nfs-utils telnet yum-utils device-mapper-persistent-data lvm2 git tar curl # 对于 CentOS 8 yum update -y && yum -y install wget psmisc vim net-tools nfs-utils telnet yum-utils device-mapper-persistent-data lvm2 git network-scripts tar curl
1.5.1 下载离线所需文件(可选)
在互联网服务器上安装一个一模一样的系统进行下载所需包
CentOS7
# 下载必要工具 yum -y install createrepo yum-utils wget epel* # 下载全量依赖包 repotrack createrepo wget psmisc vim net-tools nfs-utils telnet yum-utils device-mapper-persistent-data lvm2 git tar curl gcc keepalived haproxy bash-completion chrony sshpass ipvsadm ipset sysstat conntrack libseccomp # 删除libseccomp rm -rf libseccomp-*.rpm # 下载libseccomp wget http://rpmfind.net/linux/centos/8-stream/BaseOS/x86_64/os/Packages/libseccomp-2.5.1-1.el8.x86_64.rpm # 创建yum源信息 createrepo -u -d /data/centos7/ # 拷贝包到内网机器上 scp -r /data/centos7/ root@192.168.0.31: scp -r /data/centos7/ root@192.168.0.32: scp -r /data/centos7/ root@192.168.0.33: scp -r /data/centos7/ root@192.168.0.34: scp -r /data/centos7/ root@192.168.0.35: # 在内网机器上创建repo配置文件 rm -rf /etc/yum.repos.d/* cat > /etc/yum.repos.d/123.repo << EOF [cby] name=CentOS-$releasever - Media baseurl=file:///root/centos7/ gpgcheck=0 enabled=1 EOF # 安装下载好的包 yum clean all yum makecache yum install /root/centos7/* --skip-broken -y #### 备注 ##### # 安装完成后,可能还会出现yum无法使用那么再次执行 rm -rf /etc/yum.repos.d/* cat > /etc/yum.repos.d/123.repo << EOF [cby] name=CentOS-$releasever - Media baseurl=file:///root/centos7/ gpgcheck=0 enabled=1 EOF yum clean all yum makecache yum install /root/centos7/* --skip-broken -y #### 备注 ##### # 安装 chrony 和 libseccomp # yum install /root/centos7/libseccomp-2.5.1*.rpm -y # yum install /root/centos7/chrony-*.rpm -y
CentOS8
# 下载必要工具 yum -y install createrepo yum-utils wget epel* # 下载全量依赖包 repotrack wget psmisc vim net-tools nfs-utils telnet yum-utils device-mapper-persistent-data lvm2 git network-scripts tar curl gcc keepalived haproxy bash-completion chrony sshpass ipvsadm ipset sysstat conntrack libseccomp # 创建yum源信息 createrepo -u -d /data/centos8/ # 拷贝包到内网机器上 scp -r centos8/ root@192.168.0.31: scp -r centos8/ root@192.168.0.32: scp -r centos8/ root@192.168.0.33: scp -r centos8/ root@192.168.0.34: scp -r centos8/ root@192.168.0.35: # 在内网机器上创建repo配置文件 rm -rf /etc/yum.repos.d/* cat > /etc/yum.repos.d/123.repo << EOF [cby] name=CentOS-$releasever - Media baseurl=file:///root/centos8/ gpgcheck=0 enabled=1 EOF # 安装下载好的包 yum clean all yum makecache yum install /root/centos8/* --skip-broken -y #### 备注 ##### # 安装完成后,可能还会出现yum无法使用那么再次执行 rm -rf /etc/yum.repos.d/* cat > /etc/yum.repos.d/123.repo << EOF [cby] name=CentOS-$releasever - Media baseurl=file:///root/centos8/ gpgcheck=0 enabled=1 EOF yum clean all yum makecache yum install /root/centos8/* --skip-broken -y
Ubuntu 下载包和依赖
#!/bin/bash logfile=123.log ret="" function getDepends() { echo "fileName is" $1>>$logfile # use tr to del < > ret=`apt-cache depends $1|grep Depends |cut -d: -f2 |tr -d "<>"` echo $ret|tee -a $logfile } # 需要获取其所依赖包的包 libs="wget psmisc vim net-tools nfs-kernel-server telnet lvm2 git tar curl gcc keepalived haproxy bash-completion chrony sshpass ipvsadm ipset sysstat conntrack libseccomp" # download libs dependen. deep in 3 i=0 while [ $i -lt 3 ] ; do let i++ echo $i # download libs newlist=" " for j in $libs do added="$(getDepends $j)" newlist="$newlist $added" apt install $added --reinstall -d -y done libs=$newlist done # 创建源信息 apt install dpkg-dev sudo cp /var/cache/apt/archives/*.deb /data/ubuntu/ -r dpkg-scanpackages . /dev/null |gzip > /data/ubuntu/Packages.gz -r # 拷贝包到内网机器上 scp -r ubuntu/ root@192.168.0.31: scp -r ubuntu/ root@192.168.0.32: scp -r ubuntu/ root@192.168.0.33: scp -r ubuntu/ root@192.168.0.34: scp -r ubuntu/ root@192.168.0.35: # 在内网机器上配置apt源 vim /etc/apt/sources.list cat /etc/apt/sources.list deb file:////root/ ubuntu/ # 安装deb包 apt install ./*.deb
1.6.选择性下载需要工具
#!/bin/bash # 查看版本地址: # # https://github.com/containernetworking/plugins/releases/ # https://github.com/containerd/containerd/releases/ # https://github.com/kubernetes-sigs/cri-tools/releases/ # https://github.com/Mirantis/cri-dockerd/releases/ # https://github.com/etcd-io/etcd/releases/ # https://github.com/cloudflare/cfssl/releases/ # https://github.com/kubernetes/kubernetes/tree/master/CHANGELOG # https://download.docker.com/linux/static/stable/x86_64/ # https://github.com/opencontainers/runc/releases/ # https://mirrors.tuna.tsinghua.edu.cn/elrepo/kernel/el7/x86_64/RPMS/ # https://github.com/helm/helm/tags # http://nginx.org/download/ # Version numbers cni_plugins_version='v1.3.0' cri_containerd_cni_version='1.7.2' crictl_version='v1.27.0' cri_dockerd_version='0.3.3' etcd_version='v3.5.9' cfssl_version='1.6.4' kubernetes_server_version='1.27.3' docker_version='24.0.2' runc_version='1.1.7' kernel_version='5.4.248' helm_version='3.12.1' nginx_version='1.25.1' # URLs base_url='https://mirrors.chenby.cn/https://github.com' kernel_url="http://mirrors.tuna.tsinghua.edu.cn/elrepo/kernel/el7/x86_64/RPMS/kernel-lt-${kernel_version}-1.el7.elrepo.x86_64.rpm" runc_url="${base_url}/opencontainers/runc/releases/download/v${runc_version}/runc.amd64" docker_url="https://download.docker.com/linux/static/stable/x86_64/docker-${docker_version}.tgz" cni_plugins_url="${base_url}/containernetworking/plugins/releases/download/${cni_plugins_version}/cni-plugins-linux-amd64-${cni_plugins_version}.tgz" cri_containerd_cni_url="${base_url}/containerd/containerd/releases/download/v${cri_containerd_cni_version}/cri-containerd-cni-${cri_containerd_cni_version}-linux-amd64.tar.gz" crictl_url="${base_url}/kubernetes-sigs/cri-tools/releases/download/${crictl_version}/crictl-${crictl_version}-linux-amd64.tar.gz" cri_dockerd_url="${base_url}/Mirantis/cri-dockerd/releases/download/v${cri_dockerd_version}/cri-dockerd-${cri_dockerd_version}.amd64.tgz" etcd_url="${base_url}/etcd-io/etcd/releases/download/${etcd_version}/etcd-${etcd_version}-linux-amd64.tar.gz" cfssl_url="${base_url}/cloudflare/cfssl/releases/download/v${cfssl_version}/cfssl_${cfssl_version}_linux_amd64" cfssljson_url="${base_url}/cloudflare/cfssl/releases/download/v${cfssl_version}/cfssljson_${cfssl_version}_linux_amd64" helm_url="https://files.m.daocloud.io/get.helm.sh/helm-v${helm_version}-linux-amd64.tar.gz" kubernetes_server_url="https://dl.k8s.io/v${kubernetes_server_version}/kubernetes-server-linux-amd64.tar.gz" nginx_url="http://nginx.org/download/nginx-${nginx_version}.tar.gz" # Download packages packages=( $kernel_url $runc_url $docker_url $cni_plugins_url $cri_containerd_cni_url $crictl_url $cri_dockerd_url $etcd_url $cfssl_url $cfssljson_url $helm_url $kubernetes_server_url $nginx_url ) for package_url in "${packages[@]}"; do filename=$(basename "$package_url") if wget -cq --progress=bar:force:noscroll -nc "$package_url"; then echo "Downloaded $filename" else echo "Failed to download $filename" exit 1 fi done
1.7.关闭防火墙
# Ubuntu忽略,CentOS执行 systemctl disable --now firewalld
1.8.关闭SELinux
# Ubuntu忽略,CentOS执行 setenforce 0 sed -i 's#SELINUX=enforcing#SELINUX=disabled#g' /etc/selinux/config
1.9.关闭交换分区
sed -ri 's/.*swap.*/#&/' /etc/fstab swapoff -a && sysctl -w vm.swappiness=0 cat /etc/fstab # /dev/mapper/centos-swap swap swap defaults 0 0
1.10.网络配置(俩种方式二选一)
# Ubuntu忽略,CentOS执行 # 方式一 # systemctl disable --now NetworkManager # systemctl start network && systemctl enable network # 方式二 cat > /etc/NetworkManager/conf.d/calico.conf << EOF [keyfile] unmanaged-devices=interface-name:cali*;interface-name:tunl* EOF systemctl restart NetworkManager
1.11.进行时间同步
# 服务端 # apt install chrony -y yum install chrony -y cat > /etc/chrony.conf << EOF pool ntp.aliyun.com iburst driftfile /var/lib/chrony/drift makestep 1.0 3 rtcsync allow 192.168.0.0/24 local stratum 10 keyfile /etc/chrony.keys leapsectz right/UTC logdir /var/log/chrony EOF systemctl restart chronyd ; systemctl enable chronyd # 客户端 # apt install chrony -y yum install chrony -y cat > /etc/chrony.conf << EOF pool 192.168.0.31 iburst driftfile /var/lib/chrony/drift makestep 1.0 3 rtcsync keyfile /etc/chrony.keys leapsectz right/UTC logdir /var/log/chrony EOF systemctl restart chronyd ; systemctl enable chronyd #使用客户端进行验证 chronyc sources -v
1.12.配置ulimit
ulimit -SHn 65535 cat >> /etc/security/limits.conf <<EOF * soft nofile 655360 * hard nofile 131072 * soft nproc 655350 * hard nproc 655350 * seft memlock unlimited * hard memlock unlimitedd EOF
1.13.配置免密登录
# apt install -y sshpass yum install -y sshpass ssh-keygen -f /root/.ssh/id_rsa -P '' export IP="192.168.0.31 192.168.0.32 192.168.0.33 192.168.0.34 192.168.0.35" export SSHPASS=123123 for HOST in $IP;do sshpass -e ssh-copy-id -o StrictHostKeyChecking=no $HOST done
1.14.添加启用源
# Ubuntu忽略,CentOS执行 # 为 RHEL-8或 CentOS-8配置源 yum install https://www.elrepo.org/elrepo-release-8.el8.elrepo.noarch.rpm -y sed -i "s@mirrorlist@#mirrorlist@g" /etc/yum.repos.d/elrepo.repo sed -i "s@elrepo.org/linux@mirrors.tuna.tsinghua.edu.cn/elrepo@g" /etc/yum.repos.d/elrepo.repo # 为 RHEL-7 SL-7 或 CentOS-7 安装 ELRepo yum install https://www.elrepo.org/elrepo-release-7.el7.elrepo.noarch.rpm -y sed -i "s@mirrorlist@#mirrorlist@g" /etc/yum.repos.d/elrepo.repo sed -i "s@elrepo.org/linux@mirrors.tuna.tsinghua.edu.cn/elrepo@g" /etc/yum.repos.d/elrepo.repo # 查看可用安装包 yum --disablerepo="*" --enablerepo="elrepo-kernel" list available
1.15.升级内核至4.18版本以上
# Ubuntu忽略,CentOS执行 # 安装最新的内核 # 我这里选择的是稳定版kernel-ml 如需更新长期维护版本kernel-lt yum -y --enablerepo=elrepo-kernel install kernel-ml # 查看已安装那些内核 rpm -qa | grep kernel # 查看默认内核 grubby --default-kernel # 若不是最新的使用命令设置 grubby --set-default $(ls /boot/vmlinuz-* | grep elrepo) # 重启生效 reboot # v8 整合命令为: yum install https://www.elrepo.org/elrepo-release-8.el8.elrepo.noarch.rpm -y ; sed -i "s@mirrorlist@#mirrorlist@g" /etc/yum.repos.d/elrepo.repo ; sed -i "s@elrepo.org/linux@mirrors.tuna.tsinghua.edu.cn/elrepo@g" /etc/yum.repos.d/elrepo.repo ; yum --disablerepo="*" --enablerepo="elrepo-kernel" list available -y ; yum --enablerepo=elrepo-kernel install kernel-lt -y ; grubby --default-kernel ; reboot # v7 整合命令为: yum install https://www.elrepo.org/elrepo-release-7.el7.elrepo.noarch.rpm -y ; sed -i "s@mirrorlist@#mirrorlist@g" /etc/yum.repos.d/elrepo.repo ; sed -i "s@elrepo.org/linux@mirrors.tuna.tsinghua.edu.cn/elrepo@g" /etc/yum.repos.d/elrepo.repo ; yum --disablerepo="*" --enablerepo="elrepo-kernel" list available -y ; yum --enablerepo=elrepo-kernel install kernel-lt -y ; grubby --set-default $(ls /boot/vmlinuz-* | grep elrepo) ; grubby --default-kernel ; reboot # 离线版本 yum install -y /root/cby/kernel-lt-*-1.el7.elrepo.x86_64.rpm ; grubby --set-default $(ls /boot/vmlinuz-* | grep elrepo) ; grubby --default-kernel ; reboot
1.16.安装ipvsadm
# 对于CentOS7离线安装 # yum install /root/centos7/ipset-*.el7.x86_64.rpm /root/centos7/lm_sensors-libs-*.el7.x86_64.rpm /root/centos7/ipset-libs-*.el7.x86_64.rpm /root/centos7/sysstat-*.el7_9.x86_64.rpm /root/centos7/ipvsadm-*.el7.x86_64.rpm -y # 对于 Ubuntu # apt install ipvsadm ipset sysstat conntrack -y # 对于 CentOS yum install ipvsadm ipset sysstat conntrack libseccomp -y cat >> /etc/modules-load.d/ipvs.conf <<EOF ip_vs ip_vs_rr ip_vs_wrr ip_vs_sh nf_conntrack ip_tables ip_set xt_set ipt_set ipt_rpfilter ipt_REJECT ipip EOF systemctl restart systemd-modules-load.service lsmod | grep -e ip_vs -e nf_conntrack ip_vs_sh 16384 0 ip_vs_wrr 16384 0 ip_vs_rr 16384 0 ip_vs 180224 6 ip_vs_rr,ip_vs_sh,ip_vs_wrr nf_conntrack 176128 1 ip_vs nf_defrag_ipv6 24576 2 nf_conntrack,ip_vs nf_defrag_ipv4 16384 1 nf_conntrack libcrc32c 16384 3 nf_conntrack,xfs,ip_vs
1.17.修改内核参数
cat <<EOF > /etc/sysctl.d/k8s.conf net.ipv4.ip_forward = 1 net.bridge.bridge-nf-call-iptables = 1 fs.may_detach_mounts = 1 vm.overcommit_memory=1 vm.panic_on_oom=0 fs.inotify.max_user_watches=89100 fs.file-max=52706963 fs.nr_open=52706963 net.netfilter.nf_conntrack_max=2310720 net.ipv4.tcp_keepalive_time = 600 net.ipv4.tcp_keepalive_probes = 3 net.ipv4.tcp_keepalive_intvl =15 net.ipv4.tcp_max_tw_buckets = 36000 net.ipv4.tcp_tw_reuse = 1 net.ipv4.tcp_max_orphans = 327680 net.ipv4.tcp_orphan_retries = 3 net.ipv4.tcp_syncookies = 1 net.ipv4.tcp_max_syn_backlog = 16384 net.ipv4.ip_conntrack_max = 65536 net.ipv4.tcp_max_syn_backlog = 16384 net.ipv4.tcp_timestamps = 0 net.core.somaxconn = 16384 net.ipv6.conf.all.disable_ipv6 = 0 net.ipv6.conf.default.disable_ipv6 = 0 net.ipv6.conf.lo.disable_ipv6 = 0 net.ipv6.conf.all.forwarding = 1 EOF sysctl --system
1.18.所有节点配置hosts本地解析
cat > /etc/hosts <<EOF 127.0.0.1 localhost localhost.localdomain localhost4 localhost4.localdomain4 ::1 localhost localhost.localdomain localhost6 localhost6.localdomain6 192.168.0.31 k8s-master01 192.168.0.32 k8s-master02 192.168.0.33 k8s-master03 192.168.0.34 k8s-node01 192.168.0.35 k8s-node02 192.168.0.36 lb-vip EOF
2.k8s基本组件安装
注意 : 2.1 和 2.2 二选其一即可
2.1.安装Containerd作为Runtime (推荐)
# https://github.com/containernetworking/plugins/releases/ # wget https://mirrors.chenby.cn/https://github.com/containernetworking/plugins/releases/download/v1.3.0/cni-plugins-linux-amd64-v1.3.0.tgz cd cby/ #创建cni插件所需目录 mkdir -p /etc/cni/net.d /opt/cni/bin #解压cni二进制包 tar xf cni-plugins-linux-amd64-v*.tgz -C /opt/cni/bin/ # https://github.com/containerd/containerd/releases/ # wget https://mirrors.chenby.cn/https://github.com/containerd/containerd/releases/download/v1.7.2/cri-containerd-cni-1.7.2-linux-amd64.tar.gz #解压 tar -xzf cri-containerd-cni-*-linux-amd64.tar.gz -C / #创建服务启动文件 cat > /etc/systemd/system/containerd.service <<EOF [Unit] Description=containerd container runtime Documentation=https://containerd.io After=network.target local-fs.target [Service] ExecStartPre=-/sbin/modprobe overlay ExecStart=/usr/local/bin/containerd Type=notify Delegate=yes KillMode=process Restart=always RestartSec=5 LimitNPROC=infinity LimitCORE=infinity LimitNOFILE=infinity TasksMax=infinity OOMScoreAdjust=-999 [Install] WantedBy=multi-user.target EOF
2.1.1配置Containerd所需的模块
cat <<EOF | sudo tee /etc/modules-load.d/containerd.conf overlay br_netfilter EOF
2.1.2加载模块
systemctl restart systemd-modules-load.service
2.1.3配置Containerd所需的内核
cat <<EOF | sudo tee /etc/sysctl.d/99-kubernetes-cri.conf net.bridge.bridge-nf-call-iptables = 1 net.ipv4.ip_forward = 1 net.bridge.bridge-nf-call-ip6tables = 1 EOF # 加载内核 sysctl --system
2.1.4创建Containerd的配置文件
# 创建默认配置文件 mkdir -p /etc/containerd containerd config default | tee /etc/containerd/config.toml # 修改Containerd的配置文件 sed -i "s#SystemdCgroup\ \=\ false#SystemdCgroup\ \=\ true#g" /etc/containerd/config.toml cat /etc/containerd/config.toml | grep SystemdCgroup sed -i "s#registry.k8s.io#m.daocloud.io/registry.k8s.io#g" /etc/containerd/config.toml cat /etc/containerd/config.toml | grep sandbox_image sed -i "s#config_path\ \=\ \"\"#config_path\ \=\ \"/etc/containerd/certs.d\"#g" /etc/containerd/config.toml cat /etc/containerd/config.toml | grep certs.d mkdir /etc/containerd/certs.d/docker.io -pv # 配置加速器 cat > /etc/containerd/certs.d/docker.io/hosts.toml << EOF server = "https://docker.io" [host."https://hub-mirror.c.163.com"] capabilities = ["pull", "resolve"] EOF
2.1.5启动并设置为开机启动
systemctl daemon-reload systemctl enable --now containerd systemctl restart containerd
2.1.6配置crictl客户端连接的运行时位置
# wget https://github.com/kubernetes-sigs/cri-tools/releases/download/v1.24.2/crictl-v1.24.2-linux-amd64.tar.gz #解压 tar xf crictl-v*-linux-amd64.tar.gz -C /usr/bin/ #生成配置文件 cat > /etc/crictl.yaml <<EOF runtime-endpoint: unix:///run/containerd/containerd.sock image-endpoint: unix:///run/containerd/containerd.sock timeout: 10 debug: false EOF #测试 systemctl restart containerd crictl info
2.2 安装docker作为Runtime
2.2.1 安装docker
# 二进制包下载地址:https://download.docker.com/linux/static/stable/x86_64/ # wget https://download.docker.com/linux/static/stable/x86_64/docker-24.0.2.tgz #解压 tar xf docker-*.tgz #拷贝二进制文件 cp docker/* /usr/bin/ #创建containerd的service文件,并且启动 cat >/etc/systemd/system/containerd.service <<EOF [Unit] Description=containerd container runtime Documentation=https://containerd.io After=network.target local-fs.target [Service] ExecStartPre=-/sbin/modprobe overlay ExecStart=/usr/bin/containerd Type=notify Delegate=yes KillMode=process Restart=always RestartSec=5 LimitNPROC=infinity LimitCORE=infinity LimitNOFILE=1048576 TasksMax=infinity OOMScoreAdjust=-999 [Install] WantedBy=multi-user.target EOF # 设置开机自启 systemctl enable --now containerd.service #准备docker的service文件 cat > /etc/systemd/system/docker.service <<EOF [Unit] Description=Docker Application Container Engine Documentation=https://docs.docker.com After=network-online.target firewalld.service containerd.service Wants=network-online.target Requires=docker.socket containerd.service [Service] Type=notify ExecStart=/usr/bin/dockerd -H fd:// --containerd=/run/containerd/containerd.sock ExecReload=/bin/kill -s HUP $MAINPID TimeoutSec=0 RestartSec=2 Restart=always StartLimitBurst=3 StartLimitInterval=60s LimitNOFILE=infinity LimitNPROC=infinity LimitCORE=infinity TasksMax=infinity Delegate=yes KillMode=process OOMScoreAdjust=-500 [Install] WantedBy=multi-user.target EOF #准备docker的socket文件 cat > /etc/systemd/system/docker.socket <<EOF [Unit] Description=Docker Socket for the API [Socket] ListenStream=/var/run/docker.sock SocketMode=0660 SocketUser=root SocketGroup=docker [Install] WantedBy=sockets.target EOF #创建docker组 groupadd docker #启动docker systemctl enable --now docker.socket && systemctl enable --now docker.service #验证 docker info # 配置加速器 mkdir /etc/docker/ -pv cat >/etc/docker/daemon.json <<EOF { "exec-opts": ["native.cgroupdriver=systemd"], "registry-mirrors": [ "https://docker.m.daocloud.io", "https://docker.mirrors.ustc.edu.cn", "http://hub-mirror.c.163.com" ], "max-concurrent-downloads": 10, "log-driver": "json-file", "log-level": "warn", "log-opts": { "max-size": "10m", "max-file": "3" }, "data-root": "/var/lib/docker" } EOF systemctl daemon-reload systemctl stop docker systemctl restart docker
2.2.2 安装cri-docker
# 由于1.24以及更高版本不支持docker所以安装cri-docker # 下载cri-docker # wget https://mirrors.chenby.cn/https://github.com/Mirantis/cri-dockerd/releases/download/v0.3.3/cri-dockerd-0.3.3.amd64.tgz # 解压cri-docker tar xvf cri-dockerd-*.amd64.tgz cp -r cri-dockerd/ /usr/bin/ chmod +x /usr/bin/cri-dockerd/cri-dockerd # 写入启动配置文件 cat > /usr/lib/systemd/system/cri-docker.service <<EOF [Unit] Description=CRI Interface for Docker Application Container Engine Documentation=https://docs.mirantis.com After=network-online.target firewalld.service docker.service Wants=network-online.target Requires=cri-docker.socket [Service] Type=notify ExecStart=/usr/bin/cri-dockerd/cri-dockerd --network-plugin=cni --pod-infra-container-image=registry.aliyuncs.com/google_containers/pause:3.7 ExecReload=/bin/kill -s HUP $MAINPID TimeoutSec=0 RestartSec=2 Restart=always StartLimitBurst=3 StartLimitInterval=60s LimitNOFILE=infinity LimitNPROC=infinity LimitCORE=infinity TasksMax=infinity Delegate=yes KillMode=process [Install] WantedBy=multi-user.target EOF # 写入socket配置文件 cat > /usr/lib/systemd/system/cri-docker.socket <<EOF [Unit] Description=CRI Docker Socket for the API PartOf=cri-docker.service [Socket] ListenStream=%t/cri-dockerd.sock SocketMode=0660 SocketUser=root SocketGroup=docker [Install] WantedBy=sockets.target EOF # 进行启动cri-docker systemctl daemon-reload systemctl enable cri-docker --now systemctl restart cri-docker systemctl status cri-docker
2.3.k8s与etcd下载及安装(仅在master01操作)
2.3.1解压k8s安装包
# 下载安装包 # wget https://dl.k8s.io/v1.27.3/kubernetes-server-linux-amd64.tar.gz # wget https://github.com/etcd-io/etcd/releases/download/v3.5.9/etcd-v3.5.9-linux-amd64.tar.gz # 解压k8s安装文件 cd cby tar -xf kubernetes-server-linux-amd64.tar.gz --strip-components=3 -C /usr/local/bin kubernetes/server/bin/kube{let,ctl,-apiserver,-controller-manager,-scheduler,-proxy} # 解压etcd安装文件 tar -xf etcd*.tar.gz && mv etcd-*/etcd /usr/local/bin/ && mv etcd-*/etcdctl /usr/local/bin/ # 查看/usr/local/bin下内容 ls /usr/local/bin/ containerd crictl etcdctl kube-proxy containerd-shim critest kube-apiserver kube-scheduler containerd-shim-runc-v1 ctd-decoder kube-controller-manager containerd-shim-runc-v2 ctr kubectl containerd-stress etcd kubelet
2.3.2查看版本
[root@k8s-master01 ~]# kubelet --version Kubernetes v1.27.3 [root@k8s-master01 ~]# etcdctl version etcdctl version: 3.5.9 API version: 3.5 [root@k8s-master01 ~]#
2.3.3将组件发送至其他k8s节点
Master='k8s-master02 k8s-master03' Work='k8s-node01 k8s-node02' # 拷贝master组件 for NODE in $Master; do echo $NODE; scp /usr/local/bin/kube{let,ctl,-apiserver,-controller-manager,-scheduler,-proxy} $NODE:/usr/local/bin/; scp /usr/local/bin/etcd* $NODE:/usr/local/bin/; done # 拷贝work组件 for NODE in $Work; do scp /usr/local/bin/kube{let,-proxy} $NODE:/usr/local/bin/ ; done # 所有节点执行 mkdir -p /opt/cni/bin
2.3创建证书相关文件
# 请查看Github仓库 或者进行获取已经打好的包 https://github.com/cby-chen/Kubernetes/ https://github.com/cby-chen/Kubernetes/tags https://github.com/cby-chen/Kubernetes/releases/download/v1.27.3/kubernetes-v1.27.3.tar
3.相关证书生成
# master01节点下载证书生成工具 # wget "https://mirrors.chenby.cn/https://github.com/cloudflare/cfssl/releases/download/v1.6.4/cfssl_1.6.4_linux_amd64" -O /usr/local/bin/cfssl # wget "https://mirrors.chenby.cn/https://github.com/cloudflare/cfssl/releases/download/v1.6.4/cfssljson_1.6.4_linux_amd64" -O /usr/local/bin/cfssljson # 软件包内有 cp cfssl_*_linux_amd64 /usr/local/bin/cfssl cp cfssljson_*_linux_amd64 /usr/local/bin/cfssljson # 添加执行权限 chmod +x /usr/local/bin/cfssl /usr/local/bin/cfssljson
3.1.生成etcd证书
特别说明除外,以下操作在所有master节点操作
3.1.1所有master节点创建证书存放目录
mkdir /etc/etcd/ssl -p
3.1.2master01节点生成etcd证书
cd pki # 生成etcd证书和etcd证书的key(如果你觉得以后可能会扩容,可以在ip那多写几个预留出来) # 若没有IPv6 可删除可保留 cfssl gencert -initca etcd-ca-csr.json | cfssljson -bare /etc/etcd/ssl/etcd-ca cfssl gencert \ -ca=/etc/etcd/ssl/etcd-ca.pem \ -ca-key=/etc/etcd/ssl/etcd-ca-key.pem \ -config=ca-config.json \ -hostname=127.0.0.1,k8s-master01,k8s-master02,k8s-master03,192.168.0.31,192.168.0.32,192.168.0.33,fc00:43f4:1eea:1::10,fc00:43f4:1eea:1::20,fc00:43f4:1eea:1::30,::1 \ -profile=kubernetes \ etcd-csr.json | cfssljson -bare /etc/etcd/ssl/etcd
3.1.3将证书复制到其他节点
Master='k8s-master02 k8s-master03' for NODE in $Master; do ssh $NODE "mkdir -p /etc/etcd/ssl"; for FILE in etcd-ca-key.pem etcd-ca.pem etcd-key.pem etcd.pem; do scp /etc/etcd/ssl/${FILE} $NODE:/etc/etcd/ssl/${FILE}; done; done
3.2.生成k8s相关证书
特别说明除外,以下操作在所有master节点操作
3.2.1所有k8s节点创建证书存放目录
mkdir -p /etc/kubernetes/pki
3.2.2master01节点生成k8s证书
cfssl gencert -initca ca-csr.json | cfssljson -bare /etc/kubernetes/pki/ca # 生成一个根证书 ,多写了一些IP作为预留IP,为将来添加node做准备 # 10.96.0.1是service网段的第一个地址,需要计算,192.168.0.36为高可用vip地址 # 若没有IPv6 可删除可保留 cfssl gencert \ -ca=/etc/kubernetes/pki/ca.pem \ -ca-key=/etc/kubernetes/pki/ca-key.pem \ -config=ca-config.json \ -hostname=10.96.0.1,192.168.0.36,127.0.0.1,kubernetes,kubernetes.default,kubernetes.default.svc,kubernetes.default.svc.cluster,kubernetes.default.svc.cluster.local,x.oiox.cn,k.oiox.cn,l.oiox.cn,o.oiox.cn,192.168.0.31,192.168.0.32,192.168.0.33,192.168.0.34,192.168.0.35,192.168.0.36,192.168.0.37,192.168.0.38,192.168.0.39,192.168.1.70,fc00:43f4:1eea:1::10,fc00:43f4:1eea:1::20,fc00:43f4:1eea:1::30,fc00:43f4:1eea:1::40,fc00:43f4:1eea:1::50,fc00:43f4:1eea:1::60,fc00:43f4:1eea:1::70,fc00:43f4:1eea:1::80,fc00:43f4:1eea:1::90,fc00:43f4:1eea:1::100,::1 \ -profile=kubernetes apiserver-csr.json | cfssljson -bare /etc/kubernetes/pki/apiserver
3.2.3生成apiserver聚合证书
cfssl gencert -initca front-proxy-ca-csr.json | cfssljson -bare /etc/kubernetes/pki/front-proxy-ca # 有一个警告,可以忽略 cfssl gencert \ -ca=/etc/kubernetes/pki/front-proxy-ca.pem \ -ca-key=/etc/kubernetes/pki/front-proxy-ca-key.pem \ -config=ca-config.json \ -profile=kubernetes front-proxy-client-csr.json | cfssljson -bare /etc/kubernetes/pki/front-proxy-client
3.2.4生成controller-manage的证书
在《5.高可用配置》选择使用那种高可用方案
若使用 haproxy、keepalived 那么为 --server=https://192.168.0.36:9443
若使用 nginx方案,那么为 --server=https://127.0.0.1:8443
cfssl gencert \ -ca=/etc/kubernetes/pki/ca.pem \ -ca-key=/etc/kubernetes/pki/ca-key.pem \ -config=ca-config.json \ -profile=kubernetes \ manager-csr.json | cfssljson -bare /etc/kubernetes/pki/controller-manager # 设置一个集群项 # 在《5.高可用配置》选择使用那种高可用方案 # 若使用 haproxy、keepalived 那么为 `--server=https://192.168.0.36:8443` # 若使用 nginx方案,那么为 `--server=https://127.0.0.1:8443` kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/pki/ca.pem \ --embed-certs=true \ --server=https://127.0.0.1:8443 \ --kubeconfig=/etc/kubernetes/controller-manager.kubeconfig # 设置一个环境项,一个上下文 kubectl config set-context system:kube-controller-manager@kubernetes \ --cluster=kubernetes \ --user=system:kube-controller-manager \ --kubeconfig=/etc/kubernetes/controller-manager.kubeconfig # 设置一个用户项 kubectl config set-credentials system:kube-controller-manager \ --client-certificate=/etc/kubernetes/pki/controller-manager.pem \ --client-key=/etc/kubernetes/pki/controller-manager-key.pem \ --embed-certs=true \ --kubeconfig=/etc/kubernetes/controller-manager.kubeconfig # 设置默认环境 kubectl config use-context system:kube-controller-manager@kubernetes \ --kubeconfig=/etc/kubernetes/controller-manager.kubeconfig cfssl gencert \ -ca=/etc/kubernetes/pki/ca.pem \ -ca-key=/etc/kubernetes/pki/ca-key.pem \ -config=ca-config.json \ -profile=kubernetes \ scheduler-csr.json | cfssljson -bare /etc/kubernetes/pki/scheduler # 在《5.高可用配置》选择使用那种高可用方案 # 若使用 haproxy、keepalived 那么为 `--server=https://192.168.0.36:8443` # 若使用 nginx方案,那么为 `--server=https://127.0.0.1:8443` kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/pki/ca.pem \ --embed-certs=true \ --server=https://127.0.0.1:8443 \ --kubeconfig=/etc/kubernetes/scheduler.kubeconfig kubectl config set-credentials system:kube-scheduler \ --client-certificate=/etc/kubernetes/pki/scheduler.pem \ --client-key=/etc/kubernetes/pki/scheduler-key.pem \ --embed-certs=true \ --kubeconfig=/etc/kubernetes/scheduler.kubeconfig kubectl config set-context system:kube-scheduler@kubernetes \ --cluster=kubernetes \ --user=system:kube-scheduler \ --kubeconfig=/etc/kubernetes/scheduler.kubeconfig kubectl config use-context system:kube-scheduler@kubernetes \ --kubeconfig=/etc/kubernetes/scheduler.kubeconfig cfssl gencert \ -ca=/etc/kubernetes/pki/ca.pem \ -ca-key=/etc/kubernetes/pki/ca-key.pem \ -config=ca-config.json \ -profile=kubernetes \ admin-csr.json | cfssljson -bare /etc/kubernetes/pki/admin # 在《5.高可用配置》选择使用那种高可用方案 # 若使用 haproxy、keepalived 那么为 `--server=https://192.168.0.36:8443` # 若使用 nginx方案,那么为 `--server=https://127.0.0.1:8443` kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/pki/ca.pem \ --embed-certs=true \ --server=https://127.0.0.1:8443 \ --kubeconfig=/etc/kubernetes/admin.kubeconfig kubectl config set-credentials kubernetes-admin \ --client-certificate=/etc/kubernetes/pki/admin.pem \ --client-key=/etc/kubernetes/pki/admin-key.pem \ --embed-certs=true \ --kubeconfig=/etc/kubernetes/admin.kubeconfig kubectl config set-context kubernetes-admin@kubernetes \ --cluster=kubernetes \ --user=kubernetes-admin \ --kubeconfig=/etc/kubernetes/admin.kubeconfig kubectl config use-context kubernetes-admin@kubernetes --kubeconfig=/etc/kubernetes/admin.kubeconfig
3.2.5创建kube-proxy证书
在《5.高可用配置》选择使用那种高可用方案
若使用 haproxy、keepalived 那么为 --server=https://192.168.0.36:8443
若使用 nginx方案,那么为 --server=https://127.0.0.1:8443
cfssl gencert \ -ca=/etc/kubernetes/pki/ca.pem \ -ca-key=/etc/kubernetes/pki/ca-key.pem \ -config=ca-config.json \ -profile=kubernetes \ kube-proxy-csr.json | cfssljson -bare /etc/kubernetes/pki/kube-proxy # 在《5.高可用配置》选择使用那种高可用方案 # 若使用 haproxy、keepalived 那么为 `--server=https://192.168.0.36:8443` # 若使用 nginx方案,那么为 `--server=https://127.0.0.1:8443` kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/pki/ca.pem \ --embed-certs=true \ --server=https://127.0.0.1:8443 \ --kubeconfig=/etc/kubernetes/kube-proxy.kubeconfig kubectl config set-credentials kube-proxy \ --client-certificate=/etc/kubernetes/pki/kube-proxy.pem \ --client-key=/etc/kubernetes/pki/kube-proxy-key.pem \ --embed-certs=true \ --kubeconfig=/etc/kubernetes/kube-proxy.kubeconfig kubectl config set-context kube-proxy@kubernetes \ --cluster=kubernetes \ --user=kube-proxy \ --kubeconfig=/etc/kubernetes/kube-proxy.kubeconfig kubectl config use-context kube-proxy@kubernetes --kubeconfig=/etc/kubernetes/kube-proxy.kubeconfig
3.2.5创建ServiceAccount Key ——secret
openssl genrsa -out /etc/kubernetes/pki/sa.key 2048 openssl rsa -in /etc/kubernetes/pki/sa.key -pubout -out /etc/kubernetes/pki/sa.pub
3.2.6将证书发送到其他master节点
#其他节点创建目录 # mkdir /etc/kubernetes/pki/ -p for NODE in k8s-master02 k8s-master03; do for FILE in $(ls /etc/kubernetes/pki | grep -v etcd); do scp /etc/kubernetes/pki/${FILE} $NODE:/etc/kubernetes/pki/${FILE}; done; for FILE in admin.kubeconfig controller-manager.kubeconfig scheduler.kubeconfig; do scp /etc/kubernetes/${FILE} $NODE:/etc/kubernetes/${FILE}; done; done
3.2.7查看证书
ls /etc/kubernetes/pki/ admin.csr controller-manager.csr kube-proxy.csr admin-key.pem controller-manager-key.pem kube-proxy-key.pem admin.pem controller-manager.pem kube-proxy.pem apiserver.csr front-proxy-ca.csr sa.key apiserver-key.pem front-proxy-ca-key.pem sa.pub apiserver.pem front-proxy-ca.pem scheduler.csr ca.csr front-proxy-client.csr scheduler-key.pem ca-key.pem front-proxy-client-key.pem scheduler.pem ca.pem front-proxy-client.pem # 一共26个就对了 ls /etc/kubernetes/pki/ |wc -l 26
4.k8s系统组件配置
4.1.etcd配置
4.1.1master01配置
# 如果要用IPv6那么把IPv4地址修改为IPv6即可 cat > /etc/etcd/etcd.config.yml << EOF name: 'k8s-master01' data-dir: /var/lib/etcd wal-dir: /var/lib/etcd/wal snapshot-count: 5000 heartbeat-interval: 100 election-timeout: 1000 quota-backend-bytes: 0 listen-peer-urls: 'https://192.168.0.31:2380' listen-client-urls: 'https://192.168.0.31:2379,http://127.0.0.1:2379' max-snapshots: 3 max-wals: 5 cors: initial-advertise-peer-urls: 'https://192.168.0.31:2380' advertise-client-urls: 'https://192.168.0.31:2379' discovery: discovery-fallback: 'proxy' discovery-proxy: discovery-srv: initial-cluster: 'k8s-master01=https://192.168.0.31:2380,k8s-master02=https://192.168.0.32:2380,k8s-master03=https://192.168.0.33:2380' initial-cluster-token: 'etcd-k8s-cluster' initial-cluster-state: 'new' strict-reconfig-check: false enable-v2: true enable-pprof: true proxy: 'off' proxy-failure-wait: 5000 proxy-refresh-interval: 30000 proxy-dial-timeout: 1000 proxy-write-timeout: 5000 proxy-read-timeout: 0 client-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true peer-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' peer-client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true debug: false log-package-levels: log-outputs: [default] force-new-cluster: false EOF
4.1.2master02配置
# 如果要用IPv6那么把IPv4地址修改为IPv6即可 cat > /etc/etcd/etcd.config.yml << EOF name: 'k8s-master02' data-dir: /var/lib/etcd wal-dir: /var/lib/etcd/wal snapshot-count: 5000 heartbeat-interval: 100 election-timeout: 1000 quota-backend-bytes: 0 listen-peer-urls: 'https://192.168.0.32:2380' listen-client-urls: 'https://192.168.0.32:2379,http://127.0.0.1:2379' max-snapshots: 3 max-wals: 5 cors: initial-advertise-peer-urls: 'https://192.168.0.32:2380' advertise-client-urls: 'https://192.168.0.32:2379' discovery: discovery-fallback: 'proxy' discovery-proxy: discovery-srv: initial-cluster: 'k8s-master01=https://192.168.0.31:2380,k8s-master02=https://192.168.0.32:2380,k8s-master03=https://192.168.0.33:2380' initial-cluster-token: 'etcd-k8s-cluster' initial-cluster-state: 'new' strict-reconfig-check: false enable-v2: true enable-pprof: true proxy: 'off' proxy-failure-wait: 5000 proxy-refresh-interval: 30000 proxy-dial-timeout: 1000 proxy-write-timeout: 5000 proxy-read-timeout: 0 client-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true peer-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' peer-client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true debug: false log-package-levels: log-outputs: [default] force-new-cluster: false EOF
4.1.3master03配置
# 如果要用IPv6那么把IPv4地址修改为IPv6即可 cat > /etc/etcd/etcd.config.yml << EOF name: 'k8s-master03' data-dir: /var/lib/etcd wal-dir: /var/lib/etcd/wal snapshot-count: 5000 heartbeat-interval: 100 election-timeout: 1000 quota-backend-bytes: 0 listen-peer-urls: 'https://192.168.0.33:2380' listen-client-urls: 'https://192.168.0.33:2379,http://127.0.0.1:2379' max-snapshots: 3 max-wals: 5 cors: initial-advertise-peer-urls: 'https://192.168.0.33:2380' advertise-client-urls: 'https://192.168.0.33:2379' discovery: discovery-fallback: 'proxy' discovery-proxy: discovery-srv: initial-cluster: 'k8s-master01=https://192.168.0.31:2380,k8s-master02=https://192.168.0.32:2380,k8s-master03=https://192.168.0.33:2380' initial-cluster-token: 'etcd-k8s-cluster' initial-cluster-state: 'new' strict-reconfig-check: false enable-v2: true enable-pprof: true proxy: 'off' proxy-failure-wait: 5000 proxy-refresh-interval: 30000 proxy-dial-timeout: 1000 proxy-write-timeout: 5000 proxy-read-timeout: 0 client-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true peer-transport-security: cert-file: '/etc/kubernetes/pki/etcd/etcd.pem' key-file: '/etc/kubernetes/pki/etcd/etcd-key.pem' peer-client-cert-auth: true trusted-ca-file: '/etc/kubernetes/pki/etcd/etcd-ca.pem' auto-tls: true debug: false log-package-levels: log-outputs: [default] force-new-cluster: false EOF
4.2.创建service(所有master节点操作)
4.2.1创建etcd.service并启动
cat > /usr/lib/systemd/system/etcd.service << EOF [Unit] Description=Etcd Service Documentation=https://coreos.com/etcd/docs/latest/ After=network.target [Service] Type=notify ExecStart=/usr/local/bin/etcd --config-file=/etc/etcd/etcd.config.yml Restart=on-failure RestartSec=10 LimitNOFILE=65536 [Install] WantedBy=multi-user.target Alias=etcd3.service EOF
4.2.2创建etcd证书目录
mkdir /etc/kubernetes/pki/etcd ln -s /etc/etcd/ssl/* /etc/kubernetes/pki/etcd/ systemctl daemon-reload systemctl enable --now etcd
4.2.3查看etcd状态
# 如果要用IPv6那么把IPv4地址修改为IPv6即可 export ETCDCTL_API=3 etcdctl --endpoints="192.168.0.33:2379,192.168.0.32:2379,192.168.0.31:2379" --cacert=/etc/kubernetes/pki/etcd/etcd-ca.pem --cert=/etc/kubernetes/pki/etcd/etcd.pem --key=/etc/kubernetes/pki/etcd/etcd-key.pem endpoint status --write-out=table +-------------------+------------------+---------+---------+-----------+------------+-----------+------------+--------------------+--------+ | ENDPOINT | ID | VERSION | DB SIZE | IS LEADER | IS LEARNER | RAFT TERM | RAFT INDEX | RAFT APPLIED INDEX | ERRORS | +-------------------+------------------+---------+---------+-----------+------------+-----------+------------+--------------------+--------+ | 192.168.0.33:2379 | 6ae2196f75cd6d95 | 3.5.9 | 20 kB | false | false | 2 | 9 | 9 | | | 192.168.0.32:2379 | 46cbf93f7713a252 | 3.5.9 | 20 kB | false | false | 2 | 9 | 9 | | | 192.168.0.31:2379 | ec6051ffc7487dd7 | 3.5.9 | 20 kB | true | false | 2 | 9 | 9 | | +-------------------+------------------+---------+---------+-----------+------------+-----------+------------+--------------------+--------+
5.高可用配置(在Master服务器上操作)
注意 5.1.1 和5.1.2 二选一即可*
选择使用那种高可用方案,同时可以俩种都选用,实现内外兼顾的效果,比如:
5.1 的 NGINX方案实现集群内的高可用
5.2 的 haproxy、keepalived 方案实现集群外访问
在《3.2.生成k8s相关证书》
若使用 nginx方案,那么为 --server=https://127.0.0.1:8443
若使用 haproxy、keepalived 那么为 --server=https://192.168.0.36:9443
5.1 NGINX高可用方案
5.1.1 进行编译
# 安装编译环境 yum install gcc -y # 下载解压nginx二进制文件 # wget http://nginx.org/download/nginx-1.25.1.tar.gz tar xvf nginx-*.tar.gz cd nginx-* # 进行编译 ./configure --with-stream --without-http --without-http_uwsgi_module --without-http_scgi_module --without-http_fastcgi_module make && make install # 拷贝编译好的nginx node='k8s-master02 k8s-master03 k8s-node01 k8s-node02' for NODE in $node; do scp -r /usr/local/nginx/ $NODE:/usr/local/nginx/; done
5.1.2 写入启动配置
在所有主机上执行
# 写入nginx配置文件 cat > /usr/local/nginx/conf/kube-nginx.conf <<EOF worker_processes 1; events { worker_connections 1024; } stream { upstream backend { least_conn; hash $remote_addr consistent; server 192.168.0.31:6443 max_fails=3 fail_timeout=30s; server 192.168.0.32:6443 max_fails=3 fail_timeout=30s; server 192.168.0.33:6443 max_fails=3 fail_timeout=30s; } server { listen 127.0.0.1:8443; proxy_connect_timeout 1s; proxy_pass backend; } } EOF # 写入启动配置文件 cat > /etc/systemd/system/kube-nginx.service <<EOF [Unit] Description=kube-apiserver nginx proxy After=network.target After=network-online.target Wants=network-online.target [Service] Type=forking ExecStartPre=/usr/local/nginx/sbin/nginx -c /usr/local/nginx/conf/kube-nginx.conf -p /usr/local/nginx -t ExecStart=/usr/local/nginx/sbin/nginx -c /usr/local/nginx/conf/kube-nginx.conf -p /usr/local/nginx ExecReload=/usr/local/nginx/sbin/nginx -c /usr/local/nginx/conf/kube-nginx.conf -p /usr/local/nginx -s reload PrivateTmp=true Restart=always RestartSec=5 StartLimitInterval=0 LimitNOFILE=65536 [Install] WantedBy=multi-user.target EOF # 设置开机自启 systemctl enable --now kube-nginx systemctl restart kube-nginx systemctl status kube-nginx
5.2 keepalived和haproxy 高可用方案
5.2.1安装keepalived和haproxy服务
systemctl disable --now firewalld setenforce 0 sed -i 's#SELINUX=enforcing#SELINUX=disabled#g' /etc/selinux/config yum -y install keepalived haproxy
5.2.2修改haproxy配置文件(配置文件一样)
# cp /etc/haproxy/haproxy.cfg /etc/haproxy/haproxy.cfg.bak cat >/etc/haproxy/haproxy.cfg<<"EOF" global maxconn 2000 ulimit-n 16384 log 127.0.0.1 local0 err stats timeout 30s defaults log global mode http option httplog timeout connect 5000 timeout client 50000 timeout server 50000 timeout http-request 15s timeout http-keep-alive 15s frontend monitor-in bind *:33305 mode http option httplog monitor-uri /monitor frontend k8s-master bind 0.0.0.0:9443 bind 127.0.0.1:9443 mode tcp option tcplog tcp-request inspect-delay 5s default_backend k8s-master backend k8s-master mode tcp option tcplog option tcp-check balance roundrobin default-server inter 10s downinter 5s rise 2 fall 2 slowstart 60s maxconn 250 maxqueue 256 weight 100 server k8s-master01 192.168.0.31:6443 check server k8s-master02 192.168.0.32:6443 check server k8s-master03 192.168.0.33:6443 check EOF
5.2.3Master01配置keepalived master节点
#cp /etc/keepalived/keepalived.conf /etc/keepalived/keepalived.conf.bak cat > /etc/keepalived/keepalived.conf << EOF ! Configuration File for keepalived global_defs { router_id LVS_DEVEL } vrrp_script chk_apiserver { script "/etc/keepalived/check_apiserver.sh" interval 5 weight -5 fall 2 rise 1 } vrrp_instance VI_1 { state MASTER # 注意网卡名 interface eth0 mcast_src_ip 192.168.0.31 virtual_router_id 51 priority 100 nopreempt advert_int 2 authentication { auth_type PASS auth_pass K8SHA_KA_AUTH } virtual_ipaddress { 192.168.0.36 } track_script { chk_apiserver } } EOF
5.2.4Master02配置keepalived backup节点
# cp /etc/keepalived/keepalived.conf /etc/keepalived/keepalived.conf.bak cat > /etc/keepalived/keepalived.conf << EOF ! Configuration File for keepalived global_defs { router_id LVS_DEVEL } vrrp_script chk_apiserver { script "/etc/keepalived/check_apiserver.sh" interval 5 weight -5 fall 2 rise 1 } vrrp_instance VI_1 { state BACKUP # 注意网卡名 interface eth0 mcast_src_ip 192.168.0.32 virtual_router_id 51 priority 80 nopreempt advert_int 2 authentication { auth_type PASS auth_pass K8SHA_KA_AUTH } virtual_ipaddress { 192.168.0.36 } track_script { chk_apiserver } } EOF
5.2.5Master03配置keepalived backup节点
# cp /etc/keepalived/keepalived.conf /etc/keepalived/keepalived.conf.bak cat > /etc/keepalived/keepalived.conf << EOF ! Configuration File for keepalived global_defs { router_id LVS_DEVEL } vrrp_script chk_apiserver { script "/etc/keepalived/check_apiserver.sh" interval 5 weight -5 fall 2 rise 1 } vrrp_instance VI_1 { state BACKUP # 注意网卡名 interface eth0 mcast_src_ip 192.168.0.33 virtual_router_id 51 priority 50 nopreempt advert_int 2 authentication { auth_type PASS auth_pass K8SHA_KA_AUTH } virtual_ipaddress { 192.168.0.36 } track_script { chk_apiserver } } EOF
5.2.6健康检查脚本配置(lb主机)
cat > /etc/keepalived/check_apiserver.sh << EOF #!/bin/bash err=0 for k in \$(seq 1 3) do check_code=\$(pgrep haproxy) if [[ \$check_code == "" ]]; then err=\$(expr \$err + 1) sleep 1 continue else err=0 break fi done if [[ \$err != "0" ]]; then echo "systemctl stop keepalived" /usr/bin/systemctl stop keepalived exit 1 else exit 0 fi EOF # 给脚本授权 chmod +x /etc/keepalived/check_apiserver.sh
5.2.7启动服务
systemctl daemon-reload systemctl enable --now haproxy systemctl enable --now keepalived
5.2.8测试高可用
# 能ping同 [root@k8s-node02 ~]# ping 192.168.0.36 # 能telnet访问 [root@k8s-node02 ~]# telnet 192.168.0.36 9443 # 关闭主节点,看vip是否漂移到备节点
6.k8s组件配置
所有k8s节点创建以下目录
mkdir -p /etc/kubernetes/manifests/ /etc/systemd/system/kubelet.service.d /var/lib/kubelet /var/log/kubernetes
6.1.创建apiserver(所有master节点)
6.1.1master01节点配置
cat > /usr/lib/systemd/system/kube-apiserver.service << EOF [Unit] Description=Kubernetes API Server Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-apiserver \\ --v=2 \\ --allow-privileged=true \\ --bind-address=0.0.0.0 \\ --secure-port=6443 \\ --advertise-address=192.168.0.31 \\ --service-cluster-ip-range=10.96.0.0/12,fd00:1111::/112 \\ --service-node-port-range=30000-32767 \\ --etcd-servers=https://192.168.0.31:2379,https://192.168.0.32:2379,https://192.168.0.33:2379 \\ --etcd-cafile=/etc/etcd/ssl/etcd-ca.pem \\ --etcd-certfile=/etc/etcd/ssl/etcd.pem \\ --etcd-keyfile=/etc/etcd/ssl/etcd-key.pem \\ --client-ca-file=/etc/kubernetes/pki/ca.pem \\ --tls-cert-file=/etc/kubernetes/pki/apiserver.pem \\ --tls-private-key-file=/etc/kubernetes/pki/apiserver-key.pem \\ --kubelet-client-certificate=/etc/kubernetes/pki/apiserver.pem \\ --kubelet-client-key=/etc/kubernetes/pki/apiserver-key.pem \\ --service-account-key-file=/etc/kubernetes/pki/sa.pub \\ --service-account-signing-key-file=/etc/kubernetes/pki/sa.key \\ --service-account-issuer=https://kubernetes.default.svc.cluster.local \\ --kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname \\ --enable-admission-plugins=NamespaceLifecycle,LimitRanger,ServiceAccount,DefaultStorageClass,DefaultTolerationSeconds,NodeRestriction,ResourceQuota \ --authorization-mode=Node,RBAC \\ --enable-bootstrap-token-auth=true \\ --requestheader-client-ca-file=/etc/kubernetes/pki/front-proxy-ca.pem \\ --proxy-client-cert-file=/etc/kubernetes/pki/front-proxy-client.pem \\ --proxy-client-key-file=/etc/kubernetes/pki/front-proxy-client-key.pem \\ --requestheader-allowed-names=aggregator \\ --requestheader-group-headers=X-Remote-Group \\ --requestheader-extra-headers-prefix=X-Remote-Extra- \\ --requestheader-username-headers=X-Remote-User \\ --enable-aggregator-routing=true Restart=on-failure RestartSec=10s LimitNOFILE=65535 [Install] WantedBy=multi-user.target EOF
6.1.2master02节点配置
cat > /usr/lib/systemd/system/kube-apiserver.service << EOF [Unit] Description=Kubernetes API Server Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-apiserver \\ --v=2 \\ --allow-privileged=true \\ --bind-address=0.0.0.0 \\ --secure-port=6443 \\ --advertise-address=192.168.0.32 \\ --service-cluster-ip-range=10.96.0.0/12,fd00:1111::/112 \\ --service-node-port-range=30000-32767 \\ --etcd-servers=https://192.168.0.31:2379,https://192.168.0.32:2379,https://192.168.0.33:2379 \\ --etcd-cafile=/etc/etcd/ssl/etcd-ca.pem \\ --etcd-certfile=/etc/etcd/ssl/etcd.pem \\ --etcd-keyfile=/etc/etcd/ssl/etcd-key.pem \\ --client-ca-file=/etc/kubernetes/pki/ca.pem \\ --tls-cert-file=/etc/kubernetes/pki/apiserver.pem \\ --tls-private-key-file=/etc/kubernetes/pki/apiserver-key.pem \\ --kubelet-client-certificate=/etc/kubernetes/pki/apiserver.pem \\ --kubelet-client-key=/etc/kubernetes/pki/apiserver-key.pem \\ --service-account-key-file=/etc/kubernetes/pki/sa.pub \\ --service-account-signing-key-file=/etc/kubernetes/pki/sa.key \\ --service-account-issuer=https://kubernetes.default.svc.cluster.local \\ --kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname \\ --enable-admission-plugins=NamespaceLifecycle,LimitRanger,ServiceAccount,DefaultStorageClass,DefaultTolerationSeconds,NodeRestriction,ResourceQuota \\ --authorization-mode=Node,RBAC \\ --enable-bootstrap-token-auth=true \\ --requestheader-client-ca-file=/etc/kubernetes/pki/front-proxy-ca.pem \\ --proxy-client-cert-file=/etc/kubernetes/pki/front-proxy-client.pem \\ --proxy-client-key-file=/etc/kubernetes/pki/front-proxy-client-key.pem \\ --requestheader-allowed-names=aggregator \\ --requestheader-group-headers=X-Remote-Group \\ --requestheader-extra-headers-prefix=X-Remote-Extra- \\ --requestheader-username-headers=X-Remote-User \\ --enable-aggregator-routing=true Restart=on-failure RestartSec=10s LimitNOFILE=65535 [Install] WantedBy=multi-user.target EOF
6.1.3master03节点配置
cat > /usr/lib/systemd/system/kube-apiserver.service << EOF [Unit] Description=Kubernetes API Server Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-apiserver \\ --v=2 \\ --allow-privileged=true \\ --bind-address=0.0.0.0 \\ --secure-port=6443 \\ --advertise-address=192.168.0.33 \\ --service-cluster-ip-range=10.96.0.0/12,fd00:1111::/112 \\ --service-node-port-range=30000-32767 \\ --etcd-servers=https://192.168.0.31:2379,https://192.168.0.32:2379,https://192.168.0.33:2379 \\ --etcd-cafile=/etc/etcd/ssl/etcd-ca.pem \\ --etcd-certfile=/etc/etcd/ssl/etcd.pem \\ --etcd-keyfile=/etc/etcd/ssl/etcd-key.pem \\ --client-ca-file=/etc/kubernetes/pki/ca.pem \\ --tls-cert-file=/etc/kubernetes/pki/apiserver.pem \\ --tls-private-key-file=/etc/kubernetes/pki/apiserver-key.pem \\ --kubelet-client-certificate=/etc/kubernetes/pki/apiserver.pem \\ --kubelet-client-key=/etc/kubernetes/pki/apiserver-key.pem \\ --service-account-key-file=/etc/kubernetes/pki/sa.pub \\ --service-account-signing-key-file=/etc/kubernetes/pki/sa.key \\ --service-account-issuer=https://kubernetes.default.svc.cluster.local \\ --kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname \\ --enable-admission-plugins=NamespaceLifecycle,LimitRanger,ServiceAccount,DefaultStorageClass,DefaultTolerationSeconds,NodeRestriction,ResourceQuota \\ --authorization-mode=Node,RBAC \\ --enable-bootstrap-token-auth=true \\ --requestheader-client-ca-file=/etc/kubernetes/pki/front-proxy-ca.pem \\ --proxy-client-cert-file=/etc/kubernetes/pki/front-proxy-client.pem \\ --proxy-client-key-file=/etc/kubernetes/pki/front-proxy-client-key.pem \\ --requestheader-allowed-names=aggregator \\ --requestheader-group-headers=X-Remote-Group \\ --requestheader-extra-headers-prefix=X-Remote-Extra- \\ --requestheader-username-headers=X-Remote-User \\ --enable-aggregator-routing=true Restart=on-failure RestartSec=10s LimitNOFILE=65535 [Install] WantedBy=multi-user.target EOF
6.1.4启动apiserver(所有master节点)
systemctl daemon-reload systemctl enable --now kube-apiserver systemctl restart kube-apiserver systemctl status kube-apiserver
6.2.配置kube-controller-manager service
# 所有master节点配置,且配置相同 # 172.16.0.0/12为pod网段,按需求设置你自己的网段 cat > /usr/lib/systemd/system/kube-controller-manager.service << EOF [Unit] Description=Kubernetes Controller Manager Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-controller-manager \\ --v=2 \\ --bind-address=0.0.0.0 \\ --root-ca-file=/etc/kubernetes/pki/ca.pem \\ --cluster-signing-cert-file=/etc/kubernetes/pki/ca.pem \\ --cluster-signing-key-file=/etc/kubernetes/pki/ca-key.pem \\ --service-account-private-key-file=/etc/kubernetes/pki/sa.key \\ --kubeconfig=/etc/kubernetes/controller-manager.kubeconfig \\ --leader-elect=true \\ --use-service-account-credentials=true \\ --node-monitor-grace-period=40s \\ --node-monitor-period=5s \\ --controllers=*,bootstrapsigner,tokencleaner \\ --allocate-node-cidrs=true \\ --service-cluster-ip-range=10.96.0.0/12,fd00:1111::/112 \\ --cluster-cidr=172.16.0.0/12,fc00:2222::/112 \\ --node-cidr-mask-size-ipv4=24 \\ --node-cidr-mask-size-ipv6=120 \\ --requestheader-client-ca-file=/etc/kubernetes/pki/front-proxy-ca.pem Restart=always RestartSec=10s [Install] WantedBy=multi-user.target EOF
6.2.1启动kube-controller-manager,并查看状态
systemctl daemon-reload systemctl enable --now kube-controller-manager systemctl restart kube-controller-manager systemctl status kube-controller-manager
6.3.配置kube-scheduler service
6.3.1所有master节点配置,且配置相同
cat > /usr/lib/systemd/system/kube-scheduler.service << EOF [Unit] Description=Kubernetes Scheduler Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-scheduler \\ --v=2 \\ --bind-address=0.0.0.0 \\ --leader-elect=true \\ --kubeconfig=/etc/kubernetes/scheduler.kubeconfig Restart=always RestartSec=10s [Install] WantedBy=multi-user.target EOF
6.3.2启动并查看服务状态
systemctl daemon-reload systemctl enable --now kube-scheduler systemctl restart kube-scheduler systemctl status kube-scheduler
7.TLS Bootstrapping配置
7.1在master01上配置
# 在《5.高可用配置》选择使用那种高可用方案 # 若使用 haproxy、keepalived 那么为 `--server=https://192.168.0.36:8443` # 若使用 nginx方案,那么为 `--server=https://127.0.0.1:8443` cd bootstrap kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/pki/ca.pem \ --embed-certs=true --server=https://127.0.0.1:8443 \ --kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig kubectl config set-credentials tls-bootstrap-token-user \ --token=c8ad9c.2e4d610cf3e7426e \ --kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig kubectl config set-context tls-bootstrap-token-user@kubernetes \ --cluster=kubernetes \ --user=tls-bootstrap-token-user \ --kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig kubectl config use-context tls-bootstrap-token-user@kubernetes \ --kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig # token的位置在bootstrap.secret.yaml,如果修改的话到这个文件修改 mkdir -p /root/.kube ; cp /etc/kubernetes/admin.kubeconfig /root/.kube/config
7.2查看集群状态,没问题的话继续后续操作
kubectl get cs Warning: v1 ComponentStatus is deprecated in v1.19+ NAME STATUS MESSAGE ERROR scheduler Healthy ok controller-manager Healthy ok etcd-0 Healthy {"health":"true","reason":""} etcd-2 Healthy {"health":"true","reason":""} etcd-1 Healthy {"health":"true","reason":""} # 切记执行,别忘记!!! kubectl create -f bootstrap.secret.yaml
8.node节点配置
8.1.在master01上将证书复制到node节点
cd /etc/kubernetes/ for NODE in k8s-master02 k8s-master03 k8s-node01 k8s-node02; do ssh $NODE mkdir -p /etc/kubernetes/pki; for FILE in pki/ca.pem pki/ca-key.pem pki/front-proxy-ca.pem bootstrap-kubelet.kubeconfig kube-proxy.kubeconfig; do scp /etc/kubernetes/$FILE $NODE:/etc/kubernetes/${FILE}; done; done
8.2.kubelet配置
注意 : 8.2.1 和 8.2.2 需要和 上方 2.1 和 2.2 对应起来
8.2.1当使用docker作为Runtime
cat > /usr/lib/systemd/system/kubelet.service << EOF [Unit] Description=Kubernetes Kubelet Documentation=https://github.com/kubernetes/kubernetes After=network-online.target firewalld.service containerd.service Wants=network-online.target Requires=docker.socket containerd.service [Service] ExecStart=/usr/local/bin/kubelet \\ --bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig \\ --kubeconfig=/etc/kubernetes/kubelet.kubeconfig \\ --config=/etc/kubernetes/kubelet-conf.yml \\ --container-runtime-endpoint=unix:///run/cri-dockerd.sock \\ --node-labels=node.kubernetes.io/node= [Install] WantedBy=multi-user.target EOF # 这是一个表示 Kubernetes Kubelet 服务的 systemd 单位文件示例。下面是对每个节([Unit]、[Service]、[Install])的详细解释: # # [Unit] # # Description=Kubernetes Kubelet:指定了此单位文件对应的服务描述信息为 "Kubernetes Kubelet"。 # Documentation=...:指定了对该服务的文档链接。 # - After: 说明该服务在哪些其他服务之后启动,这里是在网络在线、firewalld服务和containerd服务后启动。 # - Wants: 说明该服务想要的其他服务,这里是网络在线服务。 # - Requires: 说明该服务需要的其他服务,这里是docker.socket和containerd.service。 # [Service] # # ExecStart=/usr/local/bin/kubelet ...:指定了启动 Kubelet 服务的命令和参数。这里使用的是 /usr/local/bin/kubelet 命令,并传递了一系列参数来配置 Kubelet 的运行。这些参数包括: # --bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig:指定了用于引导 kubelet 的 kubeconfig 文件的路径和名称。 # --kubeconfig=/etc/kubernetes/kubelet.kubeconfig:指定了 kubelet 的 kubeconfig 文件的路径和名称。 # --config=/etc/kubernetes/kubelet-conf.yml:指定了 kubelet 的配置文件的路径和名称。 # --container-runtime-endpoint=unix:///run/cri-dockerd.sock:指定了容器运行时接口的端点地址,这里使用的是 Docker 运行时(cri-dockerd)的 UNIX 套接字。 # --node-labels=node.kubernetes.io/node=:指定了节点的标签。这里的示例只给节点添加了一个简单的标签 node.kubernetes.io/node=。 # [Install] # # WantedBy=multi-user.target:指定了在 multi-user.target 被启动时,该服务应该被启用。 # 通过这个单位文件,你可以配置 Kubelet 服务的启动参数,指定相关的配置文件和凭证文件,以及定义节点的标签。请确认路径和文件名与你的实际环境中的配置相匹配。 # IPv6示例 # 若不使用IPv6那么忽略此项即可 # 下方 --node-ip 更换为每个节点的IP即可 cat > /usr/lib/systemd/system/kubelet.service << EOF [Unit] Description=Kubernetes Kubelet Documentation=https://github.com/kubernetes/kubernetes After=network-online.target firewalld.service containerd.service Wants=network-online.target Requires=docker.socket containerd.service [Service] ExecStart=/usr/local/bin/kubelet \\ --bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig \\ --kubeconfig=/etc/kubernetes/kubelet.kubeconfig \\ --config=/etc/kubernetes/kubelet-conf.yml \\ --container-runtime-endpoint=unix:///run/cri-dockerd.sock \\ --node-labels=node.kubernetes.io/node= \\ --node-ip=192.168.1.31,2408:822a:245:8c01::fab [Install] WantedBy=multi-user.target EOF
8.2.2当使用Containerd作为Runtime (推荐)
mkdir -p /var/lib/kubelet /var/log/kubernetes /etc/systemd/system/kubelet.service.d /etc/kubernetes/manifests/ # 所有k8s节点配置kubelet service cat > /usr/lib/systemd/system/kubelet.service << EOF [Unit] Description=Kubernetes Kubelet Documentation=https://github.com/kubernetes/kubernetes After=network-online.target firewalld.service containerd.service Wants=network-online.target Requires=docker.socket containerd.service [Service] ExecStart=/usr/local/bin/kubelet \\ --bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig \\ --kubeconfig=/etc/kubernetes/kubelet.kubeconfig \\ --config=/etc/kubernetes/kubelet-conf.yml \\ --container-runtime-endpoint=unix:///run/containerd/containerd.sock \\ --node-labels=node.kubernetes.io/node= [Install] WantedBy=multi-user.target EOF # 这是一个表示 Kubernetes Kubelet 服务的 systemd 单位文件示例。与之前相比,添加了 After 和 Requires 字段来指定依赖关系。 # # [Unit] # # Description=Kubernetes Kubelet:指定了此单位文件对应的服务描述信息为 "Kubernetes Kubelet"。 # Documentation=...:指定了对该服务的文档链接。 # - After: 说明该服务在哪些其他服务之后启动,这里是在网络在线、firewalld服务和containerd服务后启动。 # - Wants: 说明该服务想要的其他服务,这里是网络在线服务。 # - Requires: 说明该服务需要的其他服务,这里是docker.socket和containerd.service。 # [Service] # # ExecStart=/usr/local/bin/kubelet ...:指定了启动 Kubelet 服务的命令和参数,与之前的示例相同。 # --container-runtime-endpoint=unix:///run/containerd/containerd.sock:修改了容器运行时接口的端点地址,将其更改为使用 containerd 运行时(通过 UNIX 套接字)。 # [Install] # # WantedBy=multi-user.target:指定了在 multi-user.target 被启动时,该服务应该被启用。 # 通过这个单位文件,你可以配置 Kubelet 服务的启动参数,并指定了它依赖的 containerd 服务。确保路径和文件名与你实际环境中的配置相匹配。 # IPv6示例 # 若不使用IPv6那么忽略此项即可 # 下方 --node-ip 更换为每个节点的IP即可 cat > /usr/lib/systemd/system/kubelet.service << EOF [Unit] Description=Kubernetes Kubelet Documentation=https://github.com/kubernetes/kubernetes After=network-online.target firewalld.service containerd.service Wants=network-online.target Requires=docker.socket containerd.service [Service] ExecStart=/usr/local/bin/kubelet \\ --bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.kubeconfig \\ --kubeconfig=/etc/kubernetes/kubelet.kubeconfig \\ --config=/etc/kubernetes/kubelet-conf.yml \\ --container-runtime-endpoint=unix:///run/containerd/containerd.sock \\ --node-labels=node.kubernetes.io/node= \\ --node-ip=192.168.1.31,2408:822a:245:8c01::fab [Install] WantedBy=multi-user.target EOF
8.2.3所有k8s节点创建kubelet的配置文件
cat > /etc/kubernetes/kubelet-conf.yml <<EOF apiVersion: kubelet.config.k8s.io/v1beta1 kind: KubeletConfiguration address: 0.0.0.0 port: 10250 readOnlyPort: 10255 authentication: anonymous: enabled: false webhook: cacheTTL: 2m0s enabled: true x509: clientCAFile: /etc/kubernetes/pki/ca.pem authorization: mode: Webhook webhook: cacheAuthorizedTTL: 5m0s cacheUnauthorizedTTL: 30s cgroupDriver: systemd cgroupsPerQOS: true clusterDNS: - 10.96.0.10 clusterDomain: cluster.local containerLogMaxFiles: 5 containerLogMaxSize: 10Mi contentType: application/vnd.kubernetes.protobuf cpuCFSQuota: true cpuManagerPolicy: none cpuManagerReconcilePeriod: 10s enableControllerAttachDetach: true enableDebuggingHandlers: true enforceNodeAllocatable: - pods eventBurst: 10 eventRecordQPS: 5 evictionHard: imagefs.available: 15% memory.available: 100Mi nodefs.available: 10% nodefs.inodesFree: 5% evictionPressureTransitionPeriod: 5m0s failSwapOn: true fileCheckFrequency: 20s hairpinMode: promiscuous-bridge healthzBindAddress: 127.0.0.1 healthzPort: 10248 httpCheckFrequency: 20s imageGCHighThresholdPercent: 85 imageGCLowThresholdPercent: 80 imageMinimumGCAge: 2m0s iptablesDropBit: 15 iptablesMasqueradeBit: 14 kubeAPIBurst: 10 kubeAPIQPS: 5 makeIPTablesUtilChains: true maxOpenFiles: 1000000 maxPods: 110 nodeStatusUpdateFrequency: 10s oomScoreAdj: -999 podPidsLimit: -1 registryBurst: 10 registryPullQPS: 5 resolvConf: /etc/resolv.conf rotateCertificates: true runtimeRequestTimeout: 2m0s serializeImagePulls: true staticPodPath: /etc/kubernetes/manifests streamingConnectionIdleTimeout: 4h0m0s syncFrequency: 1m0s volumeStatsAggPeriod: 1m0s EOF
8.2.4启动kubelet
systemctl daemon-reload systemctl enable --now kubelet systemctl restart kubelet systemctl status kubelet
8.2.5查看集群
[root@k8s-master01 ~]# kubectl get node NAME STATUS ROLES AGE VERSION k8s-master01 Ready <none> 18s v1.27.3 k8s-master02 Ready <none> 16s v1.27.3 k8s-master03 Ready <none> 16s v1.27.3 k8s-node01 Ready <none> 14s v1.27.3 k8s-node02 Ready <none> 14s v1.27.3 [root@k8s-master01 ~]#
8.2.6查看容器运行时
[root@k8s-master01 ~]# kubectl describe node | grep Runtime Container Runtime Version: containerd://1.7.2 Container Runtime Version: containerd://1.7.2 Container Runtime Version: containerd://1.7.2 Container Runtime Version: containerd://1.7.2 Container Runtime Version: containerd://1.7.2 [root@k8s-master01 ~]# kubectl describe node | grep Runtime Container Runtime Version: docker://24.0.2 Container Runtime Version: docker://24.0.2 Container Runtime Version: docker://24.0.2 Container Runtime Version: docker://24.0.2 Container Runtime Version: docker://24.0.2
8.3.kube-proxy配置
8.3.1将kubeconfig发送至其他节点
for NODE in k8s-master02 k8s-master03 k8s-node01 k8s-node02; do scp /etc/kubernetes/kube-proxy.kubeconfig $NODE:/etc/kubernetes/kube-proxy.kubeconfig; done
8.3.2所有k8s节点添加kube-proxy的service文件
cat > /usr/lib/systemd/system/kube-proxy.service << EOF [Unit] Description=Kubernetes Kube Proxy Documentation=https://github.com/kubernetes/kubernetes After=network.target [Service] ExecStart=/usr/local/bin/kube-proxy \\ --config=/etc/kubernetes/kube-proxy.yaml \\ --v=2 Restart=always RestartSec=10s [Install] WantedBy=multi-user.target EOF
8.3.3所有k8s节点添加kube-proxy的配置
cat > /etc/kubernetes/kube-proxy.yaml << EOF apiVersion: kubeproxy.config.k8s.io/v1alpha1 bindAddress: 0.0.0.0 clientConnection: acceptContentTypes: "" burst: 10 contentType: application/vnd.kubernetes.protobuf kubeconfig: /etc/kubernetes/kube-proxy.kubeconfig qps: 5 clusterCIDR: 172.16.0.0/12,fc00:2222::/112 configSyncPeriod: 15m0s conntrack: max: null maxPerCore: 32768 min: 131072 tcpCloseWaitTimeout: 1h0m0s tcpEstablishedTimeout: 24h0m0s enableProfiling: false healthzBindAddress: 0.0.0.0:10256 hostnameOverride: "" iptables: masqueradeAll: false masqueradeBit: 14 minSyncPeriod: 0s syncPeriod: 30s ipvs: masqueradeAll: true minSyncPeriod: 5s scheduler: "rr" syncPeriod: 30s kind: KubeProxyConfiguration metricsBindAddress: 127.0.0.1:10249 mode: "ipvs" nodePortAddresses: null oomScoreAdj: -999 portRange: "" udpIdleTimeout: 250ms EOF
8.3.4启动kube-proxy
systemctl daemon-reload systemctl restart kube-proxy systemctl enable --now kube-proxy systemctl status kube-proxy
9.安装网络插件
注意 9.1 和 9.2 二选其一即可,建议在此处创建好快照后在进行操作,后续出问题可以回滚
** centos7 要升级libseccomp 不然 无法安装网络插件**
# https://github.com/opencontainers/runc/releases # 升级runc # wget https://mirrors.chenby.cn/https://github.com/opencontainers/runc/releases/download/v1.1.4/runc.amd64 install -m 755 runc.amd64 /usr/local/sbin/runc cp -p /usr/local/sbin/runc /usr/local/bin/runc cp -p /usr/local/sbin/runc /usr/bin/runc #下载高于2.4以上的包 yum -y install http://rpmfind.net/linux/centos/8-stream/BaseOS/x86_64/os/Packages/libseccomp-2.5.1-1.el8.x86_64.rpm # 清华源 yum -y install https://mirrors.tuna.tsinghua.edu.cn/centos/8-stream/BaseOS/x86_64/os/Packages/libseccomp-2.5.1-1.el8.x86_64.rpm #查看当前版本 [root@k8s-master-1 ~]# rpm -qa | grep libseccomp libseccomp-2.5.1-1.el8.x86_64
9.1安装Calico
9.1.1更改calico网段
wget https://mirrors.chenby.cn/https://github.com/projectcalico/calico/blob/master/manifests/calico-typha.yaml cp calico-typha.yaml calico.yaml cp calico-typha.yaml calico-ipv6.yaml vim calico.yaml # calico-config ConfigMap处 "ipam": { "type": "calico-ipam", }, - name: IP value: "autodetect" - name: CALICO_IPV4POOL_CIDR value: "172.16.0.0/12" # vim calico-ipv6.yaml # calico-config ConfigMap处 "ipam": { "type": "calico-ipam", "assign_ipv4": "true", "assign_ipv6": "true" }, - name: IP value: "autodetect" - name: IP6 value: "autodetect" - name: CALICO_IPV4POOL_CIDR value: "172.16.0.0/12" - name: CALICO_IPV6POOL_CIDR value: "fc00::/48" - name: FELIX_IPV6SUPPORT value: "true" # 若docker镜像拉不下来,可以使用国内的仓库 sed -i "s#docker.io/calico/#m.daocloud.io/docker.io/calico/#g" calico.yaml sed -i "s#docker.io/calico/#m.daocloud.io/docker.io/calico/#g" calico-ipv6.yaml # 本地没有公网 IPv6 使用 calico.yaml kubectl apply -f calico.yaml # 本地有公网 IPv6 使用 calico-ipv6.yaml # kubectl apply -f calico-ipv6.yaml
9.1.2查看容器状态
# calico 初始化会很慢 需要耐心等待一下,大约十分钟左右 [root@k8s-master01 ~]# kubectl get pod -A NAMESPACE NAME READY STATUS RESTARTS AGE kube-system calico-kube-controllers-6747f75cdc-fbvvc 1/1 Running 0 61s kube-system calico-node-fs7hl 1/1 Running 0 61s kube-system calico-node-jqz58 1/1 Running 0 61s kube-system calico-node-khjlg 1/1 Running 0 61s kube-system calico-node-wmf8q 1/1 Running 0 61s kube-system calico-node-xc6gn 1/1 Running 0 61s kube-system calico-typha-6cdc4b4fbc-57snb 1/1 Running 0 61s
9.2 安装cilium
9.2.1 安装helm
# [root@k8s-master01 ~]# curl -fsSL -o get_helm.sh https://raw.githubusercontent.com/helm/helm/main/scripts/get-helm-3 # [root@k8s-master01 ~]# chmod 700 get_helm.sh # [root@k8s-master01 ~]# ./get_helm.sh wget https://files.m.daocloud.io/get.helm.sh/helm-v3.12.1-linux-amd64.tar.gz tar xvf helm-*-linux-amd64.tar.gz cp linux-amd64/helm /usr/local/bin/
9.2.2 安装cilium
# 添加源 helm repo add cilium https://helm.cilium.io # 修改为国内源 helm pull cilium/cilium tar xvf cilium-*.tgz cd cilium/ sed -i "s#quay.io/#m.daocloud.io/quay.io/#g" values.yaml # 默认参数安装 helm install cilium ./cilium/ -n kube-system # 启用ipv6 # helm install cilium cilium/cilium --namespace kube-system --set ipv6.enabled=true # 启用路由信息和监控插件 # helm install cilium cilium/cilium --namespace kube-system --set hubble.relay.enabled=true --set hubble.ui.enabled=true --set prometheus.enabled=true --set operator.prometheus.enabled=true --set hubble.enabled=true --set hubble.metrics.enabled="{dns,drop,tcp,flow,port-distribution,icmp,http}"
9.2.3 查看
[root@k8s-master01 ~]# kubectl get pod -A | grep cil kube-system cilium-gmr6c 1/1 Running 0 5m3s kube-system cilium-kzgdj 1/1 Running 0 5m3s kube-system cilium-operator-69b677f97c-6pw4k 1/1 Running 0 5m3s kube-system cilium-operator-69b677f97c-xzzdk 1/1 Running 0 5m3s kube-system cilium-q2rnr 1/1 Running 0 5m3s kube-system cilium-smx5v 1/1 Running 0 5m3s kube-system cilium-tdjq4 1/1 Running 0 5m3s [root@k8s-master01 ~]#
9.2.4 下载专属监控面板
安装时候没有创建 监控可以忽略
[root@k8s-master01 yaml]# wget https://mirrors.chenby.cn/https://raw.githubusercontent.com/cilium/cilium/1.12.1/examples/kubernetes/addons/prometheus/monitoring-example.yaml [root@k8s-master01 yaml]# sed -i "s#docker.io/#m.daocloud.io/docker.io/#g" monitoring-example.yaml [root@k8s-master01 yaml]# kubectl apply -f monitoring-example.yaml namespace/cilium-monitoring created serviceaccount/prometheus-k8s created configmap/grafana-config created configmap/grafana-cilium-dashboard created configmap/grafana-cilium-operator-dashboard created configmap/grafana-hubble-dashboard created configmap/prometheus created clusterrole.rbac.authorization.k8s.io/prometheus created clusterrolebinding.rbac.authorization.k8s.io/prometheus created service/grafana created service/prometheus created deployment.apps/grafana created deployment.apps/prometheus created [root@k8s-master01 yaml]#
9.2.5 下载部署测试用例
说明 测试用例 需要在 安装CoreDNS 之后即可完成
[root@k8s-master01 yaml]# wget https://mirrors.chenby.cn/https://raw.githubusercontent.com/cilium/cilium/master/examples/kubernetes/connectivity-check/connectivity-check.yaml [root@k8s-master01 yaml]# sed -i "s#google.com#baidu.cn#g" connectivity-check.yaml sed -i "s#quay.io/#m.daocloud.io/quay.io/#g" connectivity-check.yaml [root@k8s-master01 yaml]# kubectl apply -f connectivity-check.yaml deployment.apps/echo-a created deployment.apps/echo-b created deployment.apps/echo-b-host created deployment.apps/pod-to-a created deployment.apps/pod-to-external-1111 created deployment.apps/pod-to-a-denied-cnp created deployment.apps/pod-to-a-allowed-cnp created deployment.apps/pod-to-external-fqdn-allow-google-cnp created deployment.apps/pod-to-b-multi-node-clusterip created deployment.apps/pod-to-b-multi-node-headless created deployment.apps/host-to-b-multi-node-clusterip created deployment.apps/host-to-b-multi-node-headless created deployment.apps/pod-to-b-multi-node-nodeport created deployment.apps/pod-to-b-intra-node-nodeport created service/echo-a created service/echo-b created service/echo-b-headless created service/echo-b-host-headless created ciliumnetworkpolicy.cilium.io/pod-to-a-denied-cnp created ciliumnetworkpolicy.cilium.io/pod-to-a-allowed-cnp created ciliumnetworkpolicy.cilium.io/pod-to-external-fqdn-allow-google-cnp created [root@k8s-master01 yaml]#
9.2.6 查看pod
[root@k8s-master01 yaml]# kubectl get pod -A NAMESPACE NAME READY STATUS RESTARTS AGE cilium-monitoring grafana-59957b9549-6zzqh 1/1 Running 0 10m cilium-monitoring prometheus-7c8c9684bb-4v9cl 1/1 Running 0 10m default chenby-75b5d7fbfb-7zjsr 1/1 Running 0 27h default chenby-75b5d7fbfb-hbvr8 1/1 Running 0 27h default chenby-75b5d7fbfb-ppbzg 1/1 Running 0 27h default echo-a-6799dff547-pnx6w 1/1 Running 0 10m default echo-b-fc47b659c-4bdg9 1/1 Running 0 10m default echo-b-host-67fcfd59b7-28r9s 1/1 Running 0 10m default host-to-b-multi-node-clusterip-69c57975d6-z4j2z 1/1 Running 0 10m default host-to-b-multi-node-headless-865899f7bb-frrmc 1/1 Running 0 10m default pod-to-a-allowed-cnp-5f9d7d4b9d-hcd8x 1/1 Running 0 10m default pod-to-a-denied-cnp-65cc5ff97b-2rzb8 1/1 Running 0 10m default pod-to-a-dfc64f564-p7xcn 1/1 Running 0 10m default pod-to-b-intra-node-nodeport-677868746b-trk2l 1/1 Running 0 10m default pod-to-b-multi-node-clusterip-76bbbc677b-knfq2 1/1 Running 0 10m default pod-to-b-multi-node-headless-698c6579fd-mmvd7 1/1 Running 0 10m default pod-to-b-multi-node-nodeport-5dc4b8cfd6-8dxmz 1/1 Running 0 10m default pod-to-external-1111-8459965778-pjt9b 1/1 Running 0 10m default pod-to-external-fqdn-allow-google-cnp-64df9fb89b-l9l4q 1/1 Running 0 10m kube-system cilium-7rfj6 1/1 Running 0 56s kube-system cilium-d4cch 1/1 Running 0 56s kube-system cilium-h5x8r 1/1 Running 0 56s kube-system cilium-operator-5dbddb6dbf-flpl5 1/1 Running 0 56s kube-system cilium-operator-5dbddb6dbf-gcznc 1/1 Running 0 56s kube-system cilium-t2xlz 1/1 Running 0 56s kube-system cilium-z65z7 1/1 Running 0 56s kube-system coredns-665475b9f8-jkqn8 1/1 Running 1 (36h ago) 36h kube-system hubble-relay-59d8575-9pl9z 1/1 Running 0 56s kube-system hubble-ui-64d4995d57-nsv9j 2/2 Running 0 56s kube-system metrics-server-776f58c94b-c6zgs 1/1 Running 1 (36h ago) 37h [root@k8s-master01 yaml]#
9.2.7 修改为NodePort
安装时候没有创建 监控可以忽略
[root@k8s-master01 yaml]# kubectl edit svc -n kube-system hubble-ui service/hubble-ui edited [root@k8s-master01 yaml]# [root@k8s-master01 yaml]# kubectl edit svc -n cilium-monitoring grafana service/grafana edited [root@k8s-master01 yaml]# [root@k8s-master01 yaml]# kubectl edit svc -n cilium-monitoring prometheus service/prometheus edited [root@k8s-master01 yaml]# type: NodePort
9.2.8 查看端口
安装时候没有创建 监控可以忽略
[root@k8s-master01 yaml]# kubectl get svc -A | grep monit cilium-monitoring grafana NodePort 10.100.250.17 <none> 3000:30707/TCP 15m cilium-monitoring prometheus NodePort 10.100.131.243 <none> 9090:31155/TCP 15m [root@k8s-master01 yaml]# [root@k8s-master01 yaml]# kubectl get svc -A | grep hubble kube-system hubble-metrics ClusterIP None <none> 9965/TCP 5m12s kube-system hubble-peer ClusterIP 10.100.150.29 <none> 443/TCP 5m12s kube-system hubble-relay ClusterIP 10.109.251.34 <none> 80/TCP 5m12s kube-system hubble-ui NodePort 10.102.253.59 <none> 80:31219/TCP 5m12s [root@k8s-master01 yaml]#
9.2.9 访问
安装时候没有创建 监控可以忽略
http://192.168.0.31:30707 http://192.168.0.31:31155 http://192.168.0.31:31219
10.安装CoreDNS
10.1以下步骤只在master01操作
10.1.1修改文件
# 下载tgz包 helm repo add coredns https://coredns.github.io/helm helm pull coredns/coredns tar xvf coredns-*.tgz cd coredns/ # 修改IP地址 vim values.yaml cat values.yaml | grep clusterIP: clusterIP: "10.96.0.10" # 示例 --- service: # clusterIP: "" # clusterIPs: [] # loadBalancerIP: "" # externalIPs: [] # externalTrafficPolicy: "" # ipFamilyPolicy: "" # The name of the Service # If not set, a name is generated using the fullname template clusterIP: "10.96.0.10" name: "" annotations: {} --- # 修改为国内源 docker源可选 sed -i "s#coredns/#m.daocloud.io/docker.io/coredns/#g" values.yaml sed -i "s#registry.k8s.io/#m.daocloud.io/registry.k8s.io/#g" values.yaml # 默认参数安装 helm install coredns ./coredns/ -n kube-system
11.安装Metrics Server
11.1以下步骤只在master01操作
11.1.1安装Metrics-server
在新版的Kubernetes中系统资源的采集均使用Metrics-server,可以通过Metrics采集节点和Pod的内存、磁盘、CPU和网络的使用率
# 单机版 wget https://mirrors.chenby.cn/https://github.com/kubernetes-sigs/metrics-server/releases/latest/download/components.yaml # 高可用版本 wget https://mirrors.chenby.cn/https://github.com/kubernetes-sigs/metrics-server/releases/latest/download/high-availability.yaml # 修改配置 vim components.yaml vim high-availability.yaml --- # 1 defaultArgs: - --cert-dir=/tmp - --kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname - --kubelet-use-node-status-port - --metric-resolution=15s - --kubelet-insecure-tls - --requestheader-client-ca-file=/etc/kubernetes/pki/front-proxy-ca.pem - --requestheader-username-headers=X-Remote-User - --requestheader-group-headers=X-Remote-Group - --requestheader-extra-headers-prefix=X-Remote-Extra- # 2 volumeMounts: - mountPath: /tmp name: tmp-dir - name: ca-ssl mountPath: /etc/kubernetes/pki # 3 volumes: - emptyDir: {} name: tmp-dir - name: ca-ssl hostPath: path: /etc/kubernetes/pki --- # 修改为国内源 docker源可选 sed -i "s#registry.k8s.io/#m.daocloud.io/registry.k8s.io/#g" *.yaml # 二选一 kubectl apply -f components.yaml # kubectl apply -f high-availability.yaml
11.1.2稍等片刻查看状态
kubectl top node NAME CPU(cores) CPU% MEMORY(bytes) MEMORY% k8s-master01 197m 4% 1497Mi 39% k8s-master02 152m 3% 1315Mi 34% k8s-master03 112m 2% 1274Mi 33% k8s-node01 142m 3% 777Mi 20% k8s-node02 71m 1% 682Mi 17%
12.集群验证
12.1部署pod资源
cat<<EOF | kubectl apply -f - apiVersion: v1 kind: Pod metadata: name: busybox namespace: default spec: containers: - name: busybox image: docker.io/library/busybox:1.28 command: - sleep - "3600" imagePullPolicy: IfNotPresent restartPolicy: Always EOF # 查看 kubectl get pod NAME READY STATUS RESTARTS AGE busybox 1/1 Running 0 17s
12.2用pod解析默认命名空间中的kubernetes
# 查看name kubectl get svc NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE kubernetes ClusterIP 10.96.0.1 <none> 443/TCP 17h # 进行解析 kubectl exec busybox -n default -- nslookup kubernetes 3Server: 10.96.0.10 Address 1: 10.96.0.10 kube-dns.kube-system.svc.cluster.local Name: kubernetes Address 1: 10.96.0.1 kubernetes.default.svc.cluster.local
12.3测试跨命名空间是否可以解析
# 查看有那些name kubectl get svc -A NAMESPACE NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE default kubernetes ClusterIP 10.96.0.1 <none> 443/TCP 76m kube-system calico-typha ClusterIP 10.105.100.82 <none> 5473/TCP 35m kube-system coredns-coredns ClusterIP 10.96.0.10 <none> 53/UDP,53/TCP 8m14s kube-system metrics-server ClusterIP 10.105.60.31 <none> 443/TCP 109s # 进行解析 kubectl exec busybox -n default -- nslookup coredns-coredns.kube-system Server: 10.96.0.10 Address 1: 10.96.0.10 coredns-coredns.kube-system.svc.cluster.local Name: coredns-coredns.kube-system Address 1: 10.96.0.10 coredns-coredns.kube-system.svc.cluster.local [root@k8s-master01 metrics-server]#
12.4每个节点都必须要能访问Kubernetes的kubernetes svc 443和kube-dns的service 53
telnet 10.96.0.1 443 Trying 10.96.0.1... Connected to 10.96.0.1. Escape character is '^]'. telnet 10.96.0.10 53 Trying 10.96.0.10... Connected to 10.96.0.10. Escape character is '^]'. curl 10.96.0.10:53 curl: (52) Empty reply from server
12.5Pod和Pod之前要能通
kubectl get po -owide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES busybox 1/1 Running 0 17m 172.27.14.193 k8s-node02 <none> <none> kubectl get po -n kube-system -owide NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES calico-kube-controllers-76754ff848-pw4xg 1/1 Running 0 38m 172.25.244.193 k8s-master01 <none> <none> calico-node-97m55 1/1 Running 0 38m 192.168.0.34 k8s-node01 <none> <none> calico-node-hlz7j 1/1 Running 0 38m 192.168.0.32 k8s-master02 <none> <none> calico-node-jtlck 1/1 Running 0 38m 192.168.0.33 k8s-master03 <none> <none> calico-node-lxfkf 1/1 Running 0 38m 192.168.0.35 k8s-node02 <none> <none> calico-node-t667x 1/1 Running 0 38m 192.168.0.31 k8s-master01 <none> <none> calico-typha-59d75c5dd4-gbhfp 1/1 Running 0 38m 192.168.0.35 k8s-node02 <none> <none> coredns-coredns-c5c6d4d9b-bd829 1/1 Running 0 10m 172.25.92.65 k8s-master02 <none> <none> metrics-server-7c8b55c754-w7q8v 1/1 Running 0 3m56s 172.17.125.3 k8s-node01 <none> <none> # 进入busybox ping其他节点上的pod kubectl exec -ti busybox -- sh / # ping 192.168.0.34 PING 192.168.0.34 (192.168.0.34): 56 data bytes 64 bytes from 192.168.0.34: seq=0 ttl=63 time=0.358 ms 64 bytes from 192.168.0.34: seq=1 ttl=63 time=0.668 ms 64 bytes from 192.168.0.34: seq=2 ttl=63 time=0.637 ms 64 bytes from 192.168.0.34: seq=3 ttl=63 time=0.624 ms 64 bytes from 192.168.0.34: seq=4 ttl=63 time=0.907 ms # 可以连通证明这个pod是可以跨命名空间和跨主机通信的
12.6创建三个副本,可以看到3个副本分布在不同的节点上(用完可以删了)
cat > deployments.yaml << EOF apiVersion: apps/v1 kind: Deployment metadata: name: nginx-deployment labels: app: nginx spec: replicas: 3 selector: matchLabels: app: nginx template: metadata: labels: app: nginx spec: containers: - name: nginx image: nginx ports: - containerPort: 80 EOF kubectl apply -f deployments.yaml deployment.apps/nginx-deployment created kubectl get pod NAME READY STATUS RESTARTS AGE busybox 1/1 Running 0 6m25s nginx-deployment-9456bbbf9-4bmvk 1/1 Running 0 8s nginx-deployment-9456bbbf9-9rcdk 1/1 Running 0 8s nginx-deployment-9456bbbf9-dqv8s 1/1 Running 0 8s # 删除nginx [root@k8s-master01 ~]# kubectl delete -f deployments.yaml
13.安装dashboard
helm repo add kubernetes-dashboard https://kubernetes.github.io/dashboard/ helm install kubernetes-dashboard kubernetes-dashboard/kubernetes-dashboard --namespace kube-system
13.1更改dashboard的svc为NodePort,如果已是请忽略
kubectl edit svc kubernetes-dashboard -n kube-system type: NodePort
13.2查看端口号
kubectl get svc kubernetes-dashboard -n kube-system NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE kubernetes-dashboard NodePort 10.108.120.110 <none> 443:30034/TCP 34s
13.3创建token
cat > dashboard-user.yaml << EOF apiVersion: v1 kind: ServiceAccount metadata: name: admin-user namespace: kube-system --- apiVersion: rbac.authorization.k8s.io/v1 kind: ClusterRoleBinding metadata: name: admin-user roleRef: apiGroup: rbac.authorization.k8s.io kind: ClusterRole name: cluster-admin subjects: - kind: ServiceAccount name: admin-user namespace: kube-system EOF kubectl apply -f dashboard-user.yaml # 创建token kubectl -n kube-system create token admin-user eyJhbGciOiJSUzI1NiIsImtpZCI6ImtHTXRwbS1IR3NabHR5WDhYTUhUX1Rnekt4M1pzNFNNM3NwLXdkSlh3T2MifQ.eyJhdWQiOlsiaHR0cHM6Ly9rdWJlcm5ldGVzLmRlZmF1bHQuc3ZjLmNsdXN0ZXIubG9jYWwiXSwiZXhwIjoxNjg3ODc1MjIyLCJpYXQiOjE2ODc4NzE2MjIsImlzcyI6Imh0dHBzOi8va3ViZXJuZXRlcy5kZWZhdWx0LnN2Yy5jbHVzdGVyLmxvY2FsIiwia3ViZXJuZXRlcy5pbyI6eyJuYW1lc3BhY2UiOiJrdWJlLXN5c3RlbSIsInNlcnZpY2VhY2NvdW50Ijp7Im5hbWUiOiJhZG1pbi11c2VyIiwidWlkIjoiZjZiMzYzYzEtZjE1Ni00YTBhLTk5MzUtYmZmN2YzZWJlNTU2In19LCJuYmYiOjE2ODc4NzE2MjIsInN1YiI6InN5c3RlbTpzZXJ2aWNlYWNjb3VudDprdWJlLXN5c3RlbTphZG1pbi11c2VyIn0.uNIwe8tzA7IjdBWiCroZxT7OGw9IiCdPT0R1E1G5k965tVH9spVxz6PFvWLwNl6QnjhvseDUAbz0yBIJ3v42nsp1EYZeKXMYxfPGqgZ_7EQ4xYh-zEEoHLtdVVo20beCVtzTzEV_0doUehV_GLDt1es794OI7s4SlxYOtc1MMg50VUr4jkUvfuDPqHSMh2cirnTJXL9TX_3K-30W4c_fN2TCxWoWpwa4G-5oCORx8j9FLejTldHDFB_Z4TNhirNQLpi05C6OT43HiVxrsD6fgvPUQatUznCedb48RWTjCk8nY0CTsZ3VR6Vby4MOrlHf57asMFfe6lSTIcDSj0lV1g
13.3登录dashboard
14.ingress安装
14.1执行部署
wget https://mirrors.chenby.cn/https://raw.githubusercontent.com/kubernetes/ingress-nginx/main/deploy/static/provider/cloud/deploy.yaml # 修改为国内源 docker源可选 sed -i "s#registry.k8s.io/#m.daocloud.io/registry.k8s.io/#g" *.yaml cat > backend.yaml << EOF apiVersion: apps/v1 kind: Deployment metadata: name: default-http-backend labels: app.kubernetes.io/name: default-http-backend namespace: kube-system spec: replicas: 1 selector: matchLabels: app.kubernetes.io/name: default-http-backend template: metadata: labels: app.kubernetes.io/name: default-http-backend spec: terminationGracePeriodSeconds: 60 containers: - name: default-http-backend image: registry.cn-hangzhou.aliyuncs.com/chenby/defaultbackend-amd64:1.5 livenessProbe: httpGet: path: /healthz port: 8080 scheme: HTTP initialDelaySeconds: 30 timeoutSeconds: 5 ports: - containerPort: 8080 resources: limits: cpu: 10m memory: 20Mi requests: cpu: 10m memory: 20Mi --- apiVersion: v1 kind: Service metadata: name: default-http-backend namespace: kube-system labels: app.kubernetes.io/name: default-http-backend spec: ports: - port: 80 targetPort: 8080 selector: app.kubernetes.io/name: default-http-backend EOF kubectl apply -f deploy.yaml kubectl apply -f backend.yaml cat > ingress-demo-app.yaml << EOF apiVersion: apps/v1 kind: Deployment metadata: name: hello-server spec: replicas: 2 selector: matchLabels: app: hello-server template: metadata: labels: app: hello-server spec: containers: - name: hello-server image: registry.cn-hangzhou.aliyuncs.com/lfy_k8s_images/hello-server ports: - containerPort: 9000 --- apiVersion: apps/v1 kind: Deployment metadata: labels: app: nginx-demo name: nginx-demo spec: replicas: 2 selector: matchLabels: app: nginx-demo template: metadata: labels: app: nginx-demo spec: containers: - image: nginx name: nginx --- apiVersion: v1 kind: Service metadata: labels: app: nginx-demo name: nginx-demo spec: selector: app: nginx-demo ports: - port: 8000 protocol: TCP targetPort: 80 --- apiVersion: v1 kind: Service metadata: labels: app: hello-server name: hello-server spec: selector: app: hello-server ports: - port: 8000 protocol: TCP targetPort: 9000 --- apiVersion: networking.k8s.io/v1 kind: Ingress metadata: name: ingress-host-bar spec: ingressClassName: nginx rules: - host: "hello.chenby.cn" http: paths: - pathType: Prefix path: "/" backend: service: name: hello-server port: number: 8000 - host: "demo.chenby.cn" http: paths: - pathType: Prefix path: "/nginx" backend: service: name: nginx-demo port: number: 8000 EOF # 等创建完成后在执行: kubectl apply -f ingress-demo-app.yaml kubectl get ingress NAME CLASS HOSTS ADDRESS PORTS AGE ingress-host-bar nginx hello.chenby.cn,demo.chenby.cn 192.168.0.32 80 7s
14.2过滤查看ingress端口
# 修改为nodeport kubectl edit svc -n ingress-nginx ingress-nginx-controller type: NodePort [root@hello ~/yaml]# kubectl get svc -A | grep ingress ingress-nginx ingress-nginx-controller NodePort 10.104.231.36 <none> 80:32636/TCP,443:30579/TCP 104s ingress-nginx ingress-nginx-controller-admission ClusterIP 10.101.85.88 <none> 443/TCP 105s [root@hello ~/yaml]#
15.IPv6测试
#部署应用 cat<<EOF | kubectl apply -f - apiVersion: apps/v1 kind: Deployment metadata: name: chenby spec: replicas: 3 selector: matchLabels: app: chenby template: metadata: labels: app: chenby spec: containers: - name: chenby image: docker.io/library/nginx resources: limits: memory: "128Mi" cpu: "500m" ports: - containerPort: 80 --- apiVersion: v1 kind: Service metadata: name: chenby spec: ipFamilyPolicy: PreferDualStack ipFamilies: - IPv6 - IPv4 type: NodePort selector: app: chenby ports: - port: 80 targetPort: 80 EOF #查看端口 [root@k8s-master01 ~]# kubectl get svc NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE chenby NodePort fd00::a29c <none> 80:30779/TCP 5s [root@k8s-master01 ~]# #使用内网访问 [root@localhost yaml]# curl -I http://[fd00::a29c] HTTP/1.1 200 OK Server: nginx/1.21.6 Date: Thu, 05 May 2022 10:20:35 GMT Content-Type: text/html Content-Length: 615 Last-Modified: Tue, 25 Jan 2022 15:03:52 GMT Connection: keep-alive ETag: "61f01158-267" Accept-Ranges: bytes [root@localhost yaml]# curl -I http://192.168.0.31:30779 HTTP/1.1 200 OK Server: nginx/1.21.6 Date: Thu, 05 May 2022 10:20:59 GMT Content-Type: text/html Content-Length: 615 Last-Modified: Tue, 25 Jan 2022 15:03:52 GMT Connection: keep-alive ETag: "61f01158-267" Accept-Ranges: bytes [root@localhost yaml]# #使用公网访问 [root@localhost yaml]# curl -I http://[2409:8a10:9e18:9020::10]:30779 HTTP/1.1 200 OK Server: nginx/1.21.6 Date: Thu, 05 May 2022 10:20:54 GMT Content-Type: text/html Content-Length: 615 Last-Modified: Tue, 25 Jan 2022 15:03:52 GMT Connection: keep-alive ETag: "61f01158-267" Accept-Ranges: bytes
16.安装命令行自动补全功能
yum install bash-completion -y source /usr/share/bash-completion/bash_completion source <(kubectl completion bash) echo "source <(kubectl completion bash)" >> ~/.bashrc
附录
# 镜像加速器可以使用DaoCloud仓库,替换规则如下 cr.l5d.io/ ===> m.daocloud.io/cr.l5d.io/ docker.elastic.co/ ===> m.daocloud.io/docker.elastic.co/ docker.io/ ===> m.daocloud.io/docker.io/ gcr.io/ ===> m.daocloud.io/gcr.io/ ghcr.io/ ===> m.daocloud.io/ghcr.io/ k8s.gcr.io/ ===> m.daocloud.io/k8s.gcr.io/ mcr.microsoft.com/ ===> m.daocloud.io/mcr.microsoft.com/ nvcr.io/ ===> m.daocloud.io/nvcr.io/ quay.io/ ===> m.daocloud.io/quay.io/ registry.jujucharms.com/ ===> m.daocloud.io/registry.jujucharms.com/ registry.k8s.io/ ===> m.daocloud.io/registry.k8s.io/ registry.opensource.zalan.do/ ===> m.daocloud.io/registry.opensource.zalan.do/ rocks.canonical.com/ ===> m.daocloud.io/rocks.canonical.com/ # 镜像版本要自行查看,因为镜像版本是随时更新的,文档无法做到实时更新 # docker pull 镜像 docker pull registry.cn-hangzhou.aliyuncs.com/chenby/cni:master docker pull registry.cn-hangzhou.aliyuncs.com/chenby/node:master docker pull registry.cn-hangzhou.aliyuncs.com/chenby/kube-controllers:master docker pull registry.cn-hangzhou.aliyuncs.com/chenby/typha:master docker pull registry.cn-hangzhou.aliyuncs.com/chenby/coredns:v1.10.0 docker pull registry.cn-hangzhou.aliyuncs.com/chenby/pause:3.6 docker pull registry.cn-hangzhou.aliyuncs.com/chenby/metrics-server:v0.5.2 docker pull kubernetesui/dashboard:v2.7.0 docker pull kubernetesui/metrics-scraper:v1.0.8 docker pull quay.io/cilium/cilium:v1.12.6 docker pull quay.io/cilium/certgen:v0.1.8 docker pull quay.io/cilium/hubble-relay:v1.12.6 docker pull quay.io/cilium/hubble-ui-backend:v0.9.2 docker pull quay.io/cilium/hubble-ui:v0.9.2 docker pull quay.io/cilium/cilium-etcd-operator:v2.0.7 docker pull quay.io/cilium/operator:v1.12.6 docker pull quay.io/cilium/clustermesh-apiserver:v1.12.6 docker pull quay.io/coreos/etcd:v3.5.4 docker pull quay.io/cilium/startup-script:d69851597ea019af980891a4628fb36b7880ec26 # docker 保存镜像 docker save registry.cn-hangzhou.aliyuncs.com/chenby/cni:master -o cni.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/node:master -o node.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/typha:master -o typha.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/kube-controllers:master -o kube-controllers.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/coredns:v1.10.0 -o coredns.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/pause:3.6 -o pause.tar docker save registry.cn-hangzhou.aliyuncs.com/chenby/metrics-server:v0.5.2 -o metrics-server.tar docker save kubernetesui/dashboard:v2.7.0 -o dashboard.tar docker save kubernetesui/metrics-scraper:v1.0.8 -o metrics-scraper.tar docker save quay.io/cilium/cilium:v1.12.6 -o cilium.tar docker save quay.io/cilium/certgen:v0.1.8 -o certgen.tar docker save quay.io/cilium/hubble-relay:v1.12.6 -o hubble-relay.tar docker save quay.io/cilium/hubble-ui-backend:v0.9.2 -o hubble-ui-backend.tar docker save quay.io/cilium/hubble-ui:v0.9.2 -o hubble-ui.tar docker save quay.io/cilium/cilium-etcd-operator:v2.0.7 -o cilium-etcd-operator.tar docker save quay.io/cilium/operator:v1.12.6 -o operator.tar docker save quay.io/cilium/clustermesh-apiserver:v1.12.6 -o clustermesh-apiserver.tar docker save quay.io/coreos/etcd:v3.5.4 -o etcd.tar docker save quay.io/cilium/startup-script:d69851597ea019af980891a4628fb36b7880ec26 -o startup-script.tar # 传输到各个节点 for NODE in k8s-master01 k8s-master02 k8s-master03 k8s-node01 k8s-node02; do scp -r images/ $NODE:/root/ ; done # 创建命名空间 ctr ns create k8s.io # 导入镜像 ctr --namespace k8s.io image import images/cni.tar ctr --namespace k8s.io image import images/node.tar ctr --namespace k8s.io image import images/typha.tar ctr --namespace k8s.io image import images/kube-controllers.tar ctr --namespace k8s.io image import images/coredns.tar ctr --namespace k8s.io image import images/pause.tar ctr --namespace k8s.io image import images/metrics-server.tar ctr --namespace k8s.io image import images/dashboard.tar ctr --namespace k8s.io image import images/metrics-scraper.tar ctr --namespace k8s.io image import images/dashboard.tar ctr --namespace k8s.io image import images/metrics-scraper.tar ctr --namespace k8s.io image import images/cilium.tar ctr --namespace k8s.io image import images/certgen.tar ctr --namespace k8s.io image import images/hubble-relay.tar ctr --namespace k8s.io image import images/hubble-ui-backend.tar ctr --namespace k8s.io image import images/hubble-ui.tar ctr --namespace k8s.io image import images/cilium-etcd-operator.tar ctr --namespace k8s.io image import images/operator.tar ctr --namespace k8s.io image import images/clustermesh-apiserver.tar ctr --namespace k8s.io image import images/etcd.tar ctr --namespace k8s.io image import images/startup-script.tar # pull tar包 解压后 helm pull cilium/cilium # 查看镜像版本 root@hello:~/cilium# cat values.yaml| grep tag: -C1 repository: "quay.io/cilium/cilium" tag: "v1.12.6" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/certgen" tag: "v0.1.8@sha256:4a456552a5f192992a6edcec2febb1c54870d665173a33dc7d876129b199ddbd" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/hubble-relay" tag: "v1.12.6" # hubble-relay-digest -- repository: "quay.io/cilium/hubble-ui-backend" tag: "v0.9.2@sha256:a3ac4d5b87889c9f7cc6323e86d3126b0d382933bd64f44382a92778b0cde5d7" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/hubble-ui" tag: "v0.9.2@sha256:d3596efc94a41c6b772b9afe6fe47c17417658956e04c3e2a28d293f2670663e" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/cilium-etcd-operator" tag: "v2.0.7@sha256:04b8327f7f992693c2cb483b999041ed8f92efc8e14f2a5f3ab95574a65ea2dc" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/operator" tag: "v1.12.6" # operator-generic-digest -- repository: "quay.io/cilium/startup-script" tag: "d69851597ea019af980891a4628fb36b7880ec26" pullPolicy: "IfNotPresent" -- repository: "quay.io/cilium/cilium" tag: "v1.12.6" # cilium-digest -- repository: "quay.io/cilium/clustermesh-apiserver" tag: "v1.12.6" # clustermesh-apiserver-digest -- repository: "quay.io/coreos/etcd" tag: "v3.5.4@sha256:795d8660c48c439a7c3764c2330ed9222ab5db5bb524d8d0607cac76f7ba82a3" pullPolicy: "IfNotPresent"