1. 组件版本和配置策略
组件版本:
- Kubernetes 1.10.4
- Docker 18.03.1-ce
- Etcd 3.3.7
- Flanneld 0.10.0
插件:
- Coredns
- Dashboard
- Heapster (influxdb、grafana)
- Metrics-Server
- EFK (elasticsearch、fluentd、kibana)
镜像仓库:
- docker registry
主要配置策略:
kube-apiserver:
- 使用 keepalived 和 haproxy 实现 3 节点高可用;
- 关闭非安全端口 8080 和匿名访问;
- 在安全端口 6443 接收 https 请求;
- 严格的认证和授权策略 (x509、token、RBAC);
- 开启 bootstrap token 认证,支持 kubelet TLS bootstrapping;
- 使用 https 访问 kubelet、etcd,加密通信;
kube-controller-manager:
- 3 节点高可用;
- 关闭非安全端口,在安全端口 10252 接收 https 请求;
- 使用 kubeconfig 访问 apiserver 的安全端口;
- 自动 approve kubelet 证书签名请求 (CSR),证书过期后自动轮转;
- 各 controller 使用自己的 ServiceAccount 访问 apiserver;
kube-scheduler:
- 3 节点高可用;
- 使用 kubeconfig 访问 apiserver 的安全端口;
kubelet:
- 使用 kubeadm 动态创建 bootstrap token,而不是在 apiserver 中静态配置;
- 使用 TLS bootstrap 机制自动生成 client 和 server 证书,过期后自动轮转;
- 在 KubeletConfiguration 类型的 JSON 文件配置主要参数;
- 关闭只读端口,在安全端口 10250 接收 https 请求,对请求进行认证和授权,拒绝匿名访非授权访问;
- 使用 kubeconfig 访问 apiserver 的安全端口;
kube-proxy:
- 使用 kubeconfig 访问 apiserver 的安全端口;
- 在 KubeProxyConfiguration 类型的 JSON 文件配置主要参数;
- 使用 ipvs 代理模式;
集群插件:
- DNS:使用功能、性能更好的 coredns;
- Dashboard:支持登录认证;
- Metric:heapster、metrics-server,使用 https 访问 kubelet 安全端口;
- Log:Elasticsearch、Fluend、Kibana;
- Registry 镜像库:docker-registry、harbor;
2. 环境准备
集群机器:
本文档中的 etcd 集群、master 节点、worker 节点均使用这三台机器。
- kube-node1:192.168.16.237
- kube-node2:192.168.16.238
- kube-node3:192.168.16.239
- uname -r: 4.17.12-1.el7.elrepo.x86_64
设置永久主机名称,然后重新登录:
$ sudo hostnamectl set-hostname kube-node1 # 将 kube-node1 替换为当前主机名
- 设置的主机名保存在
/etc/hostname
文件中;
修改每台机器的 /etc/hosts
文件,添加主机名和 IP 的对应关系:
$ grep kube-node /etc/hosts
192.168.16.237 kube-node1 kube-node1
192.168.16.238 kube-node2 kube-node2
192.168.16.239 kube-node3 kube-node3
添加 k8s 和 docker 账户
在每台机器上添加 k8s 账户,可以无密码 sudo:
$ sudo useradd -m k8s
$ sudo sh -c 'echo 123456 | passwd k8s --stdin' # 为 k8s 账户设置密码
$ sudo visudo
$ sudo grep '%wheel.*NOPASSWD: ALL' /etc/sudoers
%wheel ALL=(ALL) NOPASSWD: ALL
$ sudo gpasswd -a k8s wheel
在每台机器上添加 docker 账户,将 k8s 账户添加到 docker 组中,同时配置 dockerd 参数:
$ sudo useradd -m docker
$ sudo gpasswd -a k8s docker
$ sudo mkdir -p /etc/docker/
$ cat /etc/docker/daemon.json
{
"registry-mirrors": ["https://hub-mirror.c.163.com", "https://docker.mirrors.ustc.edu.cn"],
"max-concurrent-downloads": 20
}
无密码 ssh 登录其它节点
如果没有特殊指明,本文档的所有操作均在 kube-node1 节点上执行,然后远程分发文件和执行命令。
设置 kube-node1 可以无密码登录所有节点的 k8s 和 root 账户:
[k8s@kube-node1 k8s]$ ssh-keygen -t rsa
[k8s@kube-node1 k8s]$ ssh-copy-id root@kube-node1
[k8s@kube-node1 k8s]$ ssh-copy-id root@kube-node2
[k8s@kube-node1 k8s]$ ssh-copy-id root@kube-node3
[k8s@kube-node1 k8s]$ ssh-copy-id k8s@kube-node1
[k8s@kube-node1 k8s]$ ssh-copy-id k8s@kube-node2
[k8s@kube-node1 k8s]$ ssh-copy-id k8s@kube-node3
将可执行文件路径 /opt/k8s/bin 添加到 PATH 变量中
在每台机器上添加环境变量:
$ sudo sh -c "echo 'PATH=/opt/k8s/bin:$PATH:$HOME/bin:$JAVA_HOME/bin' >>/root/.bashrc"
$ echo 'PATH=/opt/k8s/bin:$PATH:$HOME/bin:$JAVA_HOME/bin' >>~/.bashrc
安装依赖包
在每台机器上安装依赖包:
$ sudo yum install -y epel-release
$ sudo yum install -y conntrack ipvsadm ipset jq sysstat curl iptables libseccomp
- ipvs 依赖 ipset;
关闭防火墙
在每台机器上关闭防火墙:
$ sudo systemctl stop firewalld
$ sudo systemctl disable firewalld
$ sudo iptables -F && sudo iptables -X && sudo iptables -F -t nat && sudo iptables -X -t nat
$ sudo sudo iptables -P FORWARD ACCEPT
关闭 swap 分区
如果开启了 swap 分区,kubelet 会启动失败(可以通过将参数 --fail-swap-on 设置为 false 来忽略 swap on),故需要在每台机器上关闭 swap 分区:
$ sudo swapoff -a
为了防止开机自动挂载 swap 分区,可以注释 /etc/fstab
中相应的条目:
$ sudo sed -i '/ swap / s/^\(.*\)$/#\1/g' /etc/fstab
关闭 SELinux
关闭 SELinux,否则后续 K8S 挂载目录时可能报错 Permission denied
:
$ sudo setenforce 0
$ grep SELINUX /etc/selinux/config
SELINUX=disabled
- 修改配置文件,永久生效;
关闭 dnsmasq
linux 系统开启了 dnsmasq 后(如 GUI 环境),将系统 DNS Server 设置为 127.0.0.1,这会导致 docker 容器无法解析域名,需要关闭它:
$ sudo service dnsmasq stop
$ sudo systemctl disable dnsmasq
设置系统参数
$ cat > kubernetes.conf <<EOF
net.bridge.bridge-nf-call-iptables=1
net.bridge.bridge-nf-call-ip6tables=1
net.ipv4.ip_forward=1
vm.swappiness=0
vm.overcommit_memory=1
vm.panic_on_oom=0
fs.inotify.max_user_watches=89100
EOF
$ sudo cp kubernetes.conf /etc/sysctl.d/kubernetes.conf
$ sudo sysctl -p /etc/sysctl.d/kubernetes.conf
$ sudo mount -t cgroup -o cpu,cpuacct none /sys/fs/cgroup/cpu,cpuacct
加载内核模块
$ sudo modprobe br_netfilter
$ sudo modprobe ip_vs
设置系统时区
$ # 调整系统 TimeZone
$ sudo timedatectl set-timezone Asia/Shanghai
$ # 将当前的 UTC 时间写入硬件时钟
$ sudo timedatectl set-local-rtc 0
$ # 重启依赖于系统时间的服务
$ sudo systemctl restart rsyslog
$ sudo systemctl restart crond
创建目录
在每台机器上创建目录:
$ sudo mkdir -p /opt/k8s/bin
$ sudo chown -R k8s /opt/k8s
$ sudo sudo mkdir -p /etc/kubernetes/cert
$ sudo chown -R k8s /etc/kubernetes
$ sudo mkdir -p /etc/etcd/cert
$ sudo chown -R k8s /etc/etcd/cert
$ sudo mkdir -p /var/lib/etcd && chown -R k8s /etc/etcd/cert
检查系统内核和模块是否适合运行 docker (仅适用于 linux 系统)
$ curl https://raw.githubusercontent.com/docker/docker/master/contrib/check-config.sh > check-config.sh
$ bash ./check-config.sh
集群环境变量
后续的部署步骤将使用下面定义的全局环境变量,请根据自己的机器、网络情况修改:
#!/usr/bin/bash
# 生成 EncryptionConfig 所需的加密 key
ENCRYPTION_KEY=$(head -c 32 /dev/urandom | base64)
# 最好使用 当前未用的网段 来定义服务网段和 Pod 网段
# 服务网段,部署前路由不可达,部署后集群内路由可达(kube-proxy 和 ipvs 保证)
SERVICE_CIDR="10.254.0.0/16"
# Pod 网段,建议 /16 段地址,部署前路由不可达,部署后集群内路由可达(flanneld 保证)
CLUSTER_CIDR="172.30.0.0/16"
# 服务端口范围 (NodePort Range)
export NODE_PORT_RANGE="8400-9000"
# 集群各机器 IP 数组
export NODE_IPS=(192.168.16.237 192.168.16.238 192.168.16.239)
# 集群各 IP 对应的 主机名数组
export NODE_NAMES=(kube-node1 kube-node2 kube-node3)
# kube-apiserver 的 VIP(HA 组件 keepalived 发布的 IP)
export MASTER_VIP=192.168.16.240
# kube-apiserver VIP 地址(HA 组件 haproxy 监听 8443 端口)
export KUBE_APISERVER="https://${MASTER_VIP}:8443"
# HA 节点,VIP 所在的网络接口名称
export VIP_IF="eth0"
# etcd 集群服务地址列表
export ETCD_ENDPOINTS="https://192.168.16.267:2379,https://192.168.16.238:2379,https://192.168.16.239:2379"
# etcd 集群间通信的 IP 和端口
export ETCD_NODES="kube-node1=https://192.168.16.237:2380,kube-node2=https://192.168.16.238:2380,kube-node3=https://192.168.16.239:2380"
# flanneld 网络配置前缀
export FLANNEL_ETCD_PREFIX="/kubernetes/network"
# kubernetes 服务 IP (一般是 SERVICE_CIDR 中第一个IP)
export CLUSTER_KUBERNETES_SVC_IP="10.254.0.1"
# 集群 DNS 服务 IP (从 SERVICE_CIDR 中预分配)
export CLUSTER_DNS_SVC_IP="10.254.0.2"
# 集群 DNS 域名
export CLUSTER_DNS_DOMAIN="cluster.local."
# 将二进制目录 /opt/k8s/bin 加到 PATH 中
export PATH=/opt/k8s/bin:$PATH
- 打包后的变量定义见 environment.sh,后续部署时会提示导入该脚本;
分发集群环境变量定义脚本
把全局变量定义脚本拷贝到所有节点的 /opt/k8s/bin
目录:
source environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp environment.sh k8s@${node_ip}:/opt/k8s/bin/
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
3. 创建 CA 证书和秘钥
为确保安全,kubernetes
系统各组件需要使用 x509
证书对通信进行加密和认证。
CA (Certificate Authority) 是自签名的根证书,用来签名后续创建的其它证书。
本文档使用 CloudFlare
的 PKI 工具集 cfssl 创建所有证书。
安装 cfssl 工具集
sudo mkdir -p /opt/k8s/cert && sudo chown -R k8s /opt/k8s && cd /opt/k8s
wget https://pkg.cfssl.org/R1.2/cfssl_linux-amd64
mv cfssl_linux-amd64 /opt/k8s/bin/cfssl
wget https://pkg.cfssl.org/R1.2/cfssljson_linux-amd64
mv cfssljson_linux-amd64 /opt/k8s/bin/cfssljson
wget https://pkg.cfssl.org/R1.2/cfssl-certinfo_linux-amd64
mv cfssl-certinfo_linux-amd64 /opt/k8s/bin/cfssl-certinfo
chmod +x /opt/k8s/bin/*
export PATH=/opt/k8s/bin:$PATH
创建根证书 (CA)
CA 证书是集群所有节点共享的,只需要创建一个 CA 证书,后续创建的所有证书都由它签名。
创建配置文件
CA 配置文件用于配置根证书的使用场景 (profile) 和具体参数 (usage,过期时间、服务端认证、客户端认证、加密等),后续在签名其它证书时需要指定特定场景。
cat > ca-config.json <<EOF
{
"signing": {
"default": {
"expiry": "87600h"
},
"profiles": {
"kubernetes": {
"usages": [
"signing",
"key encipherment",
"server auth",
"client auth"
],
"expiry": "87600h"
}
}
}
}
EOF
-
signing
:表示该证书可用于签名其它证书,生成的ca.pem
证书中CA=TRUE
; -
server auth
:表示 client 可以用该该证书对 server 提供的证书进行验证; -
client auth
:表示 server 可以用该该证书对 client 提供的证书进行验证;
创建证书签名请求文件
cat > ca-csr.json <<EOF
{
"CN": "kubernetes",
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "k8s",
"OU": "4Paradigm"
}
]
}
EOF
- CN:
Common Name
,kube-apiserver 从证书中提取该字段作为请求的用户名 (User Name),浏览器使用该字段验证网站是否合法; - O:
Organization
,kube-apiserver 从证书中提取该字段作为请求用户所属的组 (Group); - kube-apiserver 将提取的 User、Group 作为
RBAC
授权的用户标识;
生成 CA 证书和私钥
cfssl gencert -initca ca-csr.json | cfssljson -bare ca
ls ca*
分发证书文件
将生成的 CA 证书、秘钥文件、配置文件拷贝到所有节点的 /etc/kubernetes/cert
目录下:
source /opt/k8s/bin/environment.sh # 导入 NODE_IPS 环境变量
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /etc/kubernetes/cert && chown -R k8s /etc/kubernetes"
scp ca*.pem ca-config.json k8s@${node_ip}:/etc/kubernetes/cert
done
- k8s 账户需要有读写 /etc/kubernetes 目录及其子目录文件的权限;
4.部署 kubectl 命令行工具
kubectl 是 kubernetes 集群的命令行管理工具,本文档介绍安装和配置它的步骤。
kubectl 默认从 ~/.kube/config
文件读取 kube-apiserver 地址、证书、用户名等信息,如果没有配置,执行 kubectl 命令时可能会出错:
$ kubectl get pods
The connection to the server localhost:8080 was refused - did you specify the right host or port?
本文档只需要部署一次,生成的 kubeconfig 文件与机器无关。
下载和分发 kubectl 二进制文件
下载和解压:
wget https://dl.k8s.io/v1.10.4/kubernetes-client-linux-amd64.tar.gz
tar -xzvf kubernetes-client-linux-amd64.tar.gz
分发到所有使用 kubectl 的节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kubernetes/client/bin/kubectl k8s@${node_ip}:/opt/k8s/bin/
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
创建 admin 证书和私钥
kubectl 与 apiserver https 安全端口通信,apiserver 对提供的证书进行认证和授权。
kubectl 作为集群的管理工具,需要被授予最高权限。这里创建具有最高权限的 admin 证书。
创建证书签名请求:
cat > admin-csr.json <<EOF
{
"CN": "admin",
"hosts": [],
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "system:masters",
"OU": "4Paradigm"
}
]
}
EOF
- O 为
system:masters
,kube-apiserver 收到该证书后将请求的 Group 设置为 system:masters; - 预定义的 ClusterRoleBinding
cluster-admin
将 Groupsystem:masters
与 Rolecluster-admin
绑定,该 Role 授予所有 API的权限; - 该证书只会被 kubectl 当做 client 证书使用,所以 hosts 字段为空;
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes admin-csr.json | cfssljson -bare admin
ls admin*
创建 kubeconfig 文件
kubeconfig 为 kubectl 的配置文件,包含访问 apiserver 的所有信息,如 apiserver 地址、CA 证书和自身使用的证书;
source /opt/k8s/bin/environment.sh
# 设置集群参数
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kubectl.kubeconfig
# 设置客户端认证参数
kubectl config set-credentials admin \
--client-certificate=admin.pem \
--client-key=admin-key.pem \
--embed-certs=true \
--kubeconfig=kubectl.kubeconfig
# 设置上下文参数
kubectl config set-context kubernetes \
--cluster=kubernetes \
--user=admin \
--kubeconfig=kubectl.kubeconfig
# 设置默认上下文
kubectl config use-context kubernetes --kubeconfig=kubectl.kubeconfig
-
--certificate-authority
:验证 kube-apiserver 证书的根证书; -
--client-certificate
、--client-key
:刚生成的admin
证书和私钥,连接 kube-apiserver 时使用; -
--embed-certs=true
:将 ca.pem 和 admin.pem 证书内容嵌入到生成的 kubectl.kubeconfig 文件中(不加时,写入的是证书文件路径);
分发 kubeconfig 文件
分发到所有使用 kubectl
命令的节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "mkdir -p ~/.kube"
scp kubectl.kubeconfig k8s@${node_ip}:~/.kube/config
ssh root@${node_ip} "mkdir -p ~/.kube"
scp kubectl.kubeconfig root@${node_ip}:~/.kube/config
done
- 保存到用户的
~/.kube/config
文件;
5.部署 etcd 集群
etcd 是基于 Raft 的分布式 key-value 存储系统,由 CoreOS 开发,常用于服务发现、共享配置以及并发控制(如 leader 选举、分布式锁等)。kubernetes 使用 etcd 存储所有运行数据。
本文档介绍部署一个三节点高可用 etcd 集群的步骤:
- 下载和分发 etcd 二进制文件;
- 创建 etcd 集群各节点的 x509 证书,用于加密客户端(如 etcdctl) 与 etcd 集群、etcd 集群之间的数据流;
- 创建 etcd 的 systemd unit 文件,配置服务参数;
- 检查集群工作状态;
etcd 集群各节点的名称和 IP 如下:
- kube-node1:192.168.16.237
- kube-node2:192.168.16.238
- kube-node3:192.168.16.239
下载和分发 etcd 二进制文件
到 https://github.com/coreos/etcd/releases 页面下载最新版本的发布包:
wget https://github.com/coreos/etcd/releases/download/v3.3.7/etcd-v3.3.7-linux-amd64.tar.gz
tar -xvf etcd-v3.3.7-linux-amd64.tar.gz
分发二进制文件到集群所有节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp etcd-v3.3.7-linux-amd64/etcd* k8s@${node_ip}:/opt/k8s/bin
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
创建 etcd 证书和私钥
创建证书签名请求:
cat > etcd-csr.json <<EOF
{
"CN": "etcd",
"hosts": [
"127.0.0.1",
"192.168.16.237",
"192.168.16.238",
"192.168.16.239"
],
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "k8s",
"OU": "4Paradigm"
}
]
}
EOF
- hosts 字段指定授权使用该证书的 etcd 节点 IP 或域名列表,这里将 etcd 集群的三个节点 IP 都列在其中;
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes etcd-csr.json | cfssljson -bare etcd
ls etcd*
分发生成的证书和私钥到各 etcd 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /etc/etcd/cert && chown -R k8s /etc/etcd/cert"
scp etcd*.pem k8s@${node_ip}:/etc/etcd/cert/
done
创建 etcd 的 systemd unit 模板文件
source /opt/k8s/bin/environment.sh
cat > etcd.service.template <<EOF
[Unit]
Description=Etcd Server
After=network.target
After=network-online.target
Wants=network-online.target
Documentation=https://github.com/coreos
[Service]
User=k8s
Type=notify
WorkingDirectory=/var/lib/etcd/
ExecStart=/opt/k8s/bin/etcd \\
--data-dir=/var/lib/etcd \\
--name=##NODE_NAME## \\
--cert-file=/etc/etcd/cert/etcd.pem \\
--key-file=/etc/etcd/cert/etcd-key.pem \\
--trusted-ca-file=/etc/kubernetes/cert/ca.pem \\
--peer-cert-file=/etc/etcd/cert/etcd.pem \\
--peer-key-file=/etc/etcd/cert/etcd-key.pem \\
--peer-trusted-ca-file=/etc/kubernetes/cert/ca.pem \\
--peer-client-cert-auth \\
--client-cert-auth \\
--listen-peer-urls=https://##NODE_IP##:2380 \\
--initial-advertise-peer-urls=https://##NODE_IP##:2380 \\
--listen-client-urls=https://##NODE_IP##:2379,http://127.0.0.1:2379 \\
--advertise-client-urls=https://##NODE_IP##:2379 \\
--initial-cluster-token=etcd-cluster-0 \\
--initial-cluster=${ETCD_NODES} \\
--initial-cluster-state=new
Restart=on-failure
RestartSec=5
LimitNOFILE=65536
[Install]
WantedBy=multi-user.target
EOF
-
User
:指定以 k8s 账户运行; -
WorkingDirectory
、--data-dir
:指定工作目录和数据目录为/var/lib/etcd
,需在启动服务前创建这个目录; -
--name
:指定节点名称,当--initial-cluster-state
值为new
时,--name
的参数值必须位于--initial-cluster
列表中; -
--cert-file
、--key-file
:etcd server 与 client 通信时使用的证书和私钥; -
--trusted-ca-file
:签名 client 证书的 CA 证书,用于验证 client 证书; -
--peer-cert-file
、--peer-key-file
:etcd 与 peer 通信使用的证书和私钥; -
--peer-trusted-ca-file
:签名 peer 证书的 CA 证书,用于验证 peer 证书;
为各节点创建和分发 etcd systemd unit 文件
替换模板文件中的变量,为各节点创建 systemd unit 文件:
source /opt/k8s/bin/environment.sh
for (( i=0; i < 3; i++ ))
do
sed -e "s/##NODE_NAME##/${NODE_NAMES[i]}/" -e "s/##NODE_IP##/${NODE_IPS[i]}/" etcd.service.template > etcd-${NODE_IPS[i]}.service
done
ls *.service
- NODE_NAMES 和 NODE_IPS 为相同长度的 bash 数组,分别为节点名称和对应的 IP;
分发生成的 systemd unit 文件:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/lib/etcd && chown -R k8s /var/lib/etcd"
scp etcd-${node_ip}.service root@${node_ip}:/etc/systemd/system/etcd.service
done
- 必须先创建 etcd 数据目录和工作目录;
- 文件重命名为 etcd.service;
完整 unit 文件见:etcd.service
启动 etcd 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable etcd && systemctl restart etcd &"
done
- etcd 进程首次启动时会等待其它节点的 etcd 加入集群,命令
systemctl start etcd
会卡住一段时间,为正常现象。
检查启动结果
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status etcd|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
$ journalctl -u etcd
验证服务状态
部署完 etcd 集群后,在任一 etc 节点上执行如下命令:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ETCDCTL_API=3 /opt/k8s/bin/etcdctl \
--endpoints=https://${node_ip}:2379 \
--cacert=/etc/kubernetes/cert/ca.pem \
--cert=/etc/etcd/cert/etcd.pem \
--key=/etc/etcd/cert/etcd-key.pem endpoint health
done
预期输出:
https://192.168.16.237:2379 is healthy: successfully committed proposal: took = 2.192932ms
https://192.168.16.238:2379 is healthy: successfully committed proposal: took = 3.546896ms
https://192.168.16.239:2379 is healthy: successfully committed proposal: took = 3.013667ms
输出均为 healthy
时表示集群服务正常。
6.# 部署 flannel 网络
kubernetes 要求集群内各节点(包括 master 节点)能通过 Pod 网段互联互通。flannel 使用 vxlan 技术为各节点创建一个可以互通的 Pod 网络。
flaneel 第一次启动时,从 etcd 获取 Pod 网段信息,为本节点分配一个未使用的 /24
段地址,然后创建 flannedl.1
(也可能是其它名称,如 flannel1 等) 接口。
flannel 将分配的 Pod 网段信息写入 /run/flannel/docker
文件,docker 后续使用这个文件中的环境变量设置 docker0
网桥。
下载和分发 flanneld 二进制文件
到 https://github.com/coreos/flannel/releases 页面下载最新版本的发布包:
mkdir flannel
wget https://github.com/coreos/flannel/releases/download/v0.10.0/flannel-v0.10.0-linux-amd64.tar.gz
tar -xzvf flannel-v0.10.0-linux-amd64.tar.gz -C flannel
分发 flanneld 二进制文件到集群所有节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp flannel/{flanneld,mk-docker-opts.sh} k8s@${node_ip}:/opt/k8s/bin/
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
创建 flannel 证书和私钥
flannel 从 etcd 集群存取网段分配信息,而 etcd 集群启用了双向 x509 证书认证,所以需要为 flanneld 生成证书和私钥。
创建证书签名请求:
cat > flanneld-csr.json <<EOF
{
"CN": "flanneld",
"hosts": [],
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "k8s",
"OU": "4Paradigm"
}
]
}
EOF
- 该证书只会被 kubectl 当做 client 证书使用,所以 hosts 字段为空;
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes flanneld-csr.json | cfssljson -bare flanneld
ls flanneld*pem
将生成的证书和私钥分发到所有节点(master 和 worker):
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /etc/flanneld/cert && chown -R k8s /etc/flanneld"
scp flanneld*.pem k8s@${node_ip}:/etc/flanneld/cert
done
向 etcd 写入集群 Pod 网段信息
注意:本步骤只需执行一次。
source /opt/k8s/bin/environment.sh
etcdctl \
--endpoints=${ETCD_ENDPOINTS} \
--ca-file=/etc/kubernetes/cert/ca.pem \
--cert-file=/etc/flanneld/cert/flanneld.pem \
--key-file=/etc/flanneld/cert/flanneld-key.pem \
set ${FLANNEL_ETCD_PREFIX}/config '{"Network":"'${CLUSTER_CIDR}'", "SubnetLen": 24, "Backend": {"Type": "vxlan"}}'
- flanneld 当前版本 (v0.10.0) 不支持 etcd v3,故使用 etcd v2 API 写入配置 key 和网段数据;
- 写入的 Pod 网段 ${CLUSTER_CIDR} 必须是 /16 段地址,必须与 kube-controller-manager 的
--cluster-cidr
参数值一致;
创建 flanneld 的 systemd unit 文件
source /opt/k8s/bin/environment.sh
export IFACE=eth0
cat > flanneld.service << EOF
[Unit]
Description=Flanneld overlay address etcd agent
After=network.target
After=network-online.target
Wants=network-online.target
After=etcd.service
Before=docker.service
[Service]
Type=notify
ExecStart=/opt/k8s/bin/flanneld \\
-etcd-cafile=/etc/kubernetes/cert/ca.pem \\
-etcd-certfile=/etc/flanneld/cert/flanneld.pem \\
-etcd-keyfile=/etc/flanneld/cert/flanneld-key.pem \\
-etcd-endpoints=${ETCD_ENDPOINTS} \\
-etcd-prefix=${FLANNEL_ETCD_PREFIX} \\
-iface=${IFACE}
ExecStartPost=/opt/k8s/bin/mk-docker-opts.sh -k DOCKER_NETWORK_OPTIONS -d /run/flannel/docker
Restart=on-failure
[Install]
WantedBy=multi-user.target
RequiredBy=docker.service
EOF
-
mk-docker-opts.sh
脚本将分配给 flanneld 的 Pod 子网网段信息写入/run/flannel/docker
文件,后续 docker 启动时使用这个文件中的环境变量配置 docker0 网桥; - flanneld 使用系统缺省路由所在的接口与其它节点通信,对于有多个网络接口(如内网和公网)的节点,可以用
-iface
参数指定通信接口,如上面的 eth0 接口; - flanneld 运行时需要 root 权限;
完整 unit 见 flanneld.service
分发 flanneld systemd unit 文件到所有节点
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp flanneld.service root@${node_ip}:/etc/systemd/system/
done
启动 flanneld 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable flanneld && systemctl restart flanneld"
done
检查启动结果
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status flanneld|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
$ journalctl -u flanneld
检查分配给各 flanneld 的 Pod 网段信息
查看集群 Pod 网段(/16):
source /opt/k8s/bin/environment.sh
etcdctl \
--endpoints=${ETCD_ENDPOINTS} \
--ca-file=/etc/kubernetes/cert/ca.pem \
--cert-file=/etc/flanneld/cert/flanneld.pem \
--key-file=/etc/flanneld/cert/flanneld-key.pem \
get ${FLANNEL_ETCD_PREFIX}/config
输出:
{"Network":"172.30.0.0/16", "SubnetLen": 24, "Backend": {"Type": "vxlan"}}
查看已分配的 Pod 子网段列表(/24):
source /opt/k8s/bin/environment.sh
etcdctl \
--endpoints=${ETCD_ENDPOINTS} \
--ca-file=/etc/kubernetes/cert/ca.pem \
--cert-file=/etc/flanneld/cert/flanneld.pem \
--key-file=/etc/flanneld/cert/flanneld-key.pem \
ls ${FLANNEL_ETCD_PREFIX}/subnets
输出:
/kubernetes/network/subnets/172.30.81.0-24
/kubernetes/network/subnets/172.30.29.0-24
/kubernetes/network/subnets/172.30.39.0-24
查看某一 Pod 网段对应的节点 IP 和 flannel 接口地址:
source /opt/k8s/bin/environment.sh
etcdctl \
--endpoints=${ETCD_ENDPOINTS} \
--ca-file=/etc/kubernetes/cert/ca.pem \
--cert-file=/etc/flanneld/cert/flanneld.pem \
--key-file=/etc/flanneld/cert/flanneld-key.pem \
get ${FLANNEL_ETCD_PREFIX}/subnets/172.30.81.0-24
输出:
{"PublicIP":"192.168.16.237","BackendType":"vxlan","BackendData":{"VtepMAC":"12:21:93:9e:b1:eb"}}
验证各节点能通过 Pod 网段互通
在各节点上部署 flannel 后,检查是否创建了 flannel 接口(名称可能为 flannel0、flannel.0、flannel.1 等):
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "/usr/sbin/ip addr show flannel.1|grep -w inet"
done
输出:
inet 172.30.81.0/32 scope global flannel.1
inet 172.30.29.0/32 scope global flannel.1
inet 172.30.39.0/32 scope global flannel.1
在各节点上 ping 所有 flannel 接口 IP,确保能通:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "ping -c 1 172.30.81.0"
ssh ${node_ip} "ping -c 1 172.30.29.0"
ssh ${node_ip} "ping -c 1 172.30.39.0"
done
7.部署 master 节点
kubernetes master 节点运行如下组件:
- kube-apiserver
- kube-scheduler
- kube-controller-manager
kube-scheduler 和 kube-controller-manager 可以以集群模式运行,通过 leader 选举产生一个工作进程,其它进程处于阻塞模式。
对于 kube-apiserver,可以运行多个实例(本文档是 3 实例),但对其它组件需要提供统一的访问地址,该地址需要高可用。本文档使用 keepalived 和 haproxy 实现 kube-apiserver VIP 高可用和负载均衡。
下载最新版本的二进制文件
从 CHANGELOG
页面 下载 server tarball 文件。
wget https://dl.k8s.io/v1.10.4/kubernetes-server-linux-amd64.tar.gz
tar -xzvf kubernetes-server-linux-amd64.tar.gz
cd kubernetes
tar -xzvf kubernetes-src.tar.gz
将二进制文件拷贝到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp server/bin/* k8s@${node_ip}:/opt/k8s/bin/
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
8. 部署高可用组件
本文档讲解使用 keepalived 和 haproxy 实现 kube-apiserver 高可用的步骤:
- keepalived 提供 kube-apiserver 对外服务的 VIP;
- haproxy 监听 VIP,后端连接所有 kube-apiserver 实例,提供健康检查和负载均衡功能;
运行 keepalived 和 haproxy 的节点称为 LB 节点。由于 keepalived 是一主多备运行模式,故至少两个 LB 节点。
本文档复用 master 节点的三台机器,haproxy 监听的端口(8443) 需要与 kube-apiserver 的端口 6443 不同,避免冲突。
keepalived 在运行过程中周期检查本机的 haproxy 进程状态,如果检测到 haproxy 进程异常,则触发重新选主的过程,VIP 将飘移到新选出来的主节点,从而实现 VIP 的高可用。
所有组件(如 kubeclt、apiserver、controller-manager、scheduler 等)都通过 VIP 和 haproxy 监听的 8443 端口访问 kube-apiserver 服务。
安装软件包
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "yum install -y keepalived haproxy"
done
配置和下发 haproxy 配置文件
haproxy 配置文件:
cat > haproxy.cfg <<EOF
global
log /dev/log local0
log /dev/log local1 notice
chroot /var/lib/haproxy
stats socket /var/run/haproxy-admin.sock mode 660 level admin
stats timeout 30s
user haproxy
group haproxy
daemon
nbproc 1
defaults
log global
timeout connect 5000
timeout client 10m
timeout server 10m
listen admin_stats
bind 0.0.0.0:10080
mode http
log 127.0.0.1 local0 err
stats refresh 30s
stats uri /status
stats realm welcome login\ Haproxy
stats auth admin:123456
stats hide-version
stats admin if TRUE
listen kube-master
bind 0.0.0.0:8443
mode tcp
option tcplog
balance source
server 192.168.16.237 192.1686.16.237:6443 check inter 2000 fall 2 rise 2 weight 1
server 192.168.16.238 192.168.16.238:6443 check inter 2000 fall 2 rise 2 weight 1
server 192.168.16.239 192.168.16.239:6443 check inter 2000 fall 2 rise 2 weight 1
EOF
- haproxy 在 10080 端口输出 status 信息;
- haproxy 监听所有接口的 8443 端口,该端口与环境变量 ${KUBE_APISERVER} 指定的端口必须一致;
- server 字段列出所有 kube-apiserver 监听的 IP 和端口;
下发 haproxy.cfg 到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp haproxy.cfg root@${node_ip}:/etc/haproxy
done
起 haproxy 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl restart haproxy"
done
检查 haproxy 服务状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl status haproxy|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
journalctl -u haproxy
检查 haproxy 是否监听 8443 端口:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "netstat -lnpt|grep haproxy"
done
确保输出类似于:
tcp 0 0 0.0.0.0:8443 0.0.0.0:* LISTEN 120583/haproxy
配置和下发 keepalived 配置文件
keepalived 是一主(master)多备(backup)运行模式,故有两种类型的配置文件。master 配置文件只有一份,backup 配置文件视节点数目而定,对于本文档而言,规划如下:
- master: 192.168.16.237
- backup:192.168.16.238 192.168.16.239
master 配置文件:
source /opt/k8s/bin/environment.sh
cat > keepalived-master.conf <<EOF
global_defs {
router_id lb-master-105
}
vrrp_script check-haproxy {
script "killall -0 haproxy"
interval 5
weight -30
}
vrrp_instance VI-kube-master {
state MASTER
priority 120
dont_track_primary
interface ${VIP_IF}
virtual_router_id 68
advert_int 3
track_script {
check-haproxy
}
virtual_ipaddress {
${MASTER_VIP}
}
}
EOF
- VIP 所在的接口(interface ${VIP_IF})为
eth0
; - 使用
killall -0 haproxy
命令检查所在节点的 haproxy 进程是否正常。如果异常则将权重减少(-30),从而触发重新选主过程; - router_id、virtual_router_id 用于标识属于该 HA 的 keepalived 实例,如果有多套 keepalived HA,则必须各不相同;
backup 配置文件:
source /opt/k8s/bin/environment.sh
cat > keepalived-backup.conf <<EOF
global_defs {
router_id lb-backup-105
}
vrrp_script check-haproxy {
script "killall -0 haproxy"
interval 5
weight -30
}
vrrp_instance VI-kube-master {
state BACKUP
priority 110
dont_track_primary
interface ${VIP_IF}
virtual_router_id 68
advert_int 3
track_script {
check-haproxy
}
virtual_ipaddress {
${MASTER_VIP}
}
}
EOF
- VIP 所在的接口(interface ${VIP_IF})为
eth0
; - 使用
killall -0 haproxy
命令检查所在节点的 haproxy 进程是否正常。如果异常则将权重减少(-30),从而触发重新选主过程; - router_id、virtual_router_id 用于标识属于该 HA 的 keepalived 实例,如果有多套 keepalived HA,则必须各不相同;
- priority 的值必须小于 master 的值;
下发 keepalived 配置文件
下发 master 配置文件:
scp keepalived-master.conf root@192.168.16.237:/etc/keepalived/keepalived.conf
下发 backup 配置文件:
scp keepalived-backup.conf root@192.168.16.238:/etc/keepalived/keepalived.conf
scp keepalived-backup.conf root@192.168.16.239:/etc/keepalived/keepalived.conf
起 keepalived 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl restart keepalived"
done
检查 keepalived 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl status keepalived|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
journalctl -u keepalived
查看 VIP 所在的节点,确保可以 ping 通 VIP:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "/usr/sbin/ip addr show ${VIP_IF}"
ssh ${node_ip} "ping -c 1 ${MASTER_VIP}"
done
查看 haproxy 状态页面
浏览器访问 ${MASTER_VIP}:10080/status 地址,查看 haproxy 状态页面:
9.部署 kube-apiserver 组件
本文档讲解使用 keepalived 和 haproxy 部署一个 3 节点高可用 master 集群的步骤,对应的 LB VIP 为环境变量 ${MASTER_VIP}。
准备工作
下载最新版本的二进制文件、安装和配置 flanneld 参考:06-0.部署master节点.md
创建 kubernetes 证书和私钥
创建证书签名请求:
source /opt/k8s/bin/environment.sh
cat > kubernetes-csr.json <<EOF
{
"CN": "kubernetes",
"hosts": [
"127.0.0.1",
"192.168.16.237",
"192.168.16.238",
"192.168.16.239",
"${MASTER_VIP}",
"${CLUSTER_KUBERNETES_SVC_IP}",
"kubernetes",
"kubernetes.default",
"kubernetes.default.svc",
"kubernetes.default.svc.cluster",
"kubernetes.default.svc.cluster.local"
],
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "k8s",
"OU": "4Paradigm"
}
]
}
EOF
hosts 字段指定授权使用该证书的 IP 或域名列表,这里列出了 VIP 、apiserver 节点 IP、kubernetes 服务 IP 和域名;
域名最后字符不能是
.
(如不能为kubernetes.default.svc.cluster.local.
),否则解析时失败,提示:x509: cannot parse dnsName "kubernetes.default.svc.cluster.local."
;如果使用非
cluster.local
域名,如opsnull.com
,则需要修改域名列表中的最后两个域名为:kubernetes.default.svc.opsnull
、kubernetes.default.svc.opsnull.com
-
kubernetes 服务 IP 是 apiserver 自动创建的,一般是
--service-cluster-ip-range
参数指定的网段的第一个IP,后续可以通过如下命令获取:$ kubectl get svc kubernetes NAME CLUSTER-IP EXTERNAL-IP PORT(S) AGE kubernetes 10.254.0.1 <none> 443/TCP 1d
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes kubernetes-csr.json | cfssljson -bare kubernetes
ls kubernetes*pem
将生成的证书和私钥文件拷贝到 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /etc/kubernetes/cert/ && sudo chown -R k8s /etc/kubernetes/cert/"
scp kubernetes*.pem k8s@${node_ip}:/etc/kubernetes/cert/
done
- k8s 账户可以读写 /etc/kubernetes/cert/ 目录;
创建加密配置文件
source /opt/k8s/bin/environment.sh
cat > encryption-config.yaml <<EOF
kind: EncryptionConfig
apiVersion: v1
resources:
- resources:
- secrets
providers:
- aescbc:
keys:
- name: key1
secret: ${ENCRYPTION_KEY}
- identity: {}
EOF
将加密配置文件拷贝到 master 节点的 /etc/kubernetes
目录下:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp encryption-config.yaml root@${node_ip}:/etc/kubernetes/
done
替换后的 encryption-config.yaml 文件:encryption-config.yaml
创建 kube-apiserver systemd unit 模板文件
source /opt/k8s/bin/environment.sh
cat > kube-apiserver.service.template <<EOF
[Unit]
Description=Kubernetes API Server
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
After=network.target
[Service]
ExecStart=/opt/k8s/bin/kube-apiserver \\
--enable-admission-plugins=Initializers,NamespaceLifecycle,NodeRestriction,LimitRanger,ServiceAccount,DefaultStorageClass,ResourceQuota \\
--anonymous-auth=false \\
--experimental-encryption-provider-config=/etc/kubernetes/encryption-config.yaml \\
--advertise-address=##NODE_IP## \\
--bind-address=##NODE_IP## \\
--insecure-port=0 \\
--authorization-mode=Node,RBAC \\
--runtime-config=api/all \\
--enable-bootstrap-token-auth \\
--service-cluster-ip-range=${SERVICE_CIDR} \\
--service-node-port-range=${NODE_PORT_RANGE} \\
--tls-cert-file=/etc/kubernetes/cert/kubernetes.pem \\
--tls-private-key-file=/etc/kubernetes/cert/kubernetes-key.pem \\
--client-ca-file=/etc/kubernetes/cert/ca.pem \\
--kubelet-client-certificate=/etc/kubernetes/cert/kubernetes.pem \\
--kubelet-client-key=/etc/kubernetes/cert/kubernetes-key.pem \\
--service-account-key-file=/etc/kubernetes/cert/ca-key.pem \\
--etcd-cafile=/etc/kubernetes/cert/ca.pem \\
--etcd-certfile=/etc/kubernetes/cert/kubernetes.pem \\
--etcd-keyfile=/etc/kubernetes/cert/kubernetes-key.pem \\
--etcd-servers=${ETCD_ENDPOINTS} \\
--enable-swagger-ui=true \\
--allow-privileged=true \\
--apiserver-count=3 \\
--audit-log-maxage=30 \\
--audit-log-maxbackup=3 \\
--audit-log-maxsize=100 \\
--audit-log-path=/var/log/kube-apiserver-audit.log \\
--event-ttl=1h \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on-failure
RestartSec=5
Type=notify
User=k8s
LimitNOFILE=65536
[Install]
WantedBy=multi-user.target
EOF
-
--experimental-encryption-provider-config
:启用加密特性; -
--authorization-mode=Node,RBAC
: 开启 Node 和 RBAC 授权模式,拒绝未授权的请求; -
--enable-admission-plugins
:启用ServiceAccount
和NodeRestriction
; -
--service-account-key-file
:签名 ServiceAccount Token 的公钥文件,kube-controller-manager 的--service-account-private-key-file
指定私钥文件,两者配对使用; -
--tls-*-file
:指定 apiserver 使用的证书、私钥和 CA 文件。--client-ca-file
用于验证 client (kue-controller-manager、kube-scheduler、kubelet、kube-proxy 等)请求所带的证书; -
--kubelet-client-certificate
、--kubelet-client-key
:如果指定,则使用 https 访问 kubelet APIs;需要为证书对应的用户(上面 kubernetes*.pem 证书的用户为 kubernetes) 用户定义 RBAC 规则,否则访问 kubelet API 时提示未授权; -
--bind-address
: 不能为127.0.0.1
,否则外界不能访问它的安全端口 6443; -
--insecure-port=0
:关闭监听非安全端口(8080); -
--service-cluster-ip-range
: 指定 Service Cluster IP 地址段; -
--service-node-port-range
: 指定 NodePort 的端口范围; -
--runtime-config=api/all=true
: 启用所有版本的 APIs,如 autoscaling/v2alpha1; -
--enable-bootstrap-token-auth
:启用 kubelet bootstrap 的 token 认证; -
--apiserver-count=3
:指定集群运行模式,多台 kube-apiserver 会通过 leader 选举产生一个工作节点,其它节点处于阻塞状态; -
User=k8s
:使用 k8s 账户运行;
为各节点创建和分发 kube-apiserver systemd unit 文件
替换模板文件中的变量,为各节点创建 systemd unit 文件:
source /opt/k8s/bin/environment.sh
for (( i=0; i < 3; i++ ))
do
sed -e "s/##NODE_NAME##/${NODE_NAMES[i]}/" -e "s/##NODE_IP##/${NODE_IPS[i]}/" kube-apiserver.service.template > kube-apiserver-${NODE_IPS[i]}.service
done
ls kube-apiserver*.service
- NODE_NAMES 和 NODE_IPS 为相同长度的 bash 数组,分别为节点名称和对应的 IP;
分发生成的 systemd unit 文件:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
scp kube-apiserver-${node_ip}.service root@${node_ip}:/etc/systemd/system/kube-apiserver.service
done
- 必须先创建日志目录;
- 文件重命名为 kube-apiserver.service;
替换后的 unit 文件:kube-apiserver.service
启动 kube-apiserver 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kube-apiserver && systemctl restart kube-apiserver"
done
检查 kube-apiserver 运行状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl status kube-apiserver |grep 'Active:'"
done
确保状态为 active (running)
,否则到 master 节点查看日志,确认原因:
journalctl -u kube-apiserver
打印 kube-apiserver 写入 etcd 的数据
source /opt/k8s/bin/environment.sh
ETCDCTL_API=3 etcdctl \
--endpoints=${ETCD_ENDPOINTS} \
--cacert=/etc/kubernetes/cert/ca.pem \
--cert=/etc/etcd/cert/etcd.pem \
--key=/etc/etcd/cert/etcd-key.pem \
get /registry/ --prefix --keys-only
检查集群信息
$ kubectl cluster-info
Kubernetes master is running at https://192.168.16.240:8443
To further debug and diagnose cluster problems, use 'kubectl cluster-info dump'.
$ kubectl get all --all-namespaces
NAMESPACE NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE
default service/kubernetes ClusterIP 10.254.0.1 <none> 443/TCP 35m
$ kubectl get componentstatuses
NAME STATUS MESSAGE ERROR
controller-manager Unhealthy Get http://127.0.0.1:10252/healthz: dial tcp 127.0.0.1:10252: getsockopt: connection refused
scheduler Unhealthy Get http://127.0.0.1:10251/healthz: dial tcp 127.0.0.1:10251: getsockopt: connection refused
etcd-1 Healthy {"health":"true"}
etcd-0 Healthy {"health":"true"}
etcd-2 Healthy {"health":"true"}
注意:
-
如果执行 kubectl 命令式时输出如下错误信息,则说明使用的
~/.kube/config
文件不对,请切换到正确的账户后再执行该命令:The connection to the server localhost:8080 was refused - did you specify the right host or port?
执行
kubectl get componentstatuses
命令时,apiserver 默认向 127.0.0.1 发送请求。当 controller-manager、scheduler 以集群模式运行时,有可能和 kube-apiserver 不在一台机器上,这时 controller-manager 或 scheduler 的状态为 Unhealthy,但实际上它们工作正常。
检查 kube-apiserver 监听的端口
$ sudo netstat -lnpt|grep kube
tcp 0 0 192.168.16.237:6443 0.0.0.0:* LISTEN 13075/kube-apiserve
- 6443: 接收 https 请求的安全端口,对所有请求做认证和授权;
- 由于关闭了非安全端口,故没有监听 8080;
授予 kubernetes 证书访问 kubelet API 的权限
在执行 kubectl exec、run、logs 等命令时,apiserver 会转发到 kubelet。这里定义 RBAC 规则,授权 apiserver 调用 kubelet API。
$ kubectl create clusterrolebinding kube-apiserver:kubelet-apis --clusterrole=system:kubelet-api-admin --user kubernetes
10 部署高可用 kube-controller-manager 集群
本文档介绍部署高可用 kube-controller-manager 集群的步骤。
该集群包含 3 个节点,启动后将通过竞争选举机制产生一个 leader 节点,其它节点为阻塞状态。当 leader 节点不可用后,剩余节点将再次进行选举产生新的 leader 节点,从而保证服务的可用性。
为保证通信安全,本文档先生成 x509 证书和私钥,kube-controller-manager 在如下两种情况下使用该证书:
- 与 kube-apiserver 的安全端口通信时;
- 在安全端口(https,10252) 输出 prometheus 格式的 metrics;
准备工作
下载最新版本的二进制文件、安装和配置 flanneld 参考:06-0.部署master节点.md
创建 kube-controller-manager 证书和私钥
创建证书签名请求:
cat > kube-controller-manager-csr.json <<EOF
{
"CN": "system:kube-controller-manager",
"key": {
"algo": "rsa",
"size": 2048
},
"hosts": [
"127.0.0.1",
"192.168.16.237",
"192.168.16.238",
"192.168.16.239"
],
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "system:kube-controller-manager",
"OU": "4Paradigm"
}
]
}
EOF
- hosts 列表包含所有 kube-controller-manager 节点 IP;
- CN 为 system:kube-controller-manager、O 为 system:kube-controller-manager,kubernetes 内置的 ClusterRoleBindings system:kube-controller-manager 赋予 kube-controller-manager 工作所需的权限。
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes kube-controller-manager-csr.json | cfssljson -bare kube-controller-manager
将生成的证书和私钥分发到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager*.pem k8s@${node_ip}:/etc/kubernetes/cert/
done
创建和分发 kubeconfig 文件
kubeconfig 文件包含访问 apiserver 的所有信息,如 apiserver 地址、CA 证书和自身使用的证书;
source /opt/k8s/bin/environment.sh
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config set-credentials system:kube-controller-manager \
--client-certificate=kube-controller-manager.pem \
--client-key=kube-controller-manager-key.pem \
--embed-certs=true \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config set-context system:kube-controller-manager \
--cluster=kubernetes \
--user=system:kube-controller-manager \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config use-context system:kube-controller-manager --kubeconfig=kube-controller-manager.kubeconfig
分发 kubeconfig 到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager.kubeconfig k8s@${node_ip}:/etc/kubernetes/
done
创建和分发 kube-controller-manager systemd unit 文件
source /opt/k8s/bin/environment.sh
cat > kube-controller-manager.service <<EOF
[Unit]
Description=Kubernetes Controller Manager
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
[Service]
ExecStart=/opt/k8s/bin/kube-controller-manager \\
--port=0 \\
--secure-port=10252 \\
--bind-address=127.0.0.1 \\
--kubeconfig=/etc/kubernetes/kube-controller-manager.kubeconfig \\
--service-cluster-ip-range=${SERVICE_CIDR} \\
--cluster-name=kubernetes \\
--cluster-signing-cert-file=/etc/kubernetes/cert/ca.pem \\
--cluster-signing-key-file=/etc/kubernetes/cert/ca-key.pem \\
--experimental-cluster-signing-duration=8760h \\
--root-ca-file=/etc/kubernetes/cert/ca.pem \\
--service-account-private-key-file=/etc/kubernetes/cert/ca-key.pem \\
--leader-elect=true \\
--feature-gates=RotateKubeletServerCertificate=true \\
--controllers=*,bootstrapsigner,tokencleaner \\
--horizontal-pod-autoscaler-use-rest-clients=true \\
--horizontal-pod-autoscaler-sync-period=10s \\
--tls-cert-file=/etc/kubernetes/cert/kube-controller-manager.pem \\
--tls-private-key-file=/etc/kubernetes/cert/kube-controller-manager-key.pem \\
--use-service-account-credentials=true \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on
Restart=on-failure
RestartSec=5
User=k8s
[Install]
WantedBy=multi-user.target
EOF
-
--port=0
:关闭监听 http /metrics 的请求,同时--address
参数无效,--bind-address
参数有效; -
--secure-port=10252
、--bind-address=0.0.0.0
: 在所有网络接口监听 10252 端口的 https /metrics 请求; -
--kubeconfig
:指定 kubeconfig 文件路径,kube-controller-manager 使用它连接和验证 kube-apiserver; -
--cluster-signing-*-file
:签名 TLS Bootstrap 创建的证书; -
--experimental-cluster-signing-duration
:指定 TLS Bootstrap 证书的有效期; -
--root-ca-file
:放置到容器 ServiceAccount 中的 CA 证书,用来对 kube-apiserver 的证书进行校验; -
--service-account-private-key-file
:签名 ServiceAccount 中 Token 的私钥文件,必须和 kube-apiserver 的--service-account-key-file
指定的公钥文件配对使用; -
--service-cluster-ip-range
:指定 Service Cluster IP 网段,必须和 kube-apiserver 中的同名参数一致; -
--leader-elect=true
:集群运行模式,启用选举功能;被选为 leader 的节点负责处理工作,其它节点为阻塞状态; -
--feature-gates=RotateKubeletServerCertificate=true
:开启 kublet server 证书的自动更新特性; -
--controllers=*,bootstrapsigner,tokencleaner
:启用的控制器列表,tokencleaner 用于自动清理过期的 Bootstrap token; -
--horizontal-pod-autoscaler-*
:custom metrics 相关参数,支持 autoscaling/v2alpha1; -
--tls-cert-file
、--tls-private-key-file
:使用 https 输出 metrics 时使用的 Server 证书和秘钥; -
--use-service-account-credentials=true
: -
User=k8s
:使用 k8s 账户运行;
kube-controller-manager 不对请求 https metrics 的 Client 证书进行校验,故不需要指定 --tls-ca-file
参数,而且该参数已被淘汰。
完整 unit 见 kube-controller-manager.service
分发 systemd unit 文件到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager.service root@${node_ip}:/etc/systemd/system/
done
kube-controller-manager 的权限
ClusteRole: system:kube-controller-manager 的权限很小,只能创建 secret、serviceaccount 等资源对象,各 controller 的权限分散到 ClusterRole system:controller:XXX 中。
需要在 kube-controller-manager 的启动参数中添加 --use-service-account-credentials=true
参数,这样 main controller 会为各 controller 创建对应的 ServiceAccount XXX-controller。
内置的 ClusterRoleBinding system:controller:XXX 将赋予各 XXX-controller ServiceAccount 对应的 ClusterRole system:controller:XXX 权限。
启动 kube-controller-manager 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kube-controller-manager && systemctl restart kube-controller-manager"
done
- 必须先创建日志目录;
检查服务运行状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status kube-controller-manager|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
$ journalctl -u kube-controller-manager
查看输出的 metric
注意:以下命令在 kube-controller-manager 节点上执行。
kube-controller-manager 监听 10252 端口,接收 https 请求:
$ sudo netstat -lnpt|grep kube-controll
tcp 0 0 127.0.0.1:10252 0.0.0.0:* LISTEN 18377/kube-controll
$ curl -s --cacert /etc/kubernetes/cert/ca.pem https://127.0.0.1:10252/metrics |head
# HELP ClusterRoleAggregator_adds Total number of adds handled by workqueue: ClusterRoleAggregator
# TYPE ClusterRoleAggregator_adds counter
ClusterRoleAggregator_adds 3
# HELP ClusterRoleAggregator_depth Current depth of workqueue: ClusterRoleAggregator
# TYPE ClusterRoleAggregator_depth gauge
ClusterRoleAggregator_depth 0
# HELP ClusterRoleAggregator_queue_latency How long an item stays in workqueueClusterRoleAggregator before being requested.
# TYPE ClusterRoleAggregator_queue_latency summary
ClusterRoleAggregator_queue_latency{quantile="0.5"} 57018
ClusterRoleAggregator_queue_latency{quantile="0.9"} 57268
- curl --cacert CA 证书用来验证 kube-controller-manager https server 证书;
测试 kube-controller-manager 集群的高可用
停掉一个或两个节点的 kube-controller-manager 服务,观察其它节点的日志,看是否获取了 leader 权限。
查看当前的 leader
$ kubectl get endpoints kube-controller-manager --namespace=kube-system -o yaml
apiVersion: v1
kind: Endpoints
metadata:
annotations:
control-plane.alpha.kubernetes.io/leader: '{"holderIdentity":"kube-node2_084534e2-6cc4-11e8-a418-5254001f5b65","leaseDurationSeconds":15,"acquireTime":"2018-06-10T15:40:33Z","renewTime":"2018-06-10T16:19:08Z","leaderTransitions":12}'
creationTimestamp: 2018-06-10T13:59:42Z
name: kube-controller-manager
namespace: kube-system
resourceVersion: "4540"
selfLink: /api/v1/namespaces/kube-system/endpoints/kube-controller-manager
uid: 862cc048-6cb6-11e8-96fa-525400ba84c6
可见,当前的 leader 为 kube-node2 节点。
部署高可用 kube-controller-manager 集群
本文档介绍部署高可用 kube-controller-manager 集群的步骤。
该集群包含 3 个节点,启动后将通过竞争选举机制产生一个 leader 节点,其它节点为阻塞状态。当 leader 节点不可用后,剩余节点将再次进行选举产生新的 leader 节点,从而保证服务的可用性。
为保证通信安全,本文档先生成 x509 证书和私钥,kube-controller-manager 在如下两种情况下使用该证书:
- 与 kube-apiserver 的安全端口通信时;
- 在安全端口(https,10252) 输出 prometheus 格式的 metrics;
准备工作
下载最新版本的二进制文件、安装和配置 flanneld 参考:06-0.部署master节点.md
创建 kube-controller-manager 证书和私钥
创建证书签名请求:
cat > kube-controller-manager-csr.json <<EOF
{
"CN": "system:kube-controller-manager",
"key": {
"algo": "rsa",
"size": 2048
},
"hosts": [
"127.0.0.1",
"192.168.16.237",
"192.168.16.238",
"192.168.16.239"
],
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "system:kube-controller-manager",
"OU": "4Paradigm"
}
]
}
EOF
- hosts 列表包含所有 kube-controller-manager 节点 IP;
- CN 为 system:kube-controller-manager、O 为 system:kube-controller-manager,kubernetes 内置的 ClusterRoleBindings system:kube-controller-manager 赋予 kube-controller-manager 工作所需的权限。
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes kube-controller-manager-csr.json | cfssljson -bare kube-controller-manager
将生成的证书和私钥分发到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager*.pem k8s@${node_ip}:/etc/kubernetes/cert/
done
创建和分发 kubeconfig 文件
kubeconfig 文件包含访问 apiserver 的所有信息,如 apiserver 地址、CA 证书和自身使用的证书;
source /opt/k8s/bin/environment.sh
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config set-credentials system:kube-controller-manager \
--client-certificate=kube-controller-manager.pem \
--client-key=kube-controller-manager-key.pem \
--embed-certs=true \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config set-context system:kube-controller-manager \
--cluster=kubernetes \
--user=system:kube-controller-manager \
--kubeconfig=kube-controller-manager.kubeconfig
kubectl config use-context system:kube-controller-manager --kubeconfig=kube-controller-manager.kubeconfig
分发 kubeconfig 到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager.kubeconfig k8s@${node_ip}:/etc/kubernetes/
done
创建和分发 kube-controller-manager systemd unit 文件
source /opt/k8s/bin/environment.sh
cat > kube-controller-manager.service <<EOF
[Unit]
Description=Kubernetes Controller Manager
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
[Service]
ExecStart=/opt/k8s/bin/kube-controller-manager \\
--port=0 \\
--secure-port=10252 \\
--bind-address=127.0.0.1 \\
--kubeconfig=/etc/kubernetes/kube-controller-manager.kubeconfig \\
--service-cluster-ip-range=${SERVICE_CIDR} \\
--cluster-name=kubernetes \\
--cluster-signing-cert-file=/etc/kubernetes/cert/ca.pem \\
--cluster-signing-key-file=/etc/kubernetes/cert/ca-key.pem \\
--experimental-cluster-signing-duration=8760h \\
--root-ca-file=/etc/kubernetes/cert/ca.pem \\
--service-account-private-key-file=/etc/kubernetes/cert/ca-key.pem \\
--leader-elect=true \\
--feature-gates=RotateKubeletServerCertificate=true \\
--controllers=*,bootstrapsigner,tokencleaner \\
--horizontal-pod-autoscaler-use-rest-clients=true \\
--horizontal-pod-autoscaler-sync-period=10s \\
--tls-cert-file=/etc/kubernetes/cert/kube-controller-manager.pem \\
--tls-private-key-file=/etc/kubernetes/cert/kube-controller-manager-key.pem \\
--use-service-account-credentials=true \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on
Restart=on-failure
RestartSec=5
User=k8s
[Install]
WantedBy=multi-user.target
EOF
-
--port=0
:关闭监听 http /metrics 的请求,同时--address
参数无效,--bind-address
参数有效; -
--secure-port=10252
、--bind-address=0.0.0.0
: 在所有网络接口监听 10252 端口的 https /metrics 请求; -
--kubeconfig
:指定 kubeconfig 文件路径,kube-controller-manager 使用它连接和验证 kube-apiserver; -
--cluster-signing-*-file
:签名 TLS Bootstrap 创建的证书; -
--experimental-cluster-signing-duration
:指定 TLS Bootstrap 证书的有效期; -
--root-ca-file
:放置到容器 ServiceAccount 中的 CA 证书,用来对 kube-apiserver 的证书进行校验; -
--service-account-private-key-file
:签名 ServiceAccount 中 Token 的私钥文件,必须和 kube-apiserver 的--service-account-key-file
指定的公钥文件配对使用; -
--service-cluster-ip-range
:指定 Service Cluster IP 网段,必须和 kube-apiserver 中的同名参数一致; -
--leader-elect=true
:集群运行模式,启用选举功能;被选为 leader 的节点负责处理工作,其它节点为阻塞状态; -
--feature-gates=RotateKubeletServerCertificate=true
:开启 kublet server 证书的自动更新特性; -
--controllers=*,bootstrapsigner,tokencleaner
:启用的控制器列表,tokencleaner 用于自动清理过期的 Bootstrap token; -
--horizontal-pod-autoscaler-*
:custom metrics 相关参数,支持 autoscaling/v2alpha1; -
--tls-cert-file
、--tls-private-key-file
:使用 https 输出 metrics 时使用的 Server 证书和秘钥; -
--use-service-account-credentials=true
: -
User=k8s
:使用 k8s 账户运行;
kube-controller-manager 不对请求 https metrics 的 Client 证书进行校验,故不需要指定 --tls-ca-file
参数,而且该参数已被淘汰。
完整 unit 见 kube-controller-manager.service
分发 systemd unit 文件到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-controller-manager.service root@${node_ip}:/etc/systemd/system/
done
kube-controller-manager 的权限
ClusteRole: system:kube-controller-manager 的权限很小,只能创建 secret、serviceaccount 等资源对象,各 controller 的权限分散到 ClusterRole system:controller:XXX 中。
需要在 kube-controller-manager 的启动参数中添加 --use-service-account-credentials=true
参数,这样 main controller 会为各 controller 创建对应的 ServiceAccount XXX-controller。
内置的 ClusterRoleBinding system:controller:XXX 将赋予各 XXX-controller ServiceAccount 对应的 ClusterRole system:controller:XXX 权限。
启动 kube-controller-manager 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kube-controller-manager && systemctl restart kube-controller-manager"
done
- 必须先创建日志目录;
检查服务运行状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status kube-controller-manager|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
$ journalctl -u kube-controller-manager
查看输出的 metric
注意:以下命令在 kube-controller-manager 节点上执行。
kube-controller-manager 监听 10252 端口,接收 https 请求:
$ sudo netstat -lnpt|grep kube-controll
tcp 0 0 127.0.0.1:10252 0.0.0.0:* LISTEN 18377/kube-controll
$ curl -s --cacert /etc/kubernetes/cert/ca.pem https://127.0.0.1:10252/metrics |head
# HELP ClusterRoleAggregator_adds Total number of adds handled by workqueue: ClusterRoleAggregator
# TYPE ClusterRoleAggregator_adds counter
ClusterRoleAggregator_adds 3
# HELP ClusterRoleAggregator_depth Current depth of workqueue: ClusterRoleAggregator
# TYPE ClusterRoleAggregator_depth gauge
ClusterRoleAggregator_depth 0
# HELP ClusterRoleAggregator_queue_latency How long an item stays in workqueueClusterRoleAggregator before being requested.
# TYPE ClusterRoleAggregator_queue_latency summary
ClusterRoleAggregator_queue_latency{quantile="0.5"} 57018
ClusterRoleAggregator_queue_latency{quantile="0.9"} 57268
- curl --cacert CA 证书用来验证 kube-controller-manager https server 证书;
测试 kube-controller-manager 集群的高可用
停掉一个或两个节点的 kube-controller-manager 服务,观察其它节点的日志,看是否获取了 leader 权限。
查看当前的 leader
$ kubectl get endpoints kube-controller-manager --namespace=kube-system -o yaml
apiVersion: v1
kind: Endpoints
metadata:
annotations:
control-plane.alpha.kubernetes.io/leader: '{"holderIdentity":"kube-node2_084534e2-6cc4-11e8-a418-5254001f5b65","leaseDurationSeconds":15,"acquireTime":"2018-06-10T15:40:33Z","renewTime":"2018-06-10T16:19:08Z","leaderTransitions":12}'
creationTimestamp: 2018-06-10T13:59:42Z
name: kube-controller-manager
namespace: kube-system
resourceVersion: "4540"
selfLink: /api/v1/namespaces/kube-system/endpoints/kube-controller-manager
uid: 862cc048-6cb6-11e8-96fa-525400ba84c6
可见,当前的 leader 为 kube-node2 节点。
11. 部署高可用 kube-scheduler 集群
本文档介绍部署高可用 kube-scheduler 集群的步骤。
该集群包含 3 个节点,启动后将通过竞争选举机制产生一个 leader 节点,其它节点为阻塞状态。当 leader 节点不可用后,剩余节点将再次进行选举产生新的 leader 节点,从而保证服务的可用性。
为保证通信安全,本文档先生成 x509 证书和私钥,kube-scheduler 在如下两种情况下使用该证书:
- 与 kube-apiserver 的安全端口通信;
- 在安全端口(https,10251) 输出 prometheus 格式的 metrics;
准备工作
下载最新版本的二进制文件、安装和配置 flanneld 参考:06-0.部署master节点.md
创建 kube-scheduler 证书和私钥
创建证书签名请求:
cat > kube-scheduler-csr.json <<EOF
{
"CN": "system:kube-scheduler",
"hosts": [
"127.0.0.1",
"192.168.16.237",
"192.168.16.238",
"192.168.16.239"
],
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "system:kube-scheduler",
"OU": "4Paradigm"
}
]
}
EOF
- hosts 列表包含所有 kube-scheduler 节点 IP;
- CN 为 system:kube-scheduler、O 为 system:kube-scheduler,kubernetes 内置的 ClusterRoleBindings system:kube-scheduler 将赋予 kube-scheduler 工作所需的权限。
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes kube-scheduler-csr.json | cfssljson -bare kube-scheduler
创建和分发 kubeconfig 文件
kubeconfig 文件包含访问 apiserver 的所有信息,如 apiserver 地址、CA 证书和自身使用的证书;
source /opt/k8s/bin/environment.sh
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kube-scheduler.kubeconfig
kubectl config set-credentials system:kube-scheduler \
--client-certificate=kube-scheduler.pem \
--client-key=kube-scheduler-key.pem \
--embed-certs=true \
--kubeconfig=kube-scheduler.kubeconfig
kubectl config set-context system:kube-scheduler \
--cluster=kubernetes \
--user=system:kube-scheduler \
--kubeconfig=kube-scheduler.kubeconfig
kubectl config use-context system:kube-scheduler --kubeconfig=kube-scheduler.kubeconfig
- 上一步创建的证书、私钥以及 kube-apiserver 地址被写入到 kubeconfig 文件中;
分发 kubeconfig 到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-scheduler.kubeconfig k8s@${node_ip}:/etc/kubernetes/
done
创建和分发 kube-scheduler systemd unit 文件
cat > kube-scheduler.service <<EOF
[Unit]
Description=Kubernetes Scheduler
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
[Service]
ExecStart=/opt/k8s/bin/kube-scheduler \\
--address=127.0.0.1 \\
--kubeconfig=/etc/kubernetes/kube-scheduler.kubeconfig \\
--leader-elect=true \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on-failure
RestartSec=5
User=k8s
[Install]
WantedBy=multi-user.target
EOF
-
--address
:在 127.0.0.1:10251 端口接收 http /metrics 请求;kube-scheduler 目前还不支持接收 https 请求; -
--kubeconfig
:指定 kubeconfig 文件路径,kube-scheduler 使用它连接和验证 kube-apiserver; -
--leader-elect=true
:集群运行模式,启用选举功能;被选为 leader 的节点负责处理工作,其它节点为阻塞状态; -
User=k8s
:使用 k8s 账户运行;
完整 unit 见 kube-scheduler.service。
分发 systemd unit 文件到所有 master 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp kube-scheduler.service root@${node_ip}:/etc/systemd/system/
done
启动 kube-scheduler 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kube-scheduler && systemctl restart kube-scheduler"
done
- 必须先创建日志目录;
检查服务运行状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status kube-scheduler|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
journalctl -u kube-scheduler
查看输出的 metric
注意:以下命令在 kube-scheduler 节点上执行。
kube-scheduler 监听 10251 端口,接收 http 请求:
$ sudo netstat -lnpt|grep kube-sche
tcp 0 0 127.0.0.1:10251 0.0.0.0:* LISTEN 23783/kube-schedule
$ curl -s http://127.0.0.1:10251/metrics |head
# HELP apiserver_audit_event_total Counter of audit events generated and sent to the audit backend.
# TYPE apiserver_audit_event_total counter
apiserver_audit_event_total 0
# HELP go_gc_duration_seconds A summary of the GC invocation durations.
# TYPE go_gc_duration_seconds summary
go_gc_duration_seconds{quantile="0"} 9.7715e-05
go_gc_duration_seconds{quantile="0.25"} 0.000107676
go_gc_duration_seconds{quantile="0.5"} 0.00017868
go_gc_duration_seconds{quantile="0.75"} 0.000262444
go_gc_duration_seconds{quantile="1"} 0.001205223
测试 kube-scheduler 集群的高可用
随便找一个或两个 master 节点,停掉 kube-scheduler 服务,看其它节点是否获取了 leader 权限(systemd 日志)。
查看当前的 leader
$ kubectl get endpoints kube-scheduler --namespace=kube-system -o yaml
apiVersion: v1
kind: Endpoints
metadata:
annotations:
control-plane.alpha.kubernetes.io/leader: '{"holderIdentity":"kube-node3_61f34593-6cc8-11e8-8af7-5254002f288e","leaseDurationSeconds":15,"acquireTime":"2018-06-10T16:09:56Z","renewTime":"2018-06-10T16:20:54Z","leaderTransitions":1}'
creationTimestamp: 2018-06-10T16:07:33Z
name: kube-scheduler
namespace: kube-system
resourceVersion: "4645"
selfLink: /api/v1/namespaces/kube-system/endpoints/kube-scheduler
uid: 62382d98-6cc8-11e8-96fa-525400ba84c6
可见,当前的 leader 为 kube-node3 节点。
12.部署 worker 节点
kubernetes work 节点运行如下组件:
- docker
- kubelet
- kube-proxy
安装依赖包
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "yum install -y epel-release"
ssh root@${node_ip} "yum install -y conntrack ipvsadm ipset jq iptables curl sysstat libseccomp && /usr/sbin/modprobe ip_vs "
done
13.部署 docker 组件
docker 是容器的运行环境,管理它的生命周期。kubelet 通过 Container Runtime Interface (CRI) 与 docker 进行交互。可以二进制或者yum方式安装
13.1 二进制方式安装
使用docker info
查看存储驱动 如果是vfs的话 需要更换驱动,否则会有一些问题.
安装依赖包
下载和分发 docker 二进制文件
到 https://download.docker.com/linux/static/stable/x86_64/ 页面下载最新发布包:
wget https://download.docker.com/linux/static/stable/x86_64/docker-18.03.1-ce.tgz
tar -xvf docker-18.03.1-ce.tgz
分发二进制文件到所有 worker 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp docker/docker* k8s@${node_ip}:/opt/k8s/bin/
ssh k8s@${node_ip} "chmod +x /opt/k8s/bin/*"
done
创建和分发 systemd unit 文件
cat > docker.service <<"EOF"
[Unit]
Description=Docker Application Container Engine
Documentation=http://docs.docker.io
[Service]
Environment="PATH=/opt/k8s/bin:/bin:/sbin:/usr/bin:/usr/sbin"
EnvironmentFile=-/run/flannel/docker
ExecStart=/opt/k8s/bin/dockerd --log-level=error $DOCKER_NETWORK_OPTIONS
ExecReload=/bin/kill -s HUP $MAINPID
Restart=on-failure
RestartSec=5
LimitNOFILE=infinity
LimitNPROC=infinity
LimitCORE=infinity
Delegate=yes
KillMode=process
[Install]
WantedBy=multi-user.target
EOF
EOF 前后有双引号,这样 bash 不会替换文档中的变量,如 $DOCKER_NETWORK_OPTIONS;
dockerd 运行时会调用其它 docker 命令,如 docker-proxy,所以需要将 docker 命令所在的目录加到 PATH 环境变量中;
flanneld 启动时将网络配置写入
/run/flannel/docker
文件中,dockerd 启动前读取该文件中的环境变量DOCKER_NETWORK_OPTIONS
,然后设置 docker0 网桥网段;如果指定了多个
EnvironmentFile
选项,则必须将/run/flannel/docker
放在最后(确保 docker0 使用 flanneld 生成的 bip 参数);docker 需要以 root 用于运行;
-
docker 从 1.13 版本开始,可能将 iptables FORWARD chain的默认策略设置为DROP,从而导致 ping 其它 Node 上的 Pod IP 失败,遇到这种情况时,需要手动设置策略为
ACCEPT
:$ sudo iptables -P FORWARD ACCEPT
并且把以下命令写入
/etc/rc.local
文件中,防止节点重启iptables FORWARD chain的默认策略又还原为DROP/sbin/iptables -P FORWARD ACCEPT
完整 unit 见 docker.service
分发 systemd unit 文件到所有 worker 机器:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
scp docker.service root@${node_ip}:/etc/systemd/system/
done
配置和分发 docker 配置文件
使用国内的仓库镜像服务器以加快 pull image 的速度,同时增加下载的并发数 (需要重启 dockerd 生效):
cat > docker-daemon.json <<EOF
{
"registry-mirrors": ["https://hub-mirror.c.163.com", "https://docker.mirrors.ustc.edu.cn"],
"max-concurrent-downloads": 20
}
EOF
分发 docker 配置文件到所有 work 节点:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /etc/docker/"
scp docker-daemon.json root@${node_ip}:/etc/docker/daemon.json
done
启动 docker 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "systemctl stop firewalld && systemctl disable firewalld"
ssh root@${node_ip} "/usr/sbin/iptables -F && /usr/sbin/iptables -X && /usr/sbin/iptables -F -t nat && /usr/sbin/iptables -X -t nat"
ssh root@${node_ip} "/usr/sbin/iptables -P FORWARD ACCEPT"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable docker && systemctl restart docker"
ssh root@${node_ip} 'for intf in /sys/devices/virtual/net/docker0/brif/*; do echo 1 > $intf/hairpin_mode; done'
ssh root@${node_ip} "sudo sysctl -p /etc/sysctl.d/kubernetes.conf"
done
- 关闭 firewalld(centos7)/ufw(ubuntu16.04),否则可能会重复创建 iptables 规则;
- 清理旧的 iptables rules 和 chains 规则;
- 开启 docker0 网桥下虚拟网卡的 hairpin 模式;
检查服务运行状态
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status docker|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
$ journalctl -u docker
检查 docker0 网桥
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "/usr/sbin/ip addr show flannel.1 && /usr/sbin/ip addr show docker0"
done
确认各 work 节点的 docker0 网桥和 flannel.1 接口的 IP 处于同一个网段中(如下 172.30.39.0 和 172.30.39.1):
3: flannel.1: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1450 qdisc noqueue state UNKNOWN group default
link/ether ce:2f:d6:53:e5:f3 brd ff:ff:ff:ff:ff:ff
inet 172.30.39.0/32 scope global flannel.1
valid_lft forever preferred_lft forever
inet6 fe80::cc2f:d6ff:fe53:e5f3/64 scope link
valid_lft forever preferred_lft forever
4: docker0: <NO-CARRIER,BROADCAST,MULTICAST,UP> mtu 1500 qdisc noqueue state DOWN group default
link/ether 02:42:bf:65:16:5c brd ff:ff:ff:ff:ff:ff
inet 172.30.39.1/24 brd 172.30.39.255 scope global docker0
valid_lft forever preferred_lft forever
13.2所有节点yum 方式安装
安装docker需要的依赖包
yum install -y yum-utils \
device-mapper-persistent-data \
lvm2
安装docker的yum源,通过yum源进行下载
yum-config-manager \
--add-repo \
https://download.docker.com/linux/centos/docker-ce.repo
安装docker
yum -y install docker-ce-18.03.1.ce
修改启动文件
vim /usr/lib/systemd/system/docker.service
### 12行添加
EnvironmentFile=-/run/flannel/docker
### 13行修改
ExecStart=/usr/bin/dockerd --log-level=error $DOCKER_NETWORK_OPTIONS
启动docker
确认各 work 节点的 docker0 网桥和 flannel.1 接口的 IP 处于同一个网段中(如下 172.30.39.0 和 172.30.39.1):
systemctl daemon-reload
systemctl start docker
其他步骤和二进制方式类似,开启防火墙转发等
14.部署 kubelet 组件
kublet 运行在每个 worker 节点上,接收 kube-apiserver 发送的请求,管理 Pod 容器,执行交互式命令,如 exec、run、logs 等。
kublet 启动时自动向 kube-apiserver 注册节点信息,内置的 cadvisor 统计和监控节点的资源使用情况。
为确保安全,本文档只开启接收 https 请求的安全端口,对请求进行认证和授权,拒绝未授权的访问(如 apiserver、heapster)。
下载和分发 kubelet 二进制文件
创建 kubelet bootstrap kubeconfig 文件
source /opt/k8s/bin/environment.sh
for node_name in ${NODE_NAMES[@]}
do
echo ">>> ${node_name}"
# 创建 token
export BOOTSTRAP_TOKEN=$(kubeadm token create \
--description kubelet-bootstrap-token \
--groups system:bootstrappers:${node_name} \
--kubeconfig ~/.kube/config)
# 设置集群参数
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kubelet-bootstrap-${node_name}.kubeconfig
# 设置客户端认证参数
kubectl config set-credentials kubelet-bootstrap \
--token=${BOOTSTRAP_TOKEN} \
--kubeconfig=kubelet-bootstrap-${node_name}.kubeconfig
# 设置上下文参数
kubectl config set-context default \
--cluster=kubernetes \
--user=kubelet-bootstrap \
--kubeconfig=kubelet-bootstrap-${node_name}.kubeconfig
# 设置默认上下文
kubectl config use-context default --kubeconfig=kubelet-bootstrap-${node_name}.kubeconfig
done
- 证书中写入 Token 而非证书,证书后续由 controller-manager 创建。
查看 kubeadm 为各节点创建的 token:
$ kubeadm token list --kubeconfig ~/.kube/config
TOKEN TTL EXPIRES USAGES DESCRIPTION EXTRA GROUPS
k0s2bj.7nvw1zi1nalyz4gz 23h 2018-06-14T15:14:31+08:00 authentication,signing kubelet-bootstrap-token system:bootstrappers:kube-node1
mkus5s.vilnjk3kutei600l 23h 2018-06-14T15:14:32+08:00 authentication,signing kubelet-bootstrap-token system:bootstrappers:kube-node3
zkiem5.0m4xhw0jc8r466nk 23h 2018-06-14T15:14:32+08:00 authentication,signing kubelet-bootstrap-token system:bootstrappers:kube-node2
- 创建的 token 有效期为 1 天,超期后将不能再被使用,且会被 kube-controller-manager 的 tokencleaner 清理(如果启用该 controller 的话);
- kube-apiserver 接收 kubelet 的 bootstrap token 后,将请求的 user 设置为 system:bootstrap:,group 设置为 system:bootstrappers;
各 token 关联的 Secret:
$ kubectl get secrets -n kube-system
NAME TYPE DATA AGE
bootstrap-token-k0s2bj bootstrap.kubernetes.io/token 7 1m
bootstrap-token-mkus5s bootstrap.kubernetes.io/token 7 1m
bootstrap-token-zkiem5 bootstrap.kubernetes.io/token 7 1m
default-token-99st7 kubernetes.io/service-account-token 3 2d
分发 bootstrap kubeconfig 文件到所有 worker 节点
source /opt/k8s/bin/environment.sh
for node_name in ${NODE_NAMES[@]}
do
echo ">>> ${node_name}"
scp kubelet-bootstrap-${node_name}.kubeconfig k8s@${node_name}:/etc/kubernetes/kubelet-bootstrap.kubeconfig
done
创建和分发 kubelet 参数配置文件
从 v1.10 开始,kubelet 部分参数需在配置文件中配置,kubelet --help
会提示:
DEPRECATED: This parameter should be set via the config file specified by the Kubelet's --config flag
创建 kubelet 参数配置模板文件:
source /opt/k8s/bin/environment.sh
cat > kubelet.config.json.template <<EOF
{
"kind": "KubeletConfiguration",
"apiVersion": "kubelet.config.k8s.io/v1beta1",
"authentication": {
"x509": {
"clientCAFile": "/etc/kubernetes/cert/ca.pem"
},
"webhook": {
"enabled": true,
"cacheTTL": "2m0s"
},
"anonymous": {
"enabled": false
}
},
"authorization": {
"mode": "Webhook",
"webhook": {
"cacheAuthorizedTTL": "5m0s",
"cacheUnauthorizedTTL": "30s"
}
},
"address": "##NODE_IP##",
"port": 10250,
"readOnlyPort": 0,
"cgroupDriver": "cgroupfs",
"hairpinMode": "promiscuous-bridge",
"serializeImagePulls": false,
"featureGates": {
"RotateKubeletClientCertificate": true,
"RotateKubeletServerCertificate": true
},
"clusterDomain": "${CLUSTER_DNS_DOMAIN}",
"clusterDNS": ["${CLUSTER_DNS_SVC_IP}"]
}
EOF
- address:API 监听地址,不能为 127.0.0.1,否则 kube-apiserver、heapster 等不能调用 kubelet 的 API;
- readOnlyPort=0:关闭只读端口(默认 10255),等效为未指定;
- authentication.anonymous.enabled:设置为 false,不允许匿名�访问 10250 端口;
- authentication.x509.clientCAFile:指定签名客户端证书的 CA 证书,开启 HTTP 证书认证;
- authentication.webhook.enabled=true:开启 HTTPs bearer token 认证;
- 对于未通过 x509 证书和 webhook 认证的请求(kube-apiserver 或其他客户端),将被拒绝,提示 Unauthorized;
- authroization.mode=Webhook:kubelet 使用 SubjectAccessReview API 查询 kube-apiserver 某 user、group 是否具有操作资源的权限(RBAC);
- featureGates.RotateKubeletClientCertificate、featureGates.RotateKubeletServerCertificate:自动 rotate 证书,证书的有效期取决于 kube-controller-manager 的 --experimental-cluster-signing-duration 参数;
- 需要 root 账户运行;
为各节点创建和分发 kubelet 配置文件:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
sed -e "s/##NODE_IP##/${node_ip}/" kubelet.config.json.template > kubelet.config-${node_ip}.json
scp kubelet.config-${node_ip}.json root@${node_ip}:/etc/kubernetes/kubelet.config.json
done
替换后的 kubelet.config.json 文件: kubelet.config.json
创建和分发 kubelet systemd unit 文件
创建 kubelet systemd unit 文件模板:
cat > kubelet.service.template <<EOF
[Unit]
Description=Kubernetes Kubelet
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
After=docker.service
Requires=docker.service
[Service]
WorkingDirectory=/var/lib/kubelet
ExecStart=/opt/k8s/bin/kubelet \\
--bootstrap-kubeconfig=/etc/kubernetes/kubelet-bootstrap.kubeconfig \\
--cert-dir=/etc/kubernetes/cert \\
--kubeconfig=/etc/kubernetes/kubelet.kubeconfig \\
--config=/etc/kubernetes/kubelet.config.json \\
--hostname-override=##NODE_NAME## \\
--pod-infra-container-image=registry.access.redhat.com/rhel7/pod-infrastructure:latest \\
--allow-privileged=true \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on-failure
RestartSec=5
[Install]
WantedBy=multi-user.target
EOF
- 如果设置了
--hostname-override
选项,则kube-proxy
也需要设置该选项,否则会出现找不到 Node 的情况; -
--bootstrap-kubeconfig
:指向 bootstrap kubeconfig 文件,kubelet 使用该文件中的用户名和 token 向 kube-apiserver 发送 TLS Bootstrapping 请求; - K8S approve kubelet 的 csr 请求后,在
--cert-dir
目录创建证书和私钥文件,然后写入--kubeconfig
文件;
替换后的 unit 文件:kubelet.service
为各节点创建和分发 kubelet systemd unit 文件:
source /opt/k8s/bin/environment.sh
for node_name in ${NODE_NAMES[@]}
do
echo ">>> ${node_name}"
sed -e "s/##NODE_NAME##/${node_name}/" kubelet.service.template > kubelet-${node_name}.service
scp kubelet-${node_name}.service root@${node_name}:/etc/systemd/system/kubelet.service
done
Bootstrap Token Auth 和授予权限
kublet 启动时查找配置的 --kubeletconfig 文件是否存在,如果不存在则使用 --bootstrap-kubeconfig 向 kube-apiserver 发送证书签名请求 (CSR)。
kube-apiserver 收到 CSR 请求后,对其中的 Token 进行认证(事先使用 kubeadm 创建的 token),认证通过后将请求的 user 设置为 system:bootstrap:,group 设置为 system:bootstrappers,这一过程称为 Bootstrap Token Auth。
默认情况下,这个 user 和 group 没有创建 CSR 的权限,kubelet 启动失败,错误日志如下:
$ sudo journalctl -u kubelet -a |grep -A 2 'certificatesigningrequests'
May 06 06:42:36 kube-node1 kubelet[26986]: F0506 06:42:36.314378 26986 server.go:233] failed to run Kubelet: cannot create certificate signing request: certificatesigningrequests.certificates.k8s.io is forbidden: User "system:bootstrap:lemy40" cannot create certificatesigningrequests.certificates.k8s.io at the cluster scope
May 06 06:42:36 kube-node1 systemd[1]: kubelet.service: Main process exited, code=exited, status=255/n/a
May 06 06:42:36 kube-node1 systemd[1]: kubelet.service: Failed with result 'exit-code'.
解决办法是:创建一个 clusterrolebinding,将 group system:bootstrappers 和 clusterrole system:node-bootstrapper 绑定:
$ kubectl create clusterrolebinding kubelet-bootstrap --clusterrole=system:node-bootstrapper --group=system:bootstrappers
启动 kubelet 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/lib/kubelet"
ssh root@${node_ip} "/usr/sbin/swapoff -a"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kubelet && systemctl restart kubelet"
done
- 关闭 swap 分区,否则 kubelet 会启动失败;
- 必须先创建工作和日志目录;
$ journalctl -u kubelet |tail
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.388242 22343 feature_gate.go:226] feature gates: &{{} map[RotateKubeletServerCertificate:true RotateKubeletClientCertificate:true]}
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.394342 22343 mount_linux.go:211] Detected OS with systemd
Jun 13 16:05:40 kube-node2 kubelet[22343]: W0613 16:05:40.394494 22343 cni.go:171] Unable to update cni config: No networks found in /etc/cni/net.d
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.399508 22343 server.go:376] Version: v1.10.4
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.399583 22343 feature_gate.go:226] feature gates: &{{} map[RotateKubeletServerCertificate:true RotateKubeletClientCertificate:true]}
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.399736 22343 plugins.go:89] No cloud provider specified.
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.399752 22343 server.go:492] No cloud provider specified: "" from the config file: ""
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.399777 22343 bootstrap.go:58] Using bootstrap kubeconfig to generate TLS client cert, key and kubeconfig file
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.446068 22343 csr.go:105] csr for this node already exists, reusing
Jun 13 16:05:40 kube-node2 kubelet[22343]: I0613 16:05:40.453761 22343 csr.go:113] csr for this node is still valid
kubelet 启动后使用 --bootstrap-kubeconfig 向 kube-apiserver 发送 CSR 请求,当这个 CSR 被 approve 后,kube-controller-manager 为 kubelet 创建 TLS 客户端证书、私钥和 --kubeletconfig 文件。
注意:kube-controller-manager 需要配置 --cluster-signing-cert-file
和 --cluster-signing-key-file
参数,才会为 TLS Bootstrap 创建证书和私钥。
$ kubectl get csr
NAME AGE REQUESTOR CONDITION
node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk 43s system:bootstrap:zkiem5 Pending
node-csr-oVbPmU-ikVknpynwu0Ckz_MvkAO_F1j0hmbcDa__sGA 27s system:bootstrap:mkus5s Pending
node-csr-u0E1-ugxgotO_9FiGXo8DkD6a7-ew8sX2qPE6KPS2IY 13m system:bootstrap:k0s2bj Pending
$ kubectl get nodes
No resources found.
- 三个 work 节点的 csr 均处于 pending 状态;
approve kubelet CSR 请求
可以手动或自动 approve CSR 请求。推荐使用自动的方式,因为从 v1.8 版本开始,可以自动轮转approve csr 后生成的证书。
手动 approve CSR 请求
查看 CSR 列表:
$ kubectl get csr
NAME AGE REQUESTOR CONDITION
node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk 43s system:bootstrap:zkiem5 Pending
node-csr-oVbPmU-ikVknpynwu0Ckz_MvkAO_F1j0hmbcDa__sGA 27s system:bootstrap:mkus5s Pending
node-csr-u0E1-ugxgotO_9FiGXo8DkD6a7-ew8sX2qPE6KPS2IY 13m system:bootstrap:k0s2bj Pending
approve CSR:
$ kubectl certificate approve node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk
certificatesigningrequest.certificates.k8s.io "node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk" approved
查看 Approve 结果:
$ kubectl describe csr node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk
Name: node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk
Labels: <none>
Annotations: <none>
CreationTimestamp: Wed, 13 Jun 2018 16:05:04 +0800
Requesting User: system:bootstrap:zkiem5
Status: Approved
Subject:
Common Name: system:node:kube-node2
Serial Number:
Organization: system:nodes
Events: <none>
-
Requesting User
:请求 CSR 的用户,kube-apiserver 对它进行认证和授权; -
Subject
:请求签名的证书信息; - 证书的 CN 是 system:node:kube-node2, Organization 是 system:nodes,kube-apiserver 的 Node 授权模式会授予该证书的相关权限;
自动 approve CSR 请求
创建三个 ClusterRoleBinding,分别用于自动 approve client、renew client、renew server 证书:
cat > csr-crb.yaml <<EOF
# Approve all CSRs for the group "system:bootstrappers"
kind: ClusterRoleBinding
apiVersion: rbac.authorization.k8s.io/v1
metadata:
name: auto-approve-csrs-for-group
subjects:
- kind: Group
name: system:bootstrappers
apiGroup: rbac.authorization.k8s.io
roleRef:
kind: ClusterRole
name: system:certificates.k8s.io:certificatesigningrequests:nodeclient
apiGroup: rbac.authorization.k8s.io
---
# To let a node of the group "system:nodes" renew its own credentials
kind: ClusterRoleBinding
apiVersion: rbac.authorization.k8s.io/v1
metadata:
name: node-client-cert-renewal
subjects:
- kind: Group
name: system:nodes
apiGroup: rbac.authorization.k8s.io
roleRef:
kind: ClusterRole
name: system:certificates.k8s.io:certificatesigningrequests:selfnodeclient
apiGroup: rbac.authorization.k8s.io
---
# A ClusterRole which instructs the CSR approver to approve a node requesting a
# serving cert matching its client cert.
kind: ClusterRole
apiVersion: rbac.authorization.k8s.io/v1
metadata:
name: approve-node-server-renewal-csr
rules:
- apiGroups: ["certificates.k8s.io"]
resources: ["certificatesigningrequests/selfnodeserver"]
verbs: ["create"]
---
# To let a node of the group "system:nodes" renew its own server credentials
kind: ClusterRoleBinding
apiVersion: rbac.authorization.k8s.io/v1
metadata:
name: node-server-cert-renewal
subjects:
- kind: Group
name: system:nodes
apiGroup: rbac.authorization.k8s.io
roleRef:
kind: ClusterRole
name: approve-node-server-renewal-csr
apiGroup: rbac.authorization.k8s.io
EOF
- auto-approve-csrs-for-group:自动 approve node 的第一次 CSR; 注意第一次 CSR 时,请求的 Group 为 system:bootstrappers;
- node-client-cert-renewal:自动 approve node 后续过期的 client 证书,自动生成的证书 Group 为 system:nodes;
- node-server-cert-renewal:自动 approve node 后续过期的 server 证书,自动生成的证书 Group 为 system:nodes;
生效配置:
$ kubectl apply -f csr-crb.yaml
查看 kublet 的情况
等待一段时间(1-10 分钟),三个节点的 CSR 都被自动 approve:
$ kubectl get csr
NAME AGE REQUESTOR CONDITION
csr-98h25 6m system:node:kube-node2 Approved,Issued
csr-lb5c9 7m system:node:kube-node3 Approved,Issued
csr-m2hn4 14m system:node:kube-node1 Approved,Issued
node-csr-7q7i0q4MF_K2TSEJj16At4CJFLlJkHIqei6nMIAaJCU 28m system:bootstrap:k0s2bj Approved,Issued
node-csr-ND77wk2P8k2lHBtgBaObiyYw0uz1Um7g2pRvveMF-c4 35m system:bootstrap:mkus5s Approved,Issued
node-csr-Nysmrw55nnM48NKwEJuiuCGmZoxouK4N8jiEHBtLQso 6m system:bootstrap:zkiem5 Approved,Issued
node-csr-QzuuQiuUfcSdp3j5W4B2UOuvQ_n9aTNHAlrLzVFiqrk 1h system:bootstrap:zkiem5 Approved,Issued
node-csr-oVbPmU-ikVknpynwu0Ckz_MvkAO_F1j0hmbcDa__sGA 1h system:bootstrap:mkus5s Approved,Issued
node-csr-u0E1-ugxgotO_9FiGXo8DkD6a7-ew8sX2qPE6KPS2IY 1h system:bootstrap:k0s2bj Approved,Issued
所有节点均 ready:
$ kubectl get nodes
NAME STATUS ROLES AGE VERSION
kube-node1 Ready <none> 18m v1.10.4
kube-node2 Ready <none> 10m v1.10.4
kube-node3 Ready <none> 11m v1.10.4
kube-controller-manager 为各 node 生成了 kubeconfig 文件和公私钥:
$ ls -l /etc/kubernetes/kubelet.kubeconfig
-rw------- 1 root root 2293 Jun 13 17:07 /etc/kubernetes/kubelet.kubeconfig
$ ls -l /etc/kubernetes/cert/|grep kubelet
-rw-r--r-- 1 root root 1046 Jun 13 17:07 kubelet-client.crt
-rw------- 1 root root 227 Jun 13 17:07 kubelet-client.key
-rw------- 1 root root 1334 Jun 13 17:07 kubelet-server-2018-06-13-17-07-45.pem
lrwxrwxrwx 1 root root 58 Jun 13 17:07 kubelet-server-current.pem -> /etc/kubernetes/cert/kubelet-server-2018-06-13-17-07-45.pem
- kubelet-server 证书会周期轮转;
kubelet 提供的 API 接口
kublet 启动后监听多个端口,用于接收 kube-apiserver 或其它组件发送的请求:
$ sudo netstat -lnpt|grep kubelet
tcp 0 0 192.168.16.237:4194 0.0.0.0:* LISTEN 2490/kubelet
tcp 0 0 127.0.0.1:10248 0.0.0.0:* LISTEN 2490/kubelet
tcp 0 0 192.168.16.237:10250 0.0.0.0:* LISTEN 2490/kubelet
- 4194: cadvisor http 服务;
- 10248: healthz http 服务;
- 10250: https API 服务;注意:未开启只读端口 10255;
例如执行 kubectl ec -it nginx-ds-5rmws -- sh
命令时,kube-apiserver 会向 kubelet 发送如下请求:
POST /exec/default/nginx-ds-5rmws/my-nginx?command=sh&input=1&output=1&tty=1
kubelet 接收 10250 端口的 https 请求:
- /pods、/runningpods
- /metrics、/metrics/cadvisor、/metrics/probes
- /spec
- /stats、/stats/container
- /logs
- /run/、"/exec/", "/attach/", "/portForward/", "/containerLogs/" 等管理;
详情参考:https://github.com/kubernetes/kubernetes/blob/master/pkg/kubelet/server/server.go#L434:3
由于关闭了匿名认证,同时开启了 webhook 授权,所有访问 10250 端口 https API 的请求都需要被认证和授权。
预定义的 ClusterRole system:kubelet-api-admin 授予访问 kubelet 所有 API 的权限:
$ kubectl describe clusterrole system:kubelet-api-admin
Name: system:kubelet-api-admin
Labels: kubernetes.io/bootstrapping=rbac-defaults
Annotations: rbac.authorization.kubernetes.io/autoupdate=true
PolicyRule:
Resources Non-Resource URLs Resource Names Verbs
--------- ----------------- -------------- -----
nodes [] [] [get list watch proxy]
nodes/log [] [] [*]
nodes/metrics [] [] [*]
nodes/proxy [] [] [*]
nodes/spec [] [] [*]
nodes/stats [] [] [*]
kublet api 认证和授权
kublet 配置了如下认证参数:
- authentication.anonymous.enabled:设置为 false,不允许匿名�访问 10250 端口;
- authentication.x509.clientCAFile:指定签名客户端证书的 CA 证书,开启 HTTPs 证书认证;
- authentication.webhook.enabled=true:开启 HTTPs bearer token 认证;
同时配置了如下授权参数:
- authroization.mode=Webhook:开启 RBAC 授权;
kubelet 收到请求后,使用 clientCAFile 对证书签名进行认证,或者查询 bearer token 是否有效。如果两者都没通过,则拒绝请求,提示 Unauthorized:
$ curl -s --cacert /etc/kubernetes/cert/ca.pem https://192.168.16.237:10250/metrics
Unauthorized
$ curl -s --cacert /etc/kubernetes/cert/ca.pem -H "Authorization: Bearer 123456" https://192.168.16.237:10250/metrics
Unauthorized
通过认证后,kubelet 使用 SubjectAccessReview API 向 kube-apiserver 发送请求,查询证书或 token 对应的 user、group 是否有操作资源的权限(RBAC);
证书认证和授权:
$ # 权限不足的证书;
$ curl -s --cacert /etc/kubernetes/cert/ca.pem --cert /etc/kubernetes/cert/kube-controller-manager.pem --key /etc/kubernetes/cert/kube-controller-manager-key.pem https://192.168.16.237:10250/metrics
Forbidden (user=system:kube-controller-manager, verb=get, resource=nodes, subresource=metrics)
$ # 使用部署 kubectl 命令行工具时创建的、具有最高权限的 admin 证书;
$ curl -s --cacert /etc/kubernetes/cert/ca.pem --cert ./admin.pem --key ./admin-key.pem https://192.168.16.237:10250/metrics|head
# HELP apiserver_client_certificate_expiration_seconds Distribution of the remaining lifetime on the certificate used to authenticate a request.
# TYPE apiserver_client_certificate_expiration_seconds histogram
apiserver_client_certificate_expiration_seconds_bucket{le="0"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="21600"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="43200"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="86400"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="172800"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="345600"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="604800"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="2.592e+06"} 0
-
--cacert
、--cert
、--key
的参数值必须是文件路径,如上面的./admin.pem
不能省略./
,否则返回401 Unauthorized
;
bear token 认证和授权:
创建一个 ServiceAccount,将它和 ClusterRole system:kubelet-api-admin 绑定,从而具有调用 kubelet API 的权限:
kubectl create sa kubelet-api-test
kubectl create clusterrolebinding kubelet-api-test --clusterrole=system:kubelet-api-admin --serviceaccount=default:kubelet-api-test
SECRET=$(kubectl get secrets | grep kubelet-api-test | awk '{print $1}')
TOKEN=$(kubectl describe secret ${SECRET} | grep -E '^token' | awk '{print $2}')
echo ${TOKEN}
$ curl -s --cacert /etc/kubernetes/cert/ca.pem -H "Authorization: Bearer ${TOKEN}" https://192.168.16.237:10250/metrics|head
# HELP apiserver_client_certificate_expiration_seconds Distribution of the remaining lifetime on the certificate used to authenticate a request.
# TYPE apiserver_client_certificate_expiration_seconds histogram
apiserver_client_certificate_expiration_seconds_bucket{le="0"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="21600"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="43200"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="86400"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="172800"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="345600"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="604800"} 0
apiserver_client_certificate_expiration_seconds_bucket{le="2.592e+06"} 0
cadvisor 和 metrics
cadvisor 统计�所在节点各容器的资源(CPU、内存、磁盘、网卡)使用情况,分别在自己的 http web 页面(4194 端口)和 10250 以 promehteus metrics 的形式输出。
浏览器访问 http://192.168.16.237:4194/containers/ 可以查看到 cadvisor 的监控页面:
下面这段直接cp原文,没看懂也没有做出来,我直接忽略了
浏览器访问 https://172.27.129.80:10250/metrics 和 https://172.27.129.80:10250/metrics/cadvisor 分别返回 kublet 和 cadvisor 的 metrics。
注意:
- kublet.config.json 设置 authentication.anonymous.enabled 为 false,不允许匿名证书访问 10250 的 https 服务;
- 参考A.浏览器访问kube-apiserver安全端口.md,创建和导入相关证书,然后访问上面的 10250 端口;
获取 kublet 的配置
从 kube-apiserver 获取各 node 的配置:
$ source /opt/k8s/bin/environment.sh
$ # 使用部署 kubectl 命令行工具时创建的、具有最高权限的 admin 证书;
$ curl -sSL --cacert /etc/kubernetes/cert/ca.pem --cert ./admin.pem --key ./admin-key.pem ${KUBE_APISERVER}/api/v1/nodes/kube-node1/proxy/configz | jq \
'.kubeletconfig|.kind="KubeletConfiguration"|.apiVersion="kubelet.config.k8s.io/v1beta1"'
{
"syncFrequency": "1m0s",
"fileCheckFrequency": "20s",
"httpCheckFrequency": "20s",
"address": "172.27.129.80",
"port": 10250,
"readOnlyPort": 10255,
"authentication": {
"x509": {},
"webhook": {
"enabled": false,
"cacheTTL": "2m0s"
},
"anonymous": {
"enabled": true
}
},
"authorization": {
"mode": "AlwaysAllow",
"webhook": {
"cacheAuthorizedTTL": "5m0s",
"cacheUnauthorizedTTL": "30s"
}
},
"registryPullQPS": 5,
"registryBurst": 10,
"eventRecordQPS": 5,
"eventBurst": 10,
"enableDebuggingHandlers": true,
"healthzPort": 10248,
"healthzBindAddress": "127.0.0.1",
"oomScoreAdj": -999,
"clusterDomain": "cluster.local.",
"clusterDNS": [
"10.254.0.2"
],
"streamingConnectionIdleTimeout": "4h0m0s",
"nodeStatusUpdateFrequency": "10s",
"imageMinimumGCAge": "2m0s",
"imageGCHighThresholdPercent": 85,
"imageGCLowThresholdPercent": 80,
"volumeStatsAggPeriod": "1m0s",
"cgroupsPerQOS": true,
"cgroupDriver": "cgroupfs",
"cpuManagerPolicy": "none",
"cpuManagerReconcilePeriod": "10s",
"runtimeRequestTimeout": "2m0s",
"hairpinMode": "promiscuous-bridge",
"maxPods": 110,
"podPidsLimit": -1,
"resolvConf": "/etc/resolv.conf",
"cpuCFSQuota": true,
"maxOpenFiles": 1000000,
"contentType": "application/vnd.kubernetes.protobuf",
"kubeAPIQPS": 5,
"kubeAPIBurst": 10,
"serializeImagePulls": false,
"evictionHard": {
"imagefs.available": "15%",
"memory.available": "100Mi",
"nodefs.available": "10%",
"nodefs.inodesFree": "5%"
},
"evictionPressureTransitionPeriod": "5m0s",
"enableControllerAttachDetach": true,
"makeIPTablesUtilChains": true,
"iptablesMasqueradeBit": 14,
"iptablesDropBit": 15,
"featureGates": {
"RotateKubeletClientCertificate": true,
"RotateKubeletServerCertificate": true
},
"failSwapOn": true,
"containerLogMaxSize": "10Mi",
"containerLogMaxFiles": 5,
"enforceNodeAllocatable": [
"pods"
],
"kind": "KubeletConfiguration",
"apiVersion": "kubelet.config.k8s.io/v1beta1"
}
15.部署 kube-proxy 组件
kube-proxy 运行在所有 worker 节点上,,它监听 apiserver 中 service 和 Endpoint 的变化情况,创建路由规则来进行服务负载均衡。
本文档讲解部署 kube-proxy 的部署,使用 ipvs 模式。
下载和分发 kube-proxy 二进制文件
安装依赖包
各节点需要安装 ipvsadm
和 ipset
命令,加载 ip_vs
内核模块。
创建 kube-proxy 证书
创建证书签名请求:
cat > kube-proxy-csr.json <<EOF
{
"CN": "system:kube-proxy",
"key": {
"algo": "rsa",
"size": 2048
},
"names": [
{
"C": "CN",
"ST": "BeiJing",
"L": "BeiJing",
"O": "k8s",
"OU": "4Paradigm"
}
]
}
EOF
- CN:指定该证书的 User 为
system:kube-proxy
; - 预定义的 RoleBinding
system:node-proxier
将Usersystem:kube-proxy
与 Rolesystem:node-proxier
绑定,该 Role 授予了调用kube-apiserver
Proxy 相关 API 的权限; - 该证书只会被 kube-proxy 当做 client 证书使用,所以 hosts 字段为空;
生成证书和私钥:
cfssl gencert -ca=/etc/kubernetes/cert/ca.pem \
-ca-key=/etc/kubernetes/cert/ca-key.pem \
-config=/etc/kubernetes/cert/ca-config.json \
-profile=kubernetes kube-proxy-csr.json | cfssljson -bare kube-proxy
创建和分发 kubeconfig 文件
source /opt/k8s/bin/environment.sh
kubectl config set-cluster kubernetes \
--certificate-authority=/etc/kubernetes/cert/ca.pem \
--embed-certs=true \
--server=${KUBE_APISERVER} \
--kubeconfig=kube-proxy.kubeconfig
kubectl config set-credentials kube-proxy \
--client-certificate=kube-proxy.pem \
--client-key=kube-proxy-key.pem \
--embed-certs=true \
--kubeconfig=kube-proxy.kubeconfig
kubectl config set-context default \
--cluster=kubernetes \
--user=kube-proxy \
--kubeconfig=kube-proxy.kubeconfig
kubectl config use-context default --kubeconfig=kube-proxy.kubeconfig
-
--embed-certs=true
:将 ca.pem 和 admin.pem 证书内容嵌入到生成的 kubectl-proxy.kubeconfig 文件中(不加时,写入的是证书文件路径);
分发 kubeconfig 文件:
source /opt/k8s/bin/environment.sh
for node_name in ${NODE_NAMES[@]}
do
echo ">>> ${node_name}"
scp kube-proxy.kubeconfig k8s@${node_name}:/etc/kubernetes/
done
创建 kube-proxy 配置文件
从 v1.10 开始,kube-proxy 部分参数可以配置文件中配置。可以使用 --write-config-to
选项生成该配置文件,或者参考 kubeproxyconfig 的类型定义源文件 :https://github.com/kubernetes/kubernetes/blob/master/pkg/proxy/apis/kubeproxyconfig/types.go
创建 kube-proxy config 文件模板:
cat >kube-proxy.config.yaml.template <<EOF
apiVersion: kubeproxy.config.k8s.io/v1alpha1
bindAddress: ##NODE_IP##
clientConnection:
kubeconfig: /etc/kubernetes/kube-proxy.kubeconfig
clusterCIDR: ${CLUSTER_CIDR}
healthzBindAddress: ##NODE_IP##:10256
hostnameOverride: ##NODE_NAME##
kind: KubeProxyConfiguration
metricsBindAddress: ##NODE_IP##:10249
mode: "ipvs"
EOF
-
bindAddress
: 监听地址; -
clientConnection.kubeconfig
: 连接 apiserver 的 kubeconfig 文件; -
clusterCIDR
: kube-proxy 根据--cluster-cidr
判断集群内部和外部流量,指定--cluster-cidr
或--masquerade-all
选项后 kube-proxy 才会对访问 Service IP 的请求做 SNAT; -
hostnameOverride
: 参数值必须与 kubelet 的值一致,否则 kube-proxy 启动后会找不到该 Node,从而不会创建任何 ipvs 规则; -
mode
: 使用 ipvs 模式;
为各节点创建和分发 kube-proxy 配置文件:
source /opt/k8s/bin/environment.sh
for (( i=0; i < 3; i++ ))
do
echo ">>> ${NODE_NAMES[i]}"
sed -e "s/##NODE_NAME##/${NODE_NAMES[i]}/" -e "s/##NODE_IP##/${NODE_IPS[i]}/" kube-proxy.config.yaml.template > kube-proxy-${NODE_NAMES[i]}.config.yaml
scp kube-proxy-${NODE_NAMES[i]}.config.yaml root@${NODE_NAMES[i]}:/etc/kubernetes/kube-proxy.config.yaml
done
替换后的 kube-proxy.config.yaml 文件:kube-proxy.config.yaml
创建和分发 kube-proxy systemd unit 文件
source /opt/k8s/bin/environment.sh
cat > kube-proxy.service <<EOF
[Unit]
Description=Kubernetes Kube-Proxy Server
Documentation=https://github.com/GoogleCloudPlatform/kubernetes
After=network.target
[Service]
WorkingDirectory=/var/lib/kube-proxy
ExecStart=/opt/k8s/bin/kube-proxy \\
--config=/etc/kubernetes/kube-proxy.config.yaml \\
--alsologtostderr=true \\
--logtostderr=false \\
--log-dir=/var/log/kubernetes \\
--v=2
Restart=on-failure
RestartSec=5
LimitNOFILE=65536
[Install]
WantedBy=multi-user.target
EOF
替换后的 unit 文件:kube-proxy.service
分发 kube-proxy systemd unit 文件:
source /opt/k8s/bin/environment.sh
for node_name in ${NODE_NAMES[@]}
do
echo ">>> ${node_name}"
scp kube-proxy.service root@${node_name}:/etc/systemd/system/
done
启动 kube-proxy 服务
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "mkdir -p /var/lib/kube-proxy"
ssh root@${node_ip} "mkdir -p /var/log/kubernetes && chown -R k8s /var/log/kubernetes"
ssh root@${node_ip} "systemctl daemon-reload && systemctl enable kube-proxy && systemctl restart kube-proxy"
done
- 必须先创建工作和日志目录;
检查启动结果
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh k8s@${node_ip} "systemctl status kube-proxy|grep Active"
done
确保状态为 active (running)
,否则查看日志,确认原因:
journalctl -u kube-proxy
查看监听端口和 metrics
[k8s@kube-node1 ~]$ sudo netstat -lnpt|grep kube-prox
tcp 0 0 192.168.16.237:10249 0.0.0.0:* LISTEN 16847/kube-proxy
tcp 0 0 192.168.16.237:10256 0.0.0.0:* LISTEN 16847/kube-proxy
- 10249:http prometheus metrics port;
- 10256:http healthz port;
查看 ipvs 路由规则
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh root@${node_ip} "/usr/sbin/ipvsadm -ln"
done
预期输出:
>>> 192.168.16.237
IP Virtual Server version 1.2.1 (size=4096)
Prot LocalAddress:Port Scheduler Flags
-> RemoteAddress:Port Forward Weight ActiveConn InActConn
TCP 10.254.0.1:443 rr persistent 10800
-> 192.168.16.237:6443 Masq 1 0 0
>>>192.168.16.238
IP Virtual Server version 1.2.1 (size=4096)
Prot LocalAddress:Port Scheduler Flags
-> RemoteAddress:Port Forward Weight ActiveConn InActConn
TCP 10.254.0.1:443 rr persistent 10800
-> 192.168.16.237:6443 Masq 1 0 0
>>>192.168.16.239
IP Virtual Server version 1.2.1 (size=4096)
Prot LocalAddress:Port Scheduler Flags
-> RemoteAddress:Port Forward Weight ActiveConn InActConn
TCP 10.254.0.1:443 rr persistent 10800
-> 192.168.16.237:6443 Masq 1 0 0
可见将所有到 kubernetes cluster ip 443 端口的请求都转发到 kube-apiserver 的 6443 端口;
16. 验证集群功能
本文档使用 daemonset 验证 master 和 worker 节点是否工作正常。
检查节点状态
$ kubectl get nodes
NAME STATUS ROLES AGE VERSION
kube-node1 Ready <none> 3h v1.10.4
kube-node2 Ready <none> 3h v1.10.4
kube-node3 Ready <none> 3h v1.10.4
都为 Ready 时正常。
创建测试文件
$ cat > nginx-ds.yml <<EOF
apiVersion: v1
kind: Service
metadata:
name: nginx-ds
labels:
app: nginx-ds
spec:
type: NodePort
selector:
app: nginx-ds
ports:
- name: http
port: 80
targetPort: 80
---
apiVersion: extensions/v1beta1
kind: DaemonSet
metadata:
name: nginx-ds
labels:
addonmanager.kubernetes.io/mode: Reconcile
spec:
template:
metadata:
labels:
app: nginx-ds
spec:
containers:
- name: my-nginx
image: nginx:1.7.9
ports:
- containerPort: 80
EOF
执行定义文件
$ kubectl create -f nginx-ds.yml
service "nginx-ds" created
daemonset.extensions "nginx-ds" created
检查各 Node 上的 Pod IP 连通性
$ kubectl get pods -o wide|grep nginx-ds
nginx-ds-dbn97 1/1 Running 0 2m 172.30.29.2 kube-node2
nginx-ds-rk777 1/1 Running 0 2m 172.30.81.2 kube-node1
nginx-ds-tr9g5 1/1 Running 0 2m 172.30.39.2 kube-node3
可见,nginx-ds 的 Pod IP 分别是 172.30.39.2
、172.30.81.2
、172.30.29.2
,在所有 Node 上分别 ping 这三个 IP,看是否连通:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "ping -c 1 172.30.39.2"
ssh ${node_ip} "ping -c 1 172.30.81.2"
ssh ${node_ip} "ping -c 1 172.30.29.2"
done
检查服务 IP 和端口可达性
$ kubectl get svc |grep nginx-ds
nginx-ds NodePort 10.254.254.228 <none> 80:8900/TCP 4m
可见:
- Service Cluster IP:10.254.254.228
- 服务端口:80
- NodePort 端口:8900
在所有 Node 上 curl Service IP:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "curl 10.254.254.228"
done
预期输出 nginx 欢迎页面内容。
检查服务的 NodePort 可达性
在所有 Node 上执行:
source /opt/k8s/bin/environment.sh
for node_ip in ${NODE_IPS[@]}
do
echo ">>> ${node_ip}"
ssh ${node_ip} "curl ${node_ip}:8900"
done
预期输出 nginx 欢迎页面内容。
17. kubectl 常用命令及排查
查看集群信息
kubectl cluster-info
查看所有命名空间的pods
kubectl get pods --all-namespaces
显示Pod的更多信息
kubectl get pods --all-namespaces -o wide
查看rc和service列表
kubectl get rc,service
查看所有命名空间的servers
kubectl get svc --all-namespaces
查看pod日志
kubectl logs -f kubernetes-dashboard-86497fb476-brbz8 -n kube-system
显示Node的详细信息
kubectl describe nodes <node-name>
显示Pod的详细信息
kubectl describe pods/<pod-name>
显示由RC管理的Pod的信息
kubectl describe pods <rc-name>
创建服务
kubectl create -f nginx.yaml
删除服务
kubectl delete -f nginx.yaml
执行容器的命令
执行Pod的data命令,默认是用Pod中的第一个容器执行
kubectl exec <pod-name> data
指定Pod中某个容器执行data命令
kubectl exec <pod-name> -c <container-name> data
通过bash获得Pod中某个容器的TTY,相当于登录容器
kubectl exec -it <pod-name> -c <container-name> bash
待更新