在CentOS上部署kubernetes1.9.0集羣
原文連接:
https://jimmysong.io/kubernetes-handbook/cloud-native/play-with-kubernetes.html (在CentOS上部署kubernetes集羣)html
架構介紹(前期準備)
文檔說明
本系列文檔介紹使用二進制部署 kubernetes 集羣的全部步驟,而不是使用 kubeadm 等自動化方式來部署集羣,同時開啓了集羣的TLS安全認證,該安裝步驟適用於全部bare metal環境、on-premise環境和公有云環境。 若是您想快速的在本身電腦的本地環境下使用虛擬機來搭建kubernetes集羣,能夠參考本地分佈式開發環境搭建(使用Vagrant和Virtualbox、http://192.168.66.102/k8s/k8s-doc/blob/master/develop/using-vagrant-and-virtualbox-for-development.md)。 在部署的過程當中,將詳細列出各組件的啓動參數,給出配置文件,詳解它們的含義和可能遇到的問題。 部署完成後,你將理解系統各組件的交互原理,進而能快速解決實際問題。 因此本文檔主要適合於那些有必定 kubernetes 基礎,想經過一步步部署的方式來學習和了解系統配置、運行原理的人。 注:本文檔中不包括docker和私有鏡像倉庫的安裝,安裝說明中使用的鏡像來自 Google Cloud Platform,爲了方便國內用戶下載,我將其克隆並上傳到了 時速雲鏡像市場,供你們免費下載。 欲下載最新版本的官方鏡像請訪問 Google 雲平臺容器註冊表。
集羣詳情
•OS:CentOS Linux release 7.3.1611 (Core) 3.10.0-514.16.1.el7.x86_64 •Kubernetes 1.9.0+(最低的版本要求是1.6) •Docker 1.12.5(使用yum安裝) •Etcd 3.1.5 •Flannel 0.7.1 vxlan或者host-gw 網絡 •TLS 認證通訊 (全部組件,如 etcd、kubernetes master 和 node) •RBAC 受權 •kubelet TLS BootStrapping •kubedns、dashboard、heapster(influxdb、grafana)、EFK(elasticsearch、fluentd、kibana) 集羣插件 •私有docker鏡像倉庫harbor(請自行部署,harbor提供離線安裝包,直接使用docker-compose啓動便可)
環境說明
在下面的步驟中,咱們將在三臺CentOS系統的物理機上部署具備三個節點的kubernetes1.9.0集羣。 角色分配以下: 鏡像倉庫: 192.168.55.33 (harbor: https://www.cnblogs.com/jicki/p/5737369.html) Master:192.168.55.36 Node:192.168.55.36、192.168.55.37、192.168.55.38 注意:192.168.55.36這臺主機master和node複用。全部生成證書、執行kubectl命令的操做都在這臺節點上執行。一旦node加入到kubernetes集羣以後就不須要再登錄node節點了。
步驟介紹
1.建立 TLS 證書和祕鑰 2.建立kubeconfig 文件 3.建立高可用etcd集羣 4.安裝kubectl命令行工具 5.部署master節點 6.安裝flannel網絡插件 7.部署node節點 8.安裝kubedns插件 9.安裝dashboard插件 10.安裝heapster插件 11.安裝EFK插件
1.建立 TLS 證書和祕鑰
生成的 CA 證書和祕鑰文件以下:
•ca-key.pem
•ca.pem
•kubernetes-key.pem
•kubernetes.pem
•kube-proxy.pem
•kube-proxy-key.pem
•admin.pem
•admin-key.pemnode
使用證書的組件以下:
•etcd:使用 ca.pem、kubernetes-key.pem、kubernetes.pem;
•kube-apiserver:使用 ca.pem、kubernetes-key.pem、kubernetes.pem;
•kubelet:使用 ca.pem;
•kube-proxy:使用 ca.pem、kube-proxy-key.pem、kube-proxy.pem;
•kubectl:使用 ca.pem、admin-key.pem、admin.pem;
•kube-controller-manager:使用 ca-key.pem、ca.pemlinux
注意:如下操做都在 master 節點即 192.168.55.36 這臺主機上執行,證書只須要建立一次便可,之後在向集羣中添加新節點時只要將 /etc/kubernetes/ 目錄下的證書拷貝到新節點上便可。nginx
1.1安裝 CFSSL
方式一:直接使用二進制源碼包安裝 wget https://pkg.cfssl.org/R1.2/cfssl_linux-amd64 chmod +x cfssl_linux-amd64 mv cfssl_linux-amd64 /usr/local/bin/cfssl wget https://pkg.cfssl.org/R1.2/cfssljson_linux-amd64 chmod +x cfssljson_linux-amd64 mv cfssljson_linux-amd64 /usr/local/bin/cfssljson wget https://pkg.cfssl.org/R1.2/cfssl-certinfo_linux-amd64 chmod +x cfssl-certinfo_linux-amd64 mv cfssl-certinfo_linux-amd64 /usr/local/bin/cfssl-certinfo export PATH=/usr/local/bin:$PATH 方式二:使用go命令安裝 咱們的系統中安裝了Go1.7.5,使用如下命令安裝更快捷: $ go get -u github.com/cloudflare/cfssl/cmd/... $ echo $GOPATH /usr/local $ls /usr/local/bin/cfssl* cfssl cfssl-bundle cfssl-certinfo cfssljson cfssl-newkey cfssl-scan
1.2建立 CA (Certificate Authority)
1.2.1建立 CA 配置文件 ----------------------------------------------------------------------- mkdir /root/ssl cd /root/ssl cfssl print-defaults config > config.json cfssl print-defaults csr > csr.json # 根據config.json文件的格式建立以下的ca-config.json文件 # 過時時間設置成了 87600h cat > ca-config.json <<EOF { "signing": { "default": { "expiry": "87600h" }, "profiles": { "kubernetes": { "usages": [ "signing", "key encipherment", "server auth", "client auth" ], "expiry": "87600h" } } } } EOF ------------------------------------------------------------------------- 字段說明 • ca-config.json:能夠定義多個 profiles,分別指定不一樣的過時時間、使用場景等參數;後續在簽名證書時使用某個 profile; • signing:表示該證書可用於簽名其它證書;生成的 ca.pem 證書中 CA=TRUE; • server auth:表示client能夠用該 CA 對server提供的證書進行驗證; • client auth:表示server能夠用該CA對client提供的證書進行驗證; 1.2.2建立 CA 證書籤名請求 建立 ca-csr.json 文件,內容以下: ------------------------------------------------------------------------- cat > ca-csr.json <<EOF { "CN": "kubernetes", "key": { "algo": "rsa", "size": 2048 }, "names": [ { "C": "CN", "ST": "BeiJing", "L": "BeiJing", "O": "k8s", "OU": "System" } ], "ca": { "expiry": "87600h" } } EOF ------------------------------------------------------------------------- 字段說明 •"CN":Common Name,kube-apiserver 從證書中提取該字段做爲請求的用戶名 (User Name);瀏覽器使用該字段驗證網站是否合法; •"O":Organization,kube-apiserver 從證書中提取該字段做爲請求用戶所屬的組 (Group); 1.2.3生成 CA 證書和私鑰 ------------------------------------------------------------------------- $ cfssl gencert -initca ca-csr.json | cfssljson -bare ca $ ls ca* ca-config.json ca.csr ca-csr.json ca-key.pem ca.pem -------------------------------------------------------------------------
1.3建立 kubernetes 證書
1.3.1建立 kubernetes 證書籤名請求文件 kubernetes-csr.json: ------------------------------------------------------------------------- cd /root/ssl/ cat > kubernetes-csr.json <<EOF { "CN": "kubernetes", "hosts": [ "127.0.0.1", "192.168.55.33", "192.168.55.36", "192.168.55.37", "192.168.55.38", "172.16.0.1", "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": "System" } ] } EOF ------------------------------------------------------------------------- 字段說明 •若是 hosts 字段不爲空則須要指定受權使用該證書的 IP 或域名列表,因爲該證書後續被 etcd 集羣和 kubernetes master 集羣使用,因此上面分別指定了 etcd 集羣、kubernetes master 集羣的主機 IP 和 kubernetes 服務的服務 IP(通常是 kube-apiserver 指定的 service-cluster-ip-range 網段的第一個IP,如 10.254.0.1)。 •這是最小化安裝的kubernetes集羣,包括一個私有鏡像倉庫,三個節點的kubernetes集羣,以上物理節點的IP也能夠更換爲主機名。 注意: hosts字段爲空後繼會出問題,必定把hosts字段配置上。 1.3.2生成 kubernetes 證書和私鑰 ------------------------------------------------------------------------- 方式一: $ cfssl gencert -ca=ca.pem -ca-key=ca-key.pem -config=ca-config.json -profile=kubernetes kubernetes-csr.json | cfssljson -bare kubernetes $ ls kubernetes* kubernetes.csr kubernetes-csr.json kubernetes-key.pem kubernetes.pem 方式二: 或者直接在命令行上指定相關參數: echo '{"CN":"kubernetes","hosts":[""],"key":{"algo":"rsa","size":2048}}' | cfssl gencert -ca=ca.pem -ca-key=ca-key.pem -config=ca-config.json -profile=kubernetes -hostname="127.0.0.1,172.20.0.112,172.20.0.113,172.20.0.114,172.20.0.115,kubernetes,kubernetes.default" - | cfssljson -bare kubernetes -------------------------------------------------------------------------
1.4建立 admin 證書
1.4.1建立 admin 證書籤名請求文件 admin-csr.json: ------------------------------------------------------------------------- cd /root/ssl/ cat > admin-csr.json <<EOF { "CN": "admin", "hosts": [], "key": { "algo": "rsa", "size": 2048 }, "names": [ { "C": "CN", "ST": "BeiJing", "L": "BeiJing", "O": "system:masters", "OU": "System" } ] } EOF ------------------------------------------------------------------------- 字段說明 •後續 kube-apiserver 使用 RBAC 對客戶端(如 kubelet、kube-proxy、Pod)請求進行受權; • kube-apiserver 預約義了一些 RBAC 使用的 RoleBindings,如 cluster-admin 將 Group system:masters 與 Role cluster-admin 綁定,該 Role 授予了調用kube-apiserver 的全部 API的權限; •O 指定該證書的 Group 爲 system:masters,kubelet 使用該證書訪問 kube-apiserver 時 ,因爲證書被 CA 簽名,因此認證經過,同時因爲證書用戶組爲通過預受權的 system:masters,因此被授予訪問全部 API 的權限; 1.4.2注意: 這個admin 證書,是未來生成管理員用的kube config 配置文件用的,如今咱們通常建議使用RBAC 來對kubernetes 進行角色權限控制, kubernetes 將證書中的CN 字段 做爲User, O 字段做爲 Group(具體參考 Kubernetes中的用戶與身份認證受權中 X509 Client Certs 一段)。 在搭建完 kubernetes 集羣后,咱們能夠經過命令: kubectl get clusterrolebinding cluster-admin -o yaml ,查看到 clusterrolebinding cluster-admin 的 subjects 的 kind 是 Group,name 是 system:masters。 roleRef 對象是 ClusterRole cluster-admin。 意思是凡是 system:masters Group 的 user 或者 serviceAccount 都擁有 cluster-admin 的角色。 所以咱們在使用 kubectl 命令時候,才擁有整個集羣的管理權限。可使用 kubectl get clusterrolebinding cluster-admin -o yaml 來查看。 ------------------------------------------------------------------------- $ kubectl get clusterrolebinding cluster-admin -o yaml apiVersion: rbac.authorization.k8s.io/v1 kind: ClusterRoleBinding metadata: annotations: rbac.authorization.kubernetes.io/autoupdate: "true" creationTimestamp: 2017-04-11T11:20:42Z labels: kubernetes.io/bootstrapping: rbac-defaults name: cluster-admin resourceVersion: "52" selfLink: /apis/rbac.authorization.k8s.io/v1/clusterrolebindings/cluster-admin uid: e61b97b2-1ea8-11e7-8cd7-f4e9d49f8ed0 roleRef: apiGroup: rbac.authorization.k8s.io kind: ClusterRole name: cluster-admin subjects: - apiGroup: rbac.authorization.k8s.io kind: Group name: system:masters ------------------------------------------------------------------------- 1.4.3生成 admin 證書和私鑰: ------------------------------------------------------------------------- $ cfssl gencert -ca=ca.pem -ca-key=ca-key.pem -config=ca-config.json -profile=kubernetes admin-csr.json | cfssljson -bare admin $ ls admin* admin.csr admin-csr.json admin-key.pem admin.pem -------------------------------------------------------------------------
1.5建立 kube-proxy 證書
1.5.1建立 kube-proxy 證書籤名請求文件 kube-proxy-csr.json: ------------------------------------------------------------------------- cd /root/ssl/ cat > kube-proxy-csr.json <<EOF { "CN": "system:kube-proxy", "hosts": [], "key": { "algo": "rsa", "size": 2048 }, "names": [ { "C": "CN", "ST": "BeiJing", "L": "BeiJing", "O": "k8s", "OU": "System" } ] } EOF ------------------------------------------------------------------------- 字段說明: •CN 指定該證書的 User 爲 system:kube-proxy; • kube-apiserver 預約義的 RoleBinding cluster-admin 將User system:kube-proxy 與 Role system:node-proxier 綁定,該 Role 授予了調用 kube-apiserver Proxy 相關 API 的權限; 1.5.2生成 kube-proxy 客戶端證書和私鑰 ------------------------------------------------------------------------- $ cfssl gencert -ca=ca.pem -ca-key=ca-key.pem -config=ca-config.json -profile=kubernetes kube-proxy-csr.json | cfssljson -bare kube-proxy $ ls kube-proxy* kube-proxy.csr kube-proxy-csr.json kube-proxy-key.pem kube-proxy.pem -------------------------------------------------------------------------
1.6校驗證書
使用 opsnssl 命令 $ openssl x509 -noout -text -in kubernetes.pem ... Signature Algorithm: sha256WithRSAEncryption Issuer: C=CN, ST=BeiJing, L=BeiJing, O=k8s, OU=System, CN=Kubernetes Validity Not Before: Apr 5 05:36:00 2017 GMT Not After : Apr 5 05:36:00 2018 GMT Subject: C=CN, ST=BeiJing, L=BeiJing, O=k8s, OU=System, CN=kubernetes ... X509v3 extensions: X509v3 Key Usage: critical Digital Signature, Key Encipherment X509v3 Extended Key Usage: TLS Web Server Authentication, TLS Web Client Authentication X509v3 Basic Constraints: critical CA:FALSE X509v3 Subject Key Identifier: DD:52:04:43:10:13:A9:29:24:17:3A:0E:D7:14:DB:36:F8:6C:E0:E0 X509v3 Authority Key Identifier: keyid:44:04:3B:60:BD:69:78:14:68:AF:A0:41:13:F6:17:07:13:63:58:CD X509v3 Subject Alternative Name: DNS:kubernetes, DNS:kubernetes.default, DNS:kubernetes.default.svc, DNS:kubernetes.default.svc.cluster, DNS:kubernetes.default.svc.cluster.local, IP Address:127.0.0.1, IP Address:172.20.0.112, IP Address:172.20.0.113, IP Address:172.20.0.114, IP Address:172.20.0.115, IP Address:10.254.0.1 ... •確認 Issuer 字段的內容和 ca-csr.json 一致; •確認 Subject 字段的內容和 kubernetes-csr.json 一致; •確認 X509v3 Subject Alternative Name 字段的內容和 kubernetes-csr.json 一致; •確認 X509v3 Key Usage、Extended Key Usage 字段的內容和 ca-config.json 中 kubernetes profile 一致; 使用 cfssl-certinfo 命令 $ cfssl-certinfo -cert kubernetes.pem ... { "subject": { "common_name": "kubernetes", "country": "CN", "organization": "k8s", "organizational_unit": "System", "locality": "BeiJing", "province": "BeiJing", "names": [ "CN", "BeiJing", "BeiJing", "k8s", "System", "kubernetes" ] }, "issuer": { "common_name": "Kubernetes", "country": "CN", "organization": "k8s", "organizational_unit": "System", "locality": "BeiJing", "province": "BeiJing", "names": [ "CN", "BeiJing", "BeiJing", "k8s", "System", "Kubernetes" ] }, "serial_number": "174360492872423263473151971632292895707129022309", "sans": [ "kubernetes", "kubernetes.default", "kubernetes.default.svc", "kubernetes.default.svc.cluster", "kubernetes.default.svc.cluster.local", "127.0.0.1", "10.64.3.7", "10.254.0.1" ], "not_before": "2017-04-05T05:36:00Z", "not_after": "2018-04-05T05:36:00Z", "sigalg": "SHA256WithRSA", ...
1.7分發證書
將生成的證書和祕鑰文件(後綴名爲.pem)拷貝到全部機器的 /etc/kubernetes/ssl 目錄下備用; ------------------------------------------------------------------------- mkdir -p /etc/kubernetes/ssl cp *.pem /etc/kubernetes/ssl -------------------------------------------------------------------------
2.建立kubeconfig文件
master節點上執行如下操做git
2.1安裝kubectl命令行工具
mkdir -p /opt/k8s/bin wget https://dl.k8s.io/v1.9.0/kubernetes-server-linux-amd64.tar.gz tar -xzvf kubernetes-server-linux-amd64.tar.gz cd kubernetes cp -r server/bin/{kube-apiserver,kube-controller-manager,kube-scheduler,kubectl,kube-proxy,kubelet} /opt/k8s/bin/
2.2建立 kubectl kubeconfig 文件
------------------------------------------------------------ export KUBE_APISERVER="https://192.168.55.36:6443" # 設置集羣參數 kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/ssl/ca.pem \ --embed-certs=true \ --server=${KUBE_APISERVER} # 設置客戶端認證參數 kubectl config set-credentials admin \ --client-certificate=/etc/kubernetes/ssl/admin.pem \ --embed-certs=true \ --client-key=/etc/kubernetes/ssl/admin-key.pem # 設置上下文參數 kubectl config set-context kubernetes \ --cluster=kubernetes \ --user=admin # 設置默認上下文 kubectl config use-context kubernetes ------------------------------------------------------------ 說明: •admin.pem 證書 OU 字段值爲 system:masters,kube-apiserver 預約義的 RoleBinding cluster-admin 將 Group system:masters 與 Role cluster-admin 綁定,該 Role 授予了調用kube-apiserver 相關 API 的權限; •生成的 kubeconfig 被保存到 ~/.kube/config 文件; 注意:~/.kube/config文件擁有對該集羣的最高權限,請妥善保管。
2.3建立 TLS Bootstrapping Token
Token能夠是任意的包含128 bit的字符串,可使用安全的隨機數發生器生成。 ------------------------------------------------------------ export BOOTSTRAP_TOKEN=$(head -c 16 /dev/urandom | od -An -t x | tr -d ' ') cat > token.csv <<EOF ${BOOTSTRAP_TOKEN},kubelet-bootstrap,10001,"system:kubelet-bootstrap" EOF cp token.csv /etc/kubernetes/ ------------------------------------------------------------ 注意:在進行後續操做前請檢查 token.csv 文件,確認其中的 ${BOOTSTRAP_TOKEN} 環境變量已經被真實的值替換。 BOOTSTRAP_TOKEN 將被寫入到 kube-apiserver 使用的 token.csv 文件和 kubelet 使用的 bootstrap.kubeconfig 文件,若是後續從新生成了 BOOTSTRAP_TOKEN,則須要: 1.更新 token.csv 文件,分發到全部機器 (master 和 node)的 /etc/kubernetes/ 目錄下,分發到node節點上非必需;【步驟2.3】 2.從新生成 bootstrap.kubeconfig 文件,分發到全部 node 機器的 /etc/kubernetes/ 目錄下; 【步驟2.4】 3.重啓 kube-apiserver 和 kubelet 進程; 4.從新 approve kubelet 的 csr 請求;[步驟6.3.7]
2.4建立 kubelet bootstrapping kubeconfig 文件
cd /etc/kubernetes export KUBE_APISERVER="https://192.168.55.36:6443" # 設置集羣參數 kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/ssl/ca.pem \ --embed-certs=true \ --server=${KUBE_APISERVER} \ --kubeconfig=bootstrap.kubeconfig # 設置客戶端認證參數 kubectl config set-credentials kubelet-bootstrap \ --token=${BOOTSTRAP_TOKEN} \ --kubeconfig=bootstrap.kubeconfig # 設置上下文參數 kubectl config set-context default \ --cluster=kubernetes \ --user=kubelet-bootstrap \ --kubeconfig=bootstrap.kubeconfig # 設置默認上下文 kubectl config use-context default --kubeconfig=bootstrap.kubeconfig ------------------------------------------------------------ 說明: •--embed-certs 爲 true 時表示將 certificate-authority 證書寫入到生成的 bootstrap.kubeconfig 文件中; •設置客戶端認證參數時沒有指定祕鑰和證書,後續由 kube-apiserver 自動生成;
2.5建立 kube-proxy kubeconfig 文件
------------------------------------------------------------ export KUBE_APISERVER="https://192.168.55.36:6443" # 設置集羣參數 kubectl config set-cluster kubernetes \ --certificate-authority=/etc/kubernetes/ssl/ca.pem \ --embed-certs=true \ --server=${KUBE_APISERVER} \ --kubeconfig=kube-proxy.kubeconfig # 設置客戶端認證參數 kubectl config set-credentials kube-proxy \ --client-certificate=/etc/kubernetes/ssl/kube-proxy.pem \ --client-key=/etc/kubernetes/ssl/kube-proxy-key.pem \ --embed-certs=true \ --kubeconfig=kube-proxy.kubeconfig # 設置上下文參數 kubectl config set-context default \ --cluster=kubernetes \ --user=kube-proxy \ --kubeconfig=kube-proxy.kubeconfig # 設置默認上下文 kubectl config use-context default --kubeconfig=kube-proxy.kubeconfig ------------------------------------------------------------ 說明: •設置集羣參數和客戶端認證參數時 --embed-certs 都爲 true,這會將 certificate-authority、client-certificate 和 client-key 指向的證書文件內容寫入到生成的 kube-proxy.kubeconfig 文件中; • kube-proxy.pem 證書中 CN 爲 system:kube-proxy,kube-apiserver 預約義的 RoleBinding cluster-admin 將User system:kube-proxy 與 Role system:node-proxier 綁定,該 Role 授予了調用 kube-apiserver Proxy 相關 API 的權限;
2.6分發 kubeconfig 文件
將兩個 kubeconfig 文件分發到全部 Node 機器的 /etc/kubernetes/ 目錄 ------------------------------------------------------------ cp bootstrap.kubeconfig kube-proxy.kubeconfig /etc/kubernetes/ ------------------------------------------------------------
3.建立高可用 etcd 集羣
3.1環境
------------------------------------------------------------- 3節點: 192.168.55.36 192.168.55.37 192.168.55.38 -------------------------------------------------------------
3.2 TLS 認證文件
-------------------------------------------------------------
須要爲 etcd 集羣建立加密通訊的 TLS 證書,這裏複用之前建立的 kubernetes 證書
cp ca.pem kubernetes-key.pem kubernetes.pem /etc/kubernetes/ssl
-------------------------------------------------------------
注意:•kubernetes 證書的 hosts 字段列表中包含上面三臺機器的 IP,不然後續證書校驗會失敗;
3.3 下載etcd二進制文件和安裝
------------------------------------------------------------- 方式一: mkdir -p /opt/etcd/bin wget https://github.com/coreos/etcd/releases/download/v3.1.5/etcd-v3.1.5-linux-amd64.tar.gz tar -xvf etcd-v3.1.5-linux-amd64.tar.gz mv etcd-v3.1.5-linux-amd64/etcd* /opt/etcd/bin/ 方式二: yum install etcd 若使用yum安裝,默認etcd命令將在/usr/bin目錄下,注意修改下面的etcd.service文件中的啓動命令地址爲/usr/bin/etcd。 -------------------------------------------------------------
3.4建立 etcd 的 systemd unit 文件
在/etc/systemd/system/目錄下建立文件etcd.service,內容以下。注意替換IP地址爲你本身的etcd集羣的主機IP vim /etc/systemd/system/etcd.service ------------------------------------------------------------- [Unit] Description=Etcd Server After=network.target After=network-online.target Wants=network-online.target Documentation=https://github.com/coreos [Service] Type=notify WorkingDirectory=/var/lib/etcd/ EnvironmentFile=-/etc/etcd/etcd.conf ExecStart=/opt/etcd/bin/etcd \ --name ${ETCD_NAME} \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ --peer-cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --peer-key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ --trusted-ca-file=/etc/kubernetes/ssl/ca.pem \ --peer-trusted-ca-file=/etc/kubernetes/ssl/ca.pem \ --initial-advertise-peer-urls ${ETCD_INITIAL_ADVERTISE_PEER_URLS} \ --listen-peer-urls ${ETCD_LISTEN_PEER_URLS} \ --listen-client-urls ${ETCD_LISTEN_CLIENT_URLS},http://127.0.0.1:2379 \ --advertise-client-urls ${ETCD_ADVERTISE_CLIENT_URLS} \ --initial-cluster-token ${ETCD_INITIAL_CLUSTER_TOKEN} \ --initial-cluster infra1=https://192.168.55.36:2380,infra2=https://192.168.55.37:2380,infra3=https://192.168.55.38:2380 \ --initial-cluster-state new \ --data-dir=${ETCD_DATA_DIR} Restart=on-failure RestartSec=5 LimitNOFILE=65536 [Install] WantedBy=multi-user.target ------------------------------------------------------------- 說明: •指定 etcd 的工做目錄爲 /var/lib/etcd,數據目錄爲 /var/lib/etcd,需在啓動服務前建立這個目錄,不然啓動服務的時候會報錯「Failed at step CHDIR spawning /usr/bin/etcd: No such file or directory」; •爲了保證通訊安全,須要指定 etcd 的公私鑰(cert-file和key-file)、Peers 通訊的公私鑰和 CA 證書(peer-cert-file、peer-key-file、peer-trusted-ca-file)、客戶端的CA證書(trusted-ca-file); •建立 kubernetes.pem 證書時使用的 kubernetes-csr.json 文件的 hosts 字段包含全部 etcd 節點的IP,不然證書校驗會出錯; • --initial-cluster-state 值爲 new 時,--name 的參數值必須位於 --initial-cluster 列表中;
3.5 環境變量配置文件/etc/etcd/etcd.conf
------------------------------------------------------------- # [member] ETCD_NAME=infra1 ETCD_DATA_DIR="/var/lib/etcd" ETCD_LISTEN_PEER_URLS="https://192.168.55.36:2380" ETCD_LISTEN_CLIENT_URLS="https://192.168.55.36:2379" #[cluster] ETCD_INITIAL_ADVERTISE_PEER_URLS="https://192.168.55.36:2380" ETCD_INITIAL_CLUSTER_TOKEN="etcd-cluster" ETCD_ADVERTISE_CLIENT_URLS="https://192.168.55.36:2379" ------------------------------------------------------------- 說明: 這是192.168.55.36節點的配置,其餘兩個etcd節點只要將上面的IP地址改爲相應節點的IP地址便可。ETCD_NAME換成對應節點的infra1/2/3。
3.6啓動 etcd 服務
------------------------------------------------------------- systemctl daemon-reload systemctl enable etcd systemctl start etcd systemctl status etcd ------------------------------------------------------------- 說明: 在全部的 kubernetes master、nodes 節點重複上面的步驟,直到全部機器的 etcd 服務都已啓動。 注意: 若是日誌中出現鏈接異常信息,請確認全部節點防火牆是否開放2379,2380端口
3.7驗證服務
在任一 kubernetes master 機器上執行以下命令: ------------------------------------------------------------- $ etcdctl \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ cluster-health 2017-04-11 15:17:09.082250 I | warning: ignoring ServerName for user-provided CA for backwards compatibility is deprecated 2017-04-11 15:17:09.083681 I | warning: ignoring ServerName for user-provided CA for backwards compatibility is deprecated member 9a2ec640d25672e5 is healthy: got healthy result from https://172.20.0.115:2379 member bc6f27ae3be34308 is healthy: got healthy result from https://172.20.0.114:2379 member e5c92ea26c4edba0 is healthy: got healthy result from https://172.20.0.113:2379 cluster is healthy ------------------------------------------------------------- 說明: 結果最後一行爲 cluster is healthy 時表示集羣服務正常。
4.部署master節點
4.1 master介紹
------------------------------------------------------------- kubernetes master 節點包含的組件: •kube-apiserver •kube-scheduler •kube-controller-manager 目前這三個組件須要部署在同一臺機器上。 • kube-scheduler、kube-controller-manager 和 kube-apiserver 三者的功能緊密相關; •同時只能有一個 kube-scheduler、kube-controller-manager 進程處於工做狀態,若是運行多個,則須要經過選舉產生一個 leader; 注: •暫時未實現master節點的高可用 •master節點上沒有部署flannel網絡插件,若是想要在master節點上也能訪問ClusterIP,請參考下一節部署node節點中的配置Flanneld部分。 -------------------------------------------------------------
4.2 TLS 證書文件
------------------------------------------------------------- 如下pem證書文件咱們在建立TLS證書和祕鑰這一步中已經建立過了,token.csv文件在建立kubeconfig文件的時候建立。咱們再檢查一下。 $ ls /etc/kubernetes/ssl admin-key.pem admin.pem ca-key.pem ca.pem kube-proxy-key.pem kube-proxy.pem kubernetes-key.pem kubernetes.pem $ /etc/kubernetes/token.csv -------------------------------------------------------------
4.3 下載k8s 1.9.0二進制文件
------------------------------------------------------------- mkdir -p /opt/k8s/bin wget https://dl.k8s.io/v1.0.0/kubernetes-server-linux-amd64.tar.gz tar -xzvf kubernetes-server-linux-amd64.tar.gz cd kubernetes cp -r server/bin/{kube-apiserver,kube-controller-manager,kube-scheduler,kubectl,kube-proxy,kubelet} /opt/k8s/bin -------------------------------------------------------------
4.4 配置和啓動 kube-apiserver
4.4.1 建立 kube-apiserver的service配置文件 service配置文件/etc/systemd/system/kube-apiserver.service內容: ------------------------------------------------------------- [Unit] Description=Kubernetes API Service Documentation=https://github.com/GoogleCloudPlatform/kubernetes After=network.target After=etcd.service [Service] EnvironmentFile=-/etc/kubernetes/config EnvironmentFile=-/etc/kubernetes/apiserver ExecStart=/opt/k8s/bin/kube-apiserver \ $KUBE_LOGTOSTDERR \ $KUBE_LOG_LEVEL \ $KUBE_ETCD_SERVERS \ $KUBE_API_ADDRESS \ $KUBE_API_PORT \ $KUBELET_PORT \ $KUBE_ALLOW_PRIV \ $KUBE_SERVICE_ADDRESSES \ $KUBE_ADMISSION_CONTROL \ $KUBE_API_ARGS Restart=on-failure Type=notify LimitNOFILE=65536 [Install] WantedBy=multi-user.target ------------------------------------------------------------- 4.4.2 /etc/kubernetes/config文件的內容爲: ------------------------------------------------------------- ### # kubernetes system config # # The following values are used to configure various aspects of all # kubernetes services, including # # kube-apiserver.service # kube-controller-manager.service # kube-scheduler.service # kubelet.service # kube-proxy.service # logging to stderr means we get it in the systemd journal KUBE_LOGTOSTDERR="--logtostderr=true" # journal message level, 0 is debug KUBE_LOG_LEVEL="--v=0" # Should this cluster be allowed to run privileged docker containers KUBE_ALLOW_PRIV="--allow-privileged=true" # How the controller-manager, scheduler, and proxy find the apiserver #KUBE_MASTER="--master=http://test-001.jimmysong.io:8080" KUBE_MASTER="--master=http://192.168.55.36:8080" ------------------------------------------------------------- 說明: 該配置文件同時被kube-apiserver、kube-controller-manager、kube-scheduler、kubelet、kube-proxy使用。 4.4.3 apiserver配置文件/etc/kubernetes/apiserver內容爲: ------------------------------------------------------------- ### ## kubernetes system config ## ## The following values are used to configure the kube-apiserver ## # ## The address on the local server to listen to. #KUBE_API_ADDRESS="--insecure-bind-address=test-001.jimmysong.io" KUBE_API_ADDRESS="--advertise-address=192.168.55.36 --bind-address=192.168.55.36 --insecure-bind-address=192.168.55.36" # ## The port on the local server to listen on. #KUBE_API_PORT="--port=8080" # ## Port minions listen on #KUBELET_PORT="--kubelet-port=10250" # ## Comma separated list of nodes in the etcd cluster KUBE_ETCD_SERVERS="--etcd-servers=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379" # ## Address range to use for services KUBE_SERVICE_ADDRESSES="--service-cluster-ip-range=172.16.0.1/16" # ## default admission control policies KUBE_ADMISSION_CONTROL="--admission-control=ServiceAccount,NamespaceLifecycle,NamespaceExists,LimitRanger,ResourceQuota" # ## Add your own! KUBE_API_ARGS="--authorization-mode=Node,RBAC --runtime-config=rbac.authorization.k8s.io/v1beta1 --kubelet-https=true --enable-bootstrap-token-auth --token-auth-file=/etc/kubernetes/token.csv --service-node-port-range=30000-32767 --tls-cert-file=/etc/kubernetes/ssl/kubernetes.pem --tls-private-key-file=/etc/kubernetes/ssl/kubernetes-key.pem --client-ca-file=/etc/kubernetes/ssl/ca.pem --service-account-key-file=/etc/kubernetes/ssl/ca-key.pem --etcd-cafile=/etc/kubernetes/ssl/ca.pem --etcd-certfile=/etc/kubernetes/ssl/kubernetes.pem --etcd-keyfile=/etc/kubernetes/ssl/kubernetes-key.pem --enable-swagger-ui=true --apiserver-count=3 --audit-log-maxage=30 --audit-log-maxbackup=3 --audit-log-maxsize=100 --audit-log-path=/var/lib/audit.log --event-ttl=1h" ------------------------------------------------------------- 說明: •--experimental-bootstrap-token-auth Bootstrap Token Authentication在1.9版本已經變成了正式feature,參數名稱改成--enable-bootstrap-token-auth •若是中途修改過--service-cluster-ip-range地址,則必須將default命名空間的kubernetes的service給刪除,使用命令:kubectl delete service kubernetes,而後系統會自動用新的ip重建這個service,否則apiserver的log有報錯the cluster IP x.x.x.x for service kubernetes/default is not within the service CIDR x.x.x.x/16; please recreate • --authorization-mode=RBAC 指定在安全端口使用 RBAC 受權模式,拒絕未經過受權的請求; •kube-scheduler、kube-controller-manager 通常和 kube-apiserver 部署在同一臺機器上,它們使用非安全端口和 kube-apiserver通訊; •kubelet、kube-proxy、kubectl 部署在其它 Node 節點上,若是經過安全端口訪問 kube-apiserver,則必須先經過 TLS 證書認證,再經過 RBAC 受權; •kube-proxy、kubectl 經過在使用的證書裏指定相關的 User、Group 來達到經過 RBAC 受權的目的; •若是使用了 kubelet TLS Boostrap 機制,則不能再指定 --kubelet-certificate-authority、--kubelet-client-certificate 和 --kubelet-client-key 選項,不然後續 kube-apiserver 校驗 kubelet 證書時出現 」x509: certificate signed by unknown authority「 錯誤; • --admission-control 值必須包含 ServiceAccount; • --bind-address 不能爲 127.0.0.1; • runtime-config配置爲rbac.authorization.k8s.io/v1beta1,表示運行時的apiVersion; • --service-cluster-ip-range 指定 Service Cluster IP 地址段,該地址段不能路由可達; •缺省狀況下 kubernetes 對象保存在 etcd /registry 路徑下,能夠經過 --etcd-prefix 參數進行調整; •若是須要開通http的無認證的接口,則能夠增長如下兩個參數:--insecure-port=8080 --insecure-bind-address=127.0.0.1。注意,生產上不要綁定到非127.0.0.1的地址上 Kubernetes 1.9 •對於Kubernetes1.9集羣,須要注意配置KUBE_API_ARGS環境變量中的--authorization-mode=Node,RBAC,增長對Node受權的模式,不然將沒法註冊node。 • --experimental-bootstrap-token-auth Bootstrap Token Authentication在kubernetes 1.9版本已經廢棄,參數名稱改成--enable-bootstrap-token-auth 4.4.4 啓動kube-apiserver ------------------------------------------------------------- systemctl daemon-reload systemctl enable kube-apiserver systemctl start kube-apiserver systemctl status kube-apiserver -------------------------------------------------------------
4.5 配置和啓動 kube-controller-manager
4.5.1 建立 kube-controller-manager的serivce配置文件 文件路徑/etc/systemd/system/kube-controller-manager.service ------------------------------------------------------------- [Unit] Description=Kubernetes Controller Manager Documentation=https://github.com/GoogleCloudPlatform/kubernetes [Service] EnvironmentFile=-/etc/kubernetes/config EnvironmentFile=-/etc/kubernetes/controller-manager ExecStart=/opt/k8s/bin/kube-controller-manager \ $KUBE_LOGTOSTDERR \ $KUBE_LOG_LEVEL \ $KUBE_MASTER \ $KUBE_CONTROLLER_MANAGER_ARGS Restart=on-failure LimitNOFILE=65536 [Install] WantedBy=multi-user.target ------------------------------------------------------------- 4.5.2 配置文件/etc/kubernetes/controller-manager ------------------------------------------------------------- ### # The following values are used to configure the kubernetes controller-manager # defaults from config and apiserver should be adequate # Add your own! KUBE_CONTROLLER_MANAGER_ARGS="--address=127.0.0.1 --service-cluster-ip-range=172.16.0.1/16 --cluster-name=kubernetes --cluster-signing-cert-file=/etc/kubernetes/ssl/ca.pem --cluster-signing-key-file=/etc/kubernetes/ssl/ca-key.pem --service-account-private-key-file=/etc/kubernetes/ssl/ca-key.pem --root-ca-file=/etc/kubernetes/ssl/ca.pem --leader-elect=true" ------------------------------------------------------------- 說明: • --service-cluster-ip-range 參數指定 Cluster 中 Service 的CIDR範圍,該網絡在各 Node 間必須路由不可達,必須和 kube-apiserver 中的參數一致; • --cluster-signing-* 指定的證書和私鑰文件用來簽名爲 TLS BootStrap 建立的證書和私鑰; • --root-ca-file 用來對 kube-apiserver 證書進行校驗,指定該參數後,纔會在Pod 容器的 ServiceAccount 中放置該 CA 證書文件; • --address 值必須爲 127.0.0.1,kube-apiserver 指望 scheduler 和 controller-manager 在同一臺機器; 4.5.3 啓動 kube-controller-manager ------------------------------------------------------------- systemctl daemon-reload systemctl enable kube-controller-manager systemctl start kube-controller-manager systemctl status kube-controller-manager ------------------------------------------------------------- 4.5.4 查看各個組件的狀態; ------------------------------------------------------------- $ kubectl get componentstatuses NAME STATUS MESSAGE ERROR scheduler Unhealthy Get http://127.0.0.1:10251/healthz: dial tcp 127.0.0.1:10251: getsockopt: connection refused controller-manager Healthy ok etcd-2 Healthy {"health": "true"} etcd-0 Healthy {"health": "true"} etcd-1 Healthy {"health": "true"} -------------------------------------------------------------
4.6 配置和啓動 kube-scheduler
4.6.1 建立 kube-scheduler的serivce配置文件 文件路徑/etc/systemd/system/kube-scheduler.service ------------------------------------------------------------- [Unit] Description=Kubernetes Scheduler Plugin Documentation=https://github.com/GoogleCloudPlatform/kubernetes [Service] EnvironmentFile=-/etc/kubernetes/config EnvironmentFile=-/etc/kubernetes/scheduler ExecStart=/opt/k8s/bin/kube-scheduler \ $KUBE_LOGTOSTDERR \ $KUBE_LOG_LEVEL \ $KUBE_MASTER \ $KUBE_SCHEDULER_ARGS Restart=on-failure LimitNOFILE=65536 [Install] WantedBy=multi-user.target ------------------------------------------------------------- 4.6.2 配置文件/etc/kubernetes/scheduler ------------------------------------------------------------- ### # kubernetes scheduler config # default config should be adequate # Add your own! KUBE_SCHEDULER_ARGS="--leader-elect=true --address=127.0.0.1" ------------------------------------------------------------- 說明: • --address 值必須爲 127.0.0.1,由於當前 kube-apiserver 指望 scheduler 和 controller-manager 在同一臺機器; 4.6.3 啓動 kube-scheduler ------------------------------------------------------------- systemctl daemon-reload systemctl enable kube-scheduler systemctl start kube-scheduler systemctl status kube-scheduler -------------------------------------------------------------
4.7 驗證 master 節點功能
------------------------------------------------------------- $ kubectl get componentstatuses NAME STATUS MESSAGE ERROR scheduler Healthy ok controller-manager Healthy ok etcd-0 Healthy {"health": "true"} etcd-1 Healthy {"health": "true"} etcd-2 Healthy {"health": "true"} -------------------------------------------------------------
5.安裝flannel網絡插件
5.1 flannel介紹和安裝
------------------------------------------------------------- 全部的node節點都須要安裝網絡插件才能讓全部的Pod加入到同一個局域網中,本文是安裝flannel網絡插件的參考文檔。 建議直接使用yum安裝flanneld,除非對版本有特殊需求,默認安裝的是0.7.1版本的flannel。
注意: 0.7.1版本有問題
解決方法以下:
替換高版本的flanneld可執行文件
下載地址: wget https://github.com/coreos/flannel/releases/download/v0.9.1/flannel-v0.9.1-linux-amd64.tar.gz
原文地址: https://www.cnblogs.com/cs-zh/p/7879658.html
yum install -y flannel -------------------------------------------------------------
5.2 service配置文件
/etc/systemd/system/flanneld.service ------------------------------------------------------------- [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 EnvironmentFile=/etc/sysconfig/flanneld EnvironmentFile=-/etc/sysconfig/docker-network ExecStart=/usr/bin/flanneld-start \ -etcd-endpoints=${FLANNEL_ETCD_ENDPOINTS} \ -etcd-prefix=${FLANNEL_ETCD_PREFIX} \ $FLANNEL_OPTIONS ExecStartPost=/usr/libexec/flannel/mk-docker-opts.sh -k DOCKER_NETWORK_OPTIONS -d /run/flannel/docker Restart=on-failure [Install] WantedBy=multi-user.target RequiredBy=docker.service -------------------------------------------------------------
5.3 /etc/sysconfig/flanneld配置文件
------------------------------------------------------------- # Flanneld configuration options # etcd url location. Point this to the server where etcd runs FLANNEL_ETCD_ENDPOINTS="https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379" # etcd config key. This is the configuration key that flannel queries # For address range assignment FLANNEL_ETCD_PREFIX="/kube-centos/network" # Any additional options that you want to pass FLANNEL_OPTIONS="-etcd-cafile=/etc/kubernetes/ssl/ca.pem -etcd-certfile=/etc/kubernetes/ssl/kubernetes.pem -etcd-keyfile=/etc/kubernetes/ssl/kubernetes-key.pem" ------------------------------------------------------------- 說明: 若是是多網卡(例如vagrant環境),則須要在FLANNEL_OPTIONS中增長指定的外網出口的網卡,例如-iface=eth2
5.4 在etcd中建立網絡配置
執行下面的命令爲docker分配IP地址段 ------------------------------------------------------------- etcdctl --endpoints=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379 \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ mkdir /kube-centos/network etcdctl --endpoints=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379 \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ mk /kube-centos/network/config '{"Network":"10.200.0.0/16","SubnetLen":24,"Backend":{"Type":"host-gw"}}' ------------------------------------------------------------- 說明: 若是你要使用host-gw模式,能夠直接將vxlan改爲host-gw便可。 注:參考網絡和集羣性能測試那節,最終咱們使用的host-gw模式,關於flannel支持的backend模式見:https://github.com/coreos/flannel/blob/master/Documentation/backends.md。
5.5 啓動flannel
------------------------------------------------------------- systemctl daemon-reload systemctl enable flanneld systemctl start flanneld systemctl status flanneld -------------------------------------------------------------
5.6 驗證flannel
如今查詢etcd中的內容能夠看到 ------------------------------------------------------------- etcdctl --endpoints=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379 \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ ls /kube-centos/network/subnets 結果: /kube-centos/network/subnets/10.200.75.0-24 etcdctl --endpoints=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379 \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ get /kube-centos/network/config 結果: {"Network":"10.200.0.0/16","SubnetLen":24,"Backend":{"Type":"host-gw"}} etcdctl --endpoints=https://192.168.55.36:2379,https://192.168.55.37:2379,https://192.168.55.38:2379 \ --ca-file=/etc/kubernetes/ssl/ca.pem \ --cert-file=/etc/kubernetes/ssl/kubernetes.pem \ --key-file=/etc/kubernetes/ssl/kubernetes-key.pem \ get /kube-centos/network/subnets/10.200.75.0-24 結果: {"PublicIP":"192.168.55.36","BackendType":"host-gw"} ------------------------------------------------------------- 說明: 若是能夠查看到以上內容證實flannel已經安裝完成
6.部署node節點
6.1 部署前介紹
6.1.1 Kubernetes node節點包含以下組件: ------------------------------------------------------------- Kubernetes node節點包含以下組件: •Flanneld:參考我以前寫的文章Kubernetes基於Flannel的網絡配置,以前沒有配置TLS,如今須要在service配置文件中增長TLS配置,安裝過程請參考上一節安裝flannel網絡插件。 •Docker1.12.5:docker的安裝很簡單,這裏也不說了,可是須要注意docker的配置。 •kubelet:直接用二進制文件安裝 •kube-proxy:直接用二進制文件安裝 注意:每臺 node 上都須要安裝 flannel,master 節點上能夠不安裝。 ------------------------------------------------------------- 6.1.2 步驟簡介 ------------------------------------------------------------- 1.確認在上一步中咱們安裝配置的網絡插件flannel已啓動且運行正常 2.安裝配置docker後啓動 3.安裝配置kubelet、kube-proxy後啓動 4.驗證 ------------------------------------------------------------- 6.1.3 目錄和文件 咱們再檢查一下三個節點上,通過前幾步操做咱們已經建立了以下的證書和配置文件。 ------------------------------------------------------------- $ ls /etc/kubernetes/ssl admin-key.pem admin.pem ca-key.pem ca.pem kube-proxy-key.pem kube-proxy.pem kubernetes-key.pem kubernetes.pem $ ls /etc/kubernetes/ apiserver bootstrap.kubeconfig config controller-manager kubelet kube-proxy.kubeconfig proxy scheduler ssl token.csv -------------------------------------------------------------
6.2安裝配置docker
6.2.1 安裝docker yum install -y docker 6.2.2 配置docker ------------------------------------------------------------- 6.2.2.1 使用systemctl命令啓動flanneld後,會自動執行./mk-docker-opts.sh -i生成以下兩個文件環境變量文件: /run/flannel/subnet.env #內容以下: FLANNEL_NETWORK=10.200.0.0/16 FLANNEL_SUBNET=10.200.75.1/24 FLANNEL_MTU=1500 FLANNEL_IPMASQ=false /run/flannel/docker #內容以下: DOCKER_OPT_BIP="--bip=10.200.75.1/24" DOCKER_OPT_IPMASQ="--ip-masq=true" DOCKER_OPT_MTU="--mtu=1500" DOCKER_NETWORK_OPTIONS=" --bip=10.200.75.1/24 --ip-masq=true --mtu=1500" Docker將會讀取這兩個環境變量文件做爲容器啓動參數。 6.2.2.2 /etc/systemd/system/docker.service #內容以下: 添加了兩個 /run/flannel/docker /run/flannel/subnet.env [Unit] Description=Docker Application Container Engine Documentation=http://docs.docker.com After=network.target rhel-push-plugin.socket registries.service Wants=docker-storage-setup.service Requires=docker-cleanup.timer [Service] Type=notify NotifyAccess=all EnvironmentFile=-/run/flannel/docker EnvironmentFile=-/run/flannel/subnet.env EnvironmentFile=-/run/containers/registries.conf EnvironmentFile=-/etc/sysconfig/docker EnvironmentFile=-/etc/sysconfig/docker-storage EnvironmentFile=-/etc/sysconfig/docker-network Environment=GOTRACEBACK=crash Environment=DOCKER_HTTP_HOST_COMPAT=1 Environment=PATH=/usr/libexec/docker:/usr/bin:/usr/sbin ExecStart=/usr/bin/dockerd-current \ --add-runtime docker-runc=/usr/libexec/docker/docker-runc-current \ --default-runtime=docker-runc \ --exec-opt native.cgroupdriver=systemd \ --userland-proxy-path=/usr/libexec/docker/docker-proxy-current \ --init-path=/usr/libexec/docker/docker-init-current \ --seccomp-profile=/etc/docker/seccomp.json \ $OPTIONS \ $DOCKER_STORAGE_OPTIONS \ $DOCKER_NETWORK_OPTIONS \ $ADD_REGISTRY \ $BLOCK_REGISTRY \ $INSECURE_REGISTRY \ $REGISTRIES ExecReload=/bin/kill -s HUP $MAINPID LimitNOFILE=1048576 LimitNPROC=1048576 LimitCORE=infinity TimeoutStartSec=0 Restart=on-abnormal KillMode=process [Install] WantedBy=multi-user.target
6.2.2.2-1 docker加速
/etc/sysconfig/docker
更改OPTIONS的內容設置爲:github
OPTIONS='--selinux-enabled=false --insecure-registry daocloud.io'docker
6.2.2.3 啓動docker systemctl daemon-reload systemctl start docker systemctl enable docker systemctl status docker ps -ef | grep docker #查看進程 能夠看到有 --bip=10.200.75.1/24 這樣的參數 6.2.2.4 重啓了docker後還要重啓kubelet,這時又遇到問題,kubelet啓動失敗。報錯: Mar 31 16:44:41 test-002.jimmysong.io kubelet[81047]: error: failed to run Kubelet: failed to create kubelet: misconfiguration: kubelet cgroup driver: "cgroupfs" is different from docker cgroup driver: "systemd" 解決: 這是kubelet與docker的cgroup driver不一致致使的,/etc/kubernetes/kubelet配置裏:有個—cgroup-driver參數能夠指定爲"cgroupfs"或者「systemd」。 配置docker的service配置文件/etc/systemd/system/docker.service,設置ExecStart中的--exec-opt native.cgroupdriver=systemd。 -------------------------------------------------------------
6.3 安裝和配置kubelet
6.3.1 建立kubelet向 kube-apiserver發送請求權限(master上執行) kubelet 啓動時向 kube-apiserver 發送 TLS bootstrapping 請求,須要先將 bootstrap token 文件中的 kubelet-bootstrap 用戶賦予 system:node-bootstrapper cluster 角色(role), 而後 kubelet 纔能有權限建立認證請求(certificate signing requests): ------------------------------------------------------------- cd /etc/kubernetes kubectl create clusterrolebinding kubelet-bootstrap \ --clusterrole=system:node-bootstrapper \ --user=kubelet-bootstrap ------------------------------------------------------------- 說明: --user=kubelet-bootstrap 是在 /etc/kubernetes/token.csv 文件中指定的用戶名,同時也寫入了 /etc/kubernetes/bootstrap.kubeconfig 文件; 6.3.2 分發配置文件 將兩個 kubeconfig 文件分發到全部 Node 機器的 /etc/kubernetes/ 目錄 ------------------------------------------------------------ cp bootstrap.kubeconfig kube-proxy.kubeconfig /etc/kubernetes/ ------------------------------------------------------------ 6.3.3 下載最新的kubelet和kube-proxy二進制文件 注意請下載對應的Kubernetes版本的安裝包。 ------------------------------------------------------------ mkdir -p /opt/k8s/bin wget https://dl.k8s.io/v1.6.0/kubernetes-server-linux-amd64.tar.gz tar -xzvf kubernetes-server-linux-amd64.tar.gz cd kubernetes cp -r ./server/bin/{kube-proxy,kubelet} /opt/k8s/bin ------------------------------------------------------------ 6.3.4 建立kubelet的service配置文件 文件位置/etc/systemd/system/kubelet.service ------------------------------------------------------------ [Unit] Description=Kubernetes Kubelet Server Documentation=https://github.com/GoogleCloudPlatform/kubernetes After=docker.service Requires=docker.service [Service] WorkingDirectory=/var/lib/kubelet EnvironmentFile=-/etc/kubernetes/config EnvironmentFile=-/etc/kubernetes/kubelet ExecStart=/opt/k8s/bin/kubelet \ $KUBE_LOGTOSTDERR \ $KUBE_LOG_LEVEL \ $KUBELET_API_SERVER \ $KUBELET_ADDRESS \ $KUBELET_PORT \ $KUBELET_HOSTNAME \ $KUBE_ALLOW_PRIV \ $KUBELET_POD_INFRA_CONTAINER \ $KUBELET_ARGS Restart=on-failure [Install] WantedBy=multi-user.target ------------------------------------------------------------ kubelet的配置文件/etc/kubernetes/kubelet。其中的IP地址更改成你的每臺node節點的IP地址。 注意:在啓動kubelet以前,須要先手動建立/var/lib/kubelet目錄。 6.3.5 kubelet的配置文件/etc/kubernetes/kubelet ------------------------------------------------------------ ### ## kubernetes kubelet (minion) config # ## The address for the info server to serve on (set to 0.0.0.0 or "" for all interfaces) KUBELET_ADDRESS="--address=192.168.55.36" # ## The port for the info server to serve on #KUBELET_PORT="--port=10250" # ## You may leave this blank to use the actual hostname KUBELET_HOSTNAME="--hostname-override=192.168.55.36" # ## location of the api-server ## COMMENT THIS ON KUBERNETES 1.8+ #KUBELET_API_SERVER="--api-servers=http://192.168.55.36:8080" # ## pod infrastructure container KUBELET_POD_INFRA_CONTAINER="--pod-infra-container-image=index.tenxcloud.com/jimmy/pod-infrastructure:rhel7" # ## Add your own! KUBELET_ARGS="--fail-swap-on=false --runtime-cgroups=/systemd/system.slice --kubelet-cgroups=/systemd/system.slice --cgroup-driver=systemd --cluster-dns=172.16.0.2 --bootstrap-kubeconfig=/etc/kubernetes/bootstrap.kubeconfig --kubeconfig=/etc/kubernetes/kubelet.kubeconfig --cert-dir=/etc/kubernetes/ssl --cluster-domain=cluster.local --hairpin-mode promiscuous-bridge --serialize-image-pulls=false --logtostderr false --log-dir /var/log/kubernetes --v 2" ------------------------------------------------------------ 說明: •對於kuberentes1.9集羣中的kubelet配置,取消了KUBELET_API_SERVER的配置,而改用kubeconfig文件來定義master地址,因此請註釋掉KUBELET_API_SERVER配置 •若是使用systemd方式啓動,則須要額外增長兩個參數--runtime-cgroups=/systemd/system.slice --kubelet-cgroups=/systemd/system.slice • --experimental-bootstrap-kubeconfig 在1.9版本已經變成了--bootstrap-kubeconfig • --address 不能設置爲 127.0.0.1,不然後續 Pods 訪問 kubelet 的 API 接口時會失敗,由於 Pods 訪問的 127.0.0.1 指向本身而不是 kubelet; •若是設置了 --hostname-override 選項,則 kube-proxy 也須要設置該選項,不然會出現找不到 Node 的狀況; • "--cgroup-driver 配置成 systemd,不要使用cgroup,不然在 CentOS 系統中 kubelet 將啓動失敗(保持docker和kubelet中的cgroup driver配置一致便可,不必定非使用systemd)。 • --experimental-bootstrap-kubeconfig 指向 bootstrap kubeconfig 文件,kubelet 使用該文件中的用戶名和 token 向 kube-apiserver 發送 TLS Bootstrapping 請求; •管理員經過了 CSR 請求後,kubelet 自動在 --cert-dir 目錄建立證書和私鑰文件(kubelet-client.crt 和 kubelet-client.key),而後寫入 --kubeconfig 文件; •建議在 --kubeconfig 配置文件中指定 kube-apiserver 地址,若是未指定 --api-servers 選項,則必須指定 --require-kubeconfig 選項後才從配置文件中讀取 kube-apiserver 的地址,不然 kubelet 啓動後將找不到 kube-apiserver (日誌中提示未找到 API Server),kubectl get nodes 不會返回對應的 Node 信息; --require-kubeconfig 在1.9.0版本被移除,參看PR; • --cluster-dns 指定 kubedns 的 Service IP(能夠先分配,後續建立 kubedns 服務時指定該 IP,這個ip必須是apiserver配置中--service-cluster-ip-range值範圍內的值),--cluster-domain 指定域名後綴,這兩個參數同時指定後纔會生效; • --cluster-domain 指定 pod 啓動時 /etc/resolve.conf 文件中的 search domain ,起初咱們將其配置成了 cluster.local.,這樣在解析 service 的 DNS 名稱時是正常的,但是在解析 headless service 中的 FQDN pod name 的時候卻錯誤,所以咱們將其修改成 cluster.local,去掉最後面的 」點號「 就能夠解決該問題,關於 kubernetes 中的域名/服務名稱解析請參見個人另外一篇文章。 • --kubeconfig=/etc/kubernetes/kubelet.kubeconfig中指定的kubelet.kubeconfig文件在第一次啓動kubelet以前並不存在,請看下文,當經過CSR請求後會自動生成kubelet.kubeconfig文件,若是你的節點上已經生成了~/.kube/config文件,你能夠將該文件拷貝到該路徑下,並重命名爲kubelet.kubeconfig,全部node節點能夠共用同一個kubelet.kubeconfig文件,這樣新添加的節點就不須要再建立CSR請求就能自動添加到kubernetes集羣中。一樣,在任意可以訪問到kubernetes集羣的主機上使用kubectl --kubeconfig命令操做集羣時,只要使用~/.kube/config文件就能夠經過權限認證,由於這裏面已經有認證信息並認爲你是admin用戶,對集羣擁有全部權限。 • KUBELET_POD_INFRA_CONTAINER 是基礎鏡像容器,這裏我用的是私有鏡像倉庫地址,你們部署的時候須要修改成本身的鏡像。我上傳了一個到時速雲上,能夠直接 docker pull index.tenxcloud.com/jimmy/pod-infrastructure:rhel7 下載。pod-infrastructure鏡像是Redhat製做的,大小接近80M,下載比較耗時,其實該鏡像並不運行什麼具體進程,可使用Google的pause鏡像gcr.io/google_containers/pause-amd64:3.0,這個鏡像只有300多K,或者經過DockerHub下載jimmysong/pause-amd64:3.0。 • --fail-swap-on=false 發需要加上 這是關閉swap的,否則kubelet啓動不了。 6.3.6 啓動kublet ------------------------------------------------------------ systemctl daemon-reload systemctl enable kubelet systemctl start kubelet systemctl status kubelet ------------------------------------------------------------ 6.3.7 經過 kublet 的 TLS 證書請求 kubelet 首次啓動時向 kube-apiserver 發送證書籤名請求,必須經過後 kubernetes 系統纔會將該 Node 加入到集羣。 查看未受權的 CSR 請求 ------------------------------------------------------------ $ kubectl get csr NAME AGE REQUESTOR CONDITION csr-2b308 4m kubelet-bootstrap Pending $ kubectl get nodes No resources found. ------------------------------------------------------------ 經過 CSR 請求 ------------------------------------------------------------ $ kubectl certificate approve csr-2b308 certificatesigningrequest "csr-2b308" approved $ kubectl get nodes NAME STATUS AGE VERSION 10.64.3.7 Ready 49m v1.6.1 ------------------------------------------------------------ 自動生成了 kubelet kubeconfig 文件和公私鑰 ------------------------------------------------------------ $ ls -l /etc/kubernetes/kubelet.kubeconfig -rw------- 1 root root 2284 Apr 7 02:07 /etc/kubernetes/kubelet.kubeconfig $ ls -l /etc/kubernetes/ssl/kubelet* -rw-r--r-- 1 root root 1046 Apr 7 02:07 /etc/kubernetes/ssl/kubelet-client.crt -rw------- 1 root root 227 Apr 7 02:04 /etc/kubernetes/ssl/kubelet-client.key -rw-r--r-- 1 root root 1103 Apr 7 02:07 /etc/kubernetes/ssl/kubelet.crt -rw------- 1 root root 1675 Apr 7 02:07 /etc/kubernetes/ssl/kubelet.key ------------------------------------------------------------ 說明: 假如你更新kubernetes的證書,只要沒有更新token.csv,當重啓kubelet後,該node就會自動加入到kuberentes集羣中,而不會從新發送certificaterequest,也不須要在master節點上執行kubectl certificate approve操做。前提是不要刪除node節點上的/etc/kubernetes/ssl/kubelet*和/etc/kubernetes/kubelet.kubeconfig文件。不然kubelet啓動時會提示找不到證書而失敗。 注意:若是啓動kubelet的時候見到證書相關的報錯,有個trick能夠解決這個問題,能夠將master節點上的~/.kube/config文件(該文件在安裝kubectl命令行工具這一步中將會自動生成)拷貝到node節點的/etc/kubernetes/kubelet.kubeconfig位置,這樣就不須要經過CSR,當kubelet啓動後就會自動加入的集羣中。
6.4 配置 kube-proxy
6.4.1 安裝conntrack ------------------------------------------------------------ yum install -y conntrack-tools ------------------------------------------------------------ 6.4.2 建立 kube-proxy 的service配置文件 文件路徑/etc/systemd/system/kube-proxy.service ------------------------------------------------------------ [Unit] Description=Kubernetes Kube-Proxy Server Documentation=https://github.com/GoogleCloudPlatform/kubernetes After=network.target [Service] EnvironmentFile=-/etc/kubernetes/config EnvironmentFile=-/etc/kubernetes/proxy ExecStart=/opt/k8s/bin/kube-proxy \ $KUBE_LOGTOSTDERR \ $KUBE_LOG_LEVEL \ $KUBE_MASTER \ $KUBE_PROXY_ARGS Restart=on-failure LimitNOFILE=65536 [Install] WantedBy=multi-user.target ------------------------------------------------------------ 6.4.3 kube-proxy配置文件/etc/kubernetes/proxy ------------------------------------------------------------ ### # kubernetes proxy config # default config should be adequate # Add your own! KUBE_PROXY_ARGS="--bind-address=192.168.55.36 --hostname-override=192.168.55.36 --kubeconfig=/etc/kubernetes/kube-proxy.kubeconfig --cluster-cidr=172.16.0.0/16" ------------------------------------------------------------ 說明: • --hostname-override 參數值必須與 kubelet 的值一致,不然 kube-proxy 啓動後會找不到該 Node,從而不會建立任何 iptables 規則; • kube-proxy 根據 --cluster-cidr 判斷集羣內部和外部流量,指定 --cluster-cidr 或 --masquerade-all 選項後 kube-proxy 纔會對訪問 Service IP 的請求作 SNAT 此項要跟apiserver配置裏的--service-cluster-ip-range 值同樣; • --kubeconfig 指定的配置文件嵌入了 kube-apiserver 的地址、用戶名、證書、祕鑰等請求和認證信息; •預約義的 RoleBinding cluster-admin 將User system:kube-proxy 與 Role system:node-proxier 綁定,該 Role 授予了調用 kube-apiserver Proxy 相關 API 的權限; 6.4.4 啓動 kube-proxy ------------------------------------------------------------ systemctl daemon-reload systemctl enable kube-proxy systemctl start kube-proxy systemctl status kube-proxy ------------------------------------------------------------
6.4.5 驗證測試
咱們建立一個nginx的service試一下集羣是否可用
------------------------------------------------------------
$ kubectl get nodes
NAME STATUS ROLES AGE VERSION
192.168.55.36 Ready <none> 1d v1.9.0apache
$ kubectl run nginx --replicas=2 --labels="run=load-balancer-example" --image=index.tenxcloud.com/docker_library/nginx --port=80 #--port值須要對上容器指供的端口值
deployment "nginx" created
$ kubectl get pods
NAME READY STATUS RESTARTS AGE
nginx-744c5fd44f-lwnl7 0/1 Running 0 3m
nginx-744c5fd44f-mzrwp 0/1 Running 0 3mjson
$ kubectl expose deployment nginx --type=NodePort --name=example-service
service "example-service" exposedbootstrap
$ kubectl describe svc example-service #這步要查看到下面的內容 是須要一會時間的
Name: example-service
Namespace: default
Labels: run=load-balancer-example
Annotations: <none>
Selector: run=load-balancer-example
Type: NodePort
IP: 172.16.238.215
Port: <unset> 80/TCP
TargetPort: 80/TCP
NodePort: <unset> 31107/TCP
Endpoints: 10.200.75.2:80,10.200.75.3:80
Session Affinity: None
External Traffic Policy: Cluster
Events: <none>
$ curl "172.16.238.215:80"
------------------------------------------------------------
說明:
訪問192.168.55.36:31107 能夠獲得nginx的頁面, 172.16.238.215是service_ip 10.200.75.2:80,10.200.75.3:80是容器ip 31107是宿主機映射後端service的端口(有疑問)
7.安裝kubedns插件
7.1 kubedns yml修改過的配置
[root@k8s-master /opt/k8s/yml 11:03:15&&154]#cat kube-dns.yml apiVersion: v1 kind: Service metadata: name: kube-dns namespace: kube-system labels: k8s-app: kube-dns kubernetes.io/cluster-service: "true" addonmanager.kubernetes.io/mode: Reconcile kubernetes.io/name: "KubeDNS" spec: selector: k8s-app: kube-dns clusterIP: 172.16.0.2 #這個ip須要和 kubelet 的 --cluster-dns 參數值一致。 ports: - name: dns port: 53 protocol: UDP - name: dns-tcp port: 53 protocol: TCP --- apiVersion: v1 kind: ServiceAccount metadata: name: kube-dns namespace: kube-system labels: kubernetes.io/cluster-service: "true" addonmanager.kubernetes.io/mode: Reconcile --- apiVersion: v1 kind: ConfigMap metadata: name: kube-dns namespace: kube-system labels: addonmanager.kubernetes.io/mode: EnsureExists --- apiVersion: extensions/v1beta1 kind: Deployment metadata: name: kube-dns namespace: kube-system labels: k8s-app: kube-dns kubernetes.io/cluster-service: "true" addonmanager.kubernetes.io/mode: Reconcile spec: # replicas: not specified here: # 1. In order to make Addon Manager do not reconcile this replicas parameter. # 2. Default is 1. # 3. Will be tuned in real time if DNS horizontal auto-scaling is turned on. strategy: rollingUpdate: maxSurge: 10% maxUnavailable: 0 selector: matchLabels: k8s-app: kube-dns template: metadata: labels: k8s-app: kube-dns annotations: scheduler.alpha.kubernetes.io/critical-pod: '' spec: tolerations: - key: "CriticalAddonsOnly" operator: "Exists" volumes: - name: kube-dns-config configMap: name: kube-dns optional: true containers: - name: kubedns image: registry.cn-beijing.aliyuncs.com/k8s_images/k8s-dns-kube-dns-amd64:1.14.9 resources: # TODO: Set memory limits when we've profiled the container for large # clusters, then set request = limit to keep this container in # guaranteed class. Currently, this container falls into the # "burstable" category so the kubelet doesn't backoff from restarting it. limits: memory: 170Mi requests: cpu: 100m memory: 70Mi livenessProbe: httpGet: path: /healthcheck/kubedns port: 10054 scheme: HTTP initialDelaySeconds: 60 timeoutSeconds: 5 successThreshold: 1 failureThreshold: 5 readinessProbe: httpGet: path: /readiness port: 8081 scheme: HTTP # we poll on pod startup for the Kubernetes master service and # only setup the /readiness HTTP server once that's available. initialDelaySeconds: 3 timeoutSeconds: 5 args: - --domain=cluster.local. - --dns-port=10053 - --config-dir=/kube-dns-config - --v=2 #__PILLAR__FEDERATIONS__DOMAIN__MAP__ env: - name: PROMETHEUS_PORT value: "10055" ports: - containerPort: 10053 name: dns-local protocol: UDP - containerPort: 10053 name: dns-tcp-local protocol: TCP - containerPort: 10055 name: metrics protocol: TCP volumeMounts: - name: kube-dns-config mountPath: /kube-dns-config - name: dnsmasq image: registry.cn-beijing.aliyuncs.com/k8s_images/k8s-dns-dnsmasq-nanny-amd64:1.14.9 livenessProbe: httpGet: path: /healthcheck/dnsmasq port: 10054 scheme: HTTP initialDelaySeconds: 60 timeoutSeconds: 5 successThreshold: 1 failureThreshold: 5 args: - -v=2 - -logtostderr - -configDir=/etc/k8s/dns/dnsmasq-nanny - -restartDnsmasq=true - -- - -k - --cache-size=1000 - --log-facility=- - --server=/cluster.local./127.0.0.1#10053 - --server=/in-addr.arpa/127.0.0.1#10053 - --server=/ip6.arpa/127.0.0.1#10053 ports: - containerPort: 53 name: dns protocol: UDP - containerPort: 53 name: dns-tcp protocol: TCP # see: https://github.com/kubernetes/kubernetes/issues/29055 for details resources: requests: cpu: 150m memory: 20Mi volumeMounts: - name: kube-dns-config mountPath: /etc/k8s/dns/dnsmasq-nanny - name: sidecar image: registry.cn-beijing.aliyuncs.com/k8s_images/k8s-dns-sidecar-amd64:1.14.9 livenessProbe: httpGet: path: /metrics port: 10054 scheme: HTTP initialDelaySeconds: 60 timeoutSeconds: 5 successThreshold: 1 failureThreshold: 5 args: - --v=2 - --logtostderr - --probe=kubedns,127.0.0.1:10053,kubernetes.default.svc.cluster.local.,5,A - --probe=dnsmasq,127.0.0.1:53,kubernetes.default.svc.cluster.local.,5,A ports: - containerPort: 10054 name: metrics protocol: TCP resources: requests: memory: 20Mi cpu: 10m dnsPolicy: Default # Don't use cluster DNS. serviceAccountName: kube-dns
說明: 藍色字體的是修改部分,上面的配置文件已是修改過的。注意namespace的 kube-system是不能修改的
7.2執行apply命令 建立kubedns 而且查看驗證
建立kubedns [root@k8s-master /opt/k8s/yml 11:14:09&&167]#kubectl apply -f kube-dns.yml service "kube-dns" created serviceaccount "kube-dns" created configmap "kube-dns" created deployment "kube-dns" created 查看kubedns pod [root@k8s-master /opt/k8s/yml 11:14:17&&168]#kubectl get pod --namespace=kube-system NAME READY STATUS RESTARTS AGE kube-dns-5c874ccb67-vqtvb 3/3 Running 0 29s 驗證kubedns 說明: 建立個pod, 進入pod 查看/etc/resolv.conf的 nameserver是不是172.16.0.2 cat > httpd.yml << EOF apiVersion: extensions/v1beta1 kind: Deployment metadata: name: httpd-deployment spec: replicas: 1 template: metadata: labels: run: httpd spec: containers: - name: httpd image: daocloud.io/library/httpd ports: - containerPort: 80 EOF [root@k8s-master /opt/k8s/yml 11:17:30&&176]#kubectl apply -f httpd.yml deployment "httpd-deployment" created [root@k8s-master /opt/k8s/yml 11:18:31&&177]#kubectl get pod -o wide NAME READY STATUS RESTARTS AGE IP NODE httpd-deployment-5c9bc776cb-x82hs 1/1 Running 0 34s 10.200.75.3 192.168.55.36 [root@k8s-master /opt/k8s/yml 11:19:05&&178]#kubectl exec -ti httpd-deployment-5c9bc776cb-x82hs -- /bin/bash root@httpd-deployment-5c9bc776cb-x82hs:/usr/local/apache2# cat /etc/resolv.conf nameserver 172.16.0.2 search default.svc.cluster.local svc.cluster.local cluster.local options ndots:5 root@httpd-deployment-5c9bc776cb-x82hs:/usr/local/apache2# ping kubernetes PING kubernetes.default.svc.cluster.local (172.16.0.1) 56(84) bytes of data. ^C --- kubernetes.default.svc.cluster.local ping statistics --- 18 packets transmitted, 0 received, 100% packet loss, time 17000ms
注意:直接ping ClusterIP是ping不通的,ClusterIP是根據IPtables路由到服務的endpoint上,只有結合ClusterIP加端口才能訪問到對應的服務。
驗證kubedns2:
[root@k8s-master /opt/k8s/yml 14:56:51&&43]#kubectl run busybox --rm -ti --image=busybox /bin/sh #這個pod 退出即消失
If you don't see a command prompt, try pressing enter.
/ # cat /etc/resolv.conf
nameserver 172.16.0.2
search default.svc.cluster.local svc.cluster.local cluster.local
options ndots:5
/ # nslookup nginx-svc #注意:這個nginx-svc 須要提早建立
Server: 172.16.0.2
Address 1: 172.16.0.2 kube-dns.kube-system.svc.cluster.local
Name: nginx-svc
Address 1: 172.16.98.222 nginx-svc.default.svc.cluster.local
/ # ping kubernetes
PING kubernetes (172.16.0.1): 56 data bytes
8.安裝dashboard插件
8.1 dashboard yml 配置文件(修改過的)
apiVersion: v1 kind: ServiceAccount metadata: name: dashboard namespace: kube-system --- kind: ClusterRoleBinding apiVersion: rbac.authorization.k8s.io/v1beta1 metadata: name: dashboard subjects: - kind: ServiceAccount name: dashboard namespace: kube-system roleRef: kind: ClusterRole name: cluster-admin apiGroup: rbac.authorization.k8s.io --- apiVersion: extensions/v1beta1 kind: Deployment metadata: name: kubernetes-dashboard namespace: kube-system labels: k8s-app: kubernetes-dashboard kubernetes.io/cluster-service: "true" addonmanager.kubernetes.io/mode: Reconcile spec: selector: matchLabels: k8s-app: kubernetes-dashboard template: metadata: labels: k8s-app: kubernetes-dashboard annotations: scheduler.alpha.kubernetes.io/critical-pod: '' spec: serviceAccountName: dashboard containers: - name: kubernetes-dashboard image: registry.cn-hangzhou.aliyuncs.com/google-containers/kubernetes-dashboard-amd64:v1.7.1 resources: limits: cpu: 100m memory: 50Mi requests: cpu: 100m memory: 50Mi ports: - containerPort: 9090 livenessProbe: httpGet: path: / port: 9090 initialDelaySeconds: 30 timeoutSeconds: 30 tolerations: - key: "CriticalAddonsOnly" operator: "Exists" --- apiVersion: v1 kind: Service metadata: name: kubernetes-dashboard namespace: kube-system labels: k8s-app: kubernetes-dashboard kubernetes.io/cluster-service: "true" addonmanager.kubernetes.io/mode: Reconcile spec: type: NodePort selector: k8s-app: kubernetes-dashboard ports: - port: 80 targetPort: 9090
8.2 建立doshboard資源和查看資源並 頁面訪問
建立資源 [root@k8s-master /opt/k8s/yml 12:39:06&&196]#kubectl apply -f doshboard.yml serviceaccount "dashboard" created clusterrolebinding "dashboard" created deployment "kubernetes-dashboard" created service "kubernetes-dashboard" created 查看svc [root@k8s-master /opt/k8s/yml 12:50:10&&206]#kubectl get svc -o wide --namespace=kube-system NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE SELECTOR kubernetes-dashboard NodePort 172.16.71.213 <none> 80:31130/TCP 10m k8s-app=kubernetes-dashboard 查看pod [root@k8s-master /opt/k8s/yml 12:50:14&&207]#kubectl get pod -o wide --namespace=kube-system NAME READY STATUS RESTARTS AGE IP NODE kubernetes-dashboard-f874767d4-x8zn4 1/1 Running 0 11m 10.200.75.5 192.168.55.36 訪問dashboard http://192.168.55.36:31130
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