使用CNI网络插件(calico)实现docker容器跨主机互联
目录
- 一.系统环境
- 二.前言
- 三.CNI网络插件简介
- 四.常见的几种CNI网络插件对比
- 五.Calico网络之间是如何通信的
- 六.配置calico让物理机A上的docker容器c1可以访问物理机B上的docker容器c2
- 七.Kubernetes(k8s)环境里的calico
- 八.总结
一.系统环境
本文主要基于Docker 20.10.12和Linux操作系统CentOS7.4。
服务器版本
calico版本
docker软件版本
Kubernetes(k8s)集群版本
CPU架构
CentOS Linux release 7.4.1708 (Core)
v2.6.12
Docker version 20.10.12
v1.21.9
x86_64
etcd集群架构:etcd1为leader,etcd2为follower,etcd3为follower。
服务器
操作系统版本
CPU架构
进程
功能描述
etcd1/192.168.110.133
CentOS Linux release 7.4.1708 (Core)
x86_64
etcd
leader
etcd2/192.168.110.131
CentOS Linux release 7.4.1708 (Core)
x86_64
etcd
follower
etcd3/192.168.110.132
CentOS Linux release 7.4.1708 (Core)
x86_64
etcd
follower
Kubernetes集群架构:k8scloude1作为master节点,k8scloude2,k8scloude3作为worker节点。
服务器
操作系统版本
CPU架构
进程
功能描述
k8scloude1/192.168.110.130
CentOS Linux release 7.4.1708 (Core)
x86_64
docker,kube-apiserver,etcd,kube-scheduler,kube-controller-manager,kubelet,kube-proxy,coredns,calico
k8s master节点
k8scloude2/192.168.110.129
CentOS Linux release 7.4.1708 (Core)
x86_64
docker,kubelet,kube-proxy,calico
k8s worker节点
k8scloude3/192.168.110.128
CentOS Linux release 7.4.1708 (Core)
x86_64
docker,kubelet,kube-proxy,calico
k8s worker节点
二.前言
在Kubernetes集群中,容器之间的通信是非常重要的一部分。为了实现容器之间的跨主机互联,需要使用CNI网络插件。本文将介绍CNI网络插件的概念和常见的几种插件对比,并详细讲解如何使用Calico实现Docker容器跨主机互联。
calico的信息保存在etcd里,所以需要一套etcd集群,关于etcd集群的安装部署,可以查看博客《Kubernetes后台数据库etcd:安装部署etcd集群,数据备份与恢复》。
查看Kubernetes(k8s)环境里的calico的前提是已经有一套可以正常运行的Kubernetes集群,关于Kubernetes(k8s)集群的安装部署,可以查看博客《Centos7 安装部署Kubernetes(k8s)集群》https://www.cnblogs.com/renshengdezheli/p/16686769.html。
三.CNI网络插件简介
CNI(Containernetworking Interface)网络插件是一个由Linux基金会维护的开源项目,它可以为容器提供网络连接。在Kubernetes中,可以通过CNI网络插件来为Pod提供网络连接。
目前市面上主流的CNI网络插件有以下几种:
- Flannel:使用VXLAN技术实现网络隔离和扁平化IP;
- Calico:采用BGP协议实现高效的容器网络互连;
- Weave Net:使用虚拟机间通信(VXLAN)技术,在容器之间创建多层网络;
- Canal:结合Flannel和Calico两种CNI网络插件的优点,实现网络隔离和BGP路由。
四.常见的几种CNI网络插件对比
下面我们来对比这几种CNI网络插件。
CNI网络插件
优点
缺点
是否支持网络策略
Flannel
部署简单,性能优秀
网络层延迟高
否
Calico
性能最好,支持容器内BGP协议,支持网络策略
配置复杂
是
Weave Net
功能强大,跨平台支持
性能低下,容易出现网络死锁
是
Canal
结合了Flannel和Calico两种插件的优点,支持多种网络模式,可以满足不同的需求
部署和配置较为繁琐
是
综上所述,每种CNI网络插件都有其独特的优势和局限性,需要根据实际情况进行选择。
五.Calico网络之间是如何通信的
Calico是一种基于IP路由技术的CNI网络插件,它利用BGP协议来实现高效的容器网络互连。在Calico中,每个容器都被赋予了一个唯一的IP地址,这些IP地址在网络层面上是可达的,并且是通过数据包路由直接到达目标容器的。
Calico使用路由表来管理容器网络,每个主机上都会存在一个Calico Agent,它会监听Kubernetes API服务器,从而了解集群中所有容器的IP地址和状态。当某个容器需要向其他容器发起请求时,Calico会根据路由表信息进行查找,找到合适的路径,并将数据包转发给目标容器。
六.配置calico让物理机A上的docker容器c1可以访问物理机B上的docker容器c2
现在要解决的问题是:让物理机A上的docker容器c1可以访问物理机B上的docker容器c2!
方法一:物理机A上的容器c1想和物理机B上的容器c2通信,可以通过容器c1在物理机上映射一个端口,容器c2在物理机上映射一个端口,访问物理机的端口达到访问容器的目的,但是这样过于麻烦,有没有更好的方法呢?
方法二:可以通过网络插件来实现这个需求,这里使用calico网络插件。
因为calico的信息保存在etcd里,所以需要一套etcd集群。
查看etcd集群的健康状态。
[root@etcd1 ~]# etcdctl cluster-health
member 341a3c460c1c993a is healthy: got healthy result from http://192.168.110.131:2379
member 4679fe0fcb37326d is healthy: got healthy result from http://192.168.110.132:2379
member ab23bcc86cf3190b is healthy: got healthy result from http://192.168.110.133:2379
cluster is healthy查看etcd集群的成员,可以看到etcd133是Leader。
[root@etcd1 ~]# etcdctl member list
341a3c460c1c993a: name=etcd131 peerURLs=http://192.168.110.131:2380 clientURLs=http://192.168.110.131:2379,http://localhost:2379 isLeader=false
4679fe0fcb37326d: name=etcd132 peerURLs=http://192.168.110.132:2380 clientURLs=http://192.168.110.132:2379,http://localhost:2379 isLeader=false
ab23bcc86cf3190b: name=etcd133 peerURLs=http://192.168.110.133:2380 clientURLs=http://192.168.110.133:2379,http://localhost:2379 isLeader=trueetcd现在什么数据也没有
[root@etcd1 ~]# etcdctl ls /三个节点安装docker,用来启动容器。
[root@etcd1 ~]# yum -y install docker-ce
[root@etcd2 ~]# yum -y install docker-ce
[root@etcd3 ~]# yum -y install docker-ce修改docker的启动参数,设置docker使用etcd来存储数据,可以看到docker的启动脚本在/usr/lib/systemd/system/docker.service。
[root@etcd1 ~]# systemctl status docker
● docker.service - Docker Application Container Engine
Loaded: loaded (/usr/lib/systemd/system/docker.service; disabled; vendor preset: disabled)
Active: inactive (dead)
Docs: https://docs.docker.com
[root@etcd1 ~]# etcdctl member list
341a3c460c1c993a: name=etcd131 peerURLs=http://192.168.110.131:2380 clientURLs=http://192.168.110.131:2379,http://localhost:2379 isLeader=false
4679fe0fcb37326d: name=etcd132 peerURLs=http://192.168.110.132:2380 clientURLs=http://192.168.110.132:2379,http://localhost:2379 isLeader=false
ab23bcc86cf3190b: name=etcd133 peerURLs=http://192.168.110.133:2380 clientURLs=http://192.168.110.133:2379,http://localhost:2379 isLeader=true添加启动参数:--cluster-store=etcd://192.168.110.133:2379。
[root@etcd1 ~]# vim /usr/lib/systemd/system/docker.service
[root@etcd1 ~]# grep ExecStart /usr/lib/systemd/system/docker.service
ExecStart=/usr/bin/dockerd --cluster-store=etcd://192.168.110.133:2379 -H fd:// --containerd=/run/containerd/containerd.sock重新加载配置,启动docker。
[root@etcd1 ~]# systemctl daemon-reload ;systemctl restart docker可以看到参数添加成功:/usr/bin/dockerd --cluster-store=etcd://192.168.110.133:2379 -H fd:// --containerd=/run/containerd/containerd.sock。这样设置之后,etcd就可以存储docker的后端数据了。
[root@etcd1 ~]# systemctl status docker
● docker.service - Docker Application Container Engine
Loaded: loaded (/usr/lib/systemd/system/docker.service; disabled; vendor preset: disabled)
Active: active (running) since 三 2022-02-16 15:39:50 CST; 39s ago
Docs: https://docs.docker.com
Main PID: 1390 (dockerd)
Memory: 30.8M
CGroup: /system.slice/docker.service
└─1390 /usr/bin/dockerd --cluster-store=etcd://192.168.110.133:2379 -H fd:// --containerd=/run/containerd/containerd.sock其他两个节点进行相同操作,但是etcd的IP要修改为本机的地址。
[root@etcd2 ~]# vim /usr/lib/systemd/system/docker.service
[root@etcd2 ~]# grep ExecStart /usr/lib/systemd/system/docker.service
ExecStart=/usr/bin/dockerd --cluster-store=etcd://192.168.110.131:2379 -H fd:// --containerd=/run/containerd/containerd.sock
[root@etcd2 ~]# systemctl daemon-reload ;systemctl restart docker
[root@etcd2 ~]# systemctl status docker
● docker.service - Docker Application Container Engine
Loaded: loaded (/usr/lib/systemd/system/docker.service; disabled; vendor preset: disabled)
Active: active (running) since 三 2022-02-16 15:39:57 CST; 41s ago
Docs: https://docs.docker.com
Main PID: 1348 (dockerd)
Memory: 32.4M
CGroup: /system.slice/docker.service
└─1348 /usr/bin/dockerd --cluster-store=etcd://192.168.110.131:2379 -H fd:// --containerd=/run/containerd/containerd.sock
[root@etcd3 ~]# vim /usr/lib/systemd/system/docker.service
[root@etcd3 ~]# grep ExecStart /usr/lib/systemd/system/docker.service
ExecStart=/usr/bin/dockerd --cluster-store=etcd://192.168.110.132:2379 -H fd:// --containerd=/run/containerd/containerd.sock
[root@etcd3 ~]# systemctl daemon-reload ;systemctl restart docker
[root@etcd3 ~]# systemctl status docker
● docker.service - Docker Application Container Engine
Loaded: loaded (/usr/lib/systemd/system/docker.service; disabled; vendor preset: disabled)
Active: active (running) since 三 2022-02-16 15:39:59 CST; 41s ago
Docs: https://docs.docker.com
Main PID: 1355 (dockerd)
Memory: 34.7M
CGroup: /system.slice/docker.service
└─1355 /usr/bin/dockerd --cluster-store=etcd://192.168.110.132:2379 -H fd:// --containerd=/run/containerd/containerd.sock创建calico目录,并创建配置文件,三个节点都需要。
[root@etcd1 ~]# mkdir /etc/calico
[root@etcd1 ~]# cat > /etc/calico/calicoctl.cfg <<EOF
> apiVersion: v1
> kind: calicoApiConfig
> metadata:
> spec:
> datastoreType: "etcdv2"
> etcdEndpoints: "http://192.168.110.133:2379"
> EOF
#calico的配置文件已经配置好了
[root@etcd1 ~]# cat /etc/calico/calicoctl.cfg
apiVersion: v1
kind: calicoApiConfig
metadata:
spec:
datastoreType: "etcdv2"
etcdEndpoints: "http://192.168.110.133:2379"
[root@etcd2 ~]# mkdir /etc/calico
[root@etcd2 ~]# cat > /etc/calico/calicoctl.cfg <<EOF
> apiVersion: v1
> kind: calicoApiConfig
> metadata:
> spec:
> datastoreType: "etcdv2"
> etcdEndpoints: "http://192.168.110.131:2379"
> EOF
[root@etcd2 ~]# cat /etc/calico/calicoctl.cfg
apiVersion: v1
kind: calicoApiConfig
metadata:
spec:
datastoreType: "etcdv2"
etcdEndpoints: "http://192.168.110.131:2379"
[root@etcd3 ~]# mkdir /etc/calico
[root@etcd3 ~]# cat > /etc/calico/calicoctl.cfg <<EOF
> apiVersion: v1
> kind: calicoApiConfig
> metadata:
> spec:
> datastoreType: "etcdv2"
> etcdEndpoints: "http://192.168.110.132:2379"
> EOF
[root@etcd3 ~]# cat /etc/calico/calicoctl.cfg
apiVersion: v1
kind: calicoApiConfig
metadata:
spec:
datastoreType: "etcdv2"
etcdEndpoints: "http://192.168.110.132:2379"创建目录放置calico镜像和工具。
[root@etcd1 ~]# mkdir etcd-calico
[root@etcd1 ~]# cd etcd-calico/calicoctl是calico命令行工具,calico-node-v2.tar是calico-node镜像包。
[root@etcd1 etcd-calico]# ls
calicoctl calico-node-v2.tar其他两个节点也需要这两个文件
[root@etcd1 etcd-calico]# scp ./* etcd2:/root/etcd-calico/
root@etcd2's password:
calicoctl 100% 31MB 98.1MB/s 00:00
calico-node-v2.tar 100% 269MB 29.9MB/s 00:09
[root@etcd1 etcd-calico]# scp ./* etcd3:/root/etcd-calico/
root@etcd3's password:
calicoctl 100% 31MB 96.3MB/s 00:00
calico-node-v2.tar 100% 269MB 67.3MB/s 00:04给calicoctl赋予可执行权限
[root@etcd1 etcd-calico]# chmod +x calicoctl
[root@etcd1 etcd-calico]# mv calicoctl /bin/加载镜像
[root@etcd1 etcd-calico]# docker load -i calico-node-v2.tar
df64d3292fd6: Loading layer [==================================================>] 4.672MB/4.672MB
d6f0e85be2d0: Loading layer [==================================================>] 8.676MB/8.676MB
c9818c503193: Loading layer [==================================================>] 250.9kB/250.9kB
1f748fca5871: Loading layer [==================================================>] 4.666MB/4.666MB
714c5990d9e8: Loading layer [==================================================>] 263.9MB/263.9MB
Loaded image: quay.io/calico/node:v2.6.12另外两个节点也是相同的操作。
[root@etcd2 ~]# mkdir etcd-calico
[root@etcd2 ~]# cd etcd-calico/
[root@etcd2 etcd-calico]# pwd
/root/etcd-calico
[root@etcd2 etcd-calico]# ls
calicoctl calico-node-v2.tar
[root@etcd2 etcd-calico]# chmod +x calicoctl
[root@etcd2 etcd-calico]# mv calicoctl /bin/
[root@etcd2 etcd-calico]# docker load -i calico-node-v2.tar
[root@etcd3 ~]# mkdir etcd-calico
[root@etcd3 ~]# cd etcd-calico/
[root@etcd3 etcd-calico]# ls
calicoctl calico-node-v2.tar
[root@etcd3 etcd-calico]# chmod +x calicoctl
[root@etcd3 etcd-calico]# mv calicoctl /bin/
[root@etcd3 etcd-calico]# docker load -i calico-node-v2.tar三个节点上都启动Calico node
[root@etcd1 etcd-calico]# calicoctl node run --node-image=quay.io/calico/node:v2.6.12 -c /etc/calico/calicoctl.cfg
Running command to load modules: modprobe -a xt_set ip6_tables
......
Running the following command to start calico-node:
docker run --net=host --privileged --name=calico-node -d --restart=always -e NODENAME=etcd1 -e CALICO_NETWORKING_BACKEND=bird -e CALICO_LIBNETWORK_ENABLED=true -e ETCD_ENDPOINTS=http://192.168.110.133:2379 -v /var/log/calico:/var/log/calico -v /var/run/calico:/var/run/calico -v /lib/modules:/lib/modules -v /run:/run -v /run/docker/plugins:/run/docker/plugins -v /var/run/docker.sock:/var/run/docker.sock quay.io/calico/node:v2.6.12
Image may take a short time to download if it is not available locally.
Container started, checking progress logs.
2022-02-16 08:00:06.363 [INFO][9] startup.go 173: Early log level set to info
......
2022-02-16 08:00:06.536 [INFO][14] client.go 202: Loading config from environment
Starting libnetwork service
Calico node started successfully每个节点都建立了一个calico-node容器
[root@etcd1 etcd-calico]# docker ps
CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES
ac7d48a378b6 quay.io/calico/node:v2.6.12 "start_runit" 57 seconds ago Up 56 seconds calico-node另外两个节点也启动Calico node
[root@etcd2 etcd-calico]# calicoctl node run --node-image=quay.io/calico/node:v2.6.12 -c /etc/calico/calicoctl.cfg
[root@etcd2 etcd-calico]# docker ps
CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES
bc99f286802f quay.io/calico/node:v2.6.12 "start_runit" About a minute ago Up About a minute calico-node
[root@etcd3 etcd-calico]# calicoctl node run --node-image=quay.io/calico/node:v2.6.12 -c /etc/calico/calicoctl.cfg
[root@etcd3 etcd-calico]# docker ps
CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES
07ba9ccdcd4d quay.io/calico/node:v2.6.12 "start_runit" About a minute ago Up About a minute calico-node因为我们是使用etcd保存数据的,可以看到对方的主机的信息。
[root@etcd1 etcd-calico]# calicoctl node status
Calico process is running.
IPv4 BGP status
+-----------------+-------------------+-------+----------+-------------+
| PEER ADDRESS | PEER TYPE | STATE | SINCE | INFO |
+-----------------+-------------------+-------+----------+-------------+
| 192.168.110.131 | node-to-node mesh | up | 08:00:13 | Established |
| 192.168.110.132 | node-to-node mesh | up | 08:00:14 | Established |
+-----------------+-------------------+-------+----------+-------------+
IPv6 BGP status
No IPv6 peers found.
[root@etcd2 etcd-calico]# calicoctl node status
Calico process is running.
IPv4 BGP status
+-----------------+-------------------+-------+----------+-------------+
| PEER ADDRESS | PEER TYPE | STATE | SINCE | INFO |
+-----------------+-------------------+-------+----------+-------------+
| 192.168.110.133 | node-to-node mesh | up | 08:00:13 | Established |
| 192.168.110.132 | node-to-node mesh | up | 08:00:14 | Established |
+-----------------+-------------------+-------+----------+-------------+
IPv6 BGP status
No IPv6 peers found.
[root@etcd3 etcd-calico]# calicoctl node status
Calico process is running.
IPv4 BGP status
+-----------------+-------------------+-------+----------+-------------+
| PEER ADDRESS | PEER TYPE | STATE | SINCE | INFO |
+-----------------+-------------------+-------+----------+-------------+
| 192.168.110.133 | node-to-node mesh | up | 08:00:15 | Established |
| 192.168.110.131 | node-to-node mesh | up | 08:00:15 | Established |
+-----------------+-------------------+-------+----------+-------------+
IPv6 BGP status
No IPv6 peers found.查看docker网络类型
[root@etcd1 etcd-calico]# docker network list
NETWORK ID NAME DRIVER SCOPE
2db83772936d bridge bridge local
3c0a5a224b09 host host local
422becf3aa3b none null local创建calico类型的网络,--driver calico 指定使用 calico 的 libnetwork CNM driver。 --ipam-driver calico-ipam 指定使用 calico 的 IPAM driver 管理 IP。 calico 为 global 网络,etcd 会将 calnet1 同步到所有主机。
[root@etcd1 etcd-calico]# docker network create --driver calico --ipam-driver calico-ipam calnet1
735f15b514db3a7310a7f3ef0734a6cd6b966753dc8cf0f7847305e0ba9fe51fcalico 为 global 网络,etcd 会将 calnet1 同步到所有主机。
[root@etcd1 etcd-calico]# docker network list
NETWORK ID NAME DRIVER SCOPE
2db83772936d bridge bridge local
735f15b514db calnet1 calico global
3c0a5a224b09 host host local
422becf3aa3b none null local
[root@etcd2 etcd-calico]# docker network list
NETWORK ID NAME DRIVER SCOPE
df0044c9f6f6 bridge bridge local
735f15b514db calnet1 calico global
03b08fa135f8 host host local
c19501b7ea7b none null local
[root@etcd3 etcd-calico]# docker network list
NETWORK ID NAME DRIVER SCOPE
331a6b638487 bridge bridge local
735f15b514db calnet1 calico global
08f90f4840c1 host host local
0d2160ce7298 none null local三个节点拉取busybox镜像用来创建容器
[root@etcd1 etcd-calico]# docker pull busybox
[root@etcd2 etcd-calico]# docker pull busybox
[root@etcd3 etcd-calico]# docker pull busybox三个节点上都创建一个容器,指定网络类型为calnet1
[root@etcd1 etcd-calico]# docker run --name c1 --net calnet1 -itd busybox
73359e36becf9859e073ebce9370b83ac36754f40356e53b82a1e2a8cd7b0066
[root@etcd2 etcd-calico]# docker run --name c2 --net calnet1 -itd busybox
28d27f3effb0ea15e6f5e6cca9e8982c68d24f459978098967842242478b6d8b
[root@etcd3 etcd-calico]# docker run --name c3 --net calnet1 -itd busybox
995241af841f2da4f69c7c3cfa2ce0766de49e7b43ec327f5dc8d57ff7838b62进入容器c1,查看网卡信息
[root@etcd1 etcd-calico]# docker exec -it c1 sh
/ # ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue qlen 1
link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00
inet 127.0.0.1/8 scope host lo
valid_lft forever preferred_lft forever
4: cali0@if5: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1500 qdisc noqueue
link/ether ee:ee:ee:ee:ee:ee brd ff:ff:ff:ff:ff:ff
inet 192.168.36.192/32 scope global cali0
valid_lft forever preferred_lft forever
/ # exit每在主机上创建一个容器,则会在物理机上创建一张虚拟网卡出来,注意:cali5aa980fa781@if4里的if4是容器里网卡的4,cali0@if5里的5是物理机网卡的5。从这里可以看到容器里的虚拟网卡 cali0 和物理机的 cali5aa980fa781 是 veth pair 关系。
[root@etcd1 etcd-calico]# ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN qlen 1
link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00
inet 127.0.0.1/8 scope host lo
valid_lft forever preferred_lft forever
inet6 ::1/128 scope host
valid_lft forever preferred_lft forever
2: ens32: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP qlen 1000
link/ether 00:0c:29:1e:33:3e brd ff:ff:ff:ff:ff:ff
inet 192.168.110.133/24 brd 192.168.110.255 scope global ens32
valid_lft forever preferred_lft forever
inet6 fe80::20c:29ff:fe1e:333e/64 scope link
valid_lft forever preferred_lft forever
3: docker0: <NO-CARRIER,BROADCAST,MULTICAST,UP> mtu 1500 qdisc noqueue state DOWN
link/ether 02:42:8b:19:bc:63 brd ff:ff:ff:ff:ff:ff
inet 172.17.0.1/16 brd 172.17.255.255 scope global docker0
valid_lft forever preferred_lft forever
5: cali5aa980fa781@if4: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UP
link/ether 9a:3d:aa:d2:bc:a2 brd ff:ff:ff:ff:ff:ff link-netnsid 0
inet6 fe80::983d:aaff:fed2:bca2/64 scope link
valid_lft forever preferred_lft forever另外两个节点也是类似的
[root@etcd2 etcd-calico]# docker exec -it c2 sh
/ # ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue qlen 1
......
4: cali0@if5: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1500 qdisc noqueue
link/ether ee:ee:ee:ee:ee:ee brd ff:ff:ff:ff:ff:ff
inet 192.168.57.64/32 scope global cali0
valid_lft forever preferred_lft forever
/ # exit
[root@etcd2 etcd-calico]# ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN qlen 1
......
valid_lft forever preferred_lft forever
5: cali2e3a79a8486@if4: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UP
link/ether ce:2a:7a:5f:4e:83 brd ff:ff:ff:ff:ff:ff link-netnsid 0
inet6 fe80::cc2a:7aff:fe5f:4e83/64 scope link
valid_lft forever preferred_lft forever
[root@etcd3 etcd-calico]# docker exec -it c3 sh
/ # ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue qlen 1
......
4: cali0@if5: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1500 qdisc noqueue
link/ether ee:ee:ee:ee:ee:ee brd ff:ff:ff:ff:ff:ff
inet 192.168.175.64/32 scope global cali0
valid_lft forever preferred_lft forever
/ # exit
[root@etcd3 etcd-calico]# ip a
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN qlen 1
......
5: califd96a41066a@if4: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UP
link/ether 2e:ca:96:03:96:83 brd ff:ff:ff:ff:ff:ff link-netnsid 0
inet6 fe80::2cca:96ff:fe03:9683/64 scope link
valid_lft forever preferred_lft forever使用route -n查看路由信息:
192.168.57.64 192.168.110.131 255.255.255.192 UG 0 0 0 ens32,表示在容器里ping 192.168.57.64这个地址,都会转发到192.168.110.131这台机器 ;
192.168.57.64 0.0.0.0 255.255.255.255 UH 0 0 0 cali2e3a79a8486,表示目的地址是192.168.57.64的数据包,转发到cali2e3a79a8486这张网卡 。
cali2e3a79a8486和容器里的网卡cali0是veth pair 关系,所以就可以从容器c1访问到容器c2,其他以此类推,calico相当于建立了一个隧道,可以在物理机A的c1容器访问物理机B的c2容器。
[root@etcd1 etcd-calico]# route -n
Kernel IP routing table
Destination Gateway Genmask Flags Metric Ref Use Iface
0.0.0.0 192.168.110.2 0.0.0.0 UG 0 0 0 ens32
169.254.0.0 0.0.0.0 255.255.0.0 U 1002 0 0 ens32
172.17.0.0 0.0.0.0 255.255.0.0 U 0 0 0 docker0
192.168.36.192 0.0.0.0 255.255.255.255 UH 0 0 0 cali5aa980fa781
192.168.36.192 0.0.0.0 255.255.255.192 U 0 0 0 *
192.168.57.64 192.168.110.131 255.255.255.192 UG 0 0 0 ens32
192.168.110.0 0.0.0.0 255.255.255.0 U 0 0 0 ens32
192.168.175.64 192.168.110.132 255.255.255.192 UG 0 0 0 ens32在容器c1里,ping c2容器可以ping通。
[root@etcd1 etcd-calico]# docker exec -it c1 sh
/ # ping 192.168.57.64
PING 192.168.57.64 (192.168.57.64): 56 data bytes
64 bytes from 192.168.57.64: seq=0 ttl=62 time=0.578 ms
64 bytes from 192.168.57.64: seq=1 ttl=62 time=0.641 ms
64 bytes from 192.168.57.64: seq=2 ttl=62 time=0.543 ms
^C
--- 192.168.57.64 ping statistics ---
3 packets transmitted, 3 packets received, 0% packet loss
round-trip min/avg/max = 0.543/0.587/0.641 ms
/ # exit在物理机上ping不通容器c2。
[root@etcd1 etcd-calico]# ping 192.168.57.64
PING 192.168.57.64 (192.168.57.64) 56(84) bytes of data.
^C
--- 192.168.57.64 ping statistics ---
6 packets transmitted, 0 received, 100% packet loss, time 5000ms看下路由的关系:不管目的地是哪里都走 cali0。
[root@etcd1 etcd-calico]# docker exec c1 ip route
default via 169.254.1.1 dev cali0
169.254.1.1 dev cali0 scope link看下etcd1 的路由,目的地址到 192.168.36.192 的数据包都从 cali5aa980fa781(etcd1 新产生的虚拟网卡)走,目的地址到 192.168.57.64/26 网段的数据包都从 ens32 发到 192.168.110.131 上去,每台主机都知道不同的容器在哪台主机上,所以会动态的设置路由。
[root@etcd1 etcd-calico]# ip route
default via 192.168.110.2 dev ens32
169.254.0.0/16 dev ens32 scope link metric 1002
172.17.0.0/16 dev docker0 proto kernel scope link src 172.17.0.1
192.168.36.192 dev cali5aa980fa781 scope link
blackhole 192.168.36.192/26 proto bird
192.168.57.64/26 via 192.168.110.131 dev ens32 proto bird
192.168.110.0/24 dev ens32 proto kernel scope link src 192.168.110.133
192.168.175.64/26 via 192.168.110.132 dev ens32 proto bird七.Kubernetes(k8s)环境里的calico
在k8s环境里,每个节点上都有calico-node,calico数据存在etcd里。
[root@k8scloude1 ~]# kubectl get pod -o wide -n kube-system
NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES
calico-kube-controllers-6b9fbfff44-4jzkj 1/1 Running 55 38d 10.244.251.210 k8scloude3 <none> <none>
calico-node-bdlgm 1/1 Running 27 38d 192.168.110.130 k8scloude1 <none> <none>
calico-node-hx8bk 1/1 Running 27 38d 192.168.110.128 k8scloude3 <none> <none>
calico-node-nsbfs 1/1 Running 27 38d 192.168.110.129 k8scloude2 <none> <none>
coredns-545d6fc579-7wm95 1/1 Running 27 38d 10.244.158.121 k8scloude1 <none> <none>
coredns-545d6fc579-87q8j 1/1 Running 27 38d 10.244.158.122 k8scloude1 <none> <none>
etcd-k8scloude1 1/1 Running 27 38d 192.168.110.130 k8scloude1 <none> <none>
kube-apiserver-k8scloude1 1/1 Running 18 27d 192.168.110.130 k8scloude1 <none> <none>
kube-controller-manager-k8scloude1 1/1 Running 29 38d 192.168.110.130 k8scloude1 <none> <none>
kube-proxy-599xh 1/1 Running 27 38d 192.168.110.128 k8scloude3 <none> <none>
kube-proxy-lpj8z 1/1 Running 27 38d 192.168.110.129 k8scloude2 <none> <none>
kube-proxy-zxlk9 1/1 Running 27 38d 192.168.110.130 k8scloude1 <none> <none>
kube-scheduler-k8scloude1 1/1 Running 29 38d 192.168.110.130 k8scloude1 <none> <none>
metrics-server-bcfb98c76-n4fnb 1/1 Running 26 30d 10.244.251.196 k8scloude3 <none> <none>八.总结
本文介绍了CNI网络插件的概念和常见的几种插件对比,详细讲解了如何使用Calico实现Docker容器跨主机互联。通过使用Calico,我们可以轻松地在Kubernetes集群中实现高效的容器网络互连,提升应用程序的可靠性和可扩展性。
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