Kubernetes中的网络
1、引子
既然Kubernetes中将容器的联网经过插件的方式来实现,那么该如何解决这个的联网问题呢?node
若是你在本地单台机器上运行docker容器的话注意到全部容器都会处在docker0网桥自动分配的一个网络IP段内(172.17.0.1/16。该值能够经过docker启动参数 --bip来设置。这样全部本地的全部的容器都拥有了一个IP地址,并且仍是在一个网段内彼此就能够互相通讯来。linux
可是Kubernetes管理的是集群,Kubernetes中的网络要解决的核心问题就是每台主机的IP地址网段划分,以及单个容器的IP地址分配。归纳为:git
- 保证每一个Pod拥有一个集群内惟一的IP地址
- 保证不一样节点的IP地址划分不会重复
- 保证垮节点的Pod能够互相通讯
- 保证不一样节点的Pod能够与垮节点的主机互相通讯
为了解决该问题,出现了一系列开源的Kubetnetes中的网络插件与方案,如:github
- flannel
- calico
- contiv
- weava net
- kube-router
- cilium
- canal
2、Kubernetes中的网络解析-flannel
咱们已经安装了拥有三个节点的Kubernetes集群,节点的状态以下:docker
[root@node1 ~]# kubectl get nodes -o wide NAME STATUS ROLES AGE VERSION EXTERNAL-IP OS-IMAGE KERNEL-VERSION CONTAINER-RUNTIME node1 Ready <none> 2d v1.9.1 <none> CentOS Linux 7 (Core) 3.10.0-693.11.6.el7.x86_64 docker://1.12.6 node2 Ready <none> 2d v1.9.1 <none> CentOS Linux 7 (Core) 3.10.0-693.11.6.el7.x86_64 docker://1.12.6 node3 Ready <none> 2d v1.9.1 <none> CentOS Linux 7 (Core) 3.10.0-693.11.6.el7.x86_64 docker://1.12.6
当前Kubetnetes集群中运行的全部Pod信息centos
[root@node1 ~]# kubectl get pods --all-namespaces -o wide NAMESPACE NAME READY STATUS RESTARTS AGE IP NODE kube-system coredns-5984fb8cbb-sjqv9 1/1 Running 0 1h 172.33.68.2 node1 kube-system coredns-5984fb8cbb-tkfrc 1/1 Running 1 1h 172.33.96.3 node3 kube-system heapster-v1.5.0-684c7f9488-z6sdz 4/4 Running 0 1h 172.33.31.3 node2 kube-system kubernetes-dashboard-6b66b8b96c-mnm2c 1/1 Running 0 1h 172.33.31.2 node2 kube-system monitoring-influxdb-grafana-v4-54b7854697-tw9cd 2/2 Running 2 1h 172.33.96.2 node3
当前etcd中的注册的宿主机的pod地址网段信息:安全
[root@node1 ~]# etcdctl ls /kube-centos/network/subnets /kube-centos/network/subnets/172.33.68.0-24 /kube-centos/network/subnets/172.33.31.0-24 /kube-centos/network/subnets/172.33.96.0-24
而每一个node上的Pod子网是根据咱们在安装flannel时配置来划分的,在etcd中查看该配置:网络
[root@node1 ~]# etcdctl get /kube-centos/network/config
{"Network":"172.33.0.0/16","SubnetLen":24,"Backend":{"Type":"host-gw"}}
咱们知道Kubernets集群内部存在三类IP,分别是:架构
- Node IP:宿主机的IP地址
- Pod IP:使用网络插件建立的IP(如:flannel),该跨主机的Pod能够互通
- Cluster IP:虚拟IP,经过iptables规则访问服务
在安装node节点的时候,节点上的进程是按照flannel-->docker--->kubelet--->kube-proxy的顺序启动,flannnel的网络划分和如何与docker交互,如何经过iptables访问service。app
Flannel
Flannel是做为一个二进制文件的方式部署在每一个node上,主要实现两个功能:
- 为每一个node分配subnet,容器将自动从该子网中获取IP地址
- 当有node加入到网络中时,为每一个node增长路由配置
下面是使用 host -gw backend的flannel网络架构图:
Node1上的flannel配置以下:
[root@node1 ~]# cat /usr/lib/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 $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
其中有两个环境变量文件的配置以下:
[root@node1 ~]# cat /etc/sysconfig/flanneld # Flanneld configuration options FLANNEL_ETCD_ENDPOINTS="http://172.17.8.101:2379" FLANNEL_ETCD_PREFIX="/kube-centos/network" FLANNEL_OPTIONS="-iface=eth2"
上面的配置文件仅供flanneld使用。
[root@node1 ~]# cat /etc/sysconfig/docker-network # /etc/sysconfig/docker-network DOCKER_NETWORK_OPTIONS=
还有一个ExecStartPost=/usr/libexec/flannel/mk-docker-opts.sh -k DOCKER_NETWORK_OPTIONS -d /run/flannel/docker,其中的/usr/libexec/flannel/mk-docker-opts.sh脚本是在flanneld启动后运行,将会生成两个环境变量配置文件:
- /run/flannel/docker
- /run/flannel/subnet.env
咱们再来看下/run/flannel/docker的配置。
[root@node1 ~]# cat /run/flannel/docker DOCKER_OPT_BIP="--bip=172.33.68.1/24" DOCKER_OPT_IPMASQ="--ip-masq=true" DOCKER_OPT_MTU="--mtu=1500" DOCKER_NETWORK_OPTIONS=" --bip=172.33.68.1/24 --ip-masq=true --mtu=1500"
若是你使用systemctl命令先启动flannel后启动docker的话,docker将会读取以上环境变量。
咱们再来看下/run/flannel/subnet.env的配置。
[root@node1 ~]# cat /run/flannel/subnet.env FLANNEL_NETWORK=172.33.0.0/16 FLANNEL_SUBNET=172.33.68.1/24 FLANNEL_MTU=1500 FLANNEL_IPMASQ=false
以上环境变量是flannel向etcd中注册的。
Docker
Node1的docker配置以下:
[root@node1 ~]# cat /usr/lib/systemd/system/docker.service
[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/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 \
$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
MountFlags=slave
KillMode=process
[Install]
WantedBy=multi-user.target
查看Node1上的docker启动参数:
[root@node1 ~]# systemctl status -l docker
● docker.service - Docker Application Container Engine
Loaded: loaded (/usr/lib/systemd/system/docker.service; enabled; vendor preset: disabled)
Drop-In: /usr/lib/systemd/system/docker.service.d
└─flannel.conf
Active: active (running) since Fri 2018-02-02 22:52:43 CST; 2h 28min ago
Docs: http://docs.docker.com
Main PID: 4334 (dockerd-current)
CGroup: /system.slice/docker.service
‣ 4334 /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 --selinux-enabled --log-driver=journald --signature-verification=false --bip=172.33.68.1/24 --ip-masq=true --mtu=1500
咱们能够看到在docker在启动时有以下参数:--bip=172.33.68.1/24 --ip-masq=true --mtu=1500。上述参数flannel启动时运行的脚本生成的,经过环境变量传递过来的。
咱们查看下node1宿主机上的网络接口:
[root@node1 ~]# ip addr
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: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP qlen 1000
link/ether 52:54:00:00:57:32 brd ff:ff:ff:ff:ff:ff
inet 10.0.2.15/24 brd 10.0.2.255 scope global dynamic eth0
valid_lft 85095sec preferred_lft 85095sec
inet6 fe80::5054:ff:fe00:5732/64 scope link
valid_lft forever preferred_lft forever
3: eth1: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP qlen 1000
link/ether 08:00:27:7b:0f:b1 brd ff:ff:ff:ff:ff:ff
inet 172.17.8.101/24 brd 172.17.8.255 scope global eth1
valid_lft forever preferred_lft forever
4: eth2: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP qlen 1000
link/ether 08:00:27:ef:25:06 brd ff:ff:ff:ff:ff:ff
inet 172.30.113.231/21 brd 172.30.119.255 scope global dynamic eth2
valid_lft 85096sec preferred_lft 85096sec
inet6 fe80::a00:27ff:feef:2506/64 scope link
valid_lft forever preferred_lft forever
5: docker0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UP
link/ether 02:42:d0:ae:80:ea brd ff:ff:ff:ff:ff:ff
inet 172.33.68.1/24 scope global docker0
valid_lft forever preferred_lft forever
inet6 fe80::42:d0ff:feae:80ea/64 scope link
valid_lft forever preferred_lft forever
7: veth295bef2@if6: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue master docker0 state UP
link/ether 6a:72:d7:9f:29:19 brd ff:ff:ff:ff:ff:ff link-netnsid 0
inet6 fe80::6872:d7ff:fe9f:2919/64 scope link
valid_lft forever preferred_lft forever
咱们分类来解释下该虚拟机中的网络接口。
- lo:回环网络,127.0.0.1
- eth0:NAT网络,虚拟机建立时自动分配,仅能够在几台虚拟机之间访问
- eth1:bridge网络,使用vagrant分配给虚拟机的地址,虚拟机之间和本地电脑均可以访问
- eth2:bridge网络,使用DHCP分配,用于访问互联网的网卡
- docker0:bridge网络,docker默认使用的网卡,做为该节点上全部容器的虚拟交换机
- veth295bef2@if6:veth pair,链接docker0和Pod中的容器。veth pair能够理解为使用网线链接好的两个接口,把两个端口放到两个namespace中,那么这两个namespace就能打通。
咱们再看下该节点的docker上有哪些网络。
[root@node1 ~]# docker network ls NETWORK ID NAME DRIVER SCOPE 940bb75e653b bridge bridge local d94c046e105d host host local 2db7597fd546 none null local
再检查下bridge网络940bb75e653b的信息。
[root@node1 ~]# docker network inspect 940bb75e653b
[
{
"Name": "bridge",
"Id": "940bb75e653bfa10dab4cce8813c2b3ce17501e4e4935f7dc13805a61b732d2c",
"Scope": "local",
"Driver": "bridge",
"EnableIPv6": false,
"IPAM": {
"Driver": "default",
"Options": null,
"Config": [
{
"Subnet": "172.33.68.1/24",
"Gateway": "172.33.68.1"
}
]
},
"Internal": false,
"Containers": {
"944d4aa660e30e1be9a18d30c9dcfa3b0504d1e5dbd00f3004b76582f1c9a85b": {
"Name": "k8s_POD_coredns-5984fb8cbb-sjqv9_kube-system_c5a2e959-082a-11e8-b4cd-525400005732_0",
"EndpointID": "7397d7282e464fc4ec5756d6b328df889cdf46134dbbe3753517e175d3844a85",
"MacAddress": "02:42:ac:21:44:02",
"IPv4Address": "172.33.68.2/24",
"IPv6Address": ""
}
},
"Options": {
"com.docker.network.bridge.default_bridge": "true",
"com.docker.network.bridge.enable_icc": "true",
"com.docker.network.bridge.enable_ip_masquerade": "true",
"com.docker.network.bridge.host_binding_ipv4": "0.0.0.0",
"com.docker.network.bridge.name": "docker0",
"com.docker.network.driver.mtu": "1500"
},
"Labels": {}
}
]
咱们能够看到该网络中的Config与docker的启动配置相符。
Node1上运行的容器:
[root@node1 ~]# docker ps CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES a37407a234dd docker.io/coredns/coredns@sha256:adf2e5b4504ef9ffa43f16010bd064273338759e92f6f616dd159115748799bc "/coredns -conf /etc/" About an hour ago Up About an hour k8s_coredns_coredns-5984fb8cbb-sjqv9_kube-system_c5a2e959-082a-11e8-b4cd-525400005732_0 944d4aa660e3 docker.io/openshift/origin-pod "/usr/bin/pod" About an hour ago Up About an hour k8s_POD_coredns-5984fb8cbb-sjqv9_kube-system_c5a2e959-082a-11e8-b4cd-525400005732_0
咱们能够看到当前已经有2个容器在运行。
Node1上的路由信息:
[root@node1 ~]# route -n Kernel IP routing table Destination Gateway Genmask Flags Metric Ref Use Iface 0.0.0.0 10.0.2.2 0.0.0.0 UG 100 0 0 eth0 0.0.0.0 172.30.116.1 0.0.0.0 UG 101 0 0 eth2 10.0.2.0 0.0.0.0 255.255.255.0 U 100 0 0 eth0 172.17.8.0 0.0.0.0 255.255.255.0 U 100 0 0 eth1 172.30.112.0 0.0.0.0 255.255.248.0 U 100 0 0 eth2 172.33.68.0 0.0.0.0 255.255.255.0 U 0 0 0 docker0 172.33.96.0 172.30.118.65 255.255.255.0 UG 0 0 0 eth2
以上路由信息是由flannel添加的,当有新的节点加入Kubernetes集群中后,每一个节点上的路由表都将增长。
咱们在node上来traceroute下node3上的coredns-5984fb8cbb-tkfrc容器,其IP地址是172.33.96.3,看看其路由信息。
[root@node1 ~]# traceroute 172.33.96.3 traceroute to 172.33.96.3 (172.33.96.3), 30 hops max, 60 byte packets 1 172.30.118.65 (172.30.118.65) 0.518 ms 0.367 ms 0.398 ms 2 172.33.96.3 (172.33.96.3) 0.451 ms 0.352 ms 0.223 ms
咱们看到路由直接通过node3的公网IP后就到达了node3节点上的Pod。
Node1的iptables信息:
[root@node1 ~]# iptables -L Chain INPUT (policy ACCEPT) target prot opt source destination KUBE-FIREWALL all -- anywhere anywhere KUBE-SERVICES all -- anywhere anywhere /* kubernetes service portals */ Chain FORWARD (policy ACCEPT) target prot opt source destination KUBE-FORWARD all -- anywhere anywhere /* kubernetes forward rules */ DOCKER-ISOLATION all -- anywhere anywhere DOCKER all -- anywhere anywhere ACCEPT all -- anywhere anywhere ctstate RELATED,ESTABLISHED ACCEPT all -- anywhere anywhere ACCEPT all -- anywhere anywhere Chain OUTPUT (policy ACCEPT) target prot opt source destination KUBE-FIREWALL all -- anywhere anywhere KUBE-SERVICES all -- anywhere anywhere /* kubernetes service portals */ Chain DOCKER (1 references) target prot opt source destination Chain DOCKER-ISOLATION (1 references) target prot opt source destination RETURN all -- anywhere anywhere Chain KUBE-FIREWALL (2 references) target prot opt source destination DROP all -- anywhere anywhere /* kubernetes firewall for dropping marked packets */ mark match 0x8000/0x8000 Chain KUBE-FORWARD (1 references) target prot opt source destination ACCEPT all -- anywhere anywhere /* kubernetes forwarding rules */ mark match 0x4000/0x4000 ACCEPT all -- 10.254.0.0/16 anywhere /* kubernetes forwarding conntrack pod source rule */ ctstate RELATED,ESTABLISHED ACCEPT all -- anywhere 10.254.0.0/16 /* kubernetes forwarding conntrack pod destination rule */ ctstate RELATED,ESTABLISHED Chain KUBE-SERVICES (2 references) target prot opt source destination
3、Kubernetes中的网络解析-calico
概述
Calico建立和管理一个扁平的三层网络(不须要overlay),每一个容器会分配一个可路由的ip。因为通讯时不须要解包和封包,网络性能消耗小,易于排查,且易于水平扩展。
小规模部署时能够经过bgp client直接互联,大规模下可经过指定的BGP route reflector来完成,这样保证全部的数据流量都是经过IP路由的方式完成互联的。Calico基于iptables还提供了丰富而灵活的网络Policy,保证经过各个节点上的ACLs来提供Workload的多租户隔离,安全组以及其余可达性限制等功能。
Calico架构
calico主要由Felix,etcd,BGP client,BGP Route Reflector组成。
- Etcd:负责存储网络信息
- BGP client:负责将Felix配置的路由信息分发到其余节点
- Felix:Calico Agent,每一个节点都须要运行,主要负责配置路由、配置ACLs、报告状态
- BGP Route Reflector:大规模部署时须要用到,做为BGP client的中心链接点,能够避免每一个节点互联
部署
mkdir /etc/cni/net.d/ kubectl apply -f https://docs.projectcalico.org/v3.0/getting-started/kubernetes/installation/rbac.yaml wget https://docs.projectcalico.org/v3.0/getting-started/kubernetes/installation/hosted/calico.yaml 修改etcd_endpoints的值和默认的192.168.0.0/16(不能和已有网段冲突) kubectl apply -f calico.yaml wget https://github.com/projectcalico/calicoctl/releases/download/v2.0.0/calicoctl mv calicoctl /usr/loca/bin && chmod +x /usr/local/bin/calicoctl calicoctl get ippool calicoctl get node
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