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使用nomad在weave网络中部署工作负载

四月 20, 2019
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当初Kubernetes网络的设计目标是使得开发者使用pod时在网络这一层面可以像使用传统物理主机或虚拟机一样。具体的基本要求如下：

所有pod间均应可以在无需NAT的情况下直接通信；
所有集群节点与所有集群的Pod之间均应可以在无需NAT的情况下直接通信；
容器自身的地址和其他pod看到的它的地址是同一个地址；

按照这样的要求，集群中的每个pod都在一个平坦的、共享网络命名空间中，并且每个Pod都拥有一个IP，通信时无需端口映射。用户也需要额外考虑如何建立Pod之间的连接，也不需要考虑将容器端口映射到主机端口等问题。基于这些要求而实现的k8s pod网络模型，将具有向后兼容的特性，可以使得Pod从某些角度上可以被看成是一个传统的物理主机或vm来对待。

在《使用nomad实现集群管理和微服务部署调度》一文中，我们看到nomad部署调度的driver为docker的服务实例都是通过主机和容器间的端口映射来对外提供服务的。服务实例多的时候，大量服务端口出现在眼前，我们很难用端口判断这是什么服务。并且通过映射端口暴露服务有局限，对于那些需要映射到主机固定端口的服务来说，很可能存在与其他服务的端口冲突而导致部署失败。除此之外，这种端口映射的方式还缺少隔离的作用，所有实例暴露的端口在同一个全局网络空间。

nomad是否可以像k8s一样将服务实例部署到overlay网络中从而实现每个服务实例所在container可以被看成一个独立的vm；并且我们还可以通过划分overlay的网段来隔离，实现某种意义上的“多租户”呢？在本篇文章中，我们来试验一下上述想法是否可行。

一、搭建试验环境

我们这次在一个VirtualBox搭建的三节点环境中进行验证。如果小伙伴对这段很熟悉，或者有现成的环境可用，那么可以跳过这一小节。另外这节不是重点，我不会对这个过程用过多文字做解释。

1. 创建虚机，组建网络

我们在一台ubuntu 18.04 desktop版本主机上搭建环境，所使用的软件版本信息如下：

VirtualBox: 5.2.18
Guest OS: Ubuntu 16.04.6 LTS (GNU/Linux 4.4.0-142-generic x86_64)

组件环境的虚拟机和网络拓扑示意图如下：

img{512x368}

如上图所示：三个vm 通过连入host-only网络(vboxnet0)实现内网通；通过连入NAT网络（NatNetwork）实现外网通。（怪异：在windows上的virtualbox实际上通过natnetwork即可实现全通的，无需host-only network，但是在ubuntu下居然不行）。

每个vm中网络配置如下：

# cat /etc/network/interfaces

# This file describes the network interfaces available on your system
# and how to activate them. For more information, see interfaces(5).

source /etc/network/interfaces.d/*

# The loopback network interface
auto lo
iface lo inet loopback

# The primary network interface
auto enp0s3
iface enp0s3 inet dhcp

auto enp0s8
iface enp0s8 inet dhcp

保存后，执行/etc/init.d/networking restart生效。

另外每个vm上安装了openssh-server(apt install openssh-server)并设置root可登陆。三个vm的主机名分为为u1、u2和u3（可通过hostnamectl –static set-hostname u1设置。并在/etc/hosts中添加主机名和内网IP的对应关系）。

每台主机上安装了docker引擎(通过apt install docker.io安装），docker版本信息如下：

# docker version
Client:
 Version:           18.09.2
 API version:       1.39
 Go version:        go1.10.4
 Git commit:        6247962
 Built:             Tue Feb 26 23:56:24 2019
 OS/Arch:           linux/amd64
 Experimental:      false

Server:
 Engine:
  Version:          18.09.2
  API version:      1.39 (minimum version 1.12)
  Go version:       go1.10.4
  Git commit:       6247962
  Built:            Tue Feb 12 22:47:29 2019
  OS/Arch:          linux/amd64
  Experimental:     false

二、使用weave创建跨节点的overlay network

我们选择weave作为overlay network的实现。

1. 安装weave

我们在每个vm节点上安装目前最新版本的weave，以一个节点为例：

# curl -L git.io/weave -o /usr/local/bin/weave
  % Total    % Received % Xferd  Average Speed   Time    Time     Time  Current
                                 Dload  Upload   Total   Spent    Left  Speed
  0     0    0     0    0     0      0      0 --:--:--  0:00:01 --:--:--     0
  0     0    0     0    0     0      0      0 --:--:--  0:00:02 --:--:--     0
100   595    0   595    0     0     62      0 --:--:--  0:00:09 --:--:--   137
100 52227  100 52227    0     0   4106      0  0:00:12  0:00:12 --:--:-- 21187

# chmod a+x /usr/local/bin/weave

# weave version
weave script 2.5.1

... ...

通过weave setup预先将weave相关的容器Image下载到各个节点，为后面的weave launch所使用。

# weave setup

2.5.1: Pulling from weaveworks/weave
... ...
c458f7a37ca6: Pull complete
Digest: sha256:a170dd93fa7e678cc37919ffd65601d1015da6c3f10878534ac237381ea0db19
Status: Downloaded newer image for weaveworks/weave:2.5.1
2.5.1: Pulling from weaveworks/weaveexec
... ...
c11f30d06b58: Pull complete
Digest: sha256:ad53aaabf648548ec26cceac3ab49394778322e1623f0d184a2b74ad06338087
Status: Downloaded newer image for weaveworks/weaveexec:2.5.1
latest: Pulling from weaveworks/weavedb
9b0681f946a1: Pull complete
Digest: sha256:c280cf4e7208f4ca0d2514539e0f476dd12db70beacdc368793b7736de023d8d
Status: Downloaded newer image for weaveworks/weavedb:latest

2. 启动跨多节点(peer) weave network

weave的一个优点是建立跨节点overlay network时并不需要一个外部的存储(比如etcd），位于多个节点上的weave进程会自动同步相关信息。而且weave支持动态向weave overlay network中添加节点。

我们来初始化这个由三个vm节点构成的weave overlay network：

root@u1:~# weave launch --no-dns 192.168.56.4 192.168.56.5
78f459a4a8acc07d46c1f86a15a519b91978c809876452b9d9c1294e760394a9

root@u2:~# weave launch --no-dns 192.168.56.3 192.168.56.5
1f379e50f3917e05bd133589f75594d7b2da20a680bb1e5e7172e37a18abe3ff

root@u3:~# weave launch --no-dns 192.168.56.3 192.168.56.4
aa600bfad8db8711e2cbc5f8e127022460ca3738226dd7aa33bb5b9b049f8cee

执行完上面命令后，在任意一个vm节点上执行下面命令，查看节点weave之间的连接状态：

root@u1:~# weave status connections
<- 192.168.56.4:54715    established fastdp 8e:d8:ad:a8:32:eb(u2) mtu=1376
<- 192.168.56.5:51504    established fastdp f6:58:43:5c:68:d7(u3) mtu=1376

我们看到u1节点已经和u2、u3节点成功建立了连接，weave的工作模式是fastdp(fast data path)，mtu为默认的1376（适当调节weave mtu可以提升weave overlay network的网络性能）。
我们也可以通过weave status命令查看一下weave网络的整体状态：

# weave status

        Version: 2.5.1 (up to date; next check at 2019/04/18 12:35:41)

        Service: router
       Protocol: weave 1..2
           Name: f6:58:43:5c:68:d7(u3)
     Encryption: disabled
  PeerDiscovery: enabled
        Targets: 3
    Connections: 3 (2 established, 1 failed)
          Peers: 3 (with 6 established connections)
 TrustedSubnets: none

        Service: ipam
         Status: ready
          Range: 10.32.0.0/12
  DefaultSubnet: 10.32.0.0/12

        Service: dns
         Domain: weave.local.
       Upstream: 10.0.3.3
            TTL: 1
        Entries: 0

        Service: proxy
        Address: unix:///var/run/weave/weave.sock

        Service: plugin (legacy)
     DriverName: weave

3. 在weave overlay network中创建container并测试overlay网内container的互通性

我们通过为docker指定net driver为weave的方式让docker在weave overlay network中创建container：

root@u1:~# docker run -ti --net=weave busybox /bin/sh

root@u2:~# docker run -ti --net=weave busybox /bin/sh

root@u3:~# docker run -ti --net=weave busybox /bin/sh

我们在u1上启动的容器内去ping位于其他两个vm上启动的新容器：

/ # ping -c 3 10.32.0.1
PING 10.32.0.1 (10.32.0.1): 56 data bytes
64 bytes from 10.32.0.1: seq=0 ttl=64 time=1.540 ms
64 bytes from 10.32.0.1: seq=1 ttl=64 time=1.548 ms
64 bytes from 10.32.0.1: seq=2 ttl=64 time=1.434 ms

--- 10.32.0.1 ping statistics ---
3 packets transmitted, 3 packets received, 0% packet loss
round-trip min/avg/max = 1.434/1.507/1.548 ms

/ # ping -c 3 10.46.0.0
PING 10.46.0.0 (10.46.0.0): 56 data bytes
64 bytes from 10.46.0.0: seq=0 ttl=64 time=5.118 ms
64 bytes from 10.46.0.0: seq=1 ttl=64 time=1.608 ms
64 bytes from 10.46.0.0: seq=2 ttl=64 time=1.837 ms

--- 10.46.0.0 ping statistics ---
3 packets transmitted, 3 packets received, 0% packet loss
round-trip min/avg/max = 1.608/2.854/5.118 ms

我们看到位于weave overlay network中的三个容器是连通的。

4. 测试host到weave overlay网络中容器的连通性

考虑到后续host上的consul会对部署在weave overlay network中的container中的服务做health check，因此需要在host上能连通位于overlay network中的container。

我们来测试一下：

root@u1:~# docker run -ti --net=weave busybox /bin/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
29: ethwe0@if30: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1376 qdisc noqueue
    link/ether aa:8f:45:8f:5f:d6 brd ff:ff:ff:ff:ff:ff
    inet 10.40.0.0/12 brd 10.47.255.255 scope global ethwe0
       valid_lft forever preferred_lft forever
31: eth0@if32: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1500 qdisc noqueue
    link/ether 02:42:ac:12:00:02 brd ff:ff:ff:ff:ff:ff
    inet 172.18.0.2/16 brd 172.18.255.255 scope global eth0
       valid_lft forever preferred_lft forever

root@u1:~# ping 10.40.0.0
PING 10.40.0.0 (10.40.0.0) 56(84) bytes of data.

^C
--- 10.40.0.0 ping statistics ---
4 packets transmitted, 0 received, 100% packet loss, time 3024ms

从测试结果来看，在host无法ping通位于weave network上的container。这个问题实则也显而易见，因为当前host上的路由表中没有以weave网络range: 10.32.0.0/12为目的地址的路由，并且weave网络设备也并未启用ip地址：

root@u1:~# ip route
default via 10.0.3.2 dev enp0s8
10.0.3.0/24 dev enp0s8  proto kernel  scope link  src 10.0.3.15
172.17.0.0/16 dev docker0  proto kernel  scope link  src 172.17.0.1
172.18.0.0/16 dev docker_gwbridge  proto kernel  scope link  src 172.18.0.1
192.168.56.0/24 dev enp0s3  proto kernel  scope link  src 192.168.56.3

关于这个问题，weave官方给出了答案：我们可以通过weave expose命令自动为主机上的weave设备分配ip地址，添加到10.32.0.0/12的路由。

root@u1:~# weave expose
10.40.0.1

root@u1:~# ip a

.... ...

7: weave: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1376 qdisc noqueue state UP group default qlen 1000
    link/ether b2:97:b5:7b:0f:a9 brd ff:ff:ff:ff:ff:ff
    inet 10.40.0.1/12 brd 10.47.255.255 scope global weave
       valid_lft forever preferred_lft forever
    inet6 fe80::b097:b5ff:fe7b:fa9/64 scope link
       valid_lft forever preferred_lft forever

.... ...

root@u1:~# ip route
default via 10.0.3.2 dev enp0s8
10.0.3.0/24 dev enp0s8  proto kernel  scope link  src 10.0.3.15
10.32.0.0/12 dev weave  proto kernel  scope link  src 10.40.0.1
172.17.0.0/16 dev docker0  proto kernel  scope link  src 172.17.0.1
172.18.0.0/16 dev docker_gwbridge  proto kernel  scope link  src 172.18.0.1
192.168.56.0/24 dev enp0s3  proto kernel  scope link  src 192.168.56.3

我们看到在u1节点上执行完expose之后，weave设备拥有了自己的ip地址，并且主机路由表中也增加了10.32.0.0/12网络的路由。我们再来测试一下u1上主机到container是否通了：

root@u1:~# ping 10.40.0.0
PING 10.40.0.0 (10.40.0.0) 56(84) bytes of data.
64 bytes from 10.40.0.0: icmp_seq=1 ttl=64 time=4.42 ms

64 bytes from 10.40.0.0: icmp_seq=2 ttl=64 time=1.04 ms
64 bytes from 10.40.0.0: icmp_seq=3 ttl=64 time=1.21 ms
^C
--- 10.40.0.0 ping statistics ---
3 packets transmitted, 3 received, 0% packet loss, time 2003ms
rtt min/avg/max/mdev = 1.048/2.228/4.425/1.554 ms

网络已经打通。我们继续在u2、u3两个节点上执行weave expose，这样三台主机都可以通过网络reach到位于任何一台主机上的、weave network中的container。

而从container到host，原本就可以访问，以u1上的container为例：

/ # ping 192.168.56.3
PING 192.168.56.3 (192.168.56.3): 56 data bytes
64 bytes from 192.168.56.3: seq=0 ttl=64 time=0.345 ms
^C
--- 192.168.56.3 ping statistics ---
1 packets transmitted, 1 packets received, 0% packet loss
round-trip min/avg/max = 0.345/0.345/0.345 ms

/ # ping 192.168.56.4
PING 192.168.56.4 (192.168.56.4): 56 data bytes
64 bytes from 192.168.56.4: seq=0 ttl=63 time=1.277 ms
^C
--- 192.168.56.4 ping statistics ---
1 packets transmitted, 1 packets received, 0% packet loss
round-trip min/avg/max = 1.277/1.277/1.277 ms

三、安装consul和nomad集群

在《使用nomad实现集群管理和微服务部署调度》一文中，我们已经详细说过consul和nomad的安装配置过程，这里仅列出步骤，不再详细说明。已经有环境的朋友可以略过该步骤！

1. 安装consul

在每个节点上执行下面步骤安装：

# wget -c https://releases.hashicorp.com/consul/1.4.4/consul_1.4.4_linux_amd64.zip
# unzip consul_1.4.4_linux_amd64.zip
# mv consul /usr/local/bin

# mkdir -p ~/consul-install/consul-data

启动consul集群：

u1:

# nohup consul agent -server -ui -dns-port=53 -bootstrap-expect=3 -data-dir=/root/consul-install/consul-data -node=consul-1 -client=0.0.0.0 -bind=192.168.56.3 -datacenter=dc1 > consul-1.log & 2>&1

u2:

# nohup consul agent -server -ui -dns-port=53 -bootstrap-expect=3 -data-dir=/root/consul-install/consul-data -node=consul-2 -client=0.0.0.0 -bind=192.168.56.4 -datacenter=dc1 -join 192.168.56.3 > consul-2.log & 2>&1

u3:

nohup consul agent -server -ui -dns-port=53  -bootstrap-expect=3 -data-dir=/root/consul-install/consul-data -node=consul-3 -client=0.0.0.0 -bind=192.168.56.5 -datacenter=dc1 -join 192.168.56.3 > consul-3.log & 2>&1

查看启动状态：

#  consul operator raft list-peers
Node      ID                                    Address            State     Voter  RaftProtocol
consul-1  db838e7c-2b02-949b-763b-a6646ee51981  192.168.56.3:8300  leader    true   3
consul-2  33c81139-5054-7e76-f320-7d28d7528cc8  192.168.56.4:8300  follower  true   3
consul-3  4eda7d24-3fe2-45f5-f4ad-b95fa39f13c1  192.168.56.5:8300  follower  true   3

如果输出类似上面的日志，则说明consul集群启动成功！

接下来为了利用consul内嵌的DNS server，我们修改一下各个node的DNS配置 /etc/resolvconf/resolv.conf.d/base：

//  /etc/resolvconf/resolv.conf.d/base

nameserver 192.168.56.3
nameserver 192.168.56.4

options timeout:2 attempts:3 rotate single-request-reopen

# /etc/init.d/resolvconf restart

[ ok ] Restarting resolvconf (via systemctl): resolvconf.service.

2. 安装nomad并启动nomad集群

下面是在每个node上安装nomad的步骤：

# wget -c https://releases.hashicorp.com/nomad/0.8.7/nomad_0.8.7_linux_amd64.zip

# mkdir nomad-install

# unzip nomad_0.8.7_linux_amd64.zip

# mv nomad /usr/local/bin

# nomad version
Nomad v0.8.7 (21a2d93eecf018ad2209a5eab6aae6c359267933+CHANGES)

在每个node上创建agent.hcl文件，放到nomad-install下面：

// agent.hcl

data_dir = "/root/nomad-install/nomad.d"

bind_addr = "192.168.56.3" //node 内网ip，这里以u1 host为例

server {
  enabled = true
  bootstrap_expect = 3
}

client {
  enabled = true
}

启动集群(基于consul)：

u1:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-1.log & 2>&1

u2:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-2.log & 2>&1

u3:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-3.log & 2>&1

查看nomad集群状态：

# nomad server members -address="http://192.168.56.3:4646"
Name       Address       Port  Status  Leader  Protocol  Build  Datacenter  Region
u1.global  192.168.56.3  4648  alive   false   2         0.8.7  dc1         global
u2.global  192.168.56.4  4648  alive   true    2         0.8.7  dc1         global
u3.global  192.168.56.5  4648  alive   false   2         0.8.7  dc1         global

# nomad operator raft list-peers -address="http://192.168.56.3:4646"
Node       ID                 Address            State     Voter  RaftProtocol
u3.global  192.168.56.5:4647  192.168.56.5:4647  follower  true   2
u2.global  192.168.56.4:4647  192.168.56.4:4647  leader    true   2
u1.global  192.168.56.3:4647  192.168.56.3:4647  follower  true   2

nomad集群启动成功！

四. nomad实现在weave overlay network中的job部署

1. 创建位于weave overlay network中的nomad task service实例

我们定义如下nomad job的配置文件：

//httpbackend.nomad

job "httpbackend" {
  datacenters = ["dc1"]
  type = "service"

  group "httpbackend" {
    count = 3

    task "httpbackend" {
      driver = "docker"
      config {
        image = "bigwhite/httpbackendservice:v1.0.0"
        dns_servers =  ["192.168.56.3", "192.168.56.4", "192.168.56.5"]
        network_mode = "weave"
        logging {
          type = "json-file"
        }
      }

      resources {
        network {
          mbits = 10
        }
      }

      service {
        name = "httpbackend"
      }
    }
  }
}

与之前文章中job的配置文件不同的是，该job配置在task的config中增加了：

dns_servers：由于docker 18.09在-net=weave下，container没有继承host的/etc/resolv.conf文件，我们为了能在container中通过服务的domain查询到其真实ip地址，我们在docker的执行参数中加入dns_servers，我们将u1,u2,u3都作为dns server提供了。
network_node：我们希望nomad调度负载、创建docker容器时将docker container创建在weave network中，因此我们在network_node中传入”weave”，这就相当于在执行docker时执行：docker run … –net=weave … …

我们来创建一下该job：

# nomad job run -address=http://192.168.56.3:4646 httpbackend.nomad

==> Monitoring evaluation "806eaecf"
    Evaluation triggered by job "httpbackend"
    Allocation "6e06be74" created: node "11212ed9", group "httpbackend"
    Allocation "e7ed8569" created: node "aa5a06fe", group "httpbackend"
    Allocation "fd6c6a05" created: node "fe7a7e9c", group "httpbackend"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "806eaecf" finished with status "complete"

# nomad job status -address=http://192.168.56.3:4646  httpbackend
ID            = httpbackend
Name          = httpbackend
Submit Date   = 2019-04-19T13:18:21+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group   Queued  Starting  Running  Failed  Complete  Lost
httpbackend  0       0         3        0       0         0

Allocations
ID        Node ID   Task Group   Version  Desired  Status   Created  Modified
6e06be74  11212ed9  httpbackend  0        run      running  54s ago  7s ago
e7ed8569  aa5a06fe  httpbackend  0        run      running  54s ago  6s ago
fd6c6a05  fe7a7e9c  httpbackend  0        run      running  54s ago  12s ago

我们查看一下u1节点上的httpbackend负载的状态和ip：

root@u1:~/nomad-install/jobs# docker ps
CONTAINER ID        IMAGE                    COMMAND                  CREATED             STATUS              PORTS               NAMES
2e2229cf8f64        c196c122feea             "/root/httpbackendse…"   49 seconds ago      Up 48 seconds                           httpbackend-e7ed8569-fdde-537b-91b3-84583d1ea238
912ac43350f7        weaveworks/weave:2.5.1   "/home/weave/weaver …"   22 hours ago        Up 22 hours                             weave

root@u1:~/nomad-install/jobs# docker exec 2e2229cf8f64 ip a
... ...
49: ethwe0@if50: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1376 qdisc noqueue
    link/ether a2:f1:ef:d7:89:ee brd ff:ff:ff:ff:ff:ff
    inet 10.40.0.0/12 brd 10.47.255.255 scope global ethwe0
       valid_lft forever preferred_lft forever
.... ...

我们看到新创建的container的ip为10.40.0.0，是weave network subnet range中的一个地址。

我们访问一下该服务：

# curl http://10.40.0.0:8081
this is httpbackendservice, version: v1.0.0

我们看到了预期返回的结果。通过consul的域名访问也同样ok：

# curl httpbackend.service.dc1.consul:8081
this is httpbackendservice, version: v1.0.0

我们从一个位于weave network中的container中去访问httpbackend服务，依然会得到正确的应答结果：

# docker run -ti --net=weave --dns=192.168.56.3 --dns=8.8.8.8 ubuntu /bin/bash

root@3fe76a39b66f:/# curl httpbackend.service.dc1.consul:8081
this is httpbackendservice, version: v1.0.0

五、应用隔离

有些时候我们需要将部署的应用之间做隔离，让彼此无法互相访问。weave overlay network是支持这样做的，我们一起来看一下。

1.重建weave网络

我们首先需要重新创建weave网络，使之能支持划分不同subnet。

先在每个node上执行下面命令，将原有的weave网络清理干净：

# weave reset

执行后，发现weave网络设备、weave相关容器、路由表中有关weave的路由都不见了。

我们重新建立三节点的weave网络，在这个10.32.0.0/16的大网中，我们划分若干subnet，默认的subnet为10.32.0.0/24。

u1:

# weave launch --no-dns --ipalloc-range 10.32.0.0/16 --ipalloc-default-subnet 10.32.0.0/24 192.168.56.4 192.168.56.5

# weave expose

u2:

# weave launch --no-dns --ipalloc-range 10.32.0.0/16 --ipalloc-default-subnet 10.32.0.0/24 192.168.56.3 192.168.56.5

# weave expose

u3:

# weave launch --no-dns --ipalloc-range 10.32.0.0/16 --ipalloc-default-subnet 10.32.0.0/24 192.168.56.3 192.168.56.4

# weave expose

接下来我们在不同的subnet下分别建立两个container：

首先在u1上，在default subnet下建立两个container a1和a2：

#docker run -ti --net=weave --dns=192.168.56.3 --dns=8.8.8.8 --name a1 busybox /bin/sh

#docker run -ti --net=weave --dns=192.168.56.3 --dns=8.8.8.8 --name a2 busybox /bin/sh

再在u2上在subnet 10.32.1.0/24下建立两个container：b1和b2

u2上：

# docker run -ti --net=weave --dns=192.168.56.3 --dns=8.8.8.8 -e WEAVE_CIDR=net:10.32.1.0/24 --name b1 busybox /bin/sh

# docker run -ti --net=weave --dns=192.168.56.3 --dns=8.8.8.8 -e WEAVE_CIDR=net:10.32.1.0/24 --name b2 busybox /bin/sh

我们经过测试发现：a1与a2、a1与b1都是可以ping通的，这与我们的预期a1与b1、b2不通不符。我们发现b1(10.32.0.2)、b2(10.32.0.3)两个容器的ip地址居然依然在default subnet内，似乎通过环境变量WEAVE_CIDR传递的subnet信息没有生效。
在weave的一个issue中，有开发者提到：WEAVE_CIDR仅用于weave proxy模式，在weave作为plugin模式工作时，docker不会将该环境变量信息传递给weave。也就是说即便上面在u2上创建b1、b2时设置了环境变量WEAVE_CIDR，weave插件也无法得到该信息，于是依旧在默认subnet范围为b1、b2分配了ip。

2. 让docker使用weave proxy模式

weave proxy是位于docker client与docker engine(docker daemon)之间的代理服务：

docker client --> weave proxy ---> docker engine/daemon

默认情况下，/var/run/docker.sock是docker client和docker engine之间的通信“媒介”，Docker daemon默认监听的Unix域套接字(Unix domain socket)：/var/run/docker.sock，docker client以及容器中的进程可以通过它与Docker daemon进行通信。

我们可通过docker -H xxx.sock或通过设置 DOCKER_HOST环境变量的方式让docker client与传入的unix socket通信。这样我们就可以将weave proxy的套接字unix:///var/run/weave/weave.sock（通过weave env查看到）传给docker client了。我们来测试一下：

u1:

# docker -H unix:///var/run/weave/weave.sock run -ti --dns=192.168.56.3 --dns=8.8.8.8 --name a1 busybox /bin/sh

# docker -H unix:///var/run/weave/weave.sock run -ti --dns=192.168.56.3 --dns=8.8.8.8 --name a2 busybox /bin/sh

u2:

# docker -H unix:///var/run/weave/weave.sock  run -ti --dns=192.168.56.3 --dns=8.8.8.8 -e WEAVE_CIDR=net:10.32.1.0/24 --name b1 busybox /bin/sh

#docker -H unix:///var/run/weave/weave.sock run -ti --dns=192.168.56.3 --dns=8.8.8.8 -e WEAVE_CIDR=net:10.32.1.0/24 --name b2 busybox /bin/sh

四个container启动后，我们发现b1、b2的ip地址都在WEAVE_CIDR指定的空间内，a1、a2间互通；b1、b2间互通，但a1、a2与b1、b2间是不通的。这样就与预期相符了。

3. nomad与weave proxy模式集成实现应用工作负载的隔离

接下来，我们来看看如何将nomad和weave的proxy模式集成在一起，实现工作负载分配在不同subnet。

这里我们就无法仅仅通过在job配置文件中传入参数的方式来实现了，我们需要修改一下agent.hcl并重启nomad集群。以u1节点上的agent.hcl为例，我们需要改为下面这样：

data_dir = "/root/nomad-install/nomad.d"

bind_addr = "192.168.56.5"

server {
  enabled = true
  bootstrap_expect = 3
}

client {
  enabled = true
  "options":{
     "docker.endpoint":"unix://var/run/weave/weave.sock"
  }
}

我们在client配置block中增加一个options，设置了docker.endpoint为weave proxy监听的weave.sock。重启集群：

u1:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-1.log & 2>&1

u2:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-2.log & 2>&1

u3:

# nohup nomad agent -config=/root/nomad-install/agent.hcl  > nomad-3.log & 2>&1

接下来，我们重建一个httpbackend-another-subnet.nomad，内容如下：

//httpbackend-another-subnet.nomad

job "httpbackend" {
  datacenters = ["dc1"]
  type = "service"

  group "httpbackend" {
    count = 3

    task "httpbackend" {
      driver = "docker"
      config {
        image = "bigwhite/httpbackendservice:v1.0.0"
        dns_servers =  ["192.168.56.3", "192.168.56.4", "192.168.56.5"]
        logging {
          type = "json-file"
        }
      }

      env {
        WEAVE_CIDR="net:10.32.1.0/24"
      }

      resources {
        network {
          mbits = 10
        }
      }

      service {
        name = "httpbackend"
      }
    }
  }
}

我们去掉了network_mode = “weave”，增加了一个env：WEAVE_CIDR=”net:10.32.1.0/24″。run这个job：

# nomad job run -address=http://192.168.56.3:4646 httpbackend-another-subnet.nomad
==> Monitoring evaluation "e94bdd00"
    Evaluation triggered by job "httpbackend"
    Allocation "3f5032b5" created: node "11212ed9", group "httpbackend"
    Allocation "40d75ae8" created: node "aa5a06fe", group "httpbackend"
    Allocation "627fe1e7" created: node "fe7a7e9c", group "httpbackend"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "e94bdd00" finished with status "complete"

# docker ps
CONTAINER ID        IMAGE                    COMMAND                  CREATED             STATUS              PORTS               NAMES
700bbea7c89e        c196c122feea             "/w/w /root/httpback…"   17 seconds ago      Up 16 seconds                           httpbackend-40d75ae8-fe75-c560-b87b-c1272db4850c
8b7e29522b8b        weaveworks/weave:2.5.1   "/home/weave/weaver …"   10 hours ago        Up 10 hours                             weave
root@u1:~/nomad-install/jobs# docker exec 700bbea7c89e 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
142: eth0@if143: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1500 qdisc noqueue
    link/ether 02:42:ac:11:00:02 brd ff:ff:ff:ff:ff:ff
    inet 172.17.0.2/16 brd 172.17.255.255 scope global eth0
       valid_lft forever preferred_lft forever
144: ethwe@if145: <BROADCAST,MULTICAST,UP,LOWER_UP,M-DOWN> mtu 1376 qdisc noqueue
    link/ether f2:55:9d:26:72:56 brd ff:ff:ff:ff:ff:ff
    inet 10.32.1.192/24 brd 10.32.1.255 scope global ethwe
       valid_lft forever preferred_lft forever

我们看到新创建的httpbackend container的ip已经分配到10.32.1.0/24 subnet下面了。这种方式使得我们可以任意安排我们的job放入哪个subnet。

4. 遗留问题

我们通过consul go api试图从consul中获取service: httpbackend的ip信息，我们得到了如下的输出：

#  ./services
10.0.3.15 : 0
10.0.3.15 : 0
10.0.3.15 : 0
[]

如果在httpbackend的service配置中使用如下配置：

 service {
        name = "httpbackend"
        address_mode = "driver"
      }

那么，我们得到的是下面结果：

# ./services
172.17.0.3 : 0
172.17.0.2 : 0
172.17.0.2 : 0
[]

也就是说nomad在consul中记录的container的advertise ip不是我们想要的weave subnet网段的ip信息，这样就会导致我们通过consul的DNS服务或者通过consul api获取的服务ip信息有误，导致无法通过这两种方式访问到服务实例。在nomad的最新版v0.9.0中该问题依然存在。

综上，“隔离”的目的得到了部分满足，期待后续nomad的改进。

六、参考资料

https://www.weave.works/docs/net/latest/install/installing-weave/
https://www.weave.works/docs/net/latest/install/using-weave/#peer-connections
https://www.weave.works/docs/net/latest/install/plugin/plugin/#launching
https://www.weave.works/docs/net/latest/tasks/manage/host-network-integration/
https://docs.docker.com/v17.09/engine/userguide/networking/configure-dns/
https://www.nomadproject.io/docs/drivers/docker.html#client-requirements
https://www.weave.works/docs/net/latest/tasks/manage/application-isolation/
https://www.weave.works/docs/net/latest/tasks/weave-docker-api/weave-docker-api/
https://www.nomadproject.io/docs/drivers/docker.html
https://www.nomadproject.io/docs/configuration/client.html
https://www.nomadproject.io/docs/job-specification/service.html#using-driver-address-mode
https://success.docker.com/article/networking

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使用nomad实现工作负载版本升级

四月 9, 2019
0 条评论

书接上文。

在《使用nomad实现集群管理和微服务部署调度》一文中，我们介绍了使用nomad进行集群管理和工作负载调度的轻量级方案（相较于Kubernetes方案）。在本文中，我们继续对方案进行延展，介绍一下在nomad集群中工作负载版本升级的一些常用模式和实现方法，包括滚动升级、蓝绿部署和金丝雀部署。

一. 初始状态

这里我们利用基于tcp+sni路由(listener端口为9996)的httpsbackend-sni-1的job作为演示job，该job的初始部署nomad job文件为：httpsbackend-tcp-sni-1.nomad (注：不同的是，这里将count初始值改为了3)。

当前httpsbackend-sni-1这个job的状态如下：

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T10:57:29+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       3         0

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created    Modified
7ac186b8  7acdd7bc  httpsbackend-sni-1  22       run      running   1m18s ago  1m1s ago
8a79085f  c281658a  httpsbackend-sni-1  22       run      running   1m18s ago  46s ago
f9ffef32  9e3ef19f  httpsbackend-sni-1  22       run      running   1m18s ago  59s ago
0ed95591  9e3ef19f  httpsbackend-sni-1  20       stop     complete  5d19h ago  7m16s ago
604d2151  9e3ef19f  httpsbackend-sni-1  20       stop     complete  5d19h ago  7m16s ago
06404fff  7acdd7bc  httpsbackend-sni-1  20       stop     complete  5d20h ago  7m14s ago

fabio路由表如下：

img{512x368}

# curl -k https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.0

接下来，我们就以这个job为基础，使用各种版本升级模式对其进行更新。

二. 滚动更新(rolling update)

下面是blog.itaysk.com上一篇文章中的有关滚动更新的示意图：

img{512x368}
可以大致看出所谓滚动更新就是对目标环境下老版本的程序进行逐批的替换，每批的数量可以是1，也可以大于1，根据目标实例的个数自定义。替换过程中，新老版本是并存的，直到所有目标实例都被替换为新版本。

nomad支持通过在job描述文件中增加update配置来支持滚动更新。我们创建httpsbackend-tcp-sni-1-rolling-update.nomad，考虑篇幅，这里仅列出与httpsbackend-tcp-sni-1.nomad的差异：

# diff httpsbackend-tcp-sni-1-rolling-update.nomad ./httpsbackend-tcp-sni-1.nomad
14,19d13
<     update {
<       max_parallel = 1
<       min_healthy_time = "30s"
<       healthy_deadline = "5m"
<     }
<
23c17
<         image = "bigwhite/httpsbackendservice:v1.0.1"
---
>         image = "bigwhite/httpsbackendservice:v1.0.0"

新job nomad文件使用了v1.0.1版本的httpsbackendservice image，增加了update {…}配置环节，其中的max_parallel指示的是滚动更新每批更新的数量，这里是1，也就是说一批仅用新版本替换一个老版本实例。

执行滚动更新：

# nomad job run httpsbackend-tcp-sni-1-rolling-update.nomad
==> Monitoring evaluation "8d39ab53"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "348ef16b"
    Allocation "88c1a29e" created: node "7acdd7bc", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "8d39ab53" finished with status "complete"

httpsbackendservice job的task group有三个task实例，因此更新需要一些时间，我们在更新过程中查看job status：

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T13:06:35+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       4         0

Latest Deployment
ID          = 348ef16b
Status      = running
Description = Deployment is running

Deployed
Task Group          Desired  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  3        1       0        0          2019-04-08T13:16:35+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created   Modified
88c1a29e  7acdd7bc  httpsbackend-sni-1  23       run      running   44s ago   41s ago
7ac186b8  7acdd7bc  httpsbackend-sni-1  22       run      running   2h9m ago  2h9m ago
8a79085f  c281658a  httpsbackend-sni-1  22       run      running   2h9m ago  2h9m ago
f9ffef32  9e3ef19f  httpsbackend-sni-1  22       stop     complete  2h9m ago  44s ago

我们看到nomad job status命令输出的信息中多出了“Latest Deployment”一个小节，在该小节中，我们看到了一个ID为348ef16b的deployment正在run。这个deployment对应的就是这次的滚动更新，我们看到下面的allocations列表中，一个version为22的allocation已经stop，一个version为23的allocation已经run，这说明nomad已经完成了一个task实例的版本升级。

我们再来查看一下job执行的最终状态：

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T13:06:35+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       6         0

Latest Deployment
ID          = 348ef16b
Status      = successful
Description = Deployment completed successfully

Deployed
Task Group          Desired  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  3        3       3        0          2019-04-08T13:18:43+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created    Modified
da1b545b  7acdd7bc  httpsbackend-sni-1  23       run      running   34s ago    2s ago
44da5693  9e3ef19f  httpsbackend-sni-1  23       run      running   1m25s ago  36s ago
88c1a29e  7acdd7bc  httpsbackend-sni-1  23       run      running   2m10s ago  1m26s ago
7ac186b8  7acdd7bc  httpsbackend-sni-1  22       stop     complete  2h11m ago  1m24s ago
8a79085f  c281658a  httpsbackend-sni-1  22       stop     complete  2h11m ago  34s ago
f9ffef32  9e3ef19f  httpsbackend-sni-1  22       stop     complete  2h11m ago  2m10s ago

我们看到job执行的最终结果：ID为348ef16b的deployment执行成功；所有version 为23的allocations都处于running状态。task group的三个task实例都处于healthy状态。这说明滚动更新成功了！

我们也可以通过nomad提供的deployment子命令查看deployment的状态，deployment id作为命令参数：

# nomad deployment list
ID        Job ID              Job Version  Status      Description
348ef16b  httpsbackend-sni-1  23           successful  Deployment completed successfully

# nomad deployment status 348ef16b
ID          = 348ef16b
Job ID      = httpsbackend-sni-1
Job Version = 23
Status      = successful
Description = Deployment completed successfully

Deployed
Task Group          Desired  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  3        3       3        0          2019-04-08T13:18:43+08:00

滚动更新后的路由：

img{512x368}

测试一下部署成功的新版本服务：

# curl -k https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.1

三. 金丝雀部署(canary deployment)

金丝雀部署是另外一种十分有用的部署模式，下面示意图来自blog.itaysk.com：

img{512x368}

金丝雀 (Canary)得名于矿工的一个工作习惯：下矿洞前，先会放一只金丝雀进去探测是否有有毒气体，看金丝雀能否活下来。如果金丝雀活下来，则继续下矿操作；否则停止下矿。金丝雀部署亦是先部署少量新版本的服务实例，发布后，开发者可简单地通过手工测试验证新版本实例，又或通过完善的自动化测试基础设施对新版本实例进行详尽验证；甚至是直接接收部分生产流量以充分验证新版本功能、稳定性、性能等，以给予开发者更多信心。如果金丝雀实例通过全部测试验证，则把所有老版本全部升级为新版本。如果金丝雀测试失败，则直接回退金丝雀实例，发布失败。

nomad支持两种模式的canary部署：既支持部署canary实例去直接接收生产流量（按比例权重），也可以将其与生产实例隔离开来（利用路由）单独测试验证，下面分别说说这两种模式。

1. 部署canary实例去直接接收生产流量（按比例权重）

我们创建一个新的nomad job文件：httpsbackend-tcp-sni-1-canary-1.nomad

# diff  httpsbackend-tcp-sni-1-canary-1.nomad  httpsbackend-tcp-sni-1-rolling-update.nomad
18d17
<       canary = 1
24c23
<         image = "bigwhite/httpsbackendservice:v1.0.2"
---
>         image = "bigwhite/httpsbackendservice:v1.0.1"

我们看到除了新版本task使用v1.0.2版image之外，最大的不同就是在update {…}配置区域增加了一行：

canary = 1

我们来plan一下该nomad文件：

# nomad job plan httpsbackend-tcp-sni-1-canary-1.nomad
+/- Job: "httpsbackend-sni-1"
+/- Task Group: "httpsbackend-sni-1" (1 canary, 3 ignore)
  +/- Update {
        AutoRevert:       "false"
    +/- Canary:           "0" => "1"
        HealthCheck:      "checks"
        HealthyDeadline:  "300000000000"
        MaxParallel:      "1"
        MinHealthyTime:   "30000000000"
        ProgressDeadline: "600000000000"
      }
  +/- Task: "httpsbackend-sni-1" (forces create/destroy update)
    +/- Config {
      +/- image:              "bigwhite/httpsbackendservice:v1.0.1" => "bigwhite/httpsbackendservice:v1.0.2"
          logging[0][type]:   "json-file"
          port_map[0][https]: "7777"
        }

Scheduler dry-run:
- All tasks successfully allocated.

... ...

我们看到nomad分析的结果是：需要创建一个canary实例，忽略三个已经存在的旧版本task实例。同时task group的canary属性从“0”变为了“1”。

我们来run该job：

# nomad job run httpsbackend-tcp-sni-1-canary-1.nomad
==> Monitoring evaluation "0494a8a9"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "3e541fb3"
    Allocation "4d678e67" created: node "c281658a", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "0494a8a9" finished with status "complete"

查看job的run状态：

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T21:04:49+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         4        0       6         0

Latest Deployment
ID          = 3e541fb3
Status      = running
Description = Deployment is running but requires promotion

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  false     3        1         1       0        0          2019-04-08T21:14:49+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created    Modified
4d678e67  c281658a  httpsbackend-sni-1  24       run      running   31s ago    15s ago
da1b545b  7acdd7bc  httpsbackend-sni-1  23       run      running   7h57m ago  7h56m ago
44da5693  9e3ef19f  httpsbackend-sni-1  23       run      running   7h57m ago  7h57m ago
88c1a29e  7acdd7bc  httpsbackend-sni-1  23       run      running   7h58m ago  7h58m ago

# nomad deployment status 3e541fb3
ID          = 3e541fb3
Job ID      = httpsbackend-sni-1
Job Version = 24
Status      = running
Description = Deployment is running but requires promotion

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  false     3        1         1       1        0          2019-04-08T21:15:35+08:00

我们看到：

处于running状态的allocations变成了4个，但是只有一个是version = 24的，其余都为version = 23。version = 24这个显然是我们新部署的canary实例，而另外三个则为原有的老版本实例。
在Deployment输出信息中，我们看到了一个描述信息：“Deployment is running but requires promotion”，意思是此次用于部署canary实例的Deployment已经running了，但是还未到最终状态，还需要promote命令。只有promote后，整个的更新工作才算是ok。

下面是canary部署后的fabio的路由：

img{512x368}

我们看到canary实例与其余老版本的路由规则是一致的，并平分的负载权重。也就是说新部署的canary实例与老版本实例一起承载生产流量(canary实例占25%的权重)，我们来验证一下：

# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.1
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.1
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.1

我们看到第一个请求的流量就打到了我们部署的Canary实例身上了。

如果经过一段时间的验证后，证明canary实例满足要求，我们就要继续推动部署的进程使得该nomad deployment走向最终状态：即将老版本的实例都升级为新版本。

# nomad deployment promote 3e541fb3
==> Monitoring evaluation "b5e29b1a"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "3e541fb3"
    Allocation "085a518e" created: node "7acdd7bc", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "b5e29b1a" finished with status "complete"

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T21:04:49+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       9         0

Latest Deployment
ID          = 3e541fb3
Status      = successful
Description = Deployment completed successfully

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  true      3        1         3       3        0          2019-04-08T21:30:54+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created     Modified
40276d89  9e3ef19f  httpsbackend-sni-1  24       run      running   56s ago     11s ago
085a518e  7acdd7bc  httpsbackend-sni-1  24       run      running   1m49s ago   58s ago
4d678e67  c281658a  httpsbackend-sni-1  24       run      running   16m17s ago  1m49s ago
da1b545b  7acdd7bc  httpsbackend-sni-1  23       stop     complete  8h12m ago   56s ago
44da5693  9e3ef19f  httpsbackend-sni-1  23       stop     complete  8h13m ago   1m48s ago
88c1a29e  7acdd7bc  httpsbackend-sni-1  23       stop     complete  8h14m ago   1m47s ago

通过deployment promote命令使得canary deployment进程继续推进，直到将所有老版本的实例都用canary实例替换掉。也就是我们最终看到的上面的version = 24的allocations都处于running状态，并且一共是三个实例。

我们再来测试一下升级后的服务：

# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2

我们看到：所有实例都升级到了v1.0.2版本。

2.将canary实例与生产实例隔离开来（利用路由）单独测试验证

如果开发者对自己的代码很有信心，不需要将canary实例暴露在生产流量中去验证，nomad也支持将canary实例与生产实例隔离开来（利用路由）单独测试验证。

我们基于httpsbackend-tcp-sni-1-canary-1.nomad改写出一个httpsbackend-tcp-sni-1-canary-2.nomad：

# diff httpsbackend-tcp-sni-1-canary-2.nomad httpsbackend-tcp-sni-1-canary-1.nomad
24c24
<         image = "bigwhite/httpsbackendservice:v1.0.3"
---
>         image = "bigwhite/httpsbackendservice:v1.0.2"
43d42
<     canary_tags = ["urlprefix-canary.mysite-sni-1.com/ proto=tcp+sni"]

我们看到，在新的job文件中，我们除了将image版本升级为v1.0.3，我们还在service{…}配置区域增加了下面这行：

canary_tags = ["urlprefix-canary.mysite-sni-1.com/ proto=tcp+sni"]

该配置是canary实例专有的，这里我们通过在canary_tags为canary实例单独定义了路由，以免和老版本实例共享路由分担生产流量。

我们照例运行该job并查看job执行后的status：

# nomad job run httpsbackend-tcp-sni-1-canary-2.nomad
==> Monitoring evaluation "44e36161"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "e43d2551"
    Allocation "73319890" created: node "7acdd7bc", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "44e36161" finished with status "complete"

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T21:35:03+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         4        0       9         0

Latest Deployment
ID          = e43d2551
Status      = running
Description = Deployment is running but requires promotion

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  false     3        1         1       1        0          2019-04-08T21:45:51+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created     Modified
73319890  7acdd7bc  httpsbackend-sni-1  25       run      running   2m24s ago   1m36s ago
40276d89  9e3ef19f  httpsbackend-sni-1  24       run      running   17m18s ago  16m33s ago
085a518e  7acdd7bc  httpsbackend-sni-1  24       run      running   18m11s ago  17m20s ago
4d678e67  c281658a  httpsbackend-sni-1  24       run      running   32m39s ago  18m11s ago

这个输出信息和之前的canary模式差别不大。但是从fabio路由表上我们看到如下信息：

img{512x368}

fabio单独为canary实例生成了一个新路由，以区别于老版本的三个实例的路由。

开发人员单独测试canary实例时，可以通过下面方式注入流量:

# curl -k  https://canary.mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.3

而生产流量依旧流入老版本的实例中：

# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.2

canary实例经过测试验证后，同样可以通过promote完成对老版本的升级部署：

# nomad deployment promote e43d2551
==> Monitoring evaluation "34a67391"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "e43d2551"
    Allocation "193cbc2f" created: node "c281658a", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "34a67391" finished with status "complete"

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-08T21:35:03+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       12        0

Latest Deployment
ID          = e43d2551
Status      = successful
Description = Deployment completed successfully

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  true      3        1         3       3        0          2019-04-08T21:58:24+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created     Modified
528a75bd  7acdd7bc  httpsbackend-sni-1  25       run      running   51s ago     10s ago
193cbc2f  c281658a  httpsbackend-sni-1  25       run      running   1m39s ago   52s ago
73319890  7acdd7bc  httpsbackend-sni-1  25       run      running   13m31s ago  1m39s ago
40276d89  9e3ef19f  httpsbackend-sni-1  24       stop     complete  28m25s ago  50s ago
085a518e  7acdd7bc  httpsbackend-sni-1  24       stop     complete  29m18s ago  1m38s ago
4d678e67  c281658a  httpsbackend-sni-1  24       stop     complete  43m46s ago  1m39s ago

同时，canary实例在fabiolb上的路由也会自动删除掉。canary_tags在promote后将不再起作用，fabio使用的是tags。

# curl -k  https://canary.mysite-sni-1.com:9996/
curl: (35) gnutls_handshake() failed: The TLS connection was non-properly terminated.
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.3
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.3
# curl -k  https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.3

四. 蓝绿部署(blue-green deployment)

下面的蓝绿部署模式的示意图同样来自blog.itaysk.com：

img{512x368}

与之前的滚动更新、金丝雀部署不同的是，蓝绿部署需要“两套”环境，通过路由指向来切换流量究竟经过哪套环境。

但是在nomad官方关于blue-green部署的例子中，nomad实际只维护了一套环境，并且例子中是利用nomad的canary机制来实现的蓝绿部署。这种实现方式并非严格遵循“蓝绿部署”的公认的定义。

但nomad官方对于blue-green部署的理解似乎仅限如此。我们也来看一下nomad的这种“全量金丝雀”的蓝绿方案：

我们创建httpsbackend-tcp-sni-1-blue-green.nomad文件，重点内容差异如下：

# diff httpsbackend-tcp-sni-1-blue-green.nomad httpsbackend-tcp-sni-1-canary-1.nomad
18c18
<       canary = 3
---
>       canary = 1
24c24
<         image = "bigwhite/httpsbackendservice:v1.0.4"
---
>         image = "bigwhite/httpsbackendservice:v1.0.2"

我们看到这里canary = 3，与count值相同，这也是将其称为“全量金丝雀”的原因。

使用该文件部署新版本实例：

# nomad job run httpsbackend-tcp-sni-1-blue-green.nomad
==> Monitoring evaluation "7a5074f3"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "3c8740f2"
    Allocation "338ee344" created: node "c281658a", group "httpsbackend-sni-1"
    Allocation "3dec73d2" created: node "9e3ef19f", group "httpsbackend-sni-1"
    Allocation "e6975673" created: node "9e3ef19f", group "httpsbackend-sni-1"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "7a5074f3" finished with status "complete"

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-09T13:38:49+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         6        0       12        0

Latest Deployment
ID          = 3c8740f2
Status      = running
Description = Deployment is running but requires promotion

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  false     3        3         3       3        0          2019-04-09T13:49:41+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status   Created     Modified
338ee344  c281658a  httpsbackend-sni-1  26       run      running  57s ago     5s ago
3dec73d2  9e3ef19f  httpsbackend-sni-1  26       run      running  57s ago     11s ago
e6975673  9e3ef19f  httpsbackend-sni-1  26       run      running  57s ago     10s ago
528a75bd  7acdd7bc  httpsbackend-sni-1  25       run      running  15h52m ago  15h51m ago
193cbc2f  c281658a  httpsbackend-sni-1  25       run      running  15h52m ago  15h52m ago
73319890  7acdd7bc  httpsbackend-sni-1  25       run      running  16h4m ago   15h52m ago

部署ok后，6个实例共同接收生产流量。当然我们也可以通过canary_tags为新的部署设定不同路由，选择哪一种要看部署新实例后打算对新实例如何进行测试。

测试验证ok后，像canary deployment一样，通过promote命令用新版本替换老版本。

# nomad deployment promote 3c8740f2
==> Monitoring evaluation "fad3a69b"
    Evaluation triggered by job "httpsbackend-sni-1"
    Evaluation within deployment: "3c8740f2"
    Evaluation status changed: "pending" -> "complete"
==> Evaluation "fad3a69b" finished with status "complete"

# nomad job status httpsbackend-sni-1
ID            = httpsbackend-sni-1
Name          = httpsbackend-sni-1
Submit Date   = 2019-04-09T13:38:49+08:00
Type          = service
Priority      = 50
Datacenters   = dc1
Status        = running
Periodic      = false
Parameterized = false

Summary
Task Group          Queued  Starting  Running  Failed  Complete  Lost
httpsbackend-sni-1  0       0         3        0       15        0

Latest Deployment
ID          = 3c8740f2
Status      = successful
Description = Deployment completed successfully

Deployed
Task Group          Promoted  Desired  Canaries  Placed  Healthy  Unhealthy  Progress Deadline
httpsbackend-sni-1  true      3        3         3       3        0          2019-04-09T13:49:41+08:00

Allocations
ID        Node ID   Task Group          Version  Desired  Status    Created     Modified
338ee344  c281658a  httpsbackend-sni-1  26       run      running   4m43s ago   15s ago
3dec73d2  9e3ef19f  httpsbackend-sni-1  26       run      running   4m43s ago   15s ago
e6975673  9e3ef19f  httpsbackend-sni-1  26       run      running   4m43s ago   15s ago
528a75bd  7acdd7bc  httpsbackend-sni-1  25       stop     complete  15h55m ago  14s ago
193cbc2f  c281658a  httpsbackend-sni-1  25       stop     complete  15h56m ago  15s ago
73319890  7acdd7bc  httpsbackend-sni-1  25       stop     complete  16h8m ago   14s ago

测试结果：

# curl -k https://mysite-sni-1.com:9996/
this is httpsbackendservice, version: v1.0.4

如果要快速切换回原来的版本，可以使用：

nomad job revert httpsbackend-sni-1 {old_allocation_version}

五. 其他

本文涉及到的nomad job文件源码可在这里下载。

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标签 docker 下的文章

使用nomad在weave网络中部署工作负载

一、搭建试验环境

1. 创建虚机，组建网络

二、使用weave创建跨节点的overlay network

1. 安装weave

2. 启动跨多节点(peer) weave network

3. 在weave overlay network中创建container并测试overlay网内container的互通性

4. 测试host到weave overlay网络中容器的连通性

三、安装consul和nomad集群

1. 安装consul

2. 安装nomad并启动nomad集群

四. nomad实现在weave overlay network中的job部署

1. 创建位于weave overlay network中的nomad task service实例

五、应用隔离

1.重建weave网络

2. 让docker使用weave proxy模式

3. nomad与weave proxy模式集成实现应用工作负载的隔离

4. 遗留问题

六、参考资料

使用nomad实现工作负载版本升级

一. 初始状态

二. 滚动更新(rolling update)

三. 金丝雀部署(canary deployment)

1. 部署canary实例去直接接收生产流量（按比例权重）

2.将canary实例与生产实例隔离开来（利用路由）单独测试验证

四. 蓝绿部署(blue-green deployment)

五. 其他

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标签 docker 下的文章

使用nomad在weave网络中部署工作负载

一、搭建试验环境

1. 创建虚机，组建网络

二、使用weave创建跨节点的overlay network

1. 安装weave

2. 启动跨多节点(peer) weave network

3. 在weave overlay network中创建container并测试overlay网内container的互通性

4. 测试host到weave overlay网络中容器的连通性

三、安装consul和nomad集群

1. 安装consul

2. 安装nomad并启动nomad集群

四. nomad实现在weave overlay network中的job部署

1. 创建位于weave overlay network中的nomad task service实例

五、 应用隔离

1.重建weave网络

2. 让docker使用weave proxy模式

3. nomad与weave proxy模式集成实现应用工作负载的隔离

4. 遗留问题

六、参考资料

使用nomad实现工作负载版本升级

一. 初始状态

二. 滚动更新(rolling update)

三. 金丝雀部署(canary deployment)

1. 部署canary实例去直接接收生产流量（按比例权重）

2.将canary实例与生产实例隔离开来（利用路由）单独测试验证

四. 蓝绿部署(blue-green deployment)

五. 其他

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五、应用隔离