将 Docker Compose 文件转换为 Kubernetes 资源

Kompose 是什么?它是个转换工具,可将 compose(即 Docker Compose)所组装的所有内容转换成容器编排器(Kubernetes 或 OpenShift)可识别的形式。

更多信息请参考 Kompose 官网 http://kompose.io

准备开始

你必须拥有一个 Kubernetes 的集群,同时你的 Kubernetes 集群必须带有 kubectl 命令行工具。 如果你还没有集群,你可以通过 Minikube 构建一 个你自己的集群,或者你可以使用下面任意一个 Kubernetes 工具构建:

要获知版本信息,请输入 kubectl version.

安装 Kompose

我们有很多种方式安装 Kompose。首选方式是从最新的 GitHub 发布页面下载二进制文件。

GitHub 发布版本

Kompose 通过 GitHub 发布版本,发布周期为三星期。您可以在GitHub 发布页面上看到所有当前版本。

  1. # Linux
  2. curl -L https://github.com/kubernetes/kompose/releases/download/v1.16.0/kompose-linux-amd64 -o kompose
  4. # macOS
  5. curl -L https://github.com/kubernetes/kompose/releases/download/v1.16.0/kompose-darwin-amd64 -o kompose
  7. # Windows
  8. curl -L https://github.com/kubernetes/kompose/releases/download/v1.16.0/kompose-windows-amd64.exe -o kompose.exe
  10. chmod +x kompose
  11. sudo mv ./kompose /usr/local/bin/kompose

或者,您可以下载 tarball

Go

go get 命令从主分支拉取最新的开发变更的方法安装 Kompose。

  1. go get -u github.com/kubernetes/kompose

CentOS

Kompose 位于 EPEL CentOS 代码仓库。 如果您还没有安装启用 EPEL 代码仓库,请运行命令 sudo yum install epel-release

如果您的系统中已经启用了 EPEL,您就可以像安装其他软件包一样安装 Kompose。

  1. sudo yum -y install kompose

Fedora

Kompose 位于 Fedora 24、25 和 26 的代码仓库。您可以像安装其他软件包一样安装 Kompose。

  1. sudo dnf -y install kompose

macOS

在 macOS 上您可以通过 Homebrew 安装 Kompose 的最新版本:

  1. brew install kompose

使用 Kompose

再需几步,我们就把你从 Docker Compose 带到 Kubernetes。 您只需要一个现有的 docker-compose.yml 文件。

  1. 进入 docker-compose.yml 文件所在的目录。如果没有,请使用下面这个进行测试。

    1.   version: "2"
    3.   services:
    5.     redis-master:
    6.       image: k8s.gcr.io/redis:e2e
    7.       ports:
    8.         - "6379"
    10.     redis-slave:
    11.       image: gcr.io/google_samples/gb-redisslave:v3
    12.       ports:
    13.         - "6379"
    14.       environment:
    15.         - GET_HOSTS_FROM=dns
    17.     frontend:
    18.       image: gcr.io/google-samples/gb-frontend:v4
    19.       ports:
    20.         - "80:80"
    21.       environment:
    22.         - GET_HOSTS_FROM=dns
    23.       labels:
    24.         kompose.service.type: LoadBalancer

  2. 运行 kompose up 命令直接部署到 Kubernetes,或者跳到下一步,生成 kubectl 使用的文件。

    1.   $ kompose up
    2.   We are going to create Kubernetes Deployments, Services and PersistentVolumeClaims for your Dockerized application.
    3.   If you need different kind of resources, use the 'kompose convert' and 'kubectl create -f' commands instead.
    5.   INFO Successfully created Service: redis          
    6.   INFO Successfully created Service: web            
    7.   INFO Successfully created Deployment: redis       
    8.   INFO Successfully created Deployment: web         
    10.   Your application has been deployed to Kubernetes. You can run 'kubectl get deployment,svc,pods,pvc' for details.

  3. 要将 docker-compose.yml 转换为 kubectl 可用的文件,请运行 kompose convert 命令进行转换,然后运行 kubectl create -f <output file> 进行创建。

    1.   $ kompose convert                           
    2.   INFO Kubernetes file "frontend-service.yaml" created         
    3.   INFO Kubernetes file "redis-master-service.yaml" created     
    4.   INFO Kubernetes file "redis-slave-service.yaml" created      
    5.   INFO Kubernetes file "frontend-deployment.yaml" created      
    6.   INFO Kubernetes file "redis-master-deployment.yaml" created  
    7.   INFO Kubernetes file "redis-slave-deployment.yaml" created
    1.   $ kubectl create -f frontend-service.yaml,redis-master-service.yaml,redis-slave-service.yaml,frontend-deployment.yaml,redis-master-deployment.yaml,redis-slave-deployment.yaml
    2.   service/frontend created
    3.   service/redis-master created
    4.   service/redis-slave created
    5.   deployment.apps/frontend created
    6.   deployment.apps/redis-master created
    7.   deployment.apps/redis-slave created
  1.   您部署的应用在 Kubernetes 中运行起来了。

  1. 访问您的应用。

    如果您在开发过程中使用 minikube,请执行:

    1.   $ minikube service frontend

    否则,我们要查看一下您的服务使用了什么 IP!

    1.   $ kubectl describe svc frontend
    2.   Name:                   frontend
    3.   Namespace:              default
    4.   Labels:                 service=frontend
    5.   Selector:               service=frontend
    6.   Type:                   LoadBalancer
    7.   IP:                     10.0.0.183
    8.   LoadBalancer Ingress:   192.0.2.89
    9.   Port:                   80      80/TCP
    10.   NodePort:               80      31144/TCP
    11.   Endpoints:              172.17.0.4:80
    12.   Session Affinity:       None
    13.   No events.

    如果您使用的是云提供商,您的 IP 将在 LoadBalancer Ingress 字段给出。

    1.   $ curl http://192.0.2.89

用户指南

Kompose 支持两种驱动:OpenShift 和 Kubernetes。 您可以通过全局选项 --provider 选择驱动方式。如果没有指定,会将 Kubernetes 作为默认驱动。

kompose convert

Kompose 支持将 V1、V2 和 V3 版本的 Docker Compose 文件转换为 Kubernetes 和 OpenShift 资源对象。

Kubernetes

  1. $ kompose --file docker-voting.yml convert
  2. WARN Unsupported key networks - ignoring
  3. WARN Unsupported key build - ignoring
  4. INFO Kubernetes file "worker-svc.yaml" created
  5. INFO Kubernetes file "db-svc.yaml" created
  6. INFO Kubernetes file "redis-svc.yaml" created
  7. INFO Kubernetes file "result-svc.yaml" created
  8. INFO Kubernetes file "vote-svc.yaml" created
  9. INFO Kubernetes file "redis-deployment.yaml" created
  10. INFO Kubernetes file "result-deployment.yaml" created
  11. INFO Kubernetes file "vote-deployment.yaml" created
  12. INFO Kubernetes file "worker-deployment.yaml" created
  13. INFO Kubernetes file "db-deployment.yaml" created
  15. $ ls
  16. db-deployment.yaml  docker-compose.yml         docker-gitlab.yml  redis-deployment.yaml  result-deployment.yaml  vote-deployment.yaml  worker-deployment.yaml
  17. db-svc.yaml         docker-voting.yml          redis-svc.yaml     result-svc.yaml        vote-svc.yaml           worker-svc.yaml

您也可以同时提供多个 docker-compose 文件进行转换:

  1. $ kompose -f docker-compose.yml -f docker-guestbook.yml convert
  2. INFO Kubernetes file "frontend-service.yaml" created         
  3. INFO Kubernetes file "mlbparks-service.yaml" created         
  4. INFO Kubernetes file "mongodb-service.yaml" created          
  5. INFO Kubernetes file "redis-master-service.yaml" created     
  6. INFO Kubernetes file "redis-slave-service.yaml" created      
  7. INFO Kubernetes file "frontend-deployment.yaml" created      
  8. INFO Kubernetes file "mlbparks-deployment.yaml" created      
  9. INFO Kubernetes file "mongodb-deployment.yaml" created       
  10. INFO Kubernetes file "mongodb-claim0-persistentvolumeclaim.yaml" created
  11. INFO Kubernetes file "redis-master-deployment.yaml" created  
  12. INFO Kubernetes file "redis-slave-deployment.yaml" created   
  14. $ ls
  15. mlbparks-deployment.yaml  mongodb-service.yaml                       redis-slave-service.jsonmlbparks-service.yaml  
  16. frontend-deployment.yaml  mongodb-claim0-persistentvolumeclaim.yaml  redis-master-service.yaml
  17. frontend-service.yaml     mongodb-deployment.yaml                    redis-slave-deployment.yaml
  18. redis-master-deployment.yaml

当提供多个 docker-compose 文件时,配置将会合并。任何通用的配置都将被后续文件覆盖。

OpenShift

  1. $ kompose --provider openshift --file docker-voting.yml convert
  2. WARN [worker] Service cannot be created because of missing port.
  3. INFO OpenShift file "vote-service.yaml" created             
  4. INFO OpenShift file "db-service.yaml" created               
  5. INFO OpenShift file "redis-service.yaml" created            
  6. INFO OpenShift file "result-service.yaml" created           
  7. INFO OpenShift file "vote-deploymentconfig.yaml" created    
  8. INFO OpenShift file "vote-imagestream.yaml" created         
  9. INFO OpenShift file "worker-deploymentconfig.yaml" created  
  10. INFO OpenShift file "worker-imagestream.yaml" created       
  11. INFO OpenShift file "db-deploymentconfig.yaml" created      
  12. INFO OpenShift file "db-imagestream.yaml" created           
  13. INFO OpenShift file "redis-deploymentconfig.yaml" created   
  14. INFO OpenShift file "redis-imagestream.yaml" created        
  15. INFO OpenShift file "result-deploymentconfig.yaml" created  
  16. INFO OpenShift file "result-imagestream.yaml" created

kompose 还支持为服务中的构建指令创建 buildconfig。 默认情况下,它使用当前 git 分支的 remote 仓库作为源仓库,使用当前分支作为构建的源分支。 您可以分别使用 --build-repo--build-branch 选项指定不同的源仓库和分支。

  1. $ kompose --provider openshift --file buildconfig/docker-compose.yml convert
  2. WARN [foo] Service cannot be created because of missing port.
  3. INFO OpenShift Buildconfig using git@github.com:rtnpro/kompose.git::master as source.
  4. INFO OpenShift file "foo-deploymentconfig.yaml" created     
  5. INFO OpenShift file "foo-imagestream.yaml" created          
  6. INFO OpenShift file "foo-buildconfig.yaml" created

注意:

如果使用 oc create -f 手动推送 Openshift 工件,则需要确保在构建配置工件之前推送 imagestream 工件,以解决 Openshift 的这个问题:https://github.com/openshift/origin/issues/4518

kompose up

Kompose 支持通过 kompose up 直接将您的”复合的(composed)” 应用程序部署到 Kubernetes 或 OpenShift。

Kubernetes

  1. $ kompose --file ./examples/docker-guestbook.yml up
  2. We are going to create Kubernetes deployments and services for your Dockerized application.
  3. If you need different kind of resources, use the 'kompose convert' and 'kubectl create -f' commands instead.
  5. INFO Successfully created service: redis-master   
  6. INFO Successfully created service: redis-slave    
  7. INFO Successfully created service: frontend       
  8. INFO Successfully created deployment: redis-master
  9. INFO Successfully created deployment: redis-slave
  10. INFO Successfully created deployment: frontend    
  12. Your application has been deployed to Kubernetes. You can run 'kubectl get deployment,svc,pods' for details.
  14. $ kubectl get deployment,svc,pods
  15. NAME                                              DESIRED       CURRENT       UP-TO-DATE   AVAILABLE   AGE
  16. deployment.extensions/frontend                    1             1             1            1           4m
  17. deployment.extensions/redis-master                1             1             1            1           4m
  18. deployment.extensions/redis-slave                 1             1             1            1           4m
  20. NAME                         TYPE               CLUSTER-IP    EXTERNAL-IP   PORT(S)      AGE
  21. service/frontend             ClusterIP          10.0.174.12   <none>        80/TCP       4m
  22. service/kubernetes           ClusterIP          10.0.0.1      <none>        443/TCP      13d
  23. service/redis-master         ClusterIP          10.0.202.43   <none>        6379/TCP     4m
  24. service/redis-slave          ClusterIP          10.0.1.85     <none>        6379/TCP     4m
  26. NAME                                READY         STATUS        RESTARTS     AGE
  27. pod/frontend-2768218532-cs5t5       1/1           Running       0            4m
  28. pod/redis-master-1432129712-63jn8   1/1           Running       0            4m
  29. pod/redis-slave-2504961300-nve7b    1/1           Running       0            4m

注意

  • 您必须有一个运行正常的 Kubernetes 集群,该集群具有预先配置的 kubectl 上下文。
  • 此操作仅生成 Deployment 和 Service 对象并将其部署到 Kubernetes。如果需要部署其他不同类型的资源,请使用 kompose convertkubectl create -f 命令。

OpenShift

  1. $ kompose --file ./examples/docker-guestbook.yml --provider openshift up
  2. We are going to create OpenShift DeploymentConfigs and Services for your Dockerized application.
  3. If you need different kind of resources, use the 'kompose convert' and 'oc create -f' commands instead.
  5. INFO Successfully created service: redis-slave    
  6. INFO Successfully created service: frontend       
  7. INFO Successfully created service: redis-master   
  8. INFO Successfully created deployment: redis-slave
  9. INFO Successfully created ImageStream: redis-slave
  10. INFO Successfully created deployment: frontend    
  11. INFO Successfully created ImageStream: frontend   
  12. INFO Successfully created deployment: redis-master
  13. INFO Successfully created ImageStream: redis-master
  15. Your application has been deployed to OpenShift. You can run 'oc get dc,svc,is' for details.
  17. $ oc get dc,svc,is
  18. NAME               REVISION                              DESIRED       CURRENT    TRIGGERED BY
  19. dc/frontend        0                                     1             0          config,image(frontend:v4)
  20. dc/redis-master    0                                     1             0          config,image(redis-master:e2e)
  21. dc/redis-slave     0                                     1             0          config,image(redis-slave:v1)
  22. NAME               CLUSTER-IP                            EXTERNAL-IP   PORT(S)    AGE
  23. svc/frontend       172.30.46.64                          <none>        80/TCP     8s
  24. svc/redis-master   172.30.144.56                         <none>        6379/TCP   8s
  25. svc/redis-slave    172.30.75.245                         <none>        6379/TCP   8s
  26. NAME               DOCKER REPO                           TAGS          UPDATED
  27. is/frontend        172.30.12.200:5000/fff/frontend                     
  28. is/redis-master    172.30.12.200:5000/fff/redis-master                 
  29. is/redis-slave     172.30.12.200:5000/fff/redis-slave    v1

注意

  • 您必须有一个运行正常的 OpenShift 集群,该集群具有预先配置的 oc 上下文 (oc login)。

kompose down

您一旦将”复合(composed)” 应用部署到 Kubernetes,$ kompose down 命令将能帮您通过删除 Deployment 和 Service 对象来删除应用。如果需要删除其他资源,请使用 ‘kubectl’ 命令。

  1. $ kompose --file docker-guestbook.yml down
  2. INFO Successfully deleted service: redis-master   
  3. INFO Successfully deleted deployment: redis-master
  4. INFO Successfully deleted service: redis-slave    
  5. INFO Successfully deleted deployment: redis-slave
  6. INFO Successfully deleted service: frontend       
  7. INFO Successfully deleted deployment: frontend

注意

  • 您必须有一个运行正常的 Kubernetes 集群,该集群具有预先配置的 kubectl 上下文。

构建和推送 Docker 镜像

Kompose 支持构建和推送 Docker 镜像。如果 Docker Compose 文件中使用了 build 关键字,您的镜像将会:

  • 使用文档中指定的 image 键自动构建 Docker 镜像
  • 使用本地凭据推送到正确的 Docker 仓库

使用 Docker Compose 文件示例

  1. version: "2"
  3. services:
  4.     foo:
  5.         build: "./build"
  6.         image: docker.io/foo/bar

使用带有 build 键的 kompose up 命令:

  1. $ kompose up
  2. INFO Build key detected. Attempting to build and push image 'docker.io/foo/bar'
  3. INFO Building image 'docker.io/foo/bar' from directory 'build'
  4. INFO Image 'docker.io/foo/bar' from directory 'build' built successfully
  5. INFO Pushing image 'foo/bar:latest' to registry 'docker.io'
  6. INFO Attempting authentication credentials 'https://index.docker.io/v1/
  7. INFO Successfully pushed image 'foo/bar:latest' to registry 'docker.io'
  8. INFO We are going to create Kubernetes Deployments, Services and PersistentVolumeClaims for your Dockerized application. If you need different kind of resources, use the 'kompose convert' and 'kubectl create -f' commands instead.
  10. INFO Deploying application in "default" namespace
  11. INFO Successfully created Service: foo            
  12. INFO Successfully created Deployment: foo         
  14. Your application has been deployed to Kubernetes. You can run 'kubectl get deployment,svc,pods,pvc' for details.

要想禁用该功能,或者使用 BuildConfig 中的版本(在 OpenShift 中),可以通过传递 --build (local|build-config|none) 参数来实现。

  1. # Disable building/pushing Docker images
  2. $ kompose up --build none
  4. # Generate Build Config artifacts for OpenShift
  5. $ kompose up --provider openshift --build build-config

其他转换方式

默认的 kompose 转换会生成 yaml 格式的 Kubernetes DeploymentService 对象。 您可以选择通过 -j 参数生成 json 格式的对象。 您也可以替换生成 Replication Controllers 对象、Daemon SetsHelm charts。

  1. $ kompose convert -j
  2. INFO Kubernetes file "redis-svc.json" created
  3. INFO Kubernetes file "web-svc.json" created
  4. INFO Kubernetes file "redis-deployment.json" created
  5. INFO Kubernetes file "web-deployment.json" created

*-deployment.json 文件中包含 Deployment 对象。

  1. $ kompose convert --replication-controller
  2. INFO Kubernetes file "redis-svc.yaml" created
  3. INFO Kubernetes file "web-svc.yaml" created
  4. INFO Kubernetes file "redis-replicationcontroller.yaml" created
  5. INFO Kubernetes file "web-replicationcontroller.yaml" created

*-replicationcontroller.yaml 文件包含 Replication Controller 对象。如果您想指定副本数(默认为 1),可以使用 --replicas 参数:$ kompose convert --replication-controller --replicas 3

  1. $ kompose convert --daemon-set
  2. INFO Kubernetes file "redis-svc.yaml" created
  3. INFO Kubernetes file "web-svc.yaml" created
  4. INFO Kubernetes file "redis-daemonset.yaml" created
  5. INFO Kubernetes file "web-daemonset.yaml" created

*-daemonset.yaml 文件包含 Daemon Set 对象。

如果您想生成 Helm 可用的 Chart,只需简单的执行下面的命令:

  1. $ kompose convert -c
  2. INFO Kubernetes file "web-svc.yaml" created
  3. INFO Kubernetes file "redis-svc.yaml" created
  4. INFO Kubernetes file "web-deployment.yaml" created
  5. INFO Kubernetes file "redis-deployment.yaml" created
  6. chart created in "./docker-compose/"
  8. $ tree docker-compose/
  9. docker-compose
  10. ├── Chart.yaml
  11. ├── README.md
  12. └── templates
  13.     ├── redis-deployment.yaml
  14.     ├── redis-svc.yaml
  15.     ├── web-deployment.yaml
  16.     └── web-svc.yaml

这个图标结构旨在为构建 Helm Chart 提供框架。

标签

kompose 支持 docker-compose.yml 文件中用于 Kompose 的标签,以便在转换时明确定义 Service 的行为。

  • kompose.service.type 定义要创建的 Service 类型。

    1. version: "2"
    2. services:
    3. nginx:
    4. image: nginx
    5. dockerfile: foobar
    6. build: ./foobar
    7. cap_add:
    8.   - ALL
    9. container_name: foobar
    10. labels:
    11.   kompose.service.type: nodeport
  • kompose.service.expose 定义 是否允许从集群外部访问 Service。如果该值被设置为 “true”,提供程序将自动设置端点,对于任何其他值,该值将被设置为主机名。如果在 Service 中定义了多个端口,则选择第一个端口作为公开端口。
    • 对于 Kubernetes 驱动程序,创建了一个 Ingress 资源,并且假定已经配置了相应的 Ingress 控制器。
    • 对于 OpenShift 驱动程序, 创建一个 route。

例如:

  1. version: "2"
  2. services:
  3.   web:
  4.     image: tuna/docker-counter23
  5.     ports:
  6.      - "5000:5000"
  7.     links:
  8.      - redis
  9.     labels:
  10.       kompose.service.expose: "counter.example.com"
  11.   redis:
  12.     image: redis:3.0
  13.     ports:
  14.      - "6379"

当前支持的选项有:

kompose.service.typenodeport / clusterip / loadbalancer
kompose.service.exposetrue / hostname

注意:

kompose.service.type 标签应该只用ports来定义,否则 kompose 会失败。

重启

如果你想创建没有控制器的普通 Pod,可以使用 docker-compose 的 restart 结构来定义它。请参考下表了解 restart 的不同参数。

docker-compose restart创建的对象Pod restartPolicy
“”控制器对象Always
always控制器对象Always
on-failurePodOnFailure
noPodNever

注意:

控制器对象可以是 deploymentreplicationcontroller 等。

例如,pival Service 将在这里变成 Pod。这个容器的计算值为 pi

  1. version: '2'
  3. services:
  4.   pival:
  5.     image: perl
  6.     command: ["perl",  "-Mbignum=bpi", "-wle", "print bpi(2000)"]
  7.     restart: "on-failure"

关于 Deployment Config 的提醒

如果 Docker Compose 文件中为服务声明了卷,Deployment (Kubernetes) 或 DeploymentConfig (OpenShift) 的策略会从 “RollingUpdate” (默认) 变为 “Recreate”。 这样做的目的是为了避免服务的多个实例同时访问卷。

如果 Docker Compose 文件中的服务名包含 _ (例如 web_service),那么将会被替换为 -,服务也相应的会重命名(例如 web-service)。 Kompose 这样做的原因是 “Kubernetes” 不允许对象名称中包含 _

Docker Compose 版本

Kompose 支持的 Docker Compose 版本包括:1、2 和 3。有限支持 2.1 和 3.2 版本,因为它们还在实验阶段。

所有三个版本的兼容性列表请查看我们的 转换文档,文档中列出了所有不兼容的 Docker Compose 关键字。