/* Copyright 2017 The Kubernetes Authors All rights reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ package kubernetes import ( "fmt" "reflect" "strconv" "time" "github.com/fatih/structs" "github.com/kubernetes/kompose/pkg/kobject" "github.com/kubernetes/kompose/pkg/transformer" buildapi "github.com/openshift/origin/pkg/build/api" deployapi "github.com/openshift/origin/pkg/deploy/api" log "github.com/sirupsen/logrus" // install kubernetes api _ "k8s.io/kubernetes/pkg/api/install" _ "k8s.io/kubernetes/pkg/apis/extensions/install" "k8s.io/kubernetes/pkg/api" "k8s.io/kubernetes/pkg/api/resource" "k8s.io/kubernetes/pkg/api/unversioned" "k8s.io/kubernetes/pkg/apis/extensions" client "k8s.io/kubernetes/pkg/client/unversioned" "k8s.io/kubernetes/pkg/kubectl" cmdutil "k8s.io/kubernetes/pkg/kubectl/cmd/util" "k8s.io/kubernetes/pkg/runtime" "k8s.io/kubernetes/pkg/util/intstr" //"k8s.io/kubernetes/pkg/controller/daemon" "sort" "strings" "github.com/pkg/errors" "k8s.io/kubernetes/pkg/api/meta" "k8s.io/kubernetes/pkg/labels" ) // Kubernetes implements Transformer interface and represents Kubernetes transformer type Kubernetes struct { // the user provided options from the command line Opt kobject.ConvertOptions } // TIMEOUT is how long we'll wait for the termination of kubernetes resource to be successful // used when undeploying resources from kubernetes const TIMEOUT = 300 // PVCRequestSize (Persistent Volume Claim) has default size const PVCRequestSize = "100Mi" // CheckUnsupportedKey checks if given komposeObject contains // keys that are not supported by this transformer. // list of all unsupported keys are stored in unsupportedKey variable // returns list of TODO: .... func (k *Kubernetes) CheckUnsupportedKey(komposeObject *kobject.KomposeObject, unsupportedKey map[string]bool) []string { // collect all keys found in project var keysFound []string for _, serviceConfig := range komposeObject.ServiceConfigs { // this reflection is used in check for empty arrays val := reflect.ValueOf(serviceConfig) s := structs.New(serviceConfig) for _, f := range s.Fields() { // Check if given key is among unsupported keys, and skip it if we already saw this key if alreadySaw, ok := unsupportedKey[f.Name()]; ok && !alreadySaw { if f.IsExported() && !f.IsZero() { // IsZero returns false for empty array/slice ([]) // this check if field is Slice, and then it checks its size if field := val.FieldByName(f.Name()); field.Kind() == reflect.Slice { if field.Len() == 0 { // array is empty it doesn't matter if it is in unsupportedKey or not continue } } //get tag from kobject service configure tag := f.Tag(komposeObject.LoadedFrom) keysFound = append(keysFound, tag) unsupportedKey[f.Name()] = true } } } } return keysFound } // InitPodSpec creates the pod specification func (k *Kubernetes) InitPodSpec(name string, image string) api.PodSpec { pod := api.PodSpec{ Containers: []api.Container{ { Name: name, Image: image, }, }, } return pod } // InitRC initializes Kubernetes ReplicationController object func (k *Kubernetes) InitRC(name string, service kobject.ServiceConfig, replicas int) *api.ReplicationController { rc := &api.ReplicationController{ TypeMeta: unversioned.TypeMeta{ Kind: "ReplicationController", APIVersion: "v1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: api.ReplicationControllerSpec{ Replicas: int32(replicas), Template: &api.PodTemplateSpec{ ObjectMeta: api.ObjectMeta{ Labels: transformer.ConfigLabels(name), }, Spec: k.InitPodSpec(name, service.Image), }, }, } return rc } // InitSvc initializes Kubernetes Service object func (k *Kubernetes) InitSvc(name string, service kobject.ServiceConfig) *api.Service { svc := &api.Service{ TypeMeta: unversioned.TypeMeta{ Kind: "Service", APIVersion: "v1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: api.ServiceSpec{ Selector: transformer.ConfigLabels(name), }, } return svc } // InitConfigMap initialized a ConfigMap object func (k *Kubernetes) InitConfigMap(name string, service kobject.ServiceConfig, opt kobject.ConvertOptions, envFile string) *api.ConfigMap { envs, err := GetEnvsFromFile(envFile, opt) if err != nil { log.Fatalf("Unable to retrieve env file: %s", err) } // Remove root pathing // replace all other slashes / preiods envName := FormatEnvName(envFile) // In order to differentiate files, we append to the name and remove '.env' if applicate from the file name configMap := &api.ConfigMap{ TypeMeta: unversioned.TypeMeta{ Kind: "ConfigMap", APIVersion: "v1", }, ObjectMeta: api.ObjectMeta{ Name: name + "-" + envName, }, Data: envs, } return configMap } // InitD initializes Kubernetes Deployment object func (k *Kubernetes) InitD(name string, service kobject.ServiceConfig, replicas int) *extensions.Deployment { dc := &extensions.Deployment{ TypeMeta: unversioned.TypeMeta{ Kind: "Deployment", APIVersion: "extensions/v1beta1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: extensions.DeploymentSpec{ Replicas: int32(replicas), Template: api.PodTemplateSpec{ Spec: k.InitPodSpec(name, service.Image), }, }, } return dc } // InitDS initializes Kubernetes DaemonSet object func (k *Kubernetes) InitDS(name string, service kobject.ServiceConfig) *extensions.DaemonSet { ds := &extensions.DaemonSet{ TypeMeta: unversioned.TypeMeta{ Kind: "DaemonSet", APIVersion: "extensions/v1beta1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: extensions.DaemonSetSpec{ Template: api.PodTemplateSpec{ Spec: k.InitPodSpec(name, service.Image), }, }, } return ds } func (k *Kubernetes) initIngress(name string, service kobject.ServiceConfig, port int32) *extensions.Ingress { ingress := &extensions.Ingress{ TypeMeta: unversioned.TypeMeta{ Kind: "Ingress", APIVersion: "extensions/v1beta1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: extensions.IngressSpec{ Rules: []extensions.IngressRule{ { IngressRuleValue: extensions.IngressRuleValue{ HTTP: &extensions.HTTPIngressRuleValue{ Paths: []extensions.HTTPIngressPath{ { Backend: extensions.IngressBackend{ ServiceName: name, ServicePort: intstr.IntOrString{ IntVal: port, }, }, }, }, }, }, }, }, }, } if service.ExposeService != "true" { ingress.Spec.Rules[0].Host = service.ExposeService } return ingress } // CreatePVC initializes PersistentVolumeClaim func (k *Kubernetes) CreatePVC(name string, mode string) (*api.PersistentVolumeClaim, error) { size, err := resource.ParseQuantity(PVCRequestSize) if err != nil { return nil, errors.Wrap(err, "resource.ParseQuantity failed, Error parsing size") } pvc := &api.PersistentVolumeClaim{ TypeMeta: unversioned.TypeMeta{ Kind: "PersistentVolumeClaim", APIVersion: "v1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: api.PersistentVolumeClaimSpec{ Resources: api.ResourceRequirements{ Requests: api.ResourceList{ api.ResourceStorage: size, }, }, }, } if mode == "ro" { pvc.Spec.AccessModes = []api.PersistentVolumeAccessMode{api.ReadOnlyMany} } else { pvc.Spec.AccessModes = []api.PersistentVolumeAccessMode{api.ReadWriteOnce} } return pvc, nil } // ConfigPorts configures the container ports. func (k *Kubernetes) ConfigPorts(name string, service kobject.ServiceConfig) []api.ContainerPort { ports := []api.ContainerPort{} for _, port := range service.Port { // If the default is already TCP, no need to include it. if port.Protocol == api.ProtocolTCP { ports = append(ports, api.ContainerPort{ ContainerPort: port.ContainerPort, HostIP: port.HostIP, }) } else { ports = append(ports, api.ContainerPort{ ContainerPort: port.ContainerPort, Protocol: port.Protocol, HostIP: port.HostIP, }) } } return ports } // ConfigServicePorts configure the container service ports. func (k *Kubernetes) ConfigServicePorts(name string, service kobject.ServiceConfig) []api.ServicePort { servicePorts := []api.ServicePort{} for _, port := range service.Port { if port.HostPort == 0 { port.HostPort = port.ContainerPort } var targetPort intstr.IntOrString targetPort.IntVal = port.ContainerPort targetPort.StrVal = strconv.Itoa(int(port.ContainerPort)) // If the default is already TCP, no need to include it. if port.Protocol == api.ProtocolTCP { servicePorts = append(servicePorts, api.ServicePort{ Name: strconv.Itoa(int(port.HostPort)), Port: port.HostPort, TargetPort: targetPort, }) } else { servicePorts = append(servicePorts, api.ServicePort{ Name: strconv.Itoa(int(port.HostPort)), Protocol: port.Protocol, Port: port.HostPort, TargetPort: targetPort, }) } } return servicePorts } //ConfigCapabilities configure POSIX capabilities that can be added or removed to a container func (k *Kubernetes) ConfigCapabilities(service kobject.ServiceConfig) *api.Capabilities { capsAdd := []api.Capability{} capsDrop := []api.Capability{} for _, capAdd := range service.CapAdd { capsAdd = append(capsAdd, api.Capability(capAdd)) } for _, capDrop := range service.CapDrop { capsDrop = append(capsDrop, api.Capability(capDrop)) } return &api.Capabilities{ Add: capsAdd, Drop: capsDrop, } } // ConfigTmpfs configure the tmpfs. func (k *Kubernetes) ConfigTmpfs(name string, service kobject.ServiceConfig) ([]api.VolumeMount, []api.Volume) { //initializing volumemounts and volumes volumeMounts := []api.VolumeMount{} volumes := []api.Volume{} for index, volume := range service.TmpFs { //naming volumes if multiple tmpfs are provided volumeName := fmt.Sprintf("%s-tmpfs%d", name, index) volume = strings.Split(volume, ":")[0] // create a new volume mount object and append to list volMount := api.VolumeMount{ Name: volumeName, MountPath: volume, } volumeMounts = append(volumeMounts, volMount) //create tmpfs specific empty volumes volSource := k.ConfigEmptyVolumeSource("tmpfs") // create a new volume object using the volsource and add to list vol := api.Volume{ Name: volumeName, VolumeSource: *volSource, } volumes = append(volumes, vol) } return volumeMounts, volumes } // ConfigVolumes configure the container volumes. func (k *Kubernetes) ConfigVolumes(name string, service kobject.ServiceConfig) ([]api.VolumeMount, []api.Volume, []*api.PersistentVolumeClaim, error) { volumeMounts := []api.VolumeMount{} volumes := []api.Volume{} var PVCs []*api.PersistentVolumeClaim var volumeName string // Set a var based on if the user wants to use empty volumes // as opposed to persistent volumes and volume claims useEmptyVolumes := k.Opt.EmptyVols if k.Opt.Volumes == "emptyDir" { useEmptyVolumes = true } var count int //interating over array of `Vols` struct as it contains all necessary information about volumes for _, volume := range service.Volumes { // check if ro/rw mode is defined, default rw readonly := len(volume.Mode) > 0 && volume.Mode == "ro" if volume.VolumeName == "" { if useEmptyVolumes { volumeName = strings.Replace(volume.PVCName, "claim", "empty", 1) } else { volumeName = volume.PVCName } count++ } else { volumeName = volume.VolumeName } volmount := api.VolumeMount{ Name: volumeName, ReadOnly: readonly, MountPath: volume.Container, } volumeMounts = append(volumeMounts, volmount) // Get a volume source based on the type of volume we are using // For PVC we will also create a PVC object and add to list var volsource *api.VolumeSource if useEmptyVolumes { volsource = k.ConfigEmptyVolumeSource("volume") } else { volsource = k.ConfigPVCVolumeSource(volumeName, readonly) if volume.VFrom == "" { createdPVC, err := k.CreatePVC(volumeName, volume.Mode) if err != nil { return nil, nil, nil, errors.Wrap(err, "k.CreatePVC failed") } PVCs = append(PVCs, createdPVC) } } // create a new volume object using the volsource and add to list vol := api.Volume{ Name: volumeName, VolumeSource: *volsource, } volumes = append(volumes, vol) if len(volume.Host) > 0 { log.Warningf("Volume mount on the host %q isn't supported - ignoring path on the host", volume.Host) } } return volumeMounts, volumes, PVCs, nil } // ConfigEmptyVolumeSource is helper function to create an EmptyDir api.VolumeSource //either for Tmpfs or for emptyvolumes func (k *Kubernetes) ConfigEmptyVolumeSource(key string) *api.VolumeSource { //if key is tmpfs if key == "tmpfs" { return &api.VolumeSource{ EmptyDir: &api.EmptyDirVolumeSource{Medium: api.StorageMediumMemory}, } } //if key is volume return &api.VolumeSource{ EmptyDir: &api.EmptyDirVolumeSource{}, } } // ConfigPVCVolumeSource is helper function to create an api.VolumeSource with a PVC func (k *Kubernetes) ConfigPVCVolumeSource(name string, readonly bool) *api.VolumeSource { return &api.VolumeSource{ PersistentVolumeClaim: &api.PersistentVolumeClaimVolumeSource{ ClaimName: name, ReadOnly: readonly, }, } } // ConfigEnvs configures the environment variables. func (k *Kubernetes) ConfigEnvs(name string, service kobject.ServiceConfig, opt kobject.ConvertOptions) ([]api.EnvVar, error) { envs := transformer.EnvSort{} // If there is an env_file, use ConfigMaps and ignore the environment variables // already specified if len(service.EnvFile) > 0 { // Load each env_file for _, file := range service.EnvFile { envName := FormatEnvName(file) // Load environment variables from file envLoad, err := GetEnvsFromFile(file, opt) if err != nil { return envs, errors.Wrap(err, "Unable to read env_file") } // Add configMapKeyRef to each environment variable for k, _ := range envLoad { envs = append(envs, api.EnvVar{ Name: k, ValueFrom: &api.EnvVarSource{ ConfigMapKeyRef: &api.ConfigMapKeySelector{ LocalObjectReference: api.LocalObjectReference{ Name: name + "-" + envName, }, Key: k, }}, }) } } } else { // Load up the environment variables for _, v := range service.Environment { envs = append(envs, api.EnvVar{ Name: v.Name, Value: v.Value, }) } } // Stable sorts data while keeping the original order of equal elements // we need this because envs are not populated in any random order // this sorting ensures they are populated in a particular order sort.Stable(envs) return envs, nil } // CreateKubernetesObjects generates a Kubernetes artifact for each input type service func (k *Kubernetes) CreateKubernetesObjects(name string, service kobject.ServiceConfig, opt kobject.ConvertOptions) []runtime.Object { var objects []runtime.Object var replica int if opt.IsReplicaSetFlag || service.Replicas == 0 { replica = opt.Replicas } else { replica = service.Replicas } // Check to see if Docker Compose v3 Deploy.Mode has been set to "global" if service.DeployMode == "global" { log.Warning("Global mode not yet supported, containers will only be replicated once throughout the cluster. DaemonSet support will be added in the future.") replica = 1 } if opt.CreateD || opt.Controller == "deployment" { objects = append(objects, k.InitD(name, service, replica)) } if opt.CreateDS || opt.Controller == "daemonset" { objects = append(objects, k.InitDS(name, service)) } if opt.CreateRC || opt.Controller == "replicationcontroller" { objects = append(objects, k.InitRC(name, service, replica)) } if len(service.EnvFile) > 0 { for _, envFile := range service.EnvFile { configMap := k.InitConfigMap(name, service, opt, envFile) objects = append(objects, configMap) } } return objects } // InitPod initializes Kubernetes Pod object func (k *Kubernetes) InitPod(name string, service kobject.ServiceConfig) *api.Pod { pod := api.Pod{ TypeMeta: unversioned.TypeMeta{ Kind: "Pod", APIVersion: "v1", }, ObjectMeta: api.ObjectMeta{ Name: name, Labels: transformer.ConfigLabels(name), }, Spec: k.InitPodSpec(name, service.Image), } return &pod } // Transform maps komposeObject to k8s objects // returns object that are already sorted in the way that Services are first func (k *Kubernetes) Transform(komposeObject kobject.KomposeObject, opt kobject.ConvertOptions) ([]runtime.Object, error) { // this will hold all the converted data var allobjects []runtime.Object sortedKeys := SortedKeys(komposeObject) for _, name := range sortedKeys { service := komposeObject.ServiceConfigs[name] var objects []runtime.Object // Must build the images before conversion (got to add service.Image in case 'image' key isn't provided // Check that --build is set to true // Check to see if there is an InputFile (required!) before we build the container // Check that there's actually a Build key // Lastly, we must have an Image name to continue if opt.Build == "local" && opt.InputFiles != nil && service.Build != "" { if service.Image == "" { return nil, fmt.Errorf("image key required within build parameters in order to build and push service '%s'", name) } log.Infof("Build key detected. Attempting to build and push image '%s'", service.Image) // Get the directory where the compose file is composeFileDir, err := transformer.GetComposeFileDir(opt.InputFiles) if err != nil { return nil, err } // Build the container! err = transformer.BuildDockerImage(service, name, composeFileDir) if err != nil { return nil, errors.Wrapf(err, "Unable to build Docker image for service %v", name) } // Push the built container to the repo! err = transformer.PushDockerImage(service, name) if err != nil { return nil, errors.Wrapf(err, "Unable to push Docker image for service %v", name) } } // If there's no "image" key, use the name of the container that's built if service.Image == "" { service.Image = name } // Generate pod only and nothing more if service.Restart == "no" || service.Restart == "on-failure" { // Error out if Controller Object is specified with restart: 'on-failure' if opt.IsDeploymentFlag || opt.IsDaemonSetFlag || opt.IsReplicationControllerFlag { return nil, errors.New("Controller object cannot be specified with restart: 'on-failure'") } pod := k.InitPod(name, service) objects = append(objects, pod) } else { objects = k.CreateKubernetesObjects(name, service, opt) // If ports not provided in configuration we will not make service if k.PortsExist(name, service) { svc := k.CreateService(name, service, objects) objects = append(objects, svc) if service.ExposeService != "" { objects = append(objects, k.initIngress(name, service, svc.Spec.Ports[0].Port)) } } else { svc := k.CreateHeadlessService(name, service, objects) objects = append(objects, svc) } } err := k.UpdateKubernetesObjects(name, service, opt, &objects) if err != nil { return nil, errors.Wrap(err, "Error transforming Kubernetes objects") } allobjects = append(allobjects, objects...) } // sort all object so Services are first k.SortServicesFirst(&allobjects) return allobjects, nil } // UpdateController updates the given object with the given pod template update function and ObjectMeta update function func (k *Kubernetes) UpdateController(obj runtime.Object, updateTemplate func(*api.PodTemplateSpec) error, updateMeta func(meta *api.ObjectMeta)) (err error) { switch t := obj.(type) { case *api.ReplicationController: if t.Spec.Template == nil { t.Spec.Template = &api.PodTemplateSpec{} } err = updateTemplate(t.Spec.Template) if err != nil { return errors.Wrap(err, "updateTemplate failed") } updateMeta(&t.ObjectMeta) case *extensions.Deployment: err = updateTemplate(&t.Spec.Template) if err != nil { return errors.Wrap(err, "updateTemplate failed") } updateMeta(&t.ObjectMeta) case *extensions.DaemonSet: err = updateTemplate(&t.Spec.Template) if err != nil { return errors.Wrap(err, "updateTemplate failed") } updateMeta(&t.ObjectMeta) case *deployapi.DeploymentConfig: err = updateTemplate(t.Spec.Template) if err != nil { return errors.Wrap(err, "updateTemplate failed") } updateMeta(&t.ObjectMeta) case *api.Pod: p := api.PodTemplateSpec{ ObjectMeta: t.ObjectMeta, Spec: t.Spec, } err = updateTemplate(&p) if err != nil { return errors.Wrap(err, "updateTemplate failed") } t.Spec = p.Spec t.ObjectMeta = p.ObjectMeta case *buildapi.BuildConfig: updateMeta(&t.ObjectMeta) } return nil } // GetKubernetesClient creates the k8s Client, returns k8s client and namespace func (k *Kubernetes) GetKubernetesClient() (*client.Client, string, error) { // initialize Kubernetes client factory := cmdutil.NewFactory(nil) clientConfig, err := factory.ClientConfig() if err != nil { return nil, "", err } client := client.NewOrDie(clientConfig) // get namespace from config namespace, _, err := factory.DefaultNamespace() if err != nil { return nil, "", err } return client, namespace, nil } // Deploy submits deployment and svc to k8s endpoint func (k *Kubernetes) Deploy(komposeObject kobject.KomposeObject, opt kobject.ConvertOptions) error { //Convert komposeObject objects, err := k.Transform(komposeObject, opt) if err != nil { return errors.Wrap(err, "k.Transform failed") } pvcStr := " " if !opt.EmptyVols || opt.Volumes != "emptyDir" { pvcStr = " and PersistentVolumeClaims " } log.Info("We are going to create Kubernetes Deployments, Services" + pvcStr + "for your Dockerized application. " + "If you need different kind of resources, use the 'kompose convert' and 'kubectl create -f' commands instead. \n") client, ns, err := k.GetKubernetesClient() namespace := ns if opt.IsNamespaceFlag { namespace = opt.Namespace } if err != nil { return err } log.Infof("Deploying application in %q namespace", namespace) for _, v := range objects { switch t := v.(type) { case *extensions.Deployment: _, err := client.Deployments(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created Deployment: %s", t.Name) case *api.Service: _, err := client.Services(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created Service: %s", t.Name) case *api.PersistentVolumeClaim: _, err := client.PersistentVolumeClaims(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created PersistentVolumeClaim: %s of size %s. If your cluster has dynamic storage provisioning, you don't have to do anything. Otherwise you have to create PersistentVolume to make PVC work", t.Name, PVCRequestSize) case *extensions.Ingress: _, err := client.Ingress(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created Ingress: %s", t.Name) case *api.Pod: _, err := client.Pods(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created Pod: %s", t.Name) case *api.ConfigMap: _, err := client.ConfigMaps(namespace).Create(t) if err != nil { return err } log.Infof("Successfully created Config Map: %s", t.Name) } } if !opt.EmptyVols || opt.Volumes != "emptyDir" { pvcStr = ",pvc" } else { pvcStr = "" } fmt.Println("\nYour application has been deployed to Kubernetes. You can run 'kubectl get deployment,svc,pods" + pvcStr + "' for details.") return nil } // Undeploy deletes deployed objects from Kubernetes cluster func (k *Kubernetes) Undeploy(komposeObject kobject.KomposeObject, opt kobject.ConvertOptions) []error { var errorList []error //Convert komposeObject objects, err := k.Transform(komposeObject, opt) if err != nil { errorList = append(errorList, err) return errorList } client, ns, err := k.GetKubernetesClient() namespace := ns if opt.IsNamespaceFlag { namespace = opt.Namespace } if err != nil { errorList = append(errorList, err) return errorList } log.Infof("Deleting application in %q namespace", namespace) for _, v := range objects { label := labels.SelectorFromSet(labels.Set(map[string]string{transformer.Selector: v.(meta.Object).GetName()})) options := api.ListOptions{LabelSelector: label} komposeLabel := map[string]string{transformer.Selector: v.(meta.Object).GetName()} switch t := v.(type) { case *extensions.Deployment: //delete deployment deployment, err := client.Deployments(namespace).List(options) if err != nil { errorList = append(errorList, err) break } for _, l := range deployment.Items { if reflect.DeepEqual(l.Labels, komposeLabel) { rpDeployment, err := kubectl.ReaperFor(extensions.Kind("Deployment"), client) if err != nil { errorList = append(errorList, err) break } //FIXME: gracePeriod is nil err = rpDeployment.Stop(namespace, t.Name, TIMEOUT*time.Second, nil) if err != nil { errorList = append(errorList, err) break } log.Infof("Successfully deleted Deployment: %s", t.Name) } } case *api.Service: //delete svc svc, err := client.Services(namespace).List(options) if err != nil { errorList = append(errorList, err) break } for _, l := range svc.Items { if reflect.DeepEqual(l.Labels, komposeLabel) { rpService, err := kubectl.ReaperFor(api.Kind("Service"), client) if err != nil { errorList = append(errorList, err) break } //FIXME: gracePeriod is nil err = rpService.Stop(namespace, t.Name, TIMEOUT*time.Second, nil) if err != nil { errorList = append(errorList, err) break } log.Infof("Successfully deleted Service: %s", t.Name) } } case *api.PersistentVolumeClaim: // delete pvc pvc, err := client.PersistentVolumeClaims(namespace).List(options) if err != nil { errorList = append(errorList, err) break } for _, l := range pvc.Items { if reflect.DeepEqual(l.Labels, komposeLabel) { err = client.PersistentVolumeClaims(namespace).Delete(t.Name) if err != nil { errorList = append(errorList, err) break } log.Infof("Successfully deleted PersistentVolumeClaim: %s", t.Name) } } case *extensions.Ingress: // delete ingress ingDeleteOptions := &api.DeleteOptions{ TypeMeta: unversioned.TypeMeta{ Kind: "Ingress", APIVersion: "extensions/v1beta1", }, } ingress, err := client.Ingress(namespace).List(options) if err != nil { errorList = append(errorList, err) break } for _, l := range ingress.Items { if reflect.DeepEqual(l.Labels, komposeLabel) { err = client.Ingress(namespace).Delete(t.Name, ingDeleteOptions) if err != nil { errorList = append(errorList, err) break } log.Infof("Successfully deleted Ingress: %s", t.Name) } } case *api.Pod: //delete pod pod, err := client.Pods(namespace).List(options) if err != nil { errorList = append(errorList, err) } for _, l := range pod.Items { if reflect.DeepEqual(l.Labels, komposeLabel) { rpPod, err := kubectl.ReaperFor(api.Kind("Pod"), client) if err != nil { errorList = append(errorList, err) break } //FIXME: gracePeriod is nil err = rpPod.Stop(namespace, t.Name, TIMEOUT*time.Second, nil) if err != nil { errorList = append(errorList, err) break } log.Infof("Successfully deleted Pod: %s", t.Name) } } } } return errorList }