/* Copyright 2017 The Kubernetes Authors. 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 staticpod import ( "bytes" "fmt" "io/ioutil" "net" "net/url" "os" "sort" "strings" "github.com/pkg/errors" "k8s.io/api/core/v1" "k8s.io/apimachinery/pkg/api/resource" metav1 "k8s.io/apimachinery/pkg/apis/meta/v1" kubeadmapi "k8s.io/kubernetes/cmd/kubeadm/app/apis/kubeadm" kubeadmconstants "k8s.io/kubernetes/cmd/kubeadm/app/constants" "k8s.io/kubernetes/cmd/kubeadm/app/util" ) const ( // kubeControllerManagerAddressArg represents the address argument of the kube-controller-manager configuration. kubeControllerManagerAddressArg = "address" // kubeSchedulerAddressArg represents the address argument of the kube-scheduler configuration. kubeSchedulerAddressArg = "address" // etcdListenClientURLsArg represents the listen-client-urls argument of the etcd configuration. etcdListenClientURLsArg = "listen-client-urls" ) // ComponentPod returns a Pod object from the container and volume specifications func ComponentPod(container v1.Container, volumes map[string]v1.Volume) v1.Pod { return v1.Pod{ TypeMeta: metav1.TypeMeta{ APIVersion: "v1", Kind: "Pod", }, ObjectMeta: metav1.ObjectMeta{ Name: container.Name, Namespace: metav1.NamespaceSystem, // The component and tier labels are useful for quickly identifying the control plane Pods when doing a .List() // against Pods in the kube-system namespace. Can for example be used together with the WaitForPodsWithLabel function Labels: map[string]string{"component": container.Name, "tier": "control-plane"}, }, Spec: v1.PodSpec{ Containers: []v1.Container{container}, PriorityClassName: "system-cluster-critical", HostNetwork: true, Volumes: VolumeMapToSlice(volumes), }, } } // ComponentResources returns the v1.ResourceRequirements object needed for allocating a specified amount of the CPU func ComponentResources(cpu string) v1.ResourceRequirements { return v1.ResourceRequirements{ Requests: v1.ResourceList{ v1.ResourceName(v1.ResourceCPU): resource.MustParse(cpu), }, } } // EtcdProbe is a helper function for building a shell-based, etcdctl v1.Probe object to healthcheck etcd func EtcdProbe(cfg *kubeadmapi.Etcd, port int, certsDir string, CACertName string, CertName string, KeyName string) *v1.Probe { tlsFlags := fmt.Sprintf("--cacert=%[1]s/%[2]s --cert=%[1]s/%[3]s --key=%[1]s/%[4]s", certsDir, CACertName, CertName, KeyName) // etcd pod is alive if a linearizable get succeeds. cmd := fmt.Sprintf("ETCDCTL_API=3 etcdctl --endpoints=https://[%s]:%d %s get foo", GetEtcdProbeAddress(cfg), port, tlsFlags) return &v1.Probe{ Handler: v1.Handler{ Exec: &v1.ExecAction{ Command: []string{"/bin/sh", "-ec", cmd}, }, }, InitialDelaySeconds: 15, TimeoutSeconds: 15, FailureThreshold: 8, } } // NewVolume creates a v1.Volume with a hostPath mount to the specified location func NewVolume(name, path string, pathType *v1.HostPathType) v1.Volume { return v1.Volume{ Name: name, VolumeSource: v1.VolumeSource{ HostPath: &v1.HostPathVolumeSource{ Path: path, Type: pathType, }, }, } } // NewVolumeMount creates a v1.VolumeMount to the specified location func NewVolumeMount(name, path string, readOnly bool) v1.VolumeMount { return v1.VolumeMount{ Name: name, MountPath: path, ReadOnly: readOnly, } } // VolumeMapToSlice returns a slice of volumes from a map's values func VolumeMapToSlice(volumes map[string]v1.Volume) []v1.Volume { v := make([]v1.Volume, 0, len(volumes)) for _, vol := range volumes { v = append(v, vol) } sort.Slice(v, func(i, j int) bool { return strings.Compare(v[i].Name, v[j].Name) == -1 }) return v } // VolumeMountMapToSlice returns a slice of volumes from a map's values func VolumeMountMapToSlice(volumeMounts map[string]v1.VolumeMount) []v1.VolumeMount { v := make([]v1.VolumeMount, 0, len(volumeMounts)) for _, volMount := range volumeMounts { v = append(v, volMount) } sort.Slice(v, func(i, j int) bool { return strings.Compare(v[i].Name, v[j].Name) == -1 }) return v } // GetExtraParameters builds a list of flag arguments two string-string maps, one with default, base commands and one with overrides func GetExtraParameters(overrides map[string]string, defaults map[string]string) []string { var command []string for k, v := range overrides { if len(v) > 0 { command = append(command, fmt.Sprintf("--%s=%s", k, v)) } } for k, v := range defaults { if _, overrideExists := overrides[k]; !overrideExists { command = append(command, fmt.Sprintf("--%s=%s", k, v)) } } return command } // WriteStaticPodToDisk writes a static pod file to disk func WriteStaticPodToDisk(componentName, manifestDir string, pod v1.Pod) error { // creates target folder if not already exists if err := os.MkdirAll(manifestDir, 0700); err != nil { return errors.Wrapf(err, "failed to create directory %q", manifestDir) } // writes the pod to disk serialized, err := util.MarshalToYaml(&pod, v1.SchemeGroupVersion) if err != nil { return errors.Wrapf(err, "failed to marshal manifest for %q to YAML", componentName) } filename := kubeadmconstants.GetStaticPodFilepath(componentName, manifestDir) if err := ioutil.WriteFile(filename, serialized, 0600); err != nil { return errors.Wrapf(err, "failed to write static pod manifest file for %q (%q)", componentName, filename) } return nil } // ReadStaticPodFromDisk reads a static pod file from disk func ReadStaticPodFromDisk(manifestPath string) (*v1.Pod, error) { buf, err := ioutil.ReadFile(manifestPath) if err != nil { return &v1.Pod{}, errors.Wrapf(err, "failed to read manifest for %q", manifestPath) } obj, err := util.UnmarshalFromYaml(buf, v1.SchemeGroupVersion) if err != nil { return &v1.Pod{}, errors.Errorf("failed to unmarshal manifest for %q from YAML: %v", manifestPath, err) } pod := obj.(*v1.Pod) return pod, nil } // GetAPIServerProbeAddress returns the probe address for the API server func GetAPIServerProbeAddress(endpoint *kubeadmapi.APIEndpoint) string { // In the case of a self-hosted deployment, the initial host on which kubeadm --init is run, // will generate a DaemonSet with a nodeSelector such that all nodes with the label // node-role.kubernetes.io/master='' will have the API server deployed to it. Since the init // is run only once on an initial host, the API advertise address will be invalid for any // future hosts that do not have the same address. Furthermore, since liveness and readiness // probes do not support the Downward API we cannot dynamically set the advertise address to // the node's IP. The only option then is to use localhost. if endpoint != nil && endpoint.AdvertiseAddress != "" { return endpoint.AdvertiseAddress } return "127.0.0.1" } // GetControllerManagerProbeAddress returns the kubernetes controller manager probe address func GetControllerManagerProbeAddress(cfg *kubeadmapi.ClusterConfiguration) string { if addr, exists := cfg.ControllerManager.ExtraArgs[kubeControllerManagerAddressArg]; exists { return addr } return "127.0.0.1" } // GetSchedulerProbeAddress returns the kubernetes scheduler probe address func GetSchedulerProbeAddress(cfg *kubeadmapi.ClusterConfiguration) string { if addr, exists := cfg.Scheduler.ExtraArgs[kubeSchedulerAddressArg]; exists { return addr } return "127.0.0.1" } // GetEtcdProbeAddress returns the etcd probe address func GetEtcdProbeAddress(cfg *kubeadmapi.Etcd) string { if cfg.Local != nil && cfg.Local.ExtraArgs != nil { if arg, exists := cfg.Local.ExtraArgs[etcdListenClientURLsArg]; exists { // Use the first url in the listen-client-urls if multiple url's are specified. if strings.ContainsAny(arg, ",") { arg = strings.Split(arg, ",")[0] } parsedURL, err := url.Parse(arg) if err != nil || parsedURL.Hostname() == "" { return "127.0.0.1" } // Return the IP if the URL contains an address instead of a name. if ip := net.ParseIP(parsedURL.Hostname()); ip != nil { // etcdctl doesn't support auto-converting zero addresses into loopback addresses if ip.Equal(net.IPv4zero) { return "127.0.0.1" } if ip.Equal(net.IPv6zero) { return net.IPv6loopback.String() } return ip.String() } // Use the local resolver to try resolving the name within the URL. // If the name can not be resolved, return an IPv4 loopback address. // Otherwise, select the first valid IPv4 address. // If the name does not resolve to an IPv4 address, select the first valid IPv6 address. addrs, err := net.LookupIP(parsedURL.Hostname()) if err != nil { return "127.0.0.1" } var ip net.IP for _, addr := range addrs { if addr.To4() != nil { ip = addr break } if addr.To16() != nil && ip == nil { ip = addr } } return ip.String() } } return "127.0.0.1" } // ManifestFilesAreEqual compares 2 files. It returns true if their contents are equal, false otherwise func ManifestFilesAreEqual(path1, path2 string) (bool, error) { content1, err := ioutil.ReadFile(path1) if err != nil { return false, err } content2, err := ioutil.ReadFile(path2) if err != nil { return false, err } return bytes.Equal(content1, content2), nil }