kubernetes/pkg/api/helpers.go

/*
Copyright 2014 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 api

import (
	"crypto/md5"
	"fmt"
	"reflect"
	"strings"
	"time"

	"github.com/davecgh/go-spew/spew"

	"k8s.io/apimachinery/pkg/api/resource"
	metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
	"k8s.io/apimachinery/pkg/conversion"
	"k8s.io/apimachinery/pkg/fields"
	"k8s.io/apimachinery/pkg/labels"
	"k8s.io/apimachinery/pkg/runtime"
	"k8s.io/apimachinery/pkg/selection"
	"k8s.io/apimachinery/pkg/util/sets"
)

// Conversion error conveniently packages up errors in conversions.
type ConversionError struct {
	In, Out interface{}
	Message string
}

// Return a helpful string about the error
func (c *ConversionError) Error() string {
	return spew.Sprintf(
		"Conversion error: %s. (in: %v(%+v) out: %v)",
		c.Message, reflect.TypeOf(c.In), c.In, reflect.TypeOf(c.Out),
	)
}

const (
	// annotation key prefix used to identify non-convertible json paths.
	NonConvertibleAnnotationPrefix = "non-convertible.kubernetes.io"
)

// NonConvertibleFields iterates over the provided map and filters out all but
// any keys with the "non-convertible.kubernetes.io" prefix.
func NonConvertibleFields(annotations map[string]string) map[string]string {
	nonConvertibleKeys := map[string]string{}
	for key, value := range annotations {
		if strings.HasPrefix(key, NonConvertibleAnnotationPrefix) {
			nonConvertibleKeys[key] = value
		}
	}
	return nonConvertibleKeys
}

// Semantic can do semantic deep equality checks for api objects.
// Example: apiequality.Semantic.DeepEqual(aPod, aPodWithNonNilButEmptyMaps) == true
var Semantic = conversion.EqualitiesOrDie(
	func(a, b resource.Quantity) bool {
		// Ignore formatting, only care that numeric value stayed the same.
		// TODO: if we decide it's important, it should be safe to start comparing the format.
		//
		// Uninitialized quantities are equivalent to 0 quantities.
		return a.Cmp(b) == 0
	},
	func(a, b metav1.Time) bool {
		return a.UTC() == b.UTC()
	},
	func(a, b labels.Selector) bool {
		return a.String() == b.String()
	},
	func(a, b fields.Selector) bool {
		return a.String() == b.String()
	},
)

var standardResourceQuotaScopes = sets.NewString(
	string(ResourceQuotaScopeTerminating),
	string(ResourceQuotaScopeNotTerminating),
	string(ResourceQuotaScopeBestEffort),
	string(ResourceQuotaScopeNotBestEffort),
)

// IsStandardResourceQuotaScope returns true if the scope is a standard value
func IsStandardResourceQuotaScope(str string) bool {
	return standardResourceQuotaScopes.Has(str)
}

var podObjectCountQuotaResources = sets.NewString(
	string(ResourcePods),
)

var podComputeQuotaResources = sets.NewString(
	string(ResourceCPU),
	string(ResourceMemory),
	string(ResourceLimitsCPU),
	string(ResourceLimitsMemory),
	string(ResourceRequestsCPU),
	string(ResourceRequestsMemory),
)

// IsResourceQuotaScopeValidForResource returns true if the resource applies to the specified scope
func IsResourceQuotaScopeValidForResource(scope ResourceQuotaScope, resource string) bool {
	switch scope {
	case ResourceQuotaScopeTerminating, ResourceQuotaScopeNotTerminating, ResourceQuotaScopeNotBestEffort:
		return podObjectCountQuotaResources.Has(resource) || podComputeQuotaResources.Has(resource)
	case ResourceQuotaScopeBestEffort:
		return podObjectCountQuotaResources.Has(resource)
	default:
		return true
	}
}

var standardContainerResources = sets.NewString(
	string(ResourceCPU),
	string(ResourceMemory),
)

// IsStandardContainerResourceName returns true if the container can make a resource request
// for the specified resource
func IsStandardContainerResourceName(str string) bool {
	return standardContainerResources.Has(str)
}

// IsOpaqueIntResourceName returns true if the resource name has the opaque
// integer resource prefix.
func IsOpaqueIntResourceName(name ResourceName) bool {
	return strings.HasPrefix(string(name), ResourceOpaqueIntPrefix)
}

// OpaqueIntResourceName returns a ResourceName with the canonical opaque
// integer prefix prepended. If the argument already has the prefix, it is
// returned unmodified.
func OpaqueIntResourceName(name string) ResourceName {
	if IsOpaqueIntResourceName(ResourceName(name)) {
		return ResourceName(name)
	}
	return ResourceName(fmt.Sprintf("%s%s", ResourceOpaqueIntPrefix, name))
}

var standardLimitRangeTypes = sets.NewString(
	string(LimitTypePod),
	string(LimitTypeContainer),
	string(LimitTypePersistentVolumeClaim),
)

// IsStandardLimitRangeType returns true if the type is Pod or Container
func IsStandardLimitRangeType(str string) bool {
	return standardLimitRangeTypes.Has(str)
}

var standardQuotaResources = sets.NewString(
	string(ResourceCPU),
	string(ResourceMemory),
	string(ResourceRequestsCPU),
	string(ResourceRequestsMemory),
	string(ResourceRequestsStorage),
	string(ResourceLimitsCPU),
	string(ResourceLimitsMemory),
	string(ResourcePods),
	string(ResourceQuotas),
	string(ResourceServices),
	string(ResourceReplicationControllers),
	string(ResourceSecrets),
	string(ResourcePersistentVolumeClaims),
	string(ResourceConfigMaps),
	string(ResourceServicesNodePorts),
	string(ResourceServicesLoadBalancers),
)

// IsStandardQuotaResourceName returns true if the resource is known to
// the quota tracking system
func IsStandardQuotaResourceName(str string) bool {
	return standardQuotaResources.Has(str)
}

var standardResources = sets.NewString(
	string(ResourceCPU),
	string(ResourceMemory),
	string(ResourceRequestsCPU),
	string(ResourceRequestsMemory),
	string(ResourceLimitsCPU),
	string(ResourceLimitsMemory),
	string(ResourcePods),
	string(ResourceQuotas),
	string(ResourceServices),
	string(ResourceReplicationControllers),
	string(ResourceSecrets),
	string(ResourceConfigMaps),
	string(ResourcePersistentVolumeClaims),
	string(ResourceStorage),
	string(ResourceRequestsStorage),
)

// IsStandardResourceName returns true if the resource is known to the system
func IsStandardResourceName(str string) bool {
	return standardResources.Has(str)
}

var integerResources = sets.NewString(
	string(ResourcePods),
	string(ResourceQuotas),
	string(ResourceServices),
	string(ResourceReplicationControllers),
	string(ResourceSecrets),
	string(ResourceConfigMaps),
	string(ResourcePersistentVolumeClaims),
	string(ResourceServicesNodePorts),
	string(ResourceServicesLoadBalancers),
)

// IsIntegerResourceName returns true if the resource is measured in integer values
func IsIntegerResourceName(str string) bool {
	return integerResources.Has(str) || IsOpaqueIntResourceName(ResourceName(str))
}

// this function aims to check if the service's ClusterIP is set or not
// the objective is not to perform validation here
func IsServiceIPSet(service *Service) bool {
	return service.Spec.ClusterIP != ClusterIPNone && service.Spec.ClusterIP != ""
}

// this function aims to check if the service's cluster IP is requested or not
func IsServiceIPRequested(service *Service) bool {
	// ExternalName services are CNAME aliases to external ones. Ignore the IP.
	if service.Spec.Type == ServiceTypeExternalName {
		return false
	}
	return service.Spec.ClusterIP == ""
}

var standardFinalizers = sets.NewString(
	string(FinalizerKubernetes),
	metav1.FinalizerOrphanDependents,
)

// HasAnnotation returns a bool if passed in annotation exists
func HasAnnotation(obj ObjectMeta, ann string) bool {
	_, found := obj.Annotations[ann]
	return found
}

// SetMetaDataAnnotation sets the annotation and value
func SetMetaDataAnnotation(obj *ObjectMeta, ann string, value string) {
	if obj.Annotations == nil {
		obj.Annotations = make(map[string]string)
	}
	obj.Annotations[ann] = value
}

func IsStandardFinalizerName(str string) bool {
	return standardFinalizers.Has(str)
}

// AddToNodeAddresses appends the NodeAddresses to the passed-by-pointer slice,
// only if they do not already exist
func AddToNodeAddresses(addresses *[]NodeAddress, addAddresses ...NodeAddress) {
	for _, add := range addAddresses {
		exists := false
		for _, existing := range *addresses {
			if existing.Address == add.Address && existing.Type == add.Type {
				exists = true
				break
			}
		}
		if !exists {
			*addresses = append(*addresses, add)
		}
	}
}

func HashObject(obj runtime.Object, codec runtime.Codec) (string, error) {
	data, err := runtime.Encode(codec, obj)
	if err != nil {
		return "", err
	}
	return fmt.Sprintf("%x", md5.Sum(data)), nil
}

// TODO: make method on LoadBalancerStatus?
func LoadBalancerStatusEqual(l, r *LoadBalancerStatus) bool {
	return ingressSliceEqual(l.Ingress, r.Ingress)
}

func ingressSliceEqual(lhs, rhs []LoadBalancerIngress) bool {
	if len(lhs) != len(rhs) {
		return false
	}
	for i := range lhs {
		if !ingressEqual(&lhs[i], &rhs[i]) {
			return false
		}
	}
	return true
}

func ingressEqual(lhs, rhs *LoadBalancerIngress) bool {
	if lhs.IP != rhs.IP {
		return false
	}
	if lhs.Hostname != rhs.Hostname {
		return false
	}
	return true
}

// TODO: make method on LoadBalancerStatus?
func LoadBalancerStatusDeepCopy(lb *LoadBalancerStatus) *LoadBalancerStatus {
	c := &LoadBalancerStatus{}
	c.Ingress = make([]LoadBalancerIngress, len(lb.Ingress))
	for i := range lb.Ingress {
		c.Ingress[i] = lb.Ingress[i]
	}
	return c
}

// GetAccessModesAsString returns a string representation of an array of access modes.
// modes, when present, are always in the same order: RWO,ROX,RWX.
func GetAccessModesAsString(modes []PersistentVolumeAccessMode) string {
	modes = removeDuplicateAccessModes(modes)
	modesStr := []string{}
	if containsAccessMode(modes, ReadWriteOnce) {
		modesStr = append(modesStr, "RWO")
	}
	if containsAccessMode(modes, ReadOnlyMany) {
		modesStr = append(modesStr, "ROX")
	}
	if containsAccessMode(modes, ReadWriteMany) {
		modesStr = append(modesStr, "RWX")
	}
	return strings.Join(modesStr, ",")
}

// GetAccessModesAsString returns an array of AccessModes from a string created by GetAccessModesAsString
func GetAccessModesFromString(modes string) []PersistentVolumeAccessMode {
	strmodes := strings.Split(modes, ",")
	accessModes := []PersistentVolumeAccessMode{}
	for _, s := range strmodes {
		s = strings.Trim(s, " ")
		switch {
		case s == "RWO":
			accessModes = append(accessModes, ReadWriteOnce)
		case s == "ROX":
			accessModes = append(accessModes, ReadOnlyMany)
		case s == "RWX":
			accessModes = append(accessModes, ReadWriteMany)
		}
	}
	return accessModes
}

// removeDuplicateAccessModes returns an array of access modes without any duplicates
func removeDuplicateAccessModes(modes []PersistentVolumeAccessMode) []PersistentVolumeAccessMode {
	accessModes := []PersistentVolumeAccessMode{}
	for _, m := range modes {
		if !containsAccessMode(accessModes, m) {
			accessModes = append(accessModes, m)
		}
	}
	return accessModes
}

func containsAccessMode(modes []PersistentVolumeAccessMode, mode PersistentVolumeAccessMode) bool {
	for _, m := range modes {
		if m == mode {
			return true
		}
	}
	return false
}

// ParseRFC3339 parses an RFC3339 date in either RFC3339Nano or RFC3339 format.
func ParseRFC3339(s string, nowFn func() metav1.Time) (metav1.Time, error) {
	if t, timeErr := time.Parse(time.RFC3339Nano, s); timeErr == nil {
		return metav1.Time{Time: t}, nil
	}
	t, err := time.Parse(time.RFC3339, s)
	if err != nil {
		return metav1.Time{}, err
	}
	return metav1.Time{Time: t}, nil
}

// NodeSelectorRequirementsAsSelector converts the []NodeSelectorRequirement api type into a struct that implements
// labels.Selector.
func NodeSelectorRequirementsAsSelector(nsm []NodeSelectorRequirement) (labels.Selector, error) {
	if len(nsm) == 0 {
		return labels.Nothing(), nil
	}
	selector := labels.NewSelector()
	for _, expr := range nsm {
		var op selection.Operator
		switch expr.Operator {
		case NodeSelectorOpIn:
			op = selection.In
		case NodeSelectorOpNotIn:
			op = selection.NotIn
		case NodeSelectorOpExists:
			op = selection.Exists
		case NodeSelectorOpDoesNotExist:
			op = selection.DoesNotExist
		case NodeSelectorOpGt:
			op = selection.GreaterThan
		case NodeSelectorOpLt:
			op = selection.LessThan
		default:
			return nil, fmt.Errorf("%q is not a valid node selector operator", expr.Operator)
		}
		r, err := labels.NewRequirement(expr.Key, op, expr.Values)
		if err != nil {
			return nil, err
		}
		selector = selector.Add(*r)
	}
	return selector, nil
}

const (
	// SeccompPodAnnotationKey represents the key of a seccomp profile applied
	// to all containers of a pod.
	SeccompPodAnnotationKey string = "seccomp.security.alpha.kubernetes.io/pod"

	// SeccompContainerAnnotationKeyPrefix represents the key of a seccomp profile applied
	// to one container of a pod.
	SeccompContainerAnnotationKeyPrefix string = "container.seccomp.security.alpha.kubernetes.io/"

	// CreatedByAnnotation represents the key used to store the spec(json)
	// used to create the resource.
	CreatedByAnnotation = "kubernetes.io/created-by"

	// PreferAvoidPodsAnnotationKey represents the key of preferAvoidPods data (json serialized)
	// in the Annotations of a Node.
	PreferAvoidPodsAnnotationKey string = "scheduler.alpha.kubernetes.io/preferAvoidPods"

	// SysctlsPodAnnotationKey represents the key of sysctls which are set for the infrastructure
	// container of a pod. The annotation value is a comma separated list of sysctl_name=value
	// key-value pairs. Only a limited set of whitelisted and isolated sysctls is supported by
	// the kubelet. Pods with other sysctls will fail to launch.
	SysctlsPodAnnotationKey string = "security.alpha.kubernetes.io/sysctls"

	// UnsafeSysctlsPodAnnotationKey represents the key of sysctls which are set for the infrastructure
	// container of a pod. The annotation value is a comma separated list of sysctl_name=value
	// key-value pairs. Unsafe sysctls must be explicitly enabled for a kubelet. They are properly
	// namespaced to a pod or a container, but their isolation is usually unclear or weak. Their use
	// is at-your-own-risk. Pods that attempt to set an unsafe sysctl that is not enabled for a kubelet
	// will fail to launch.
	UnsafeSysctlsPodAnnotationKey string = "security.alpha.kubernetes.io/unsafe-sysctls"

	// ObjectTTLAnnotations represents a suggestion for kubelet for how long it can cache
	// an object (e.g. secret, config map) before fetching it again from apiserver.
	// This annotation can be attached to node.
	ObjectTTLAnnotationKey string = "node.alpha.kubernetes.io/ttl"
)

// TolerationToleratesTaint checks if the toleration tolerates the taint.
func TolerationToleratesTaint(toleration *Toleration, taint *Taint) bool {
	if len(toleration.Effect) != 0 && toleration.Effect != taint.Effect {
		return false
	}

	if toleration.Key != taint.Key {
		return false
	}
	// TODO: Use proper defaulting when Toleration becomes a field of PodSpec
	if (len(toleration.Operator) == 0 || toleration.Operator == TolerationOpEqual) && toleration.Value == taint.Value {
		return true
	}
	if toleration.Operator == TolerationOpExists {
		return true
	}
	return false
}

// TaintToleratedByTolerations checks if taint is tolerated by any of the tolerations.
func TaintToleratedByTolerations(taint *Taint, tolerations []Toleration) bool {
	tolerated := false
	for i := range tolerations {
		if TolerationToleratesTaint(&tolerations[i], taint) {
			tolerated = true
			break
		}
	}
	return tolerated
}

// MatchTaint checks if the taint matches taintToMatch. Taints are unique by key:effect,
// if the two taints have same key:effect, regard as they match.
func (t *Taint) MatchTaint(taintToMatch Taint) bool {
	return t.Key == taintToMatch.Key && t.Effect == taintToMatch.Effect
}

// taint.ToString() converts taint struct to string in format key=value:effect or key:effect.
func (t *Taint) ToString() string {
	if len(t.Value) == 0 {
		return fmt.Sprintf("%v:%v", t.Key, t.Effect)
	}
	return fmt.Sprintf("%v=%v:%v", t.Key, t.Value, t.Effect)
}

// SysctlsFromPodAnnotations parses the sysctl annotations into a slice of safe Sysctls
// and a slice of unsafe Sysctls. This is only a convenience wrapper around
// SysctlsFromPodAnnotation.
func SysctlsFromPodAnnotations(a map[string]string) ([]Sysctl, []Sysctl, error) {
	safe, err := SysctlsFromPodAnnotation(a[SysctlsPodAnnotationKey])
	if err != nil {
		return nil, nil, err
	}
	unsafe, err := SysctlsFromPodAnnotation(a[UnsafeSysctlsPodAnnotationKey])
	if err != nil {
		return nil, nil, err
	}

	return safe, unsafe, nil
}

// SysctlsFromPodAnnotation parses an annotation value into a slice of Sysctls.
func SysctlsFromPodAnnotation(annotation string) ([]Sysctl, error) {
	if len(annotation) == 0 {
		return nil, nil
	}

	kvs := strings.Split(annotation, ",")
	sysctls := make([]Sysctl, len(kvs))
	for i, kv := range kvs {
		cs := strings.Split(kv, "=")
		if len(cs) != 2 || len(cs[0]) == 0 {
			return nil, fmt.Errorf("sysctl %q not of the format sysctl_name=value", kv)
		}
		sysctls[i].Name = cs[0]
		sysctls[i].Value = cs[1]
	}
	return sysctls, nil
}

// PodAnnotationsFromSysctls creates an annotation value for a slice of Sysctls.
func PodAnnotationsFromSysctls(sysctls []Sysctl) string {
	if len(sysctls) == 0 {
		return ""
	}

	kvs := make([]string, len(sysctls))
	for i := range sysctls {
		kvs[i] = fmt.Sprintf("%s=%s", sysctls[i].Name, sysctls[i].Value)
	}
	return strings.Join(kvs, ",")
}

// GetPersistentVolumeClass returns StorageClassName.
func GetPersistentVolumeClass(volume *PersistentVolume) string {
	// Use beta annotation first
	if class, found := volume.Annotations[BetaStorageClassAnnotation]; found {
		return class
	}

	return volume.Spec.StorageClassName
}

// GetPersistentVolumeClaimClass returns StorageClassName. If no storage class was
// requested, it returns "".
func GetPersistentVolumeClaimClass(claim *PersistentVolumeClaim) string {
	// Use beta annotation first
	if class, found := claim.Annotations[BetaStorageClassAnnotation]; found {
		return class
	}

	if claim.Spec.StorageClassName != nil {
		return *claim.Spec.StorageClassName
	}

	return ""
}

// PersistentVolumeClaimHasClass returns true if given claim has set StorageClassName field.
func PersistentVolumeClaimHasClass(claim *PersistentVolumeClaim) bool {
	// Use beta annotation first
	if _, found := claim.Annotations[BetaStorageClassAnnotation]; found {
		return true
	}

	if claim.Spec.StorageClassName != nil {
		return true
	}

	return false
}