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rebase: update K8s packages to v0.32.1

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Update K8s packages in go.mod to v0.32.1

Signed-off-by: Praveen M <m.praveen@ibm.com>
This commit is contained in:
Praveen M
2025-01-16 09:41:46 +05:30
committed by mergify[bot]
parent 5aef21ea4e
commit 7eb99fc6c9
2442 changed files with 273386 additions and 47788 deletions
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vendor/k8s.io/kube-scheduler/config/v1/doc.go generated vendored Normal file
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/*
Copyright 2022 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.
*/
// +k8s:deepcopy-gen=package
// +k8s:openapi-gen=true
// +groupName=kubescheduler.config.k8s.io
package v1 // import "k8s.io/kube-scheduler/config/v1"

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vendor/k8s.io/kube-scheduler/config/v1/register.go generated vendored Normal file
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/*
Copyright 2022 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 v1
import (
"k8s.io/apimachinery/pkg/runtime"
"k8s.io/apimachinery/pkg/runtime/schema"
)
// GroupName is the group name used in this package
const GroupName = "kubescheduler.config.k8s.io"
// SchemeGroupVersion is group version used to register these objects
var SchemeGroupVersion = schema.GroupVersion{Group: GroupName, Version: "v1"}
var (
// SchemeBuilder is the scheme builder with scheme init functions to run for this API package
SchemeBuilder = runtime.NewSchemeBuilder(addKnownTypes)
// AddToScheme is a global function that registers this API group & version to a scheme
AddToScheme = SchemeBuilder.AddToScheme
)
// addKnownTypes registers known types to the given scheme
func addKnownTypes(scheme *runtime.Scheme) error {
scheme.AddKnownTypes(SchemeGroupVersion,
&KubeSchedulerConfiguration{},
&DefaultPreemptionArgs{},
&InterPodAffinityArgs{},
&NodeResourcesBalancedAllocationArgs{},
&NodeResourcesFitArgs{},
&PodTopologySpreadArgs{},
&VolumeBindingArgs{},
&NodeAffinityArgs{},
)
return nil
}

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vendor/k8s.io/kube-scheduler/config/v1/types.go generated vendored Normal file
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/*
Copyright 2022 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 v1
import (
"bytes"
"fmt"
metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
"k8s.io/apimachinery/pkg/runtime"
componentbaseconfigv1alpha1 "k8s.io/component-base/config/v1alpha1"
"sigs.k8s.io/yaml"
)
const (
// SchedulerDefaultLockObjectNamespace defines default scheduler lock object namespace ("kube-system")
SchedulerDefaultLockObjectNamespace string = metav1.NamespaceSystem
// SchedulerDefaultLockObjectName defines default scheduler lock object name ("kube-scheduler")
SchedulerDefaultLockObjectName = "kube-scheduler"
// SchedulerDefaultProviderName defines the default provider names
SchedulerDefaultProviderName = "DefaultProvider"
)
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// KubeSchedulerConfiguration configures a scheduler
type KubeSchedulerConfiguration struct {
metav1.TypeMeta `json:",inline"`
// Parallelism defines the amount of parallelism in algorithms for scheduling a Pods. Must be greater than 0. Defaults to 16
Parallelism *int32 `json:"parallelism,omitempty"`
// LeaderElection defines the configuration of leader election client.
LeaderElection componentbaseconfigv1alpha1.LeaderElectionConfiguration `json:"leaderElection"`
// ClientConnection specifies the kubeconfig file and client connection
// settings for the proxy server to use when communicating with the apiserver.
ClientConnection componentbaseconfigv1alpha1.ClientConnectionConfiguration `json:"clientConnection"`
// DebuggingConfiguration holds configuration for Debugging related features
// TODO: We might wanna make this a substruct like Debugging componentbaseconfigv1alpha1.DebuggingConfiguration
componentbaseconfigv1alpha1.DebuggingConfiguration `json:",inline"`
// PercentageOfNodesToScore is the percentage of all nodes that once found feasible
// for running a pod, the scheduler stops its search for more feasible nodes in
// the cluster. This helps improve scheduler's performance. Scheduler always tries to find
// at least "minFeasibleNodesToFind" feasible nodes no matter what the value of this flag is.
// Example: if the cluster size is 500 nodes and the value of this flag is 30,
// then scheduler stops finding further feasible nodes once it finds 150 feasible ones.
// When the value is 0, default percentage (5%--50% based on the size of the cluster) of the
// nodes will be scored. It is overridden by profile level PercentageOfNodesToScore.
PercentageOfNodesToScore *int32 `json:"percentageOfNodesToScore,omitempty"`
// PodInitialBackoffSeconds is the initial backoff for unschedulable pods.
// If specified, it must be greater than 0. If this value is null, the default value (1s)
// will be used.
PodInitialBackoffSeconds *int64 `json:"podInitialBackoffSeconds,omitempty"`
// PodMaxBackoffSeconds is the max backoff for unschedulable pods.
// If specified, it must be greater than podInitialBackoffSeconds. If this value is null,
// the default value (10s) will be used.
PodMaxBackoffSeconds *int64 `json:"podMaxBackoffSeconds,omitempty"`
// Profiles are scheduling profiles that kube-scheduler supports. Pods can
// choose to be scheduled under a particular profile by setting its associated
// scheduler name. Pods that don't specify any scheduler name are scheduled
// with the "default-scheduler" profile, if present here.
// +listType=map
// +listMapKey=schedulerName
Profiles []KubeSchedulerProfile `json:"profiles,omitempty"`
// Extenders are the list of scheduler extenders, each holding the values of how to communicate
// with the extender. These extenders are shared by all scheduler profiles.
// +listType=set
Extenders []Extender `json:"extenders,omitempty"`
// DelayCacheUntilActive specifies when to start caching. If this is true and leader election is enabled,
// the scheduler will wait to fill informer caches until it is the leader. Doing so will have slower
// failover with the benefit of lower memory overhead while waiting to become leader.
// Defaults to false.
DelayCacheUntilActive bool `json:"delayCacheUntilActive,omitempty"`
}
// DecodeNestedObjects decodes plugin args for known types.
func (c *KubeSchedulerConfiguration) DecodeNestedObjects(d runtime.Decoder) error {
var strictDecodingErrs []error
for i := range c.Profiles {
prof := &c.Profiles[i]
for j := range prof.PluginConfig {
err := prof.PluginConfig[j].decodeNestedObjects(d)
if err != nil {
decodingErr := fmt.Errorf("decoding .profiles[%d].pluginConfig[%d]: %w", i, j, err)
if runtime.IsStrictDecodingError(err) {
strictDecodingErrs = append(strictDecodingErrs, decodingErr)
} else {
return decodingErr
}
}
}
}
if len(strictDecodingErrs) > 0 {
return runtime.NewStrictDecodingError(strictDecodingErrs)
}
return nil
}
// EncodeNestedObjects encodes plugin args.
func (c *KubeSchedulerConfiguration) EncodeNestedObjects(e runtime.Encoder) error {
for i := range c.Profiles {
prof := &c.Profiles[i]
for j := range prof.PluginConfig {
err := prof.PluginConfig[j].encodeNestedObjects(e)
if err != nil {
return fmt.Errorf("encoding .profiles[%d].pluginConfig[%d]: %w", i, j, err)
}
}
}
return nil
}
// KubeSchedulerProfile is a scheduling profile.
type KubeSchedulerProfile struct {
// SchedulerName is the name of the scheduler associated to this profile.
// If SchedulerName matches with the pod's "spec.schedulerName", then the pod
// is scheduled with this profile.
SchedulerName *string `json:"schedulerName,omitempty"`
// PercentageOfNodesToScore is the percentage of all nodes that once found feasible
// for running a pod, the scheduler stops its search for more feasible nodes in
// the cluster. This helps improve scheduler's performance. Scheduler always tries to find
// at least "minFeasibleNodesToFind" feasible nodes no matter what the value of this flag is.
// Example: if the cluster size is 500 nodes and the value of this flag is 30,
// then scheduler stops finding further feasible nodes once it finds 150 feasible ones.
// When the value is 0, default percentage (5%--50% based on the size of the cluster) of the
// nodes will be scored. It will override global PercentageOfNodesToScore. If it is empty,
// global PercentageOfNodesToScore will be used.
PercentageOfNodesToScore *int32 `json:"percentageOfNodesToScore,omitempty"`
// Plugins specify the set of plugins that should be enabled or disabled.
// Enabled plugins are the ones that should be enabled in addition to the
// default plugins. Disabled plugins are any of the default plugins that
// should be disabled.
// When no enabled or disabled plugin is specified for an extension point,
// default plugins for that extension point will be used if there is any.
// If a QueueSort plugin is specified, the same QueueSort Plugin and
// PluginConfig must be specified for all profiles.
Plugins *Plugins `json:"plugins,omitempty"`
// PluginConfig is an optional set of custom plugin arguments for each plugin.
// Omitting config args for a plugin is equivalent to using the default config
// for that plugin.
// +listType=map
// +listMapKey=name
PluginConfig []PluginConfig `json:"pluginConfig,omitempty"`
}
// Plugins include multiple extension points. When specified, the list of plugins for
// a particular extension point are the only ones enabled. If an extension point is
// omitted from the config, then the default set of plugins is used for that extension point.
// Enabled plugins are called in the order specified here, after default plugins. If they need to
// be invoked before default plugins, default plugins must be disabled and re-enabled here in desired order.
type Plugins struct {
// PreEnqueue is a list of plugins that should be invoked before adding pods to the scheduling queue.
PreEnqueue PluginSet `json:"preEnqueue,omitempty"`
// QueueSort is a list of plugins that should be invoked when sorting pods in the scheduling queue.
QueueSort PluginSet `json:"queueSort,omitempty"`
// PreFilter is a list of plugins that should be invoked at "PreFilter" extension point of the scheduling framework.
PreFilter PluginSet `json:"preFilter,omitempty"`
// Filter is a list of plugins that should be invoked when filtering out nodes that cannot run the Pod.
Filter PluginSet `json:"filter,omitempty"`
// PostFilter is a list of plugins that are invoked after filtering phase, but only when no feasible nodes were found for the pod.
PostFilter PluginSet `json:"postFilter,omitempty"`
// PreScore is a list of plugins that are invoked before scoring.
PreScore PluginSet `json:"preScore,omitempty"`
// Score is a list of plugins that should be invoked when ranking nodes that have passed the filtering phase.
Score PluginSet `json:"score,omitempty"`
// Reserve is a list of plugins invoked when reserving/unreserving resources
// after a node is assigned to run the pod.
Reserve PluginSet `json:"reserve,omitempty"`
// Permit is a list of plugins that control binding of a Pod. These plugins can prevent or delay binding of a Pod.
Permit PluginSet `json:"permit,omitempty"`
// PreBind is a list of plugins that should be invoked before a pod is bound.
PreBind PluginSet `json:"preBind,omitempty"`
// Bind is a list of plugins that should be invoked at "Bind" extension point of the scheduling framework.
// The scheduler call these plugins in order. Scheduler skips the rest of these plugins as soon as one returns success.
Bind PluginSet `json:"bind,omitempty"`
// PostBind is a list of plugins that should be invoked after a pod is successfully bound.
PostBind PluginSet `json:"postBind,omitempty"`
// MultiPoint is a simplified config section to enable plugins for all valid extension points.
// Plugins enabled through MultiPoint will automatically register for every individual extension
// point the plugin has implemented. Disabling a plugin through MultiPoint disables that behavior.
// The same is true for disabling "*" through MultiPoint (no default plugins will be automatically registered).
// Plugins can still be disabled through their individual extension points.
//
// In terms of precedence, plugin config follows this basic hierarchy
// 1. Specific extension points
// 2. Explicitly configured MultiPoint plugins
// 3. The set of default plugins, as MultiPoint plugins
// This implies that a higher precedence plugin will run first and overwrite any settings within MultiPoint.
// Explicitly user-configured plugins also take a higher precedence over default plugins.
// Within this hierarchy, an Enabled setting takes precedence over Disabled. For example, if a plugin is
// set in both `multiPoint.Enabled` and `multiPoint.Disabled`, the plugin will be enabled. Similarly,
// including `multiPoint.Disabled = '*'` and `multiPoint.Enabled = pluginA` will still register that specific
// plugin through MultiPoint. This follows the same behavior as all other extension point configurations.
MultiPoint PluginSet `json:"multiPoint,omitempty"`
}
// PluginSet specifies enabled and disabled plugins for an extension point.
// If an array is empty, missing, or nil, default plugins at that extension point will be used.
type PluginSet struct {
// Enabled specifies plugins that should be enabled in addition to default plugins.
// If the default plugin is also configured in the scheduler config file, the weight of plugin will
// be overridden accordingly.
// These are called after default plugins and in the same order specified here.
// +listType=atomic
Enabled []Plugin `json:"enabled,omitempty"`
// Disabled specifies default plugins that should be disabled.
// When all default plugins need to be disabled, an array containing only one "*" should be provided.
// +listType=map
// +listMapKey=name
Disabled []Plugin `json:"disabled,omitempty"`
}
// Plugin specifies a plugin name and its weight when applicable. Weight is used only for Score plugins.
type Plugin struct {
// Name defines the name of plugin
Name string `json:"name"`
// Weight defines the weight of plugin, only used for Score plugins.
Weight *int32 `json:"weight,omitempty"`
}
// PluginConfig specifies arguments that should be passed to a plugin at the time of initialization.
// A plugin that is invoked at multiple extension points is initialized once. Args can have arbitrary structure.
// It is up to the plugin to process these Args.
type PluginConfig struct {
// Name defines the name of plugin being configured
Name string `json:"name"`
// Args defines the arguments passed to the plugins at the time of initialization. Args can have arbitrary structure.
Args runtime.RawExtension `json:"args,omitempty"`
}
func (c *PluginConfig) decodeNestedObjects(d runtime.Decoder) error {
gvk := SchemeGroupVersion.WithKind(c.Name + "Args")
// dry-run to detect and skip out-of-tree plugin args.
if _, _, err := d.Decode(nil, &gvk, nil); runtime.IsNotRegisteredError(err) {
return nil
}
var strictDecodingErr error
obj, parsedGvk, err := d.Decode(c.Args.Raw, &gvk, nil)
if err != nil {
decodingArgsErr := fmt.Errorf("decoding args for plugin %s: %w", c.Name, err)
if obj != nil && runtime.IsStrictDecodingError(err) {
strictDecodingErr = runtime.NewStrictDecodingError([]error{decodingArgsErr})
} else {
return decodingArgsErr
}
}
if parsedGvk.GroupKind() != gvk.GroupKind() {
return fmt.Errorf("args for plugin %s were not of type %s, got %s", c.Name, gvk.GroupKind(), parsedGvk.GroupKind())
}
c.Args.Object = obj
return strictDecodingErr
}
func (c *PluginConfig) encodeNestedObjects(e runtime.Encoder) error {
if c.Args.Object == nil {
return nil
}
var buf bytes.Buffer
err := e.Encode(c.Args.Object, &buf)
if err != nil {
return err
}
// The <e> encoder might be a YAML encoder, but the parent encoder expects
// JSON output, so we convert YAML back to JSON.
// This is a no-op if <e> produces JSON.
json, err := yaml.YAMLToJSON(buf.Bytes())
if err != nil {
return err
}
c.Args.Raw = json
return nil
}
// Extender holds the parameters used to communicate with the extender. If a verb is unspecified/empty,
// it is assumed that the extender chose not to provide that extension.
type Extender struct {
// URLPrefix at which the extender is available
URLPrefix string `json:"urlPrefix"`
// Verb for the filter call, empty if not supported. This verb is appended to the URLPrefix when issuing the filter call to extender.
FilterVerb string `json:"filterVerb,omitempty"`
// Verb for the preempt call, empty if not supported. This verb is appended to the URLPrefix when issuing the preempt call to extender.
PreemptVerb string `json:"preemptVerb,omitempty"`
// Verb for the prioritize call, empty if not supported. This verb is appended to the URLPrefix when issuing the prioritize call to extender.
PrioritizeVerb string `json:"prioritizeVerb,omitempty"`
// The numeric multiplier for the node scores that the prioritize call generates.
// The weight should be a positive integer
Weight int64 `json:"weight,omitempty"`
// Verb for the bind call, empty if not supported. This verb is appended to the URLPrefix when issuing the bind call to extender.
// If this method is implemented by the extender, it is the extender's responsibility to bind the pod to apiserver. Only one extender
// can implement this function.
BindVerb string `json:"bindVerb,omitempty"`
// EnableHTTPS specifies whether https should be used to communicate with the extender
EnableHTTPS bool `json:"enableHTTPS,omitempty"`
// TLSConfig specifies the transport layer security config
TLSConfig *ExtenderTLSConfig `json:"tlsConfig,omitempty"`
// HTTPTimeout specifies the timeout duration for a call to the extender. Filter timeout fails the scheduling of the pod. Prioritize
// timeout is ignored, k8s/other extenders priorities are used to select the node.
HTTPTimeout metav1.Duration `json:"httpTimeout,omitempty"`
// NodeCacheCapable specifies that the extender is capable of caching node information,
// so the scheduler should only send minimal information about the eligible nodes
// assuming that the extender already cached full details of all nodes in the cluster
NodeCacheCapable bool `json:"nodeCacheCapable,omitempty"`
// ManagedResources is a list of extended resources that are managed by
// this extender.
// - A pod will be sent to the extender on the Filter, Prioritize and Bind
// (if the extender is the binder) phases iff the pod requests at least
// one of the extended resources in this list. If empty or unspecified,
// all pods will be sent to this extender.
// - If IgnoredByScheduler is set to true for a resource, kube-scheduler
// will skip checking the resource in predicates.
// +optional
// +listType=atomic
ManagedResources []ExtenderManagedResource `json:"managedResources,omitempty"`
// Ignorable specifies if the extender is ignorable, i.e. scheduling should not
// fail when the extender returns an error or is not reachable.
Ignorable bool `json:"ignorable,omitempty"`
}
// ExtenderManagedResource describes the arguments of extended resources
// managed by an extender.
type ExtenderManagedResource struct {
// Name is the extended resource name.
Name string `json:"name"`
// IgnoredByScheduler indicates whether kube-scheduler should ignore this
// resource when applying predicates.
IgnoredByScheduler bool `json:"ignoredByScheduler,omitempty"`
}
// ExtenderTLSConfig contains settings to enable TLS with extender
type ExtenderTLSConfig struct {
// Server should be accessed without verifying the TLS certificate. For testing only.
Insecure bool `json:"insecure,omitempty"`
// ServerName is passed to the server for SNI and is used in the client to check server
// certificates against. If ServerName is empty, the hostname used to contact the
// server is used.
ServerName string `json:"serverName,omitempty"`
// Server requires TLS client certificate authentication
CertFile string `json:"certFile,omitempty"`
// Server requires TLS client certificate authentication
KeyFile string `json:"keyFile,omitempty"`
// Trusted root certificates for server
CAFile string `json:"caFile,omitempty"`
// CertData holds PEM-encoded bytes (typically read from a client certificate file).
// CertData takes precedence over CertFile
// +listType=atomic
CertData []byte `json:"certData,omitempty"`
// KeyData holds PEM-encoded bytes (typically read from a client certificate key file).
// KeyData takes precedence over KeyFile
// +listType=atomic
KeyData []byte `json:"keyData,omitempty"`
// CAData holds PEM-encoded bytes (typically read from a root certificates bundle).
// CAData takes precedence over CAFile
// +listType=atomic
CAData []byte `json:"caData,omitempty"`
}

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/*
Copyright 2022 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 v1
import (
corev1 "k8s.io/api/core/v1"
metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
)
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// DefaultPreemptionArgs holds arguments used to configure the
// DefaultPreemption plugin.
type DefaultPreemptionArgs struct {
metav1.TypeMeta `json:",inline"`
// MinCandidateNodesPercentage is the minimum number of candidates to
// shortlist when dry running preemption as a percentage of number of nodes.
// Must be in the range [0, 100]. Defaults to 10% of the cluster size if
// unspecified.
MinCandidateNodesPercentage *int32 `json:"minCandidateNodesPercentage,omitempty"`
// MinCandidateNodesAbsolute is the absolute minimum number of candidates to
// shortlist. The likely number of candidates enumerated for dry running
// preemption is given by the formula:
// numCandidates = max(numNodes * minCandidateNodesPercentage, minCandidateNodesAbsolute)
// We say "likely" because there are other factors such as PDB violations
// that play a role in the number of candidates shortlisted. Must be at least
// 0 nodes. Defaults to 100 nodes if unspecified.
MinCandidateNodesAbsolute *int32 `json:"minCandidateNodesAbsolute,omitempty"`
}
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// InterPodAffinityArgs holds arguments used to configure the InterPodAffinity plugin.
type InterPodAffinityArgs struct {
metav1.TypeMeta `json:",inline"`
// HardPodAffinityWeight is the scoring weight for existing pods with a
// matching hard affinity to the incoming pod.
HardPodAffinityWeight *int32 `json:"hardPodAffinityWeight,omitempty"`
// IgnorePreferredTermsOfExistingPods configures the scheduler to ignore existing pods' preferred affinity
// rules when scoring candidate nodes, unless the incoming pod has inter-pod affinities.
IgnorePreferredTermsOfExistingPods bool `json:"ignorePreferredTermsOfExistingPods"`
}
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// NodeResourcesFitArgs holds arguments used to configure the NodeResourcesFit plugin.
type NodeResourcesFitArgs struct {
metav1.TypeMeta `json:",inline"`
// IgnoredResources is the list of resources that NodeResources fit filter
// should ignore. This doesn't apply to scoring.
// +listType=atomic
IgnoredResources []string `json:"ignoredResources,omitempty"`
// IgnoredResourceGroups defines the list of resource groups that NodeResources fit filter should ignore.
// e.g. if group is ["example.com"], it will ignore all resource names that begin
// with "example.com", such as "example.com/aaa" and "example.com/bbb".
// A resource group name can't contain '/'. This doesn't apply to scoring.
// +listType=atomic
IgnoredResourceGroups []string `json:"ignoredResourceGroups,omitempty"`
// ScoringStrategy selects the node resource scoring strategy.
// The default strategy is LeastAllocated with an equal "cpu" and "memory" weight.
ScoringStrategy *ScoringStrategy `json:"scoringStrategy,omitempty"`
}
// PodTopologySpreadConstraintsDefaulting defines how to set default constraints
// for the PodTopologySpread plugin.
type PodTopologySpreadConstraintsDefaulting string
const (
// SystemDefaulting instructs to use the kubernetes defined default.
SystemDefaulting PodTopologySpreadConstraintsDefaulting = "System"
// ListDefaulting instructs to use the config provided default.
ListDefaulting PodTopologySpreadConstraintsDefaulting = "List"
)
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// PodTopologySpreadArgs holds arguments used to configure the PodTopologySpread plugin.
type PodTopologySpreadArgs struct {
metav1.TypeMeta `json:",inline"`
// DefaultConstraints defines topology spread constraints to be applied to
// Pods that don't define any in `pod.spec.topologySpreadConstraints`.
// `.defaultConstraints[*].labelSelectors` must be empty, as they are
// deduced from the Pod's membership to Services, ReplicationControllers,
// ReplicaSets or StatefulSets.
// When not empty, .defaultingType must be "List".
// +optional
// +listType=atomic
DefaultConstraints []corev1.TopologySpreadConstraint `json:"defaultConstraints,omitempty"`
// DefaultingType determines how .defaultConstraints are deduced. Can be one
// of "System" or "List".
//
// - "System": Use kubernetes defined constraints that spread Pods among
// Nodes and Zones.
// - "List": Use constraints defined in .defaultConstraints.
//
// Defaults to "System".
// +optional
DefaultingType PodTopologySpreadConstraintsDefaulting `json:"defaultingType,omitempty"`
}
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// NodeResourcesBalancedAllocationArgs holds arguments used to configure NodeResourcesBalancedAllocation plugin.
type NodeResourcesBalancedAllocationArgs struct {
metav1.TypeMeta `json:",inline"`
// Resources to be managed, the default is "cpu" and "memory" if not specified.
// +listType=map
// +listMapKey=name
Resources []ResourceSpec `json:"resources,omitempty"`
}
// UtilizationShapePoint represents single point of priority function shape.
type UtilizationShapePoint struct {
// Utilization (x axis). Valid values are 0 to 100. Fully utilized node maps to 100.
Utilization int32 `json:"utilization"`
// Score assigned to given utilization (y axis). Valid values are 0 to 10.
Score int32 `json:"score"`
}
// ResourceSpec represents a single resource.
type ResourceSpec struct {
// Name of the resource.
Name string `json:"name"`
// Weight of the resource.
Weight int64 `json:"weight,omitempty"`
}
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// VolumeBindingArgs holds arguments used to configure the VolumeBinding plugin.
type VolumeBindingArgs struct {
metav1.TypeMeta `json:",inline"`
// BindTimeoutSeconds is the timeout in seconds in volume binding operation.
// Value must be non-negative integer. The value zero indicates no waiting.
// If this value is nil, the default value (600) will be used.
BindTimeoutSeconds *int64 `json:"bindTimeoutSeconds,omitempty"`
// Shape specifies the points defining the score function shape, which is
// used to score nodes based on the utilization of statically provisioned
// PVs. The utilization is calculated by dividing the total requested
// storage of the pod by the total capacity of feasible PVs on each node.
// Each point contains utilization (ranges from 0 to 100) and its
// associated score (ranges from 0 to 10). You can turn the priority by
// specifying different scores for different utilization numbers.
// The default shape points are:
// 1) 0 for 0 utilization
// 2) 10 for 100 utilization
// All points must be sorted in increasing order by utilization.
// +featureGate=VolumeCapacityPriority
// +optional
// +listType=atomic
Shape []UtilizationShapePoint `json:"shape,omitempty"`
}
// +k8s:deepcopy-gen:interfaces=k8s.io/apimachinery/pkg/runtime.Object
// NodeAffinityArgs holds arguments to configure the NodeAffinity plugin.
type NodeAffinityArgs struct {
metav1.TypeMeta `json:",inline"`
// AddedAffinity is applied to all Pods additionally to the NodeAffinity
// specified in the PodSpec. That is, Nodes need to satisfy AddedAffinity
// AND .spec.NodeAffinity. AddedAffinity is empty by default (all Nodes
// match).
// When AddedAffinity is used, some Pods with affinity requirements that match
// a specific Node (such as Daemonset Pods) might remain unschedulable.
// +optional
AddedAffinity *corev1.NodeAffinity `json:"addedAffinity,omitempty"`
}
// ScoringStrategyType the type of scoring strategy used in NodeResourcesFit plugin.
type ScoringStrategyType string
const (
// LeastAllocated strategy prioritizes nodes with least allocated resources.
LeastAllocated ScoringStrategyType = "LeastAllocated"
// MostAllocated strategy prioritizes nodes with most allocated resources.
MostAllocated ScoringStrategyType = "MostAllocated"
// RequestedToCapacityRatio strategy allows specifying a custom shape function
// to score nodes based on the request to capacity ratio.
RequestedToCapacityRatio ScoringStrategyType = "RequestedToCapacityRatio"
)
// ScoringStrategy define ScoringStrategyType for node resource plugin
type ScoringStrategy struct {
// Type selects which strategy to run.
Type ScoringStrategyType `json:"type,omitempty"`
// Resources to consider when scoring.
// The default resource set includes "cpu" and "memory" with an equal weight.
// Allowed weights go from 1 to 100.
// Weight defaults to 1 if not specified or explicitly set to 0.
// +listType=map
// +listMapKey=topologyKey
Resources []ResourceSpec `json:"resources,omitempty"`
// Arguments specific to RequestedToCapacityRatio strategy.
RequestedToCapacityRatio *RequestedToCapacityRatioParam `json:"requestedToCapacityRatio,omitempty"`
}
// RequestedToCapacityRatioParam define RequestedToCapacityRatio parameters
type RequestedToCapacityRatioParam struct {
// Shape is a list of points defining the scoring function shape.
// +listType=atomic
Shape []UtilizationShapePoint `json:"shape,omitempty"`
}

609
vendor/k8s.io/kube-scheduler/config/v1/zz_generated.deepcopy.go generated vendored Normal file
View File

@ -0,0 +1,609 @@
//go:build !ignore_autogenerated
// +build !ignore_autogenerated
/*
Copyright 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.
*/
// Code generated by deepcopy-gen. DO NOT EDIT.
package v1
import (
corev1 "k8s.io/api/core/v1"
runtime "k8s.io/apimachinery/pkg/runtime"
)
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *DefaultPreemptionArgs) DeepCopyInto(out *DefaultPreemptionArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.MinCandidateNodesPercentage != nil {
in, out := &in.MinCandidateNodesPercentage, &out.MinCandidateNodesPercentage
*out = new(int32)
**out = **in
}
if in.MinCandidateNodesAbsolute != nil {
in, out := &in.MinCandidateNodesAbsolute, &out.MinCandidateNodesAbsolute
*out = new(int32)
**out = **in
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new DefaultPreemptionArgs.
func (in *DefaultPreemptionArgs) DeepCopy() *DefaultPreemptionArgs {
if in == nil {
return nil
}
out := new(DefaultPreemptionArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *DefaultPreemptionArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *Extender) DeepCopyInto(out *Extender) {
*out = *in
if in.TLSConfig != nil {
in, out := &in.TLSConfig, &out.TLSConfig
*out = new(ExtenderTLSConfig)
(*in).DeepCopyInto(*out)
}
out.HTTPTimeout = in.HTTPTimeout
if in.ManagedResources != nil {
in, out := &in.ManagedResources, &out.ManagedResources
*out = make([]ExtenderManagedResource, len(*in))
copy(*out, *in)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new Extender.
func (in *Extender) DeepCopy() *Extender {
if in == nil {
return nil
}
out := new(Extender)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *ExtenderManagedResource) DeepCopyInto(out *ExtenderManagedResource) {
*out = *in
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new ExtenderManagedResource.
func (in *ExtenderManagedResource) DeepCopy() *ExtenderManagedResource {
if in == nil {
return nil
}
out := new(ExtenderManagedResource)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *ExtenderTLSConfig) DeepCopyInto(out *ExtenderTLSConfig) {
*out = *in
if in.CertData != nil {
in, out := &in.CertData, &out.CertData
*out = make([]byte, len(*in))
copy(*out, *in)
}
if in.KeyData != nil {
in, out := &in.KeyData, &out.KeyData
*out = make([]byte, len(*in))
copy(*out, *in)
}
if in.CAData != nil {
in, out := &in.CAData, &out.CAData
*out = make([]byte, len(*in))
copy(*out, *in)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new ExtenderTLSConfig.
func (in *ExtenderTLSConfig) DeepCopy() *ExtenderTLSConfig {
if in == nil {
return nil
}
out := new(ExtenderTLSConfig)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *InterPodAffinityArgs) DeepCopyInto(out *InterPodAffinityArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.HardPodAffinityWeight != nil {
in, out := &in.HardPodAffinityWeight, &out.HardPodAffinityWeight
*out = new(int32)
**out = **in
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new InterPodAffinityArgs.
func (in *InterPodAffinityArgs) DeepCopy() *InterPodAffinityArgs {
if in == nil {
return nil
}
out := new(InterPodAffinityArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *InterPodAffinityArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *KubeSchedulerConfiguration) DeepCopyInto(out *KubeSchedulerConfiguration) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.Parallelism != nil {
in, out := &in.Parallelism, &out.Parallelism
*out = new(int32)
**out = **in
}
in.LeaderElection.DeepCopyInto(&out.LeaderElection)
out.ClientConnection = in.ClientConnection
in.DebuggingConfiguration.DeepCopyInto(&out.DebuggingConfiguration)
if in.PercentageOfNodesToScore != nil {
in, out := &in.PercentageOfNodesToScore, &out.PercentageOfNodesToScore
*out = new(int32)
**out = **in
}
if in.PodInitialBackoffSeconds != nil {
in, out := &in.PodInitialBackoffSeconds, &out.PodInitialBackoffSeconds
*out = new(int64)
**out = **in
}
if in.PodMaxBackoffSeconds != nil {
in, out := &in.PodMaxBackoffSeconds, &out.PodMaxBackoffSeconds
*out = new(int64)
**out = **in
}
if in.Profiles != nil {
in, out := &in.Profiles, &out.Profiles
*out = make([]KubeSchedulerProfile, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
if in.Extenders != nil {
in, out := &in.Extenders, &out.Extenders
*out = make([]Extender, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new KubeSchedulerConfiguration.
func (in *KubeSchedulerConfiguration) DeepCopy() *KubeSchedulerConfiguration {
if in == nil {
return nil
}
out := new(KubeSchedulerConfiguration)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *KubeSchedulerConfiguration) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *KubeSchedulerProfile) DeepCopyInto(out *KubeSchedulerProfile) {
*out = *in
if in.SchedulerName != nil {
in, out := &in.SchedulerName, &out.SchedulerName
*out = new(string)
**out = **in
}
if in.PercentageOfNodesToScore != nil {
in, out := &in.PercentageOfNodesToScore, &out.PercentageOfNodesToScore
*out = new(int32)
**out = **in
}
if in.Plugins != nil {
in, out := &in.Plugins, &out.Plugins
*out = new(Plugins)
(*in).DeepCopyInto(*out)
}
if in.PluginConfig != nil {
in, out := &in.PluginConfig, &out.PluginConfig
*out = make([]PluginConfig, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new KubeSchedulerProfile.
func (in *KubeSchedulerProfile) DeepCopy() *KubeSchedulerProfile {
if in == nil {
return nil
}
out := new(KubeSchedulerProfile)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *NodeAffinityArgs) DeepCopyInto(out *NodeAffinityArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.AddedAffinity != nil {
in, out := &in.AddedAffinity, &out.AddedAffinity
*out = new(corev1.NodeAffinity)
(*in).DeepCopyInto(*out)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new NodeAffinityArgs.
func (in *NodeAffinityArgs) DeepCopy() *NodeAffinityArgs {
if in == nil {
return nil
}
out := new(NodeAffinityArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *NodeAffinityArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *NodeResourcesBalancedAllocationArgs) DeepCopyInto(out *NodeResourcesBalancedAllocationArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.Resources != nil {
in, out := &in.Resources, &out.Resources
*out = make([]ResourceSpec, len(*in))
copy(*out, *in)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new NodeResourcesBalancedAllocationArgs.
func (in *NodeResourcesBalancedAllocationArgs) DeepCopy() *NodeResourcesBalancedAllocationArgs {
if in == nil {
return nil
}
out := new(NodeResourcesBalancedAllocationArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *NodeResourcesBalancedAllocationArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *NodeResourcesFitArgs) DeepCopyInto(out *NodeResourcesFitArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.IgnoredResources != nil {
in, out := &in.IgnoredResources, &out.IgnoredResources
*out = make([]string, len(*in))
copy(*out, *in)
}
if in.IgnoredResourceGroups != nil {
in, out := &in.IgnoredResourceGroups, &out.IgnoredResourceGroups
*out = make([]string, len(*in))
copy(*out, *in)
}
if in.ScoringStrategy != nil {
in, out := &in.ScoringStrategy, &out.ScoringStrategy
*out = new(ScoringStrategy)
(*in).DeepCopyInto(*out)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new NodeResourcesFitArgs.
func (in *NodeResourcesFitArgs) DeepCopy() *NodeResourcesFitArgs {
if in == nil {
return nil
}
out := new(NodeResourcesFitArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *NodeResourcesFitArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *Plugin) DeepCopyInto(out *Plugin) {
*out = *in
if in.Weight != nil {
in, out := &in.Weight, &out.Weight
*out = new(int32)
**out = **in
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new Plugin.
func (in *Plugin) DeepCopy() *Plugin {
if in == nil {
return nil
}
out := new(Plugin)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *PluginConfig) DeepCopyInto(out *PluginConfig) {
*out = *in
in.Args.DeepCopyInto(&out.Args)
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new PluginConfig.
func (in *PluginConfig) DeepCopy() *PluginConfig {
if in == nil {
return nil
}
out := new(PluginConfig)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *PluginSet) DeepCopyInto(out *PluginSet) {
*out = *in
if in.Enabled != nil {
in, out := &in.Enabled, &out.Enabled
*out = make([]Plugin, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
if in.Disabled != nil {
in, out := &in.Disabled, &out.Disabled
*out = make([]Plugin, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new PluginSet.
func (in *PluginSet) DeepCopy() *PluginSet {
if in == nil {
return nil
}
out := new(PluginSet)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *Plugins) DeepCopyInto(out *Plugins) {
*out = *in
in.PreEnqueue.DeepCopyInto(&out.PreEnqueue)
in.QueueSort.DeepCopyInto(&out.QueueSort)
in.PreFilter.DeepCopyInto(&out.PreFilter)
in.Filter.DeepCopyInto(&out.Filter)
in.PostFilter.DeepCopyInto(&out.PostFilter)
in.PreScore.DeepCopyInto(&out.PreScore)
in.Score.DeepCopyInto(&out.Score)
in.Reserve.DeepCopyInto(&out.Reserve)
in.Permit.DeepCopyInto(&out.Permit)
in.PreBind.DeepCopyInto(&out.PreBind)
in.Bind.DeepCopyInto(&out.Bind)
in.PostBind.DeepCopyInto(&out.PostBind)
in.MultiPoint.DeepCopyInto(&out.MultiPoint)
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new Plugins.
func (in *Plugins) DeepCopy() *Plugins {
if in == nil {
return nil
}
out := new(Plugins)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *PodTopologySpreadArgs) DeepCopyInto(out *PodTopologySpreadArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.DefaultConstraints != nil {
in, out := &in.DefaultConstraints, &out.DefaultConstraints
*out = make([]corev1.TopologySpreadConstraint, len(*in))
for i := range *in {
(*in)[i].DeepCopyInto(&(*out)[i])
}
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new PodTopologySpreadArgs.
func (in *PodTopologySpreadArgs) DeepCopy() *PodTopologySpreadArgs {
if in == nil {
return nil
}
out := new(PodTopologySpreadArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *PodTopologySpreadArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *RequestedToCapacityRatioParam) DeepCopyInto(out *RequestedToCapacityRatioParam) {
*out = *in
if in.Shape != nil {
in, out := &in.Shape, &out.Shape
*out = make([]UtilizationShapePoint, len(*in))
copy(*out, *in)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new RequestedToCapacityRatioParam.
func (in *RequestedToCapacityRatioParam) DeepCopy() *RequestedToCapacityRatioParam {
if in == nil {
return nil
}
out := new(RequestedToCapacityRatioParam)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *ResourceSpec) DeepCopyInto(out *ResourceSpec) {
*out = *in
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new ResourceSpec.
func (in *ResourceSpec) DeepCopy() *ResourceSpec {
if in == nil {
return nil
}
out := new(ResourceSpec)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *ScoringStrategy) DeepCopyInto(out *ScoringStrategy) {
*out = *in
if in.Resources != nil {
in, out := &in.Resources, &out.Resources
*out = make([]ResourceSpec, len(*in))
copy(*out, *in)
}
if in.RequestedToCapacityRatio != nil {
in, out := &in.RequestedToCapacityRatio, &out.RequestedToCapacityRatio
*out = new(RequestedToCapacityRatioParam)
(*in).DeepCopyInto(*out)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new ScoringStrategy.
func (in *ScoringStrategy) DeepCopy() *ScoringStrategy {
if in == nil {
return nil
}
out := new(ScoringStrategy)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *UtilizationShapePoint) DeepCopyInto(out *UtilizationShapePoint) {
*out = *in
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new UtilizationShapePoint.
func (in *UtilizationShapePoint) DeepCopy() *UtilizationShapePoint {
if in == nil {
return nil
}
out := new(UtilizationShapePoint)
in.DeepCopyInto(out)
return out
}
// DeepCopyInto is an autogenerated deepcopy function, copying the receiver, writing into out. in must be non-nil.
func (in *VolumeBindingArgs) DeepCopyInto(out *VolumeBindingArgs) {
*out = *in
out.TypeMeta = in.TypeMeta
if in.BindTimeoutSeconds != nil {
in, out := &in.BindTimeoutSeconds, &out.BindTimeoutSeconds
*out = new(int64)
**out = **in
}
if in.Shape != nil {
in, out := &in.Shape, &out.Shape
*out = make([]UtilizationShapePoint, len(*in))
copy(*out, *in)
}
return
}
// DeepCopy is an autogenerated deepcopy function, copying the receiver, creating a new VolumeBindingArgs.
func (in *VolumeBindingArgs) DeepCopy() *VolumeBindingArgs {
if in == nil {
return nil
}
out := new(VolumeBindingArgs)
in.DeepCopyInto(out)
return out
}
// DeepCopyObject is an autogenerated deepcopy function, copying the receiver, creating a new runtime.Object.
func (in *VolumeBindingArgs) DeepCopyObject() runtime.Object {
if c := in.DeepCopy(); c != nil {
return c
}
return nil
}