rebase: update kubernetes to 1.26.1

update kubernetes and its dependencies
to v1.26.1

Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>

vendor/k8s.io/apimachinery/pkg/util/sets/set.go

@@ -0,0 +1,227 @@
+/*
+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 sets
+
+import (
+	"sort"
+)
+
+// Set is a set of the same type elements, implemented via map[comparable]struct{} for minimal memory consumption.
+type Set[T comparable] map[T]Empty
+
+// cast transforms specified set to generic Set[T].
+func cast[T comparable](s map[T]Empty) Set[T] { return s }
+
+// New creates a Set from a list of values.
+// NOTE: type param must be explicitly instantiated if given items are empty.
+func New[T comparable](items ...T) Set[T] {
+	ss := make(Set[T], len(items))
+	ss.Insert(items...)
+	return ss
+}
+
+// KeySet creates a Set from a keys of a map[comparable](? extends interface{}).
+// If the value passed in is not actually a map, this will panic.
+func KeySet[T comparable, V any](theMap map[T]V) Set[T] {
+	ret := Set[T]{}
+	for keyValue := range theMap {
+		ret.Insert(keyValue)
+	}
+	return ret
+}
+
+// Insert adds items to the set.
+func (s Set[T]) Insert(items ...T) Set[T] {
+	for _, item := range items {
+		s[item] = Empty{}
+	}
+	return s
+}
+
+func Insert[T comparable](set Set[T], items ...T) Set[T] {
+	return set.Insert(items...)
+}
+
+// Delete removes all items from the set.
+func (s Set[T]) Delete(items ...T) Set[T] {
+	for _, item := range items {
+		delete(s, item)
+	}
+	return s
+}
+
+// Has returns true if and only if item is contained in the set.
+func (s Set[T]) Has(item T) bool {
+	_, contained := s[item]
+	return contained
+}
+
+// HasAll returns true if and only if all items are contained in the set.
+func (s Set[T]) HasAll(items ...T) bool {
+	for _, item := range items {
+		if !s.Has(item) {
+			return false
+		}
+	}
+	return true
+}
+
+// HasAny returns true if any items are contained in the set.
+func (s Set[T]) HasAny(items ...T) bool {
+	for _, item := range items {
+		if s.Has(item) {
+			return true
+		}
+	}
+	return false
+}
+
+// Clone returns a new set which is a copy of the current set.
+func (s Set[T]) Clone() Set[T] {
+	result := make(Set[T], len(s))
+	for key := range s {
+		result.Insert(key)
+	}
+	return result
+}
+
+// Difference returns a set of objects that are not in s2.
+// For example:
+// s1 = {a1, a2, a3}
+// s2 = {a1, a2, a4, a5}
+// s1.Difference(s2) = {a3}
+// s2.Difference(s1) = {a4, a5}
+func (s1 Set[T]) Difference(s2 Set[T]) Set[T] {
+	result := New[T]()
+	for key := range s1 {
+		if !s2.Has(key) {
+			result.Insert(key)
+		}
+	}
+	return result
+}
+
+// SymmetricDifference returns a set of elements which are in either of the sets, but not in their intersection.
+// For example:
+// s1 = {a1, a2, a3}
+// s2 = {a1, a2, a4, a5}
+// s1.SymmetricDifference(s2) = {a3, a4, a5}
+// s2.SymmetricDifference(s1) = {a3, a4, a5}
+func (s1 Set[T]) SymmetricDifference(s2 Set[T]) Set[T] {
+	return s1.Difference(s2).Union(s2.Difference(s1))
+}
+
+// Union returns a new set which includes items in either s1 or s2.
+// For example:
+// s1 = {a1, a2}
+// s2 = {a3, a4}
+// s1.Union(s2) = {a1, a2, a3, a4}
+// s2.Union(s1) = {a1, a2, a3, a4}
+func (s1 Set[T]) Union(s2 Set[T]) Set[T] {
+	result := s1.Clone()
+	for key := range s2 {
+		result.Insert(key)
+	}
+	return result
+}
+
+// Intersection returns a new set which includes the item in BOTH s1 and s2
+// For example:
+// s1 = {a1, a2}
+// s2 = {a2, a3}
+// s1.Intersection(s2) = {a2}
+func (s1 Set[T]) Intersection(s2 Set[T]) Set[T] {
+	var walk, other Set[T]
+	result := New[T]()
+	if s1.Len() < s2.Len() {
+		walk = s1
+		other = s2
+	} else {
+		walk = s2
+		other = s1
+	}
+	for key := range walk {
+		if other.Has(key) {
+			result.Insert(key)
+		}
+	}
+	return result
+}
+
+// IsSuperset returns true if and only if s1 is a superset of s2.
+func (s1 Set[T]) IsSuperset(s2 Set[T]) bool {
+	for item := range s2 {
+		if !s1.Has(item) {
+			return false
+		}
+	}
+	return true
+}
+
+// Equal returns true if and only if s1 is equal (as a set) to s2.
+// Two sets are equal if their membership is identical.
+// (In practice, this means same elements, order doesn't matter)
+func (s1 Set[T]) Equal(s2 Set[T]) bool {
+	return len(s1) == len(s2) && s1.IsSuperset(s2)
+}
+
+type sortableSliceOfGeneric[T ordered] []T
+
+func (g sortableSliceOfGeneric[T]) Len() int           { return len(g) }
+func (g sortableSliceOfGeneric[T]) Less(i, j int) bool { return less[T](g[i], g[j]) }
+func (g sortableSliceOfGeneric[T]) Swap(i, j int)      { g[i], g[j] = g[j], g[i] }
+
+// List returns the contents as a sorted T slice.
+//
+// This is a separate function and not a method because not all types supported
+// by Generic are ordered and only those can be sorted.
+func List[T ordered](s Set[T]) []T {
+	res := make(sortableSliceOfGeneric[T], 0, len(s))
+	for key := range s {
+		res = append(res, key)
+	}
+	sort.Sort(res)
+	return res
+}
+
+// UnsortedList returns the slice with contents in random order.
+func (s Set[T]) UnsortedList() []T {
+	res := make([]T, 0, len(s))
+	for key := range s {
+		res = append(res, key)
+	}
+	return res
+}
+
+// PopAny returns a single element from the set.
+func (s Set[T]) PopAny() (T, bool) {
+	for key := range s {
+		s.Delete(key)
+		return key, true
+	}
+	var zeroValue T
+	return zeroValue, false
+}
+
+// Len returns the size of the set.
+func (s Set[T]) Len() int {
+	return len(s)
+}
+
+func less[T ordered](lhs, rhs T) bool {
+	return lhs < rhs
+}