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set.go
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set.go
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// package set implements a Set using a golang map.
// This implies that only the types that are accepted as valid map keys can be used as set elements.
// For instance, do not try to Add a slice, or the program will panic.
package set
// New gives new set.
func New[T comparable](items ...T) Set[T] {
st := set[T]{
elements: make(map[T]bool),
}
for _, item := range items {
st.Add(item)
}
return &st
}
// Set is an interface of possible methods on 'set'.
type Set[T comparable] interface {
// Add: adds new element to the set
Add(item T)
// Delete: deletes the passed element from the set if present
Delete(item T)
// Len: gives the length of the set (total no. of elements in set)
Len() int
// GetItems: gives the array( []T ) of elements of the set.
GetItems() []T
// In: checks whether item is present in set or not.
In(item T) bool
// IsSubsetOf: checks whether set is subset of set2 or not.
IsSubsetOf(set2 Set[T]) bool
// IsProperSubsetOf: checks whether set is proper subset of set2 or not.
// ex: [1,2,3] proper subset of [1,2,3,4] -> true
IsProperSubsetOf(set2 Set[T]) bool
// IsSupersetOf: checks whether set is superset of set2 or not.
IsSupersetOf(set2 Set[T]) bool
// IsProperSupersetOf: checks whether set is proper superset of set2 or not.
// ex: [1,2,3,4] proper superset of [1,2,3] -> true
IsProperSupersetOf(set2 Set[T]) bool
// Union: gives new union set of both sets.
// ex: [1,2,3] union [3,4,5] -> [1,2,3,4,5]
Union(set2 Set[T]) Set[T]
// Intersection: gives new intersection set of both sets.
// ex: [1,2,3] Intersection [3,4,5] -> [3]
Intersection(set2 Set[T]) Set[T]
// Difference: gives new difference set of both sets.
// ex: [1,2,3] Difference [3,4,5] -> [1,2]
Difference(set2 Set[T]) Set[T]
// SymmetricDifference: gives new symmetric difference set of both sets.
// ex: [1,2,3] SymmetricDifference [3,4,5] -> [1,2,4,5]
SymmetricDifference(set2 Set[T]) Set[T]
}
type set[T comparable] struct {
elements map[T]bool
}
func (st *set[T]) Add(value T) {
st.elements[value] = true
}
func (st *set[T]) Delete(value T) {
delete(st.elements, value)
}
func (st *set[T]) GetItems() []T {
keys := make([]T, 0, len(st.elements))
for k := range st.elements {
keys = append(keys, k)
}
return keys
}
func (st *set[T]) Len() int {
return len(st.elements)
}
func (st *set[T]) In(value T) bool {
if _, in := st.elements[value]; in {
return true
}
return false
}
func (st *set[T]) IsSubsetOf(superSet Set[T]) bool {
if st.Len() > superSet.Len() {
return false
}
for _, item := range st.GetItems() {
if !superSet.In(item) {
return false
}
}
return true
}
func (st *set[T]) IsProperSubsetOf(superSet Set[T]) bool {
if st.Len() == superSet.Len() {
return false
}
return st.IsSubsetOf(superSet)
}
func (st *set[T]) IsSupersetOf(subSet Set[T]) bool {
return subSet.IsSubsetOf(st)
}
func (st *set[T]) IsProperSupersetOf(subSet Set[T]) bool {
if st.Len() == subSet.Len() {
return false
}
return st.IsSupersetOf(subSet)
}
func (st *set[T]) Union(st2 Set[T]) Set[T] {
unionSet := New[T]()
for _, item := range st.GetItems() {
unionSet.Add(item)
}
for _, item := range st2.GetItems() {
unionSet.Add(item)
}
return unionSet
}
func (st *set[T]) Intersection(st2 Set[T]) Set[T] {
intersectionSet := New[T]()
var minSet, maxSet Set[T]
if st.Len() > st2.Len() {
minSet = st2
maxSet = st
} else {
minSet = st
maxSet = st2
}
for _, item := range minSet.GetItems() {
if maxSet.In(item) {
intersectionSet.Add(item)
}
}
return intersectionSet
}
func (st *set[T]) Difference(st2 Set[T]) Set[T] {
differenceSet := New[T]()
for _, item := range st.GetItems() {
if !st2.In(item) {
differenceSet.Add(item)
}
}
return differenceSet
}
func (st *set[T]) SymmetricDifference(st2 Set[T]) Set[T] {
symmetricDifferenceSet := New[T]()
dropSet := New[T]()
for _, item := range st.GetItems() {
if st2.In(item) {
dropSet.Add(item)
} else {
symmetricDifferenceSet.Add(item)
}
}
for _, item := range st2.GetItems() {
if !dropSet.In(item) {
symmetricDifferenceSet.Add(item)
}
}
return symmetricDifferenceSet
}