v1.5.7/internal/legacy/helper/schema/set.go - terraform - Git at Google

 // Copyright (c) HashiCorp, Inc.
 // SPDX-License-Identifier: MPL-2.0

 package schema

 import (
 	"bytes"
 	"fmt"
 	"reflect"
 	"sort"
 	"strconv"
 	"sync"

 	"github.com/hashicorp/terraform/internal/legacy/helper/hashcode"
 )

 // HashString hashes strings. If you want a Set of strings, this is the
 // SchemaSetFunc you want.
 func HashString(v interface{}) int {
 	return hashcode.String(v.(string))
 }

 // HashInt hashes integers. If you want a Set of integers, this is the
 // SchemaSetFunc you want.
 func HashInt(v interface{}) int {
 	return hashcode.String(strconv.Itoa(v.(int)))
 }

 // HashResource hashes complex structures that are described using
 // a *Resource. This is the default set implementation used when a set's
 // element type is a full resource.
 func HashResource(resource *Resource) SchemaSetFunc {
 	return func(v interface{}) int {
 		var buf bytes.Buffer
 		SerializeResourceForHash(&buf, v, resource)
 		return hashcode.String(buf.String())
 	}
 }

 // HashSchema hashes values that are described using a *Schema. This is the
 // default set implementation used when a set's element type is a single
 // schema.
 func HashSchema(schema *Schema) SchemaSetFunc {
 	return func(v interface{}) int {
 		var buf bytes.Buffer
 		SerializeValueForHash(&buf, v, schema)
 		return hashcode.String(buf.String())
 	}
 }

 // Set is a set data structure that is returned for elements of type
 // TypeSet.
 type Set struct {
 	F SchemaSetFunc

 	m    map[string]interface{}
 	once sync.Once
 }

 // NewSet is a convenience method for creating a new set with the given
 // items.
 func NewSet(f SchemaSetFunc, items []interface{}) *Set {
 	s := &Set{F: f}
 	for _, i := range items {
 		s.Add(i)
 	}

 	return s
 }

 // CopySet returns a copy of another set.
 func CopySet(otherSet *Set) *Set {
 	return NewSet(otherSet.F, otherSet.List())
 }

 // Add adds an item to the set if it isn't already in the set.
 func (s *Set) Add(item interface{}) {
 	s.add(item, false)
 }

 // Remove removes an item if it's already in the set. Idempotent.
 func (s *Set) Remove(item interface{}) {
 	s.remove(item)
 }

 // Contains checks if the set has the given item.
 func (s *Set) Contains(item interface{}) bool {
 	_, ok := s.m[s.hash(item)]
 	return ok
 }

 // Len returns the amount of items in the set.
 func (s *Set) Len() int {
 	return len(s.m)
 }

 // List returns the elements of this set in slice format.
 //
 // The order of the returned elements is deterministic. Given the same
 // set, the order of this will always be the same.
 func (s *Set) List() []interface{} {
 	result := make([]interface{}, len(s.m))
 	for i, k := range s.listCode() {
 		result[i] = s.m[k]
 	}

 	return result
 }

 // Difference performs a set difference of the two sets, returning
 // a new third set that has only the elements unique to this set.
 func (s *Set) Difference(other *Set) *Set {
 	result := &Set{F: s.F}
 	result.once.Do(result.init)

 	for k, v := range s.m {
 		if _, ok := other.m[k]; !ok {
 			result.m[k] = v
 		}
 	}

 	return result
 }

 // Intersection performs the set intersection of the two sets
 // and returns a new third set.
 func (s *Set) Intersection(other *Set) *Set {
 	result := &Set{F: s.F}
 	result.once.Do(result.init)

 	for k, v := range s.m {
 		if _, ok := other.m[k]; ok {
 			result.m[k] = v
 		}
 	}

 	return result
 }

 // Union performs the set union of the two sets and returns a new third
 // set.
 func (s *Set) Union(other *Set) *Set {
 	result := &Set{F: s.F}
 	result.once.Do(result.init)

 	for k, v := range s.m {
 		result.m[k] = v
 	}
 	for k, v := range other.m {
 		result.m[k] = v
 	}

 	return result
 }

 func (s *Set) Equal(raw interface{}) bool {
 	other, ok := raw.(*Set)
 	if !ok {
 		return false
 	}

 	return reflect.DeepEqual(s.m, other.m)
 }

 // HashEqual simply checks to the keys the top-level map to the keys in the
 // other set's top-level map to see if they are equal. This obviously assumes
 // you have a properly working hash function - use HashResource if in doubt.
 func (s *Set) HashEqual(raw interface{}) bool {
 	other, ok := raw.(*Set)
 	if !ok {
 		return false
 	}

 	ks1 := make([]string, 0)
 	ks2 := make([]string, 0)

 	for k := range s.m {
 		ks1 = append(ks1, k)
 	}
 	for k := range other.m {
 		ks2 = append(ks2, k)
 	}

 	sort.Strings(ks1)
 	sort.Strings(ks2)

 	return reflect.DeepEqual(ks1, ks2)
 }

 func (s *Set) GoString() string {
 	return fmt.Sprintf("*Set(%#v)", s.m)
 }

 func (s *Set) init() {
 	s.m = make(map[string]interface{})
 }

 func (s *Set) add(item interface{}, computed bool) string {
 	s.once.Do(s.init)

 	code := s.hash(item)
 	if computed {
 		code = "~" + code

 		if isProto5() {
 			tmpCode := code
 			count := 0
 			for _, exists := s.m[tmpCode]; exists; _, exists = s.m[tmpCode] {
 				count++
 				tmpCode = fmt.Sprintf("%s%d", code, count)
 			}
 			code = tmpCode
 		}
 	}

 	if _, ok := s.m[code]; !ok {
 		s.m[code] = item
 	}

 	return code
 }

 func (s *Set) hash(item interface{}) string {
 	code := s.F(item)
 	// Always return a nonnegative hashcode.
 	if code < 0 {
 		code = -code
 	}
 	return strconv.Itoa(code)
 }

 func (s *Set) remove(item interface{}) string {
 	s.once.Do(s.init)

 	code := s.hash(item)
 	delete(s.m, code)

 	return code
 }

 func (s *Set) index(item interface{}) int {
 	return sort.SearchStrings(s.listCode(), s.hash(item))
 }

 func (s *Set) listCode() []string {
 	// Sort the hash codes so the order of the list is deterministic
 	keys := make([]string, 0, len(s.m))
 	for k := range s.m {
 		keys = append(keys, k)
 	}
 	sort.Sort(sort.StringSlice(keys))
 	return keys
 }
	// Copyright (c) HashiCorp, Inc.
	// SPDX-License-Identifier: MPL-2.0

	package schema

	import (
	"bytes"
	"fmt"
	"reflect"
	"sort"
	"strconv"
	"sync"

	"github.com/hashicorp/terraform/internal/legacy/helper/hashcode"
	)

	// HashString hashes strings. If you want a Set of strings, this is the
	// SchemaSetFunc you want.
	func HashString(v interface{}) int {
	return hashcode.String(v.(string))
	}

	// HashInt hashes integers. If you want a Set of integers, this is the
	// SchemaSetFunc you want.
	func HashInt(v interface{}) int {
	return hashcode.String(strconv.Itoa(v.(int)))
	}

	// HashResource hashes complex structures that are described using
	// a *Resource. This is the default set implementation used when a set's
	// element type is a full resource.
	func HashResource(resource *Resource) SchemaSetFunc {
	return func(v interface{}) int {
	var buf bytes.Buffer
	SerializeResourceForHash(&buf, v, resource)
	return hashcode.String(buf.String())
	}
	}

	// HashSchema hashes values that are described using a *Schema. This is the
	// default set implementation used when a set's element type is a single
	// schema.
	func HashSchema(schema *Schema) SchemaSetFunc {
	return func(v interface{}) int {
	var buf bytes.Buffer
	SerializeValueForHash(&buf, v, schema)
	return hashcode.String(buf.String())
	}
	}

	// Set is a set data structure that is returned for elements of type
	// TypeSet.
	type Set struct {
	F SchemaSetFunc

	m map[string]interface{}
	once sync.Once
	}

	// NewSet is a convenience method for creating a new set with the given
	// items.
	func NewSet(f SchemaSetFunc, items []interface{}) *Set {
	s := &Set{F: f}
	for _, i := range items {
	s.Add(i)
	}

	return s
	}

	// CopySet returns a copy of another set.
	func CopySet(otherSet Set) Set {
	return NewSet(otherSet.F, otherSet.List())
	}

	// Add adds an item to the set if it isn't already in the set.
	func (s *Set) Add(item interface{}) {
	s.add(item, false)
	}

	// Remove removes an item if it's already in the set. Idempotent.
	func (s *Set) Remove(item interface{}) {
	s.remove(item)
	}

	// Contains checks if the set has the given item.
	func (s *Set) Contains(item interface{}) bool {
	_, ok := s.m[s.hash(item)]
	return ok
	}

	// Len returns the amount of items in the set.
	func (s *Set) Len() int {
	return len(s.m)
	}

	// List returns the elements of this set in slice format.
	//
	// The order of the returned elements is deterministic. Given the same
	// set, the order of this will always be the same.
	func (s *Set) List() []interface{} {
	result := make([]interface{}, len(s.m))
	for i, k := range s.listCode() {
	result[i] = s.m[k]
	}

	return result
	}

	// Difference performs a set difference of the two sets, returning
	// a new third set that has only the elements unique to this set.
	func (s Set) Difference(other Set) *Set {
	result := &Set{F: s.F}
	result.once.Do(result.init)

	for k, v := range s.m {
	if _, ok := other.m[k]; !ok {
	result.m[k] = v
	}
	}

	return result
	}

	// Intersection performs the set intersection of the two sets
	// and returns a new third set.
	func (s Set) Intersection(other Set) *Set {
	result := &Set{F: s.F}
	result.once.Do(result.init)

	for k, v := range s.m {
	if _, ok := other.m[k]; ok {
	result.m[k] = v
	}
	}

	return result
	}

	// Union performs the set union of the two sets and returns a new third
	// set.
	func (s Set) Union(other Set) *Set {
	result := &Set{F: s.F}
	result.once.Do(result.init)

	for k, v := range s.m {
	result.m[k] = v
	}
	for k, v := range other.m {
	result.m[k] = v
	}

	return result
	}

	func (s *Set) Equal(raw interface{}) bool {
	other, ok := raw.(*Set)
	if !ok {
	return false
	}

	return reflect.DeepEqual(s.m, other.m)
	}

	// HashEqual simply checks to the keys the top-level map to the keys in the
	// other set's top-level map to see if they are equal. This obviously assumes
	// you have a properly working hash function - use HashResource if in doubt.
	func (s *Set) HashEqual(raw interface{}) bool {
	other, ok := raw.(*Set)
	if !ok {
	return false
	}

	ks1 := make([]string, 0)
	ks2 := make([]string, 0)

	for k := range s.m {
	ks1 = append(ks1, k)
	}
	for k := range other.m {
	ks2 = append(ks2, k)
	}

	sort.Strings(ks1)
	sort.Strings(ks2)

	return reflect.DeepEqual(ks1, ks2)
	}

	func (s *Set) GoString() string {
	return fmt.Sprintf("*Set(%#v)", s.m)
	}

	func (s *Set) init() {
	s.m = make(map[string]interface{})
	}

	func (s *Set) add(item interface{}, computed bool) string {
	s.once.Do(s.init)

	code := s.hash(item)
	if computed {
	code = "~" + code

	if isProto5() {
	tmpCode := code
	count := 0
	for _, exists := s.m[tmpCode]; exists; _, exists = s.m[tmpCode] {
	count++
	tmpCode = fmt.Sprintf("%s%d", code, count)
	}
	code = tmpCode
	}
	}

	if _, ok := s.m[code]; !ok {
	s.m[code] = item
	}

	return code
	}

	func (s *Set) hash(item interface{}) string {
	code := s.F(item)
	// Always return a nonnegative hashcode.
	if code < 0 {
	code = -code
	}
	return strconv.Itoa(code)
	}

	func (s *Set) remove(item interface{}) string {
	s.once.Do(s.init)

	code := s.hash(item)
	delete(s.m, code)

	return code
	}

	func (s *Set) index(item interface{}) int {
	return sort.SearchStrings(s.listCode(), s.hash(item))
	}

	func (s *Set) listCode() []string {
	// Sort the hash codes so the order of the list is deterministic
	keys := make([]string, 0, len(s.m))
	for k := range s.m {
	keys = append(keys, k)
	}
	sort.Sort(sort.StringSlice(keys))
	return keys
	}