terraformDummyRepo2/vendor/github.com/zclconf/go-cty/cty/value_init.go

package cty

import (
	"fmt"
	"math/big"
	"reflect"

	"golang.org/x/text/unicode/norm"

	"github.com/zclconf/go-cty/cty/set"
)

// BoolVal returns a Value of type Number whose internal value is the given
// bool.
func BoolVal(v bool) Value {
	return Value{
		ty: Bool,
		v:  v,
	}
}

// NumberVal returns a Value of type Number whose internal value is the given
// big.Float. The returned value becomes the owner of the big.Float object,
// and so it's forbidden for the caller to mutate the object after it's
// wrapped in this way.
func NumberVal(v *big.Float) Value {
	return Value{
		ty: Number,
		v:  v,
	}
}

// ParseNumberVal returns a Value of type number produced by parsing the given
// string as a decimal real number. To ensure that two identical strings will
// always produce an equal number, always use this function to derive a number
// from a string; it will ensure that the precision and rounding mode for the
// internal big decimal is configured in a consistent way.
//
// If the given string cannot be parsed as a number, the returned error has
// the message "a number is required", making it suitable to return to an
// end-user to signal a type conversion error.
//
// If the given string contains a number that becomes a recurring fraction
// when expressed in binary then it will be truncated to have a 512-bit
// mantissa. Note that this is a higher precision than that of a float64,
// so coverting the same decimal number first to float64 and then calling
// NumberFloatVal will not produce an equal result; the conversion first
// to float64 will round the mantissa to fewer than 512 bits.
func ParseNumberVal(s string) (Value, error) {
	// Base 10, precision 512, and rounding to nearest even is the standard
	// way to handle numbers arriving as strings.
	f, _, err := big.ParseFloat(s, 10, 512, big.ToNearestEven)
	if err != nil {
		return NilVal, fmt.Errorf("a number is required")
	}
	return NumberVal(f), nil
}

// MustParseNumberVal is like ParseNumberVal but it will panic in case of any
// error. It can be used during initialization or any other situation where
// the given string is a constant or otherwise known to be correct by the
// caller.
func MustParseNumberVal(s string) Value {
	ret, err := ParseNumberVal(s)
	if err != nil {
		panic(err)
	}
	return ret
}

// NumberIntVal returns a Value of type Number whose internal value is equal
// to the given integer.
func NumberIntVal(v int64) Value {
	return NumberVal(new(big.Float).SetInt64(v))
}

// NumberUIntVal returns a Value of type Number whose internal value is equal
// to the given unsigned integer.
func NumberUIntVal(v uint64) Value {
	return NumberVal(new(big.Float).SetUint64(v))
}

// NumberFloatVal returns a Value of type Number whose internal value is
// equal to the given float.
func NumberFloatVal(v float64) Value {
	return NumberVal(new(big.Float).SetFloat64(v))
}

// StringVal returns a Value of type String whose internal value is the
// given string.
//
// Strings must be UTF-8 encoded sequences of valid unicode codepoints, and
// they are NFC-normalized on entry into the world of cty values.
//
// If the given string is not valid UTF-8 then behavior of string operations
// is undefined.
func StringVal(v string) Value {
	return Value{
		ty: String,
		v:  NormalizeString(v),
	}
}

// NormalizeString applies the same normalization that cty applies when
// constructing string values.
//
// A return value from this function can be meaningfully compared byte-for-byte
// with a Value.AsString result.
func NormalizeString(s string) string {
	return norm.NFC.String(s)
}

// ObjectVal returns a Value of an object type whose structure is defined
// by the key names and value types in the given map.
func ObjectVal(attrs map[string]Value) Value {
	attrTypes := make(map[string]Type, len(attrs))
	attrVals := make(map[string]interface{}, len(attrs))

	for attr, val := range attrs {
		attr = NormalizeString(attr)
		attrTypes[attr] = val.ty
		attrVals[attr] = val.v
	}

	return Value{
		ty: Object(attrTypes),
		v:  attrVals,
	}
}

// TupleVal returns a Value of a tuple type whose element types are
// defined by the value types in the given slice.
func TupleVal(elems []Value) Value {
	elemTypes := make([]Type, len(elems))
	elemVals := make([]interface{}, len(elems))

	for i, val := range elems {
		elemTypes[i] = val.ty
		elemVals[i] = val.v
	}

	return Value{
		ty: Tuple(elemTypes),
		v:  elemVals,
	}
}

// ListVal returns a Value of list type whose element type is defined by
// the types of the given values, which must be homogenous.
//
// If the types are not all consistent (aside from elements that are of the
// dynamic pseudo-type) then this function will panic. It will panic also
// if the given list is empty, since then the element type cannot be inferred.
// (See also ListValEmpty.)
func ListVal(vals []Value) Value {
	if len(vals) == 0 {
		panic("must not call ListVal with empty slice")
	}
	elementType := DynamicPseudoType
	rawList := make([]interface{}, len(vals))

	for i, val := range vals {
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			panic(fmt.Errorf(
				"inconsistent list element types (%#v then %#v)",
				elementType, val.ty,
			))
		}

		rawList[i] = val.v
	}

	return Value{
		ty: List(elementType),
		v:  rawList,
	}
}

// ListValEmpty returns an empty list of the given element type.
func ListValEmpty(element Type) Value {
	return Value{
		ty: List(element),
		v:  []interface{}{},
	}
}

// CanListVal returns false if the given Values can not be coalesced
// into a single List due to inconsistent element types.
func CanListVal(vals []Value) bool {
	elementType := DynamicPseudoType
	for _, val := range vals {
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			return false
		}
	}
	return true
}

// MapVal returns a Value of a map type whose element type is defined by
// the types of the given values, which must be homogenous.
//
// If the types are not all consistent (aside from elements that are of the
// dynamic pseudo-type) then this function will panic. It will panic also
// if the given map is empty, since then the element type cannot be inferred.
// (See also MapValEmpty.)
func MapVal(vals map[string]Value) Value {
	if len(vals) == 0 {
		panic("must not call MapVal with empty map")
	}
	elementType := DynamicPseudoType
	rawMap := make(map[string]interface{}, len(vals))

	for key, val := range vals {
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			panic(fmt.Errorf(
				"inconsistent map element types (%#v then %#v)",
				elementType, val.ty,
			))
		}

		rawMap[NormalizeString(key)] = val.v
	}

	return Value{
		ty: Map(elementType),
		v:  rawMap,
	}
}

// MapValEmpty returns an empty map of the given element type.
func MapValEmpty(element Type) Value {
	return Value{
		ty: Map(element),
		v:  map[string]interface{}{},
	}
}

// CanMapVal returns false if the given Values can not be coalesced into a
// single Map due to inconsistent element types.
func CanMapVal(vals map[string]Value) bool {
	elementType := DynamicPseudoType
	for _, val := range vals {
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			return false
		}
	}
	return true
}

// SetVal returns a Value of set type whose element type is defined by
// the types of the given values, which must be homogenous.
//
// If the types are not all consistent (aside from elements that are of the
// dynamic pseudo-type) then this function will panic. It will panic also
// if the given list is empty, since then the element type cannot be inferred.
// (See also SetValEmpty.)
func SetVal(vals []Value) Value {
	if len(vals) == 0 {
		panic("must not call SetVal with empty slice")
	}
	elementType := DynamicPseudoType
	rawList := make([]interface{}, len(vals))
	var markSets []ValueMarks

	for i, val := range vals {
		if unmarkedVal, marks := val.UnmarkDeep(); len(marks) > 0 {
			val = unmarkedVal
			markSets = append(markSets, marks)
		}
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			panic(fmt.Errorf(
				"inconsistent set element types (%#v then %#v)",
				elementType, val.ty,
			))
		}

		rawList[i] = val.v
	}

	rawVal := set.NewSetFromSlice(setRules{elementType}, rawList)

	return Value{
		ty: Set(elementType),
		v:  rawVal,
	}.WithMarks(markSets...)
}

// CanSetVal returns false if the given Values can not be coalesced
// into a single Set due to inconsistent element types.
func CanSetVal(vals []Value) bool {
	elementType := DynamicPseudoType
	var markSets []ValueMarks

	for _, val := range vals {
		if unmarkedVal, marks := val.UnmarkDeep(); len(marks) > 0 {
			val = unmarkedVal
			markSets = append(markSets, marks)
		}
		if elementType == DynamicPseudoType {
			elementType = val.ty
		} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {
			return false
		}
	}
	return true
}

// SetValFromValueSet returns a Value of set type based on an already-constructed
// ValueSet.
//
// The element type of the returned value is the element type of the given
// set.
func SetValFromValueSet(s ValueSet) Value {
	ety := s.ElementType()
	rawVal := s.s.Copy() // copy so caller can't mutate what we wrap

	return Value{
		ty: Set(ety),
		v:  rawVal,
	}
}

// SetValEmpty returns an empty set of the given element type.
func SetValEmpty(element Type) Value {
	return Value{
		ty: Set(element),
		v:  set.NewSet(setRules{element}),
	}
}

// CapsuleVal creates a value of the given capsule type using the given
// wrapVal, which must be a pointer to a value of the capsule type's native
// type.
//
// This function will panic if the given type is not a capsule type, if
// the given wrapVal is not compatible with the given capsule type, or if
// wrapVal is not a pointer.
func CapsuleVal(ty Type, wrapVal interface{}) Value {
	if !ty.IsCapsuleType() {
		panic("not a capsule type")
	}

	wv := reflect.ValueOf(wrapVal)
	if wv.Kind() != reflect.Ptr {
		panic("wrapVal is not a pointer")
	}

	it := ty.typeImpl.(*capsuleType).GoType
	if !wv.Type().Elem().AssignableTo(it) {
		panic("wrapVal target is not compatible with the given capsule type")
	}

	return Value{
		ty: ty,
		v:  wrapVal,
	}
}
add vendor 2022-04-03 04:07:16 +00:00			`package cty`

			`import (`
			`"fmt"`
			`"math/big"`
			`"reflect"`

			`"golang.org/x/text/unicode/norm"`

			`"github.com/zclconf/go-cty/cty/set"`
			`)`

			`// BoolVal returns a Value of type Number whose internal value is the given`
			`// bool.`
			`func BoolVal(v bool) Value {`
			`return Value{`
			`ty: Bool,`
			`v: v,`
			`}`
			`}`

			`// NumberVal returns a Value of type Number whose internal value is the given`
			`// big.Float. The returned value becomes the owner of the big.Float object,`
			`// and so it's forbidden for the caller to mutate the object after it's`
			`// wrapped in this way.`
			`func NumberVal(v *big.Float) Value {`
			`return Value{`
			`ty: Number,`
			`v: v,`
			`}`
			`}`

			`// ParseNumberVal returns a Value of type number produced by parsing the given`
			`// string as a decimal real number. To ensure that two identical strings will`
			`// always produce an equal number, always use this function to derive a number`
			`// from a string; it will ensure that the precision and rounding mode for the`
			`// internal big decimal is configured in a consistent way.`
			`//`
			`// If the given string cannot be parsed as a number, the returned error has`
			`// the message "a number is required", making it suitable to return to an`
			`// end-user to signal a type conversion error.`
			`//`
			`// If the given string contains a number that becomes a recurring fraction`
			`// when expressed in binary then it will be truncated to have a 512-bit`
			`// mantissa. Note that this is a higher precision than that of a float64,`
			`// so coverting the same decimal number first to float64 and then calling`
			`// NumberFloatVal will not produce an equal result; the conversion first`
			`// to float64 will round the mantissa to fewer than 512 bits.`
			`func ParseNumberVal(s string) (Value, error) {`
			`// Base 10, precision 512, and rounding to nearest even is the standard`
			`// way to handle numbers arriving as strings.`
			`f, _, err := big.ParseFloat(s, 10, 512, big.ToNearestEven)`
			`if err != nil {`
			`return NilVal, fmt.Errorf("a number is required")`
			`}`
			`return NumberVal(f), nil`
			`}`

			`// MustParseNumberVal is like ParseNumberVal but it will panic in case of any`
			`// error. It can be used during initialization or any other situation where`
			`// the given string is a constant or otherwise known to be correct by the`
			`// caller.`
			`func MustParseNumberVal(s string) Value {`
			`ret, err := ParseNumberVal(s)`
			`if err != nil {`
			`panic(err)`
			`}`
			`return ret`
			`}`

			`// NumberIntVal returns a Value of type Number whose internal value is equal`
			`// to the given integer.`
			`func NumberIntVal(v int64) Value {`
			`return NumberVal(new(big.Float).SetInt64(v))`
			`}`

			`// NumberUIntVal returns a Value of type Number whose internal value is equal`
			`// to the given unsigned integer.`
			`func NumberUIntVal(v uint64) Value {`
			`return NumberVal(new(big.Float).SetUint64(v))`
			`}`

			`// NumberFloatVal returns a Value of type Number whose internal value is`
			`// equal to the given float.`
			`func NumberFloatVal(v float64) Value {`
			`return NumberVal(new(big.Float).SetFloat64(v))`
			`}`

			`// StringVal returns a Value of type String whose internal value is the`
			`// given string.`
			`//`
			`// Strings must be UTF-8 encoded sequences of valid unicode codepoints, and`
			`// they are NFC-normalized on entry into the world of cty values.`
			`//`
			`// If the given string is not valid UTF-8 then behavior of string operations`
			`// is undefined.`
			`func StringVal(v string) Value {`
			`return Value{`
			`ty: String,`
			`v: NormalizeString(v),`
			`}`
			`}`

			`// NormalizeString applies the same normalization that cty applies when`
			`// constructing string values.`
			`//`
			`// A return value from this function can be meaningfully compared byte-for-byte`
			`// with a Value.AsString result.`
			`func NormalizeString(s string) string {`
			`return norm.NFC.String(s)`
			`}`

			`// ObjectVal returns a Value of an object type whose structure is defined`
			`// by the key names and value types in the given map.`
			`func ObjectVal(attrs map[string]Value) Value {`
			`attrTypes := make(map[string]Type, len(attrs))`
			`attrVals := make(map[string]interface{}, len(attrs))`

			`for attr, val := range attrs {`
			`attr = NormalizeString(attr)`
			`attrTypes[attr] = val.ty`
			`attrVals[attr] = val.v`
			`}`

			`return Value{`
			`ty: Object(attrTypes),`
			`v: attrVals,`
			`}`
			`}`

			`// TupleVal returns a Value of a tuple type whose element types are`
			`// defined by the value types in the given slice.`
			`func TupleVal(elems []Value) Value {`
			`elemTypes := make([]Type, len(elems))`
			`elemVals := make([]interface{}, len(elems))`

			`for i, val := range elems {`
			`elemTypes[i] = val.ty`
			`elemVals[i] = val.v`
			`}`

			`return Value{`
			`ty: Tuple(elemTypes),`
			`v: elemVals,`
			`}`
			`}`

			`// ListVal returns a Value of list type whose element type is defined by`
			`// the types of the given values, which must be homogenous.`
			`//`
			`// If the types are not all consistent (aside from elements that are of the`
			`// dynamic pseudo-type) then this function will panic. It will panic also`
			`// if the given list is empty, since then the element type cannot be inferred.`
			`// (See also ListValEmpty.)`
			`func ListVal(vals []Value) Value {`
			`if len(vals) == 0 {`
			`panic("must not call ListVal with empty slice")`
			`}`
			`elementType := DynamicPseudoType`
			`rawList := make([]interface{}, len(vals))`

			`for i, val := range vals {`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`panic(fmt.Errorf(`
			`"inconsistent list element types (%#v then %#v)",`
			`elementType, val.ty,`
			`))`
			`}`

			`rawList[i] = val.v`
			`}`

			`return Value{`
			`ty: List(elementType),`
			`v: rawList,`
			`}`
			`}`

			`// ListValEmpty returns an empty list of the given element type.`
			`func ListValEmpty(element Type) Value {`
			`return Value{`
			`ty: List(element),`
			`v: []interface{}{},`
			`}`
			`}`

			`// CanListVal returns false if the given Values can not be coalesced`
			`// into a single List due to inconsistent element types.`
			`func CanListVal(vals []Value) bool {`
			`elementType := DynamicPseudoType`
			`for _, val := range vals {`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`return false`
			`}`
			`}`
			`return true`
			`}`

			`// MapVal returns a Value of a map type whose element type is defined by`
			`// the types of the given values, which must be homogenous.`
			`//`
			`// If the types are not all consistent (aside from elements that are of the`
			`// dynamic pseudo-type) then this function will panic. It will panic also`
			`// if the given map is empty, since then the element type cannot be inferred.`
			`// (See also MapValEmpty.)`
			`func MapVal(vals map[string]Value) Value {`
			`if len(vals) == 0 {`
			`panic("must not call MapVal with empty map")`
			`}`
			`elementType := DynamicPseudoType`
			`rawMap := make(map[string]interface{}, len(vals))`

			`for key, val := range vals {`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`panic(fmt.Errorf(`
			`"inconsistent map element types (%#v then %#v)",`
			`elementType, val.ty,`
			`))`
			`}`

			`rawMap[NormalizeString(key)] = val.v`
			`}`

			`return Value{`
			`ty: Map(elementType),`
			`v: rawMap,`
			`}`
			`}`

			`// MapValEmpty returns an empty map of the given element type.`
			`func MapValEmpty(element Type) Value {`
			`return Value{`
			`ty: Map(element),`
			`v: map[string]interface{}{},`
			`}`
			`}`

			`// CanMapVal returns false if the given Values can not be coalesced into a`
			`// single Map due to inconsistent element types.`
			`func CanMapVal(vals map[string]Value) bool {`
			`elementType := DynamicPseudoType`
			`for _, val := range vals {`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`return false`
			`}`
			`}`
			`return true`
			`}`

			`// SetVal returns a Value of set type whose element type is defined by`
			`// the types of the given values, which must be homogenous.`
			`//`
			`// If the types are not all consistent (aside from elements that are of the`
			`// dynamic pseudo-type) then this function will panic. It will panic also`
			`// if the given list is empty, since then the element type cannot be inferred.`
			`// (See also SetValEmpty.)`
			`func SetVal(vals []Value) Value {`
			`if len(vals) == 0 {`
			`panic("must not call SetVal with empty slice")`
			`}`
			`elementType := DynamicPseudoType`
			`rawList := make([]interface{}, len(vals))`
			`var markSets []ValueMarks`

			`for i, val := range vals {`
			`if unmarkedVal, marks := val.UnmarkDeep(); len(marks) > 0 {`
			`val = unmarkedVal`
			`markSets = append(markSets, marks)`
			`}`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`panic(fmt.Errorf(`
			`"inconsistent set element types (%#v then %#v)",`
			`elementType, val.ty,`
			`))`
			`}`

			`rawList[i] = val.v`
			`}`

			`rawVal := set.NewSetFromSlice(setRules{elementType}, rawList)`

			`return Value{`
			`ty: Set(elementType),`
			`v: rawVal,`
			`}.WithMarks(markSets...)`
			`}`

			`// CanSetVal returns false if the given Values can not be coalesced`
			`// into a single Set due to inconsistent element types.`
			`func CanSetVal(vals []Value) bool {`
			`elementType := DynamicPseudoType`
			`var markSets []ValueMarks`

			`for _, val := range vals {`
			`if unmarkedVal, marks := val.UnmarkDeep(); len(marks) > 0 {`
			`val = unmarkedVal`
			`markSets = append(markSets, marks)`
			`}`
			`if elementType == DynamicPseudoType {`
			`elementType = val.ty`
			`} else if val.ty != DynamicPseudoType && !elementType.Equals(val.ty) {`
			`return false`
			`}`
			`}`
			`return true`
			`}`

			`// SetValFromValueSet returns a Value of set type based on an already-constructed`
			`// ValueSet.`
			`//`
			`// The element type of the returned value is the element type of the given`
			`// set.`
			`func SetValFromValueSet(s ValueSet) Value {`
			`ety := s.ElementType()`
			`rawVal := s.s.Copy() // copy so caller can't mutate what we wrap`

			`return Value{`
			`ty: Set(ety),`
			`v: rawVal,`
			`}`
			`}`

			`// SetValEmpty returns an empty set of the given element type.`
			`func SetValEmpty(element Type) Value {`
			`return Value{`
			`ty: Set(element),`
			`v: set.NewSet(setRules{element}),`
			`}`
			`}`

			`// CapsuleVal creates a value of the given capsule type using the given`
			`// wrapVal, which must be a pointer to a value of the capsule type's native`
			`// type.`
			`//`
			`// This function will panic if the given type is not a capsule type, if`
			`// the given wrapVal is not compatible with the given capsule type, or if`
			`// wrapVal is not a pointer.`
			`func CapsuleVal(ty Type, wrapVal interface{}) Value {`
			`if !ty.IsCapsuleType() {`
			`panic("not a capsule type")`
			`}`

			`wv := reflect.ValueOf(wrapVal)`
			`if wv.Kind() != reflect.Ptr {`
			`panic("wrapVal is not a pointer")`
			`}`

			`it := ty.typeImpl.(*capsuleType).GoType`
			`if !wv.Type().Elem().AssignableTo(it) {`
			`panic("wrapVal target is not compatible with the given capsule type")`
			`}`

			`return Value{`
			`ty: ty,`
			`v: wrapVal,`
			`}`
			`}`