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

package cty

// Value represents a value of a particular type, and is the interface by
// which operations are executed on typed values.
//
// Value has two different classes of method. Operation methods stay entirely
// within the type system (methods accept and return Value instances) and
// are intended for use in implementing a language in terms of cty, while
// integration methods either enter or leave the type system, working with
// native Go values. Operation methods are guaranteed to support all of the
// expected short-circuit behavior for unknown and dynamic values, while
// integration methods may not.
//
// The philosophy for the operations API is that it's the caller's
// responsibility to ensure that the given types and values satisfy the
// specified invariants during a separate type check, so that the caller is
// able to return errors to its user from the application's own perspective.
//
// Consequently the design of these methods assumes such checks have already
// been done and panics if any invariants turn out not to be satisfied. These
// panic errors are not intended to be handled, but rather indicate a bug in
// the calling application that should be fixed with more checks prior to
// executing operations.
//
// A related consequence of this philosophy is that no automatic type
// conversions are done. If a method specifies that its argument must be
// number then it's the caller's responsibility to do that conversion before
// the call, thus allowing the application to have more constrained conversion
// rules than are offered by the built-in converter where necessary.
type Value struct {
	ty Type
	v  interface{}
}

// Type returns the type of the value.
func (val Value) Type() Type {
	return val.ty
}

// IsKnown returns true if the value is known. That is, if it is not
// the result of the unknown value constructor Unknown(...), and is not
// the result of an operation on another unknown value.
//
// Unknown values are only produced either directly or as a result of
// operating on other unknown values, and so an application that never
// introduces Unknown values can be guaranteed to never receive any either.
func (val Value) IsKnown() bool {
	if val.IsMarked() {
		return val.unmarkForce().IsKnown()
	}
	return val.v != unknown
}

// IsNull returns true if the value is null. Values of any type can be
// null, but any operations on a null value will panic. No operation ever
// produces null, so an application that never introduces Null values can
// be guaranteed to never receive any either.
func (val Value) IsNull() bool {
	if val.IsMarked() {
		return val.unmarkForce().IsNull()
	}
	return val.v == nil
}

// NilVal is an invalid Value that can be used as a placeholder when returning
// with an error from a function that returns (Value, error).
//
// NilVal is *not* a valid error and so no operations may be performed on it.
// Any attempt to use it will result in a panic.
//
// This should not be confused with the idea of a Null value, as returned by
// NullVal. NilVal is a nil within the *Go* type system, and is invalid in
// the cty type system. Null values *do* exist in the cty type system.
var NilVal = Value{
	ty: Type{typeImpl: nil},
	v:  nil,
}

// IsWhollyKnown is an extension of IsKnown that also recursively checks
// inside collections and structures to see if there are any nested unknown
// values.
func (val Value) IsWhollyKnown() bool {
	if val.IsMarked() {
		return val.unmarkForce().IsWhollyKnown()
	}

	if !val.IsKnown() {
		return false
	}

	if val.IsNull() {
		// Can't recurse into a null, so we're done
		return true
	}

	switch {
	case val.CanIterateElements():
		for it := val.ElementIterator(); it.Next(); {
			_, ev := it.Element()
			if !ev.IsWhollyKnown() {
				return false
			}
		}
		return true
	default:
		return true
	}
}

// HasWhollyKnownType checks if the value is dynamic, or contains any nested
// DynamicVal. This implies that both the value is not known, and the final
// type may change.
func (val Value) HasWhollyKnownType() bool {
	// a null dynamic type is known
	if val.IsNull() {
		return true
	}

	// an unknown DynamicPseudoType is a DynamicVal, but we don't want to
	// check that value for equality here, since this method is used within the
	// equality check.
	if !val.IsKnown() && val.ty == DynamicPseudoType {
		return false
	}

	if val.CanIterateElements() {
		// if the value is not known, then we can look directly at the internal
		// types
		if !val.IsKnown() {
			return !val.ty.HasDynamicTypes()
		}

		for it := val.ElementIterator(); it.Next(); {
			_, ev := it.Element()
			if !ev.HasWhollyKnownType() {
				return false
			}
		}
	}

	return true
}
add vendor 2022-04-03 04:07:16 +00:00			`package cty`

			`// Value represents a value of a particular type, and is the interface by`
			`// which operations are executed on typed values.`
			`//`
			`// Value has two different classes of method. Operation methods stay entirely`
			`// within the type system (methods accept and return Value instances) and`
			`// are intended for use in implementing a language in terms of cty, while`
			`// integration methods either enter or leave the type system, working with`
			`// native Go values. Operation methods are guaranteed to support all of the`
			`// expected short-circuit behavior for unknown and dynamic values, while`
			`// integration methods may not.`
			`//`
			`// The philosophy for the operations API is that it's the caller's`
			`// responsibility to ensure that the given types and values satisfy the`
			`// specified invariants during a separate type check, so that the caller is`
			`// able to return errors to its user from the application's own perspective.`
			`//`
			`// Consequently the design of these methods assumes such checks have already`
			`// been done and panics if any invariants turn out not to be satisfied. These`
			`// panic errors are not intended to be handled, but rather indicate a bug in`
			`// the calling application that should be fixed with more checks prior to`
			`// executing operations.`
			`//`
			`// A related consequence of this philosophy is that no automatic type`
			`// conversions are done. If a method specifies that its argument must be`
			`// number then it's the caller's responsibility to do that conversion before`
			`// the call, thus allowing the application to have more constrained conversion`
			`// rules than are offered by the built-in converter where necessary.`
			`type Value struct {`
			`ty Type`
			`v interface{}`
			`}`

			`// Type returns the type of the value.`
			`func (val Value) Type() Type {`
			`return val.ty`
			`}`

			`// IsKnown returns true if the value is known. That is, if it is not`
			`// the result of the unknown value constructor Unknown(...), and is not`
			`// the result of an operation on another unknown value.`
			`//`
			`// Unknown values are only produced either directly or as a result of`
			`// operating on other unknown values, and so an application that never`
			`// introduces Unknown values can be guaranteed to never receive any either.`
			`func (val Value) IsKnown() bool {`
			`if val.IsMarked() {`
			`return val.unmarkForce().IsKnown()`
			`}`
			`return val.v != unknown`
			`}`

			`// IsNull returns true if the value is null. Values of any type can be`
			`// null, but any operations on a null value will panic. No operation ever`
			`// produces null, so an application that never introduces Null values can`
			`// be guaranteed to never receive any either.`
			`func (val Value) IsNull() bool {`
			`if val.IsMarked() {`
			`return val.unmarkForce().IsNull()`
			`}`
			`return val.v == nil`
			`}`

			`// NilVal is an invalid Value that can be used as a placeholder when returning`
			`// with an error from a function that returns (Value, error).`
			`//`
			`// NilVal is not a valid error and so no operations may be performed on it.`
			`// Any attempt to use it will result in a panic.`
			`//`
			`// This should not be confused with the idea of a Null value, as returned by`
			`// NullVal. NilVal is a nil within the Go type system, and is invalid in`
			`// the cty type system. Null values do exist in the cty type system.`
			`var NilVal = Value{`
			`ty: Type{typeImpl: nil},`
			`v: nil,`
			`}`

			`// IsWhollyKnown is an extension of IsKnown that also recursively checks`
			`// inside collections and structures to see if there are any nested unknown`
			`// values.`
			`func (val Value) IsWhollyKnown() bool {`
			`if val.IsMarked() {`
			`return val.unmarkForce().IsWhollyKnown()`
			`}`

			`if !val.IsKnown() {`
			`return false`
			`}`

			`if val.IsNull() {`
			`// Can't recurse into a null, so we're done`
			`return true`
			`}`

			`switch {`
			`case val.CanIterateElements():`
			`for it := val.ElementIterator(); it.Next(); {`
			`_, ev := it.Element()`
			`if !ev.IsWhollyKnown() {`
			`return false`
			`}`
			`}`
			`return true`
			`default:`
			`return true`
			`}`
			`}`

			`// HasWhollyKnownType checks if the value is dynamic, or contains any nested`
			`// DynamicVal. This implies that both the value is not known, and the final`
			`// type may change.`
			`func (val Value) HasWhollyKnownType() bool {`
			`// a null dynamic type is known`
			`if val.IsNull() {`
			`return true`
			`}`

			`// an unknown DynamicPseudoType is a DynamicVal, but we don't want to`
			`// check that value for equality here, since this method is used within the`
			`// equality check.`
			`if !val.IsKnown() && val.ty == DynamicPseudoType {`
			`return false`
			`}`

			`if val.CanIterateElements() {`
			`// if the value is not known, then we can look directly at the internal`
			`// types`
			`if !val.IsKnown() {`
			`return !val.ty.HasDynamicTypes()`
			`}`

			`for it := val.ElementIterator(); it.Next(); {`
			`_, ev := it.Element()`
			`if !ev.HasWhollyKnownType() {`
			`return false`
			`}`
			`}`
			`}`

			`return true`
			`}`