terraform-provider-gitea/vendor/github.com/zclconf/go-cty/cty/convert/conversion.go

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2022-04-03 04:07:16 +00:00
package convert
import (
"github.com/zclconf/go-cty/cty"
)
// conversion is an internal variant of Conversion that carries around
// a cty.Path to be used in error responses.
type conversion func(cty.Value, cty.Path) (cty.Value, error)
func getConversion(in cty.Type, out cty.Type, unsafe bool) conversion {
conv := getConversionKnown(in, out, unsafe)
if conv == nil {
return nil
}
// Wrap the conversion in some standard checks that we don't want to
// have to repeat in every conversion function.
var ret conversion
ret = func(in cty.Value, path cty.Path) (cty.Value, error) {
if in.IsMarked() {
// We must unmark during the conversion and then re-apply the
// same marks to the result.
in, inMarks := in.Unmark()
v, err := ret(in, path)
if v != cty.NilVal {
v = v.WithMarks(inMarks)
}
return v, err
}
if out == cty.DynamicPseudoType {
// Conversion to DynamicPseudoType always just passes through verbatim.
return in, nil
}
if isKnown, isNull := in.IsKnown(), in.IsNull(); !isKnown || isNull {
// Avoid constructing unknown or null values with types which
// include optional attributes. Known or non-null object values
// will be passed to a conversion function which drops the optional
// attributes from the type. Unknown and null pass through values
// must do the same to ensure that homogeneous collections have a
// single element type.
out = out.WithoutOptionalAttributesDeep()
if !isKnown {
return prepareUnknownResult(in.Range(), dynamicReplace(in.Type(), out)), nil
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}
if isNull {
// We'll pass through nulls, albeit type converted, and let
// the caller deal with whatever handling they want to do in
// case null values are considered valid in some applications.
return cty.NullVal(dynamicReplace(in.Type(), out)), nil
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}
}
return conv(in, path)
}
return ret
}
func getConversionKnown(in cty.Type, out cty.Type, unsafe bool) conversion {
switch {
case out == cty.DynamicPseudoType:
// Conversion *to* DynamicPseudoType means that the caller wishes
// to allow any type in this position, so we'll produce a do-nothing
// conversion that just passes through the value as-is.
return dynamicPassthrough
case unsafe && in == cty.DynamicPseudoType:
// Conversion *from* DynamicPseudoType means that we have a value
// whose type isn't yet known during type checking. For these we will
// assume that conversion will succeed and deal with any errors that
// result (which is why we can only do this when "unsafe" is set).
return dynamicFixup(out)
case in.IsPrimitiveType() && out.IsPrimitiveType():
conv := primitiveConversionsSafe[in][out]
if conv != nil {
return conv
}
if unsafe {
return primitiveConversionsUnsafe[in][out]
}
return nil
case out.IsObjectType() && in.IsObjectType():
return conversionObjectToObject(in, out, unsafe)
case out.IsTupleType() && in.IsTupleType():
return conversionTupleToTuple(in, out, unsafe)
case out.IsListType() && (in.IsListType() || in.IsSetType()):
inEty := in.ElementType()
outEty := out.ElementType()
if inEty.Equals(outEty) {
// This indicates that we're converting from list to set with
// the same element type, so we don't need an element converter.
return conversionCollectionToList(outEty, nil)
}
convEty := getConversion(inEty, outEty, unsafe)
if convEty == nil {
return nil
}
return conversionCollectionToList(outEty, convEty)
case out.IsSetType() && (in.IsListType() || in.IsSetType()):
if in.IsListType() && !unsafe {
// Conversion from list to map is unsafe because it will lose
// information: the ordering will not be preserved, and any
// duplicate elements will be conflated.
return nil
}
inEty := in.ElementType()
outEty := out.ElementType()
convEty := getConversion(inEty, outEty, unsafe)
if inEty.Equals(outEty) {
// This indicates that we're converting from set to list with
// the same element type, so we don't need an element converter.
return conversionCollectionToSet(outEty, nil)
}
if convEty == nil {
return nil
}
return conversionCollectionToSet(outEty, convEty)
case out.IsMapType() && in.IsMapType():
inEty := in.ElementType()
outEty := out.ElementType()
convEty := getConversion(inEty, outEty, unsafe)
if convEty == nil {
return nil
}
return conversionCollectionToMap(outEty, convEty)
case out.IsListType() && in.IsTupleType():
outEty := out.ElementType()
return conversionTupleToList(in, outEty, unsafe)
case out.IsSetType() && in.IsTupleType():
outEty := out.ElementType()
return conversionTupleToSet(in, outEty, unsafe)
case out.IsMapType() && in.IsObjectType():
outEty := out.ElementType()
return conversionObjectToMap(in, outEty, unsafe)
case out.IsObjectType() && in.IsMapType():
if !unsafe {
// Converting a map to an object is an "unsafe" conversion,
// because we don't know if all the map keys will correspond to
// object attributes.
return nil
}
return conversionMapToObject(in, out, unsafe)
case in.IsCapsuleType() || out.IsCapsuleType():
if !unsafe {
// Capsule types can only participate in "unsafe" conversions,
// because we don't know enough about their conversion behaviors
// to be sure that they will always be safe.
return nil
}
if in.Equals(out) {
// conversion to self is never allowed
return nil
}
if out.IsCapsuleType() {
if fn := out.CapsuleOps().ConversionTo; fn != nil {
return conversionToCapsule(in, out, fn)
}
}
if in.IsCapsuleType() {
if fn := in.CapsuleOps().ConversionFrom; fn != nil {
return conversionFromCapsule(in, out, fn)
}
}
// No conversion operation is available, then.
return nil
default:
return nil
}
}
// retConversion wraps a conversion (internal type) so it can be returned
// as a Conversion (public type).
func retConversion(conv conversion) Conversion {
if conv == nil {
return nil
}
return func(in cty.Value) (cty.Value, error) {
return conv(in, cty.Path(nil))
}
}
// prepareUnknownResult can apply value refinements to a returned unknown value
// in certain cases where characteristics of the source value or type can
// transfer into range constraints on the result value.
func prepareUnknownResult(sourceRange cty.ValueRange, targetTy cty.Type) cty.Value {
sourceTy := sourceRange.TypeConstraint()
ret := cty.UnknownVal(targetTy)
if sourceRange.DefinitelyNotNull() {
ret = ret.RefineNotNull()
}
switch {
case sourceTy.IsObjectType() && targetTy.IsMapType():
// A map built from an object type always has the same number of
// elements as the source type has attributes.
return ret.Refine().CollectionLength(len(sourceTy.AttributeTypes())).NewValue()
case sourceTy.IsTupleType() && targetTy.IsListType():
// A list built from a typle type always has the same number of
// elements as the source type has elements.
return ret.Refine().CollectionLength(sourceTy.Length()).NewValue()
case sourceTy.IsTupleType() && targetTy.IsSetType():
// When building a set from a tuple type we can't exactly constrain
// the length because some elements might coalesce, but we can
// guarantee an upper limit. We can also guarantee at least one
// element if the tuple isn't empty.
switch l := sourceTy.Length(); l {
case 0, 1:
return ret.Refine().CollectionLength(l).NewValue()
default:
return ret.Refine().
CollectionLengthLowerBound(1).
CollectionLengthUpperBound(sourceTy.Length()).
NewValue()
}
case sourceTy.IsCollectionType() && targetTy.IsCollectionType():
// NOTE: We only reach this function if there is an available
// conversion between the source and target type, so we don't
// need to repeat element type compatibility checks and such here.
//
// If the source value already has a refined length then we'll
// transfer those refinements to the result, because conversion
// does not change length (aside from set element coalescing).
b := ret.Refine()
if targetTy.IsSetType() {
if sourceRange.LengthLowerBound() > 0 {
// If the source has at least one element then the result
// must always have at least one too, because value coalescing
// cannot totally empty the set.
b = b.CollectionLengthLowerBound(1)
}
} else {
b = b.CollectionLengthLowerBound(sourceRange.LengthLowerBound())
}
b = b.CollectionLengthUpperBound(sourceRange.LengthUpperBound())
return b.NewValue()
default:
return ret
}
}