v1.4.7/internal/configs/configschema/coerce_value.go - terraform - Git at Google

 package configschema

 import (
 	"fmt"

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

 // CoerceValue attempts to force the given value to conform to the type
 // implied by the receiever.
 //
 // This is useful in situations where a configuration must be derived from
 // an already-decoded value. It is always better to decode directly from
 // configuration where possible since then source location information is
 // still available to produce diagnostics, but in special situations this
 // function allows a compatible result to be obtained even if the
 // configuration objects are not available.
 //
 // If the given value cannot be converted to conform to the receiving schema
 // then an error is returned describing one of possibly many problems. This
 // error may be a cty.PathError indicating a position within the nested
 // data structure where the problem applies.
 func (b *Block) CoerceValue(in cty.Value) (cty.Value, error) {
 	var path cty.Path
 	return b.coerceValue(in, path)
 }

 func (b *Block) coerceValue(in cty.Value, path cty.Path) (cty.Value, error) {
 	convType := b.specType()
 	impliedType := convType.WithoutOptionalAttributesDeep()

 	switch {
 	case in.IsNull():
 		return cty.NullVal(impliedType), nil
 	case !in.IsKnown():
 		return cty.UnknownVal(impliedType), nil
 	}

 	ty := in.Type()
 	if !ty.IsObjectType() {
 		return cty.UnknownVal(impliedType), path.NewErrorf("an object is required")
 	}

 	for name := range ty.AttributeTypes() {
 		if _, defined := b.Attributes[name]; defined {
 			continue
 		}
 		if _, defined := b.BlockTypes[name]; defined {
 			continue
 		}
 		return cty.UnknownVal(impliedType), path.NewErrorf("unexpected attribute %q", name)
 	}

 	attrs := make(map[string]cty.Value)

 	for name, attrS := range b.Attributes {
 		attrType := impliedType.AttributeType(name)
 		attrConvType := convType.AttributeType(name)

 		var val cty.Value
 		switch {
 		case ty.HasAttribute(name):
 			val = in.GetAttr(name)
 		case attrS.Computed || attrS.Optional:
 			val = cty.NullVal(attrType)
 		default:
 			return cty.UnknownVal(impliedType), path.NewErrorf("attribute %q is required", name)
 		}

 		val, err := convert.Convert(val, attrConvType)
 		if err != nil {
 			return cty.UnknownVal(impliedType), append(path, cty.GetAttrStep{Name: name}).NewError(err)
 		}
 		attrs[name] = val
 	}

 	for typeName, blockS := range b.BlockTypes {
 		switch blockS.Nesting {

 		case NestingSingle, NestingGroup:
 			switch {
 			case ty.HasAttribute(typeName):
 				var err error
 				val := in.GetAttr(typeName)
 				attrs[typeName], err = blockS.coerceValue(val, append(path, cty.GetAttrStep{Name: typeName}))
 				if err != nil {
 					return cty.UnknownVal(impliedType), err
 				}
 			default:
 				attrs[typeName] = blockS.EmptyValue()
 			}

 		case NestingList:
 			switch {
 			case ty.HasAttribute(typeName):
 				coll := in.GetAttr(typeName)

 				switch {
 				case coll.IsNull():
 					attrs[typeName] = cty.NullVal(cty.List(blockS.ImpliedType()))
 					continue
 				case !coll.IsKnown():
 					attrs[typeName] = cty.UnknownVal(cty.List(blockS.ImpliedType()))
 					continue
 				}

 				if !coll.CanIterateElements() {
 					return cty.UnknownVal(impliedType), path.NewErrorf("must be a list")
 				}
 				l := coll.LengthInt()

 				if l == 0 {
 					attrs[typeName] = cty.ListValEmpty(blockS.ImpliedType())
 					continue
 				}
 				elems := make([]cty.Value, 0, l)
 				{
 					path = append(path, cty.GetAttrStep{Name: typeName})
 					for it := coll.ElementIterator(); it.Next(); {
 						var err error
 						idx, val := it.Element()
 						val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: idx}))
 						if err != nil {
 							return cty.UnknownVal(impliedType), err
 						}
 						elems = append(elems, val)
 					}
 				}
 				attrs[typeName] = cty.ListVal(elems)
 			default:
 				attrs[typeName] = cty.ListValEmpty(blockS.ImpliedType())
 			}

 		case NestingSet:
 			switch {
 			case ty.HasAttribute(typeName):
 				coll := in.GetAttr(typeName)

 				switch {
 				case coll.IsNull():
 					attrs[typeName] = cty.NullVal(cty.Set(blockS.ImpliedType()))
 					continue
 				case !coll.IsKnown():
 					attrs[typeName] = cty.UnknownVal(cty.Set(blockS.ImpliedType()))
 					continue
 				}

 				if !coll.CanIterateElements() {
 					return cty.UnknownVal(impliedType), path.NewErrorf("must be a set")
 				}
 				l := coll.LengthInt()

 				if l == 0 {
 					attrs[typeName] = cty.SetValEmpty(blockS.ImpliedType())
 					continue
 				}
 				elems := make([]cty.Value, 0, l)
 				{
 					path = append(path, cty.GetAttrStep{Name: typeName})
 					for it := coll.ElementIterator(); it.Next(); {
 						var err error
 						idx, val := it.Element()
 						val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: idx}))
 						if err != nil {
 							return cty.UnknownVal(impliedType), err
 						}
 						elems = append(elems, val)
 					}
 				}
 				attrs[typeName] = cty.SetVal(elems)
 			default:
 				attrs[typeName] = cty.SetValEmpty(blockS.ImpliedType())
 			}

 		case NestingMap:
 			switch {
 			case ty.HasAttribute(typeName):
 				coll := in.GetAttr(typeName)

 				switch {
 				case coll.IsNull():
 					attrs[typeName] = cty.NullVal(cty.Map(blockS.ImpliedType()))
 					continue
 				case !coll.IsKnown():
 					attrs[typeName] = cty.UnknownVal(cty.Map(blockS.ImpliedType()))
 					continue
 				}

 				if !coll.CanIterateElements() {
 					return cty.UnknownVal(impliedType), path.NewErrorf("must be a map")
 				}
 				l := coll.LengthInt()
 				if l == 0 {
 					attrs[typeName] = cty.MapValEmpty(blockS.ImpliedType())
 					continue
 				}
 				elems := make(map[string]cty.Value)
 				{
 					path = append(path, cty.GetAttrStep{Name: typeName})
 					for it := coll.ElementIterator(); it.Next(); {
 						var err error
 						key, val := it.Element()
 						if key.Type() != cty.String || key.IsNull() || !key.IsKnown() {
 							return cty.UnknownVal(impliedType), path.NewErrorf("must be a map")
 						}
 						val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: key}))
 						if err != nil {
 							return cty.UnknownVal(impliedType), err
 						}
 						elems[key.AsString()] = val
 					}
 				}

 				// If the attribute values here contain any DynamicPseudoTypes,
 				// the concrete type must be an object.
 				useObject := false
 				switch {
 				case coll.Type().IsObjectType():
 					useObject = true
 				default:
 					// It's possible that we were given a map, and need to coerce it to an object
 					ety := coll.Type().ElementType()
 					for _, v := range elems {
 						if !v.Type().Equals(ety) {
 							useObject = true
 							break
 						}
 					}
 				}

 				if useObject {
 					attrs[typeName] = cty.ObjectVal(elems)
 				} else {
 					attrs[typeName] = cty.MapVal(elems)
 				}
 			default:
 				attrs[typeName] = cty.MapValEmpty(blockS.ImpliedType())
 			}

 		default:
 			// should never happen because above is exhaustive
 			panic(fmt.Errorf("unsupported nesting mode %#v", blockS.Nesting))
 		}
 	}

 	return cty.ObjectVal(attrs), nil
 }
	package configschema

	import (
	"fmt"

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

	// CoerceValue attempts to force the given value to conform to the type
	// implied by the receiever.
	//
	// This is useful in situations where a configuration must be derived from
	// an already-decoded value. It is always better to decode directly from
	// configuration where possible since then source location information is
	// still available to produce diagnostics, but in special situations this
	// function allows a compatible result to be obtained even if the
	// configuration objects are not available.
	//
	// If the given value cannot be converted to conform to the receiving schema
	// then an error is returned describing one of possibly many problems. This
	// error may be a cty.PathError indicating a position within the nested
	// data structure where the problem applies.
	func (b *Block) CoerceValue(in cty.Value) (cty.Value, error) {
	var path cty.Path
	return b.coerceValue(in, path)
	}

	func (b *Block) coerceValue(in cty.Value, path cty.Path) (cty.Value, error) {
	convType := b.specType()
	impliedType := convType.WithoutOptionalAttributesDeep()

	switch {
	case in.IsNull():
	return cty.NullVal(impliedType), nil
	case !in.IsKnown():
	return cty.UnknownVal(impliedType), nil
	}

	ty := in.Type()
	if !ty.IsObjectType() {
	return cty.UnknownVal(impliedType), path.NewErrorf("an object is required")
	}

	for name := range ty.AttributeTypes() {
	if _, defined := b.Attributes[name]; defined {
	continue
	}
	if _, defined := b.BlockTypes[name]; defined {
	continue
	}
	return cty.UnknownVal(impliedType), path.NewErrorf("unexpected attribute %q", name)
	}

	attrs := make(map[string]cty.Value)

	for name, attrS := range b.Attributes {
	attrType := impliedType.AttributeType(name)
	attrConvType := convType.AttributeType(name)

	var val cty.Value
	switch {
	case ty.HasAttribute(name):
	val = in.GetAttr(name)
	case attrS.Computed \|\| attrS.Optional:
	val = cty.NullVal(attrType)
	default:
	return cty.UnknownVal(impliedType), path.NewErrorf("attribute %q is required", name)
	}

	val, err := convert.Convert(val, attrConvType)
	if err != nil {
	return cty.UnknownVal(impliedType), append(path, cty.GetAttrStep{Name: name}).NewError(err)
	}
	attrs[name] = val
	}

	for typeName, blockS := range b.BlockTypes {
	switch blockS.Nesting {

	case NestingSingle, NestingGroup:
	switch {
	case ty.HasAttribute(typeName):
	var err error
	val := in.GetAttr(typeName)
	attrs[typeName], err = blockS.coerceValue(val, append(path, cty.GetAttrStep{Name: typeName}))
	if err != nil {
	return cty.UnknownVal(impliedType), err
	}
	default:
	attrs[typeName] = blockS.EmptyValue()
	}

	case NestingList:
	switch {
	case ty.HasAttribute(typeName):
	coll := in.GetAttr(typeName)

	switch {
	case coll.IsNull():
	attrs[typeName] = cty.NullVal(cty.List(blockS.ImpliedType()))
	continue
	case !coll.IsKnown():
	attrs[typeName] = cty.UnknownVal(cty.List(blockS.ImpliedType()))
	continue
	}

	if !coll.CanIterateElements() {
	return cty.UnknownVal(impliedType), path.NewErrorf("must be a list")
	}
	l := coll.LengthInt()

	if l == 0 {
	attrs[typeName] = cty.ListValEmpty(blockS.ImpliedType())
	continue
	}
	elems := make([]cty.Value, 0, l)
	{
	path = append(path, cty.GetAttrStep{Name: typeName})
	for it := coll.ElementIterator(); it.Next(); {
	var err error
	idx, val := it.Element()
	val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: idx}))
	if err != nil {
	return cty.UnknownVal(impliedType), err
	}
	elems = append(elems, val)
	}
	}
	attrs[typeName] = cty.ListVal(elems)
	default:
	attrs[typeName] = cty.ListValEmpty(blockS.ImpliedType())
	}

	case NestingSet:
	switch {
	case ty.HasAttribute(typeName):
	coll := in.GetAttr(typeName)

	switch {
	case coll.IsNull():
	attrs[typeName] = cty.NullVal(cty.Set(blockS.ImpliedType()))
	continue
	case !coll.IsKnown():
	attrs[typeName] = cty.UnknownVal(cty.Set(blockS.ImpliedType()))
	continue
	}

	if !coll.CanIterateElements() {
	return cty.UnknownVal(impliedType), path.NewErrorf("must be a set")
	}
	l := coll.LengthInt()

	if l == 0 {
	attrs[typeName] = cty.SetValEmpty(blockS.ImpliedType())
	continue
	}
	elems := make([]cty.Value, 0, l)
	{
	path = append(path, cty.GetAttrStep{Name: typeName})
	for it := coll.ElementIterator(); it.Next(); {
	var err error
	idx, val := it.Element()
	val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: idx}))
	if err != nil {
	return cty.UnknownVal(impliedType), err
	}
	elems = append(elems, val)
	}
	}
	attrs[typeName] = cty.SetVal(elems)
	default:
	attrs[typeName] = cty.SetValEmpty(blockS.ImpliedType())
	}

	case NestingMap:
	switch {
	case ty.HasAttribute(typeName):
	coll := in.GetAttr(typeName)

	switch {
	case coll.IsNull():
	attrs[typeName] = cty.NullVal(cty.Map(blockS.ImpliedType()))
	continue
	case !coll.IsKnown():
	attrs[typeName] = cty.UnknownVal(cty.Map(blockS.ImpliedType()))
	continue
	}

	if !coll.CanIterateElements() {
	return cty.UnknownVal(impliedType), path.NewErrorf("must be a map")
	}
	l := coll.LengthInt()
	if l == 0 {
	attrs[typeName] = cty.MapValEmpty(blockS.ImpliedType())
	continue
	}
	elems := make(map[string]cty.Value)
	{
	path = append(path, cty.GetAttrStep{Name: typeName})
	for it := coll.ElementIterator(); it.Next(); {
	var err error
	key, val := it.Element()
	if key.Type() != cty.String \|\| key.IsNull() \|\| !key.IsKnown() {
	return cty.UnknownVal(impliedType), path.NewErrorf("must be a map")
	}
	val, err = blockS.coerceValue(val, append(path, cty.IndexStep{Key: key}))
	if err != nil {
	return cty.UnknownVal(impliedType), err
	}
	elems[key.AsString()] = val
	}
	}

	// If the attribute values here contain any DynamicPseudoTypes,
	// the concrete type must be an object.
	useObject := false
	switch {
	case coll.Type().IsObjectType():
	useObject = true
	default:
	// It's possible that we were given a map, and need to coerce it to an object
	ety := coll.Type().ElementType()
	for _, v := range elems {
	if !v.Type().Equals(ety) {
	useObject = true
	break
	}
	}
	}

	if useObject {
	attrs[typeName] = cty.ObjectVal(elems)
	} else {
	attrs[typeName] = cty.MapVal(elems)
	}
	default:
	attrs[typeName] = cty.MapValEmpty(blockS.ImpliedType())
	}

	default:
	// should never happen because above is exhaustive
	panic(fmt.Errorf("unsupported nesting mode %#v", blockS.Nesting))
	}
	}

	return cty.ObjectVal(attrs), nil
	}