334 lines
8.5 KiB
Go
334 lines
8.5 KiB
Go
package schema
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import (
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"fmt"
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"strconv"
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"strings"
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"sync"
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"github.com/hashicorp/terraform/terraform"
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"github.com/mitchellh/mapstructure"
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)
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// ConfigFieldReader reads fields out of an untyped map[string]string to the
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// best of its ability. It also applies defaults from the Schema. (The other
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// field readers do not need default handling because they source fully
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// populated data structures.)
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type ConfigFieldReader struct {
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Config *terraform.ResourceConfig
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Schema map[string]*Schema
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indexMaps map[string]map[string]int
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once sync.Once
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}
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func (r *ConfigFieldReader) ReadField(address []string) (FieldReadResult, error) {
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r.once.Do(func() { r.indexMaps = make(map[string]map[string]int) })
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return r.readField(address, false)
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}
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func (r *ConfigFieldReader) readField(
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address []string, nested bool) (FieldReadResult, error) {
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schemaList := addrToSchema(address, r.Schema)
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if len(schemaList) == 0 {
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return FieldReadResult{}, nil
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}
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if !nested {
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// If we have a set anywhere in the address, then we need to
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// read that set out in order and actually replace that part of
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// the address with the real list index. i.e. set.50 might actually
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// map to set.12 in the config, since it is in list order in the
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// config, not indexed by set value.
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for i, v := range schemaList {
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// Sets are the only thing that cause this issue.
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if v.Type != TypeSet {
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continue
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}
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// If we're at the end of the list, then we don't have to worry
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// about this because we're just requesting the whole set.
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if i == len(schemaList)-1 {
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continue
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}
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// If we're looking for the count, then ignore...
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if address[i+1] == "#" {
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continue
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}
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indexMap, ok := r.indexMaps[strings.Join(address[:i+1], ".")]
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if !ok {
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// Get the set so we can get the index map that tells us the
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// mapping of the hash code to the list index
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_, err := r.readSet(address[:i+1], v)
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if err != nil {
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return FieldReadResult{}, err
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}
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indexMap = r.indexMaps[strings.Join(address[:i+1], ".")]
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}
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index, ok := indexMap[address[i+1]]
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if !ok {
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return FieldReadResult{}, nil
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}
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address[i+1] = strconv.FormatInt(int64(index), 10)
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}
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}
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k := strings.Join(address, ".")
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schema := schemaList[len(schemaList)-1]
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// If we're getting the single element of a promoted list, then
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// check to see if we have a single element we need to promote.
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if address[len(address)-1] == "0" && len(schemaList) > 1 {
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lastSchema := schemaList[len(schemaList)-2]
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if lastSchema.Type == TypeList && lastSchema.PromoteSingle {
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k := strings.Join(address[:len(address)-1], ".")
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result, err := r.readPrimitive(k, schema)
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if err == nil {
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return result, nil
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}
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}
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}
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switch schema.Type {
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case TypeBool, TypeFloat, TypeInt, TypeString:
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return r.readPrimitive(k, schema)
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case TypeList:
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// If we support promotion then we first check if we have a lone
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// value that we must promote.
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// a value that is alone.
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if schema.PromoteSingle {
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result, err := r.readPrimitive(k, schema.Elem.(*Schema))
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if err == nil && result.Exists {
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result.Value = []interface{}{result.Value}
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return result, nil
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}
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}
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return readListField(&nestedConfigFieldReader{r}, address, schema)
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case TypeMap:
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return r.readMap(k, schema)
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case TypeSet:
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return r.readSet(address, schema)
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case typeObject:
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return readObjectField(
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&nestedConfigFieldReader{r},
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address, schema.Elem.(map[string]*Schema))
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default:
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panic(fmt.Sprintf("Unknown type: %s", schema.Type))
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}
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}
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func (r *ConfigFieldReader) readMap(k string, schema *Schema) (FieldReadResult, error) {
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// We want both the raw value and the interpolated. We use the interpolated
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// to store actual values and we use the raw one to check for
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// computed keys. Actual values are obtained in the switch, depending on
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// the type of the raw value.
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mraw, ok := r.Config.GetRaw(k)
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if !ok {
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// check if this is from an interpolated field by seeing if it exists
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// in the config
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_, ok := r.Config.Get(k)
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if !ok {
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// this really doesn't exist
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return FieldReadResult{}, nil
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}
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// We couldn't fetch the value from a nested data structure, so treat the
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// raw value as an interpolation string. The mraw value is only used
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// for the type switch below.
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mraw = "${INTERPOLATED}"
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}
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result := make(map[string]interface{})
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computed := false
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switch m := mraw.(type) {
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case string:
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// This is a map which has come out of an interpolated variable, so we
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// can just get the value directly from config. Values cannot be computed
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// currently.
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v, _ := r.Config.Get(k)
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// If this isn't a map[string]interface, it must be computed.
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mapV, ok := v.(map[string]interface{})
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if !ok {
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return FieldReadResult{
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Exists: true,
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Computed: true,
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}, nil
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}
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// Otherwise we can proceed as usual.
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for i, iv := range mapV {
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result[i] = iv
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}
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case []interface{}:
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for i, innerRaw := range m {
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for ik := range innerRaw.(map[string]interface{}) {
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key := fmt.Sprintf("%s.%d.%s", k, i, ik)
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if r.Config.IsComputed(key) {
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computed = true
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break
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}
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v, _ := r.Config.Get(key)
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result[ik] = v
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}
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}
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case []map[string]interface{}:
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for i, innerRaw := range m {
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for ik := range innerRaw {
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key := fmt.Sprintf("%s.%d.%s", k, i, ik)
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if r.Config.IsComputed(key) {
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computed = true
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break
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}
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v, _ := r.Config.Get(key)
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result[ik] = v
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}
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}
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case map[string]interface{}:
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for ik := range m {
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key := fmt.Sprintf("%s.%s", k, ik)
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if r.Config.IsComputed(key) {
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computed = true
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break
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}
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v, _ := r.Config.Get(key)
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result[ik] = v
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}
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default:
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panic(fmt.Sprintf("unknown type: %#v", mraw))
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}
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err := mapValuesToPrimitive(k, result, schema)
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if err != nil {
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return FieldReadResult{}, nil
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}
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var value interface{}
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if !computed {
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value = result
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}
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return FieldReadResult{
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Value: value,
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Exists: true,
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Computed: computed,
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}, nil
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}
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func (r *ConfigFieldReader) readPrimitive(
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k string, schema *Schema) (FieldReadResult, error) {
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raw, ok := r.Config.Get(k)
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if !ok {
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// Nothing in config, but we might still have a default from the schema
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var err error
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raw, err = schema.DefaultValue()
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if err != nil {
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return FieldReadResult{}, fmt.Errorf("%s, error loading default: %s", k, err)
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}
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if raw == nil {
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return FieldReadResult{}, nil
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}
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}
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var result string
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if err := mapstructure.WeakDecode(raw, &result); err != nil {
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return FieldReadResult{}, err
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}
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computed := r.Config.IsComputed(k)
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returnVal, err := stringToPrimitive(result, computed, schema)
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if err != nil {
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return FieldReadResult{}, err
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}
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return FieldReadResult{
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Value: returnVal,
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Exists: true,
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Computed: computed,
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}, nil
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}
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func (r *ConfigFieldReader) readSet(
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address []string, schema *Schema) (FieldReadResult, error) {
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indexMap := make(map[string]int)
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// Create the set that will be our result
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set := schema.ZeroValue().(*Set)
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raw, err := readListField(&nestedConfigFieldReader{r}, address, schema)
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if err != nil {
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return FieldReadResult{}, err
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}
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if !raw.Exists {
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return FieldReadResult{Value: set}, nil
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}
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// If the list is computed, the set is necessarilly computed
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if raw.Computed {
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return FieldReadResult{
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Value: set,
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Exists: true,
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Computed: raw.Computed,
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}, nil
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}
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// Build up the set from the list elements
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for i, v := range raw.Value.([]interface{}) {
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// Check if any of the keys in this item are computed
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computed := r.hasComputedSubKeys(
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fmt.Sprintf("%s.%d", strings.Join(address, "."), i), schema)
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code := set.add(v, computed)
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indexMap[code] = i
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}
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r.indexMaps[strings.Join(address, ".")] = indexMap
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return FieldReadResult{
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Value: set,
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Exists: true,
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}, nil
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}
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// hasComputedSubKeys walks through a schema and returns whether or not the
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// given key contains any subkeys that are computed.
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func (r *ConfigFieldReader) hasComputedSubKeys(key string, schema *Schema) bool {
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prefix := key + "."
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switch t := schema.Elem.(type) {
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case *Resource:
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for k, schema := range t.Schema {
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if r.Config.IsComputed(prefix + k) {
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return true
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}
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if r.hasComputedSubKeys(prefix+k, schema) {
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return true
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}
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}
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}
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return false
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}
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// nestedConfigFieldReader is a funny little thing that just wraps a
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// ConfigFieldReader to call readField when ReadField is called so that
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// we don't recalculate the set rewrites in the address, which leads to
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// an infinite loop.
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type nestedConfigFieldReader struct {
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Reader *ConfigFieldReader
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}
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func (r *nestedConfigFieldReader) ReadField(
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address []string) (FieldReadResult, error) {
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return r.Reader.readField(address, true)
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}
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