terraform/helper/schema/field_reader_diff.go

245 lines
6.1 KiB
Go

package schema
import (
"fmt"
"strings"
"github.com/hashicorp/terraform/terraform"
"github.com/mitchellh/mapstructure"
)
// DiffFieldReader reads fields out of a diff structures.
//
// It also requires access to a Reader that reads fields from the structure
// that the diff was derived from. This is usually the state. This is required
// because a diff on its own doesn't have complete data about full objects
// such as maps.
//
// The Source MUST be the data that the diff was derived from. If it isn't,
// the behavior of this struct is undefined.
//
// Reading fields from a DiffFieldReader is identical to reading from
// Source except the diff will be applied to the end result.
//
// The "Exists" field on the result will be set to true if the complete
// field exists whether its from the source, diff, or a combination of both.
// It cannot be determined whether a retrieved value is composed of
// diff elements.
type DiffFieldReader struct {
Diff *terraform.InstanceDiff
Source FieldReader
Schema map[string]*Schema
// cache for memoizing ReadField calls.
cache map[string]cachedFieldReadResult
}
type cachedFieldReadResult struct {
val FieldReadResult
err error
}
func (r *DiffFieldReader) ReadField(address []string) (FieldReadResult, error) {
if r.cache == nil {
r.cache = make(map[string]cachedFieldReadResult)
}
// Create the cache key by joining around a value that isn't a valid part
// of an address. This assumes that the Source and Schema are not changed
// for the life of this DiffFieldReader.
cacheKey := strings.Join(address, "|")
if cached, ok := r.cache[cacheKey]; ok {
return cached.val, cached.err
}
schemaList := addrToSchema(address, r.Schema)
if len(schemaList) == 0 {
r.cache[cacheKey] = cachedFieldReadResult{}
return FieldReadResult{}, nil
}
var res FieldReadResult
var err error
schema := schemaList[len(schemaList)-1]
switch schema.Type {
case TypeBool, TypeInt, TypeFloat, TypeString:
res, err = r.readPrimitive(address, schema)
case TypeList:
res, err = readListField(r, address, schema)
case TypeMap:
res, err = r.readMap(address, schema)
case TypeSet:
res, err = r.readSet(address, schema)
case typeObject:
res, err = readObjectField(r, address, schema.Elem.(map[string]*Schema))
default:
panic(fmt.Sprintf("Unknown type: %#v", schema.Type))
}
r.cache[cacheKey] = cachedFieldReadResult{
val: res,
err: err,
}
return res, err
}
func (r *DiffFieldReader) readMap(
address []string, schema *Schema) (FieldReadResult, error) {
result := make(map[string]interface{})
resultSet := false
// First read the map from the underlying source
source, err := r.Source.ReadField(address)
if err != nil {
return FieldReadResult{}, err
}
if source.Exists {
// readMap may return a nil value, or an unknown value placeholder in
// some cases, causing the type assertion to panic if we don't assign the ok value
result, _ = source.Value.(map[string]interface{})
resultSet = true
}
// Next, read all the elements we have in our diff, and apply
// the diff to our result.
prefix := strings.Join(address, ".") + "."
for k, v := range r.Diff.Attributes {
if !strings.HasPrefix(k, prefix) {
continue
}
if strings.HasPrefix(k, prefix+"%") {
// Ignore the count field
continue
}
resultSet = true
k = k[len(prefix):]
if v.NewRemoved {
delete(result, k)
continue
}
result[k] = v.New
}
key := address[len(address)-1]
err = mapValuesToPrimitive(key, result, schema)
if err != nil {
return FieldReadResult{}, nil
}
var resultVal interface{}
if resultSet {
resultVal = result
}
return FieldReadResult{
Value: resultVal,
Exists: resultSet,
}, nil
}
func (r *DiffFieldReader) readPrimitive(
address []string, schema *Schema) (FieldReadResult, error) {
result, err := r.Source.ReadField(address)
if err != nil {
return FieldReadResult{}, err
}
attrD, ok := r.Diff.Attributes[strings.Join(address, ".")]
if !ok {
return result, nil
}
var resultVal string
if !attrD.NewComputed {
resultVal = attrD.New
if attrD.NewExtra != nil {
result.ValueProcessed = resultVal
if err := mapstructure.WeakDecode(attrD.NewExtra, &resultVal); err != nil {
return FieldReadResult{}, err
}
}
}
result.Computed = attrD.NewComputed
result.Exists = true
result.Value, err = stringToPrimitive(resultVal, false, schema)
if err != nil {
return FieldReadResult{}, err
}
return result, nil
}
func (r *DiffFieldReader) readSet(
address []string, schema *Schema) (FieldReadResult, error) {
// copy address to ensure we don't modify the argument
address = append([]string(nil), address...)
prefix := strings.Join(address, ".") + "."
// Create the set that will be our result
set := schema.ZeroValue().(*Set)
// Go through the map and find all the set items
for k, d := range r.Diff.Attributes {
if d.NewRemoved {
// If the field is removed, we always ignore it
continue
}
if !strings.HasPrefix(k, prefix) {
continue
}
if strings.HasSuffix(k, "#") {
// Ignore any count field
continue
}
// Split the key, since it might be a sub-object like "idx.field"
parts := strings.Split(k[len(prefix):], ".")
idx := parts[0]
raw, err := r.ReadField(append(address, idx))
if err != nil {
return FieldReadResult{}, err
}
if !raw.Exists {
// This shouldn't happen because we just verified it does exist
panic("missing field in set: " + k + "." + idx)
}
set.Add(raw.Value)
}
// Determine if the set "exists". It exists if there are items or if
// the diff explicitly wanted it empty.
exists := set.Len() > 0
if !exists {
// We could check if the diff value is "0" here but I think the
// existence of "#" on its own is enough to show it existed. This
// protects us in the future from the zero value changing from
// "0" to "" breaking us (if that were to happen).
if _, ok := r.Diff.Attributes[prefix+"#"]; ok {
exists = true
}
}
if !exists {
result, err := r.Source.ReadField(address)
if err != nil {
return FieldReadResult{}, err
}
if result.Exists {
return result, nil
}
}
return FieldReadResult{
Value: set,
Exists: exists,
}, nil
}