v1.4.7/internal/legacy/terraform/state_upgrade_v2_to_v3.go - terraform - Git at Google

 package terraform

 import (
 	"fmt"
 	"log"
 	"regexp"
 	"sort"
 	"strconv"
 	"strings"
 )

 // The upgrade process from V2 to V3 state does not affect the structure,
 // so we do not need to redeclare all of the structs involved - we just
 // take a deep copy of the old structure and assert the version number is
 // as we expect.
 func upgradeStateV2ToV3(old *State) (*State, error) {
 	new := old.DeepCopy()

 	// Ensure the copied version is v2 before attempting to upgrade
 	if new.Version != 2 {
 		return nil, fmt.Errorf("Cannot apply v2->v3 state upgrade to " +
 			"a state which is not version 2.")
 	}

 	// Set the new version number
 	new.Version = 3

 	// Change the counts for things which look like maps to use the %
 	// syntax. Remove counts for empty collections - they will be added
 	// back in later.
 	for _, module := range new.Modules {
 		for _, resource := range module.Resources {
 			// Upgrade Primary
 			if resource.Primary != nil {
 				upgradeAttributesV2ToV3(resource.Primary)
 			}

 			// Upgrade Deposed
 			if resource.Deposed != nil {
 				for _, deposed := range resource.Deposed {
 					upgradeAttributesV2ToV3(deposed)
 				}
 			}
 		}
 	}

 	return new, nil
 }

 func upgradeAttributesV2ToV3(instanceState *InstanceState) error {
 	collectionKeyRegexp := regexp.MustCompile(`^(.*\.)#$`)
 	collectionSubkeyRegexp := regexp.MustCompile(`^([^\.]+)\..*`)

 	// Identify the key prefix of anything which is a collection
 	var collectionKeyPrefixes []string
 	for key := range instanceState.Attributes {
 		if submatches := collectionKeyRegexp.FindAllStringSubmatch(key, -1); len(submatches) > 0 {
 			collectionKeyPrefixes = append(collectionKeyPrefixes, submatches[0][1])
 		}
 	}
 	sort.Strings(collectionKeyPrefixes)

 	log.Printf("[STATE UPGRADE] Detected the following collections in state: %v", collectionKeyPrefixes)

 	// This could be rolled into fewer loops, but it is somewhat clearer this way, and will not
 	// run very often.
 	for _, prefix := range collectionKeyPrefixes {
 		// First get the actual keys that belong to this prefix
 		var potentialKeysMatching []string
 		for key := range instanceState.Attributes {
 			if strings.HasPrefix(key, prefix) {
 				potentialKeysMatching = append(potentialKeysMatching, strings.TrimPrefix(key, prefix))
 			}
 		}
 		sort.Strings(potentialKeysMatching)

 		var actualKeysMatching []string
 		for _, key := range potentialKeysMatching {
 			if submatches := collectionSubkeyRegexp.FindAllStringSubmatch(key, -1); len(submatches) > 0 {
 				actualKeysMatching = append(actualKeysMatching, submatches[0][1])
 			} else {
 				if key != "#" {
 					actualKeysMatching = append(actualKeysMatching, key)
 				}
 			}
 		}
 		actualKeysMatching = uniqueSortedStrings(actualKeysMatching)

 		// Now inspect the keys in order to determine whether this is most likely to be
 		// a map, list or set. There is room for error here, so we log in each case. If
 		// there is no method of telling, we remove the key from the InstanceState in
 		// order that it will be recreated. Again, this could be rolled into fewer loops
 		// but we prefer clarity.

 		oldCountKey := fmt.Sprintf("%s#", prefix)

 		// First, detect "obvious" maps - which have non-numeric keys (mostly).
 		hasNonNumericKeys := false
 		for _, key := range actualKeysMatching {
 			if _, err := strconv.Atoi(key); err != nil {
 				hasNonNumericKeys = true
 			}
 		}
 		if hasNonNumericKeys {
 			newCountKey := fmt.Sprintf("%s%%", prefix)

 			instanceState.Attributes[newCountKey] = instanceState.Attributes[oldCountKey]
 			delete(instanceState.Attributes, oldCountKey)
 			log.Printf("[STATE UPGRADE] Detected %s as a map. Replaced count = %s",
 				strings.TrimSuffix(prefix, "."), instanceState.Attributes[newCountKey])
 		}

 		// Now detect empty collections and remove them from state.
 		if len(actualKeysMatching) == 0 {
 			delete(instanceState.Attributes, oldCountKey)
 			log.Printf("[STATE UPGRADE] Detected %s as an empty collection. Removed from state.",
 				strings.TrimSuffix(prefix, "."))
 		}
 	}

 	return nil
 }

 // uniqueSortedStrings removes duplicates from a slice of strings and returns
 // a sorted slice of the unique strings.
 func uniqueSortedStrings(input []string) []string {
 	uniquemap := make(map[string]struct{})
 	for _, str := range input {
 		uniquemap[str] = struct{}{}
 	}

 	output := make([]string, len(uniquemap))

 	i := 0
 	for key := range uniquemap {
 		output[i] = key
 		i = i + 1
 	}

 	sort.Strings(output)
 	return output
 }
	package terraform

	import (
	"fmt"
	"log"
	"regexp"
	"sort"
	"strconv"
	"strings"
	)

	// The upgrade process from V2 to V3 state does not affect the structure,
	// so we do not need to redeclare all of the structs involved - we just
	// take a deep copy of the old structure and assert the version number is
	// as we expect.
	func upgradeStateV2ToV3(old State) (State, error) {
	new := old.DeepCopy()

	// Ensure the copied version is v2 before attempting to upgrade
	if new.Version != 2 {
	return nil, fmt.Errorf("Cannot apply v2->v3 state upgrade to " +
	"a state which is not version 2.")
	}

	// Set the new version number
	new.Version = 3

	// Change the counts for things which look like maps to use the %
	// syntax. Remove counts for empty collections - they will be added
	// back in later.
	for _, module := range new.Modules {
	for _, resource := range module.Resources {
	// Upgrade Primary
	if resource.Primary != nil {
	upgradeAttributesV2ToV3(resource.Primary)
	}

	// Upgrade Deposed
	if resource.Deposed != nil {
	for _, deposed := range resource.Deposed {
	upgradeAttributesV2ToV3(deposed)
	}
	}
	}
	}

	return new, nil
	}

	func upgradeAttributesV2ToV3(instanceState *InstanceState) error {
	collectionKeyRegexp := regexp.MustCompile(`^(.*\.)#$`)
	collectionSubkeyRegexp := regexp.MustCompile(`^([^\.]+)\..*`)

	// Identify the key prefix of anything which is a collection
	var collectionKeyPrefixes []string
	for key := range instanceState.Attributes {
	if submatches := collectionKeyRegexp.FindAllStringSubmatch(key, -1); len(submatches) > 0 {
	collectionKeyPrefixes = append(collectionKeyPrefixes, submatches[0][1])
	}
	}
	sort.Strings(collectionKeyPrefixes)

	log.Printf("[STATE UPGRADE] Detected the following collections in state: %v", collectionKeyPrefixes)

	// This could be rolled into fewer loops, but it is somewhat clearer this way, and will not
	// run very often.
	for _, prefix := range collectionKeyPrefixes {
	// First get the actual keys that belong to this prefix
	var potentialKeysMatching []string
	for key := range instanceState.Attributes {
	if strings.HasPrefix(key, prefix) {
	potentialKeysMatching = append(potentialKeysMatching, strings.TrimPrefix(key, prefix))
	}
	}
	sort.Strings(potentialKeysMatching)

	var actualKeysMatching []string
	for _, key := range potentialKeysMatching {
	if submatches := collectionSubkeyRegexp.FindAllStringSubmatch(key, -1); len(submatches) > 0 {
	actualKeysMatching = append(actualKeysMatching, submatches[0][1])
	} else {
	if key != "#" {
	actualKeysMatching = append(actualKeysMatching, key)
	}
	}
	}
	actualKeysMatching = uniqueSortedStrings(actualKeysMatching)

	// Now inspect the keys in order to determine whether this is most likely to be
	// a map, list or set. There is room for error here, so we log in each case. If
	// there is no method of telling, we remove the key from the InstanceState in
	// order that it will be recreated. Again, this could be rolled into fewer loops
	// but we prefer clarity.

	oldCountKey := fmt.Sprintf("%s#", prefix)

	// First, detect "obvious" maps - which have non-numeric keys (mostly).
	hasNonNumericKeys := false
	for _, key := range actualKeysMatching {
	if _, err := strconv.Atoi(key); err != nil {
	hasNonNumericKeys = true
	}
	}
	if hasNonNumericKeys {
	newCountKey := fmt.Sprintf("%s%%", prefix)

	instanceState.Attributes[newCountKey] = instanceState.Attributes[oldCountKey]
	delete(instanceState.Attributes, oldCountKey)
	log.Printf("[STATE UPGRADE] Detected %s as a map. Replaced count = %s",
	strings.TrimSuffix(prefix, "."), instanceState.Attributes[newCountKey])
	}

	// Now detect empty collections and remove them from state.
	if len(actualKeysMatching) == 0 {
	delete(instanceState.Attributes, oldCountKey)
	log.Printf("[STATE UPGRADE] Detected %s as an empty collection. Removed from state.",
	strings.TrimSuffix(prefix, "."))
	}
	}

	return nil
	}

	// uniqueSortedStrings removes duplicates from a slice of strings and returns
	// a sorted slice of the unique strings.
	func uniqueSortedStrings(input []string) []string {
	uniquemap := make(map[string]struct{})
	for _, str := range input {
	uniquemap[str] = struct{}{}
	}

	output := make([]string, len(uniquemap))

	i := 0
	for key := range uniquemap {
	output[i] = key
	i = i + 1
	}

	sort.Strings(output)
	return output
	}