terraform/states/statefile/version3_upgrade.go

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statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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package statefile
import (
"encoding/json"
"fmt"
"log"
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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"strconv"
"strings"
"github.com/hashicorp/hcl/v2/hclsyntax"
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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"github.com/zclconf/go-cty/cty"
ctyjson "github.com/zclconf/go-cty/cty/json"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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"github.com/hashicorp/terraform/states"
"github.com/hashicorp/terraform/tfdiags"
)
func upgradeStateV3ToV4(old *stateV3) (*stateV4, error) {
if old.Serial < 0 {
// The new format is using uint64 here, which should be fine for any
// real state (we only used positive integers in practice) but we'll
// catch this explicitly here to avoid weird behavior if a state file
// has been tampered with in some way.
return nil, fmt.Errorf("state has serial less than zero, which is invalid")
}
new := &stateV4{
TerraformVersion: old.TFVersion,
Serial: uint64(old.Serial),
Lineage: old.Lineage,
RootOutputs: map[string]outputStateV4{},
Resources: []resourceStateV4{},
}
if new.TerraformVersion == "" {
// Older formats considered this to be optional, but now it's required
// and so we'll stub it out with something that's definitely older
// than the version that really created this state.
new.TerraformVersion = "0.0.0"
}
for _, msOld := range old.Modules {
if len(msOld.Path) < 1 || msOld.Path[0] != "root" {
return nil, fmt.Errorf("state contains invalid module path %#v", msOld.Path)
}
// Convert legacy-style module address into our newer address type.
// Since these old formats are only generated by versions of Terraform
// that don't support count and for_each on modules, we can just assume
// all of the modules are unkeyed.
moduleAddr := make(addrs.ModuleInstance, len(msOld.Path)-1)
for i, name := range msOld.Path[1:] {
if !hclsyntax.ValidIdentifier(name) {
// If we don't fail here then we'll produce an invalid state
// version 4 which subsequent operations will reject, so we'll
// fail early here for safety to make sure we can never
// inadvertently commit an invalid snapshot to a backend.
return nil, fmt.Errorf("state contains invalid module path %#v: %q is not a valid identifier; rename it in Terraform 0.11 before upgrading to Terraform 0.12", msOld.Path, name)
}
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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moduleAddr[i] = addrs.ModuleInstanceStep{
Name: name,
InstanceKey: addrs.NoKey,
}
}
// In a v3 state file, a "resource state" is actually an instance
// state, so we need to fill in a missing level of heirarchy here
// by lazily creating resource states as we encounter them.
// We'll track them in here, keyed on the string representation of
// the resource address.
resourceStates := map[string]*resourceStateV4{}
for legacyAddr, rsOld := range msOld.Resources {
instAddr, err := parseLegacyResourceAddress(legacyAddr)
if err != nil {
return nil, err
}
resAddr := instAddr.Resource
rs, exists := resourceStates[resAddr.String()]
if !exists {
var modeStr string
switch resAddr.Mode {
case addrs.ManagedResourceMode:
modeStr = "managed"
case addrs.DataResourceMode:
modeStr = "data"
default:
return nil, fmt.Errorf("state contains resource %s with an unsupported resource mode %#v", resAddr, resAddr.Mode)
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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}
// In state versions prior to 4 we allowed each instance of a
// resource to have its own provider configuration address,
// which makes no real sense in practice because providers
// are associated with resources in the configuration. We
// elevate that to the resource level during this upgrade,
// implicitly taking the provider address of the first instance
// we encounter for each resource. While this is lossy in
// theory, in practice there is no reason for these values to
// differ between instances.
var providerAddr addrs.AbsProviderConfig
oldProviderAddr := rsOld.Provider
if strings.Contains(oldProviderAddr, "provider.") {
// Smells like a new-style provider address, but we'll test it.
var diags tfdiags.Diagnostics
providerAddr, diags = addrs.ParseAbsProviderConfigStr(oldProviderAddr)
if diags.HasErrors() {
if strings.Contains(oldProviderAddr, "${") {
// There seems to be a common misconception that
// interpolation was valid in provider aliases
// in 0.11, so we'll use a specialized error
// message for that case.
return nil, fmt.Errorf("invalid provider config reference %q for %s: this alias seems to contain a template interpolation sequence, which was not supported but also not error-checked in Terraform 0.11. To proceed, rename the associated provider alias to a valid identifier and apply the change with Terraform 0.11 before upgrading to Terraform 0.12", oldProviderAddr, instAddr)
}
return nil, fmt.Errorf("invalid provider config reference %q for %s: %s", oldProviderAddr, instAddr, diags.Err())
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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}
} else {
// Smells like an old-style module-local provider address,
// which we'll need to migrate. We'll assume it's referring
// to the same module the resource is in, which might be
// incorrect but it'll get fixed up next time any updates
// are made to an instance.
if oldProviderAddr != "" {
localAddr, diags := configs.ParseProviderConfigCompactStr(oldProviderAddr)
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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if diags.HasErrors() {
if strings.Contains(oldProviderAddr, "${") {
// There seems to be a common misconception that
// interpolation was valid in provider aliases
// in 0.11, so we'll use a specialized error
// message for that case.
return nil, fmt.Errorf("invalid legacy provider config reference %q for %s: this alias seems to contain a template interpolation sequence, which was not supported but also not error-checked in Terraform 0.11. To proceed, rename the associated provider alias to a valid identifier and apply the change with Terraform 0.11 before upgrading to Terraform 0.12", oldProviderAddr, instAddr)
}
return nil, fmt.Errorf("invalid legacy provider config reference %q for %s: %s", oldProviderAddr, instAddr, diags.Err())
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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}
providerAddr = localAddr.Absolute(moduleAddr)
} else {
Initial steps towards AbsProviderConfig/LocalProviderConfig separation (#23978) * Introduce "Local" terminology for non-absolute provider config addresses In a future change AbsProviderConfig and LocalProviderConfig are going to become two entirely distinct types, rather than Abs embedding Local as written here. This naming change is in preparation for that subsequent work, which will also include introducing a new "ProviderConfig" type that is an interface that AbsProviderConfig and LocalProviderConfig both implement. This is intended to be largely just a naming change to get started, so we can deal with all of the messy renaming. However, this did also require a slight change in modeling where the Resource.DefaultProviderConfig method has become Resource.DefaultProvider returning a Provider address directly, because this method doesn't have enough information to construct a true and accurate LocalProviderConfig -- it would need to refer to the configuration to know what this module is calling the provider it has selected. In order to leave a trail to follow for subsequent work, all of the changes here are intended to ensure that remaining work will become obvious via compile-time errors when all of the following changes happen: - The concept of "legacy" provider addresses is removed from the addrs package, including removing addrs.NewLegacyProvider and addrs.Provider.LegacyString. - addrs.AbsProviderConfig stops having addrs.LocalProviderConfig embedded in it and has an addrs.Provider and a string alias directly instead. - The provider-schema-handling parts of Terraform core are updated to work with addrs.Provider to identify providers, rather than legacy strings. In particular, there are still several codepaths here making legacy provider address assumptions (in order to limit the scope of this change) but I've made sure each one is doing something that relies on at least one of the above changes not having been made yet. * addrs: ProviderConfig interface In a (very) few special situations in the main "terraform" package we need to make runtime decisions about whether a provider config is absolute or local. We currently do that by exploiting the fact that AbsProviderConfig has LocalProviderConfig nested inside of it and so in the local case we can just ignore the wrapping AbsProviderConfig and use the embedded value. In a future change we'll be moving away from that embedding and making these two types distinct in order to represent that mapping between them requires consulting a lookup table in the configuration, and so here we introduce a new interface type ProviderConfig that can represent either AbsProviderConfig or LocalProviderConfig decided dynamically at runtime. This also includes the Config.ResolveAbsProviderAddr method that will eventually be responsible for that local-to-absolute translation, so that callers with access to the configuration can normalize to an addrs.AbsProviderConfig given a non-nil addrs.ProviderConfig. That's currently unused because existing callers are still relying on the simplistic structural transform, but we'll switch them over in a later commit. * rename LocalType to LocalName Co-authored-by: Kristin Laemmert <mildwonkey@users.noreply.github.com>
2020-01-31 14:23:07 +01:00
defaultProvider := resAddr.DefaultProvider()
// FIXME: Once AbsProviderConfig is using addrs.Provider
// instead of embedding LocalProviderConfig, just use
// the defaultProvider value as the FQN here, removing
// the reliance on legacy address forms.
providerAddr = addrs.AbsProviderConfig{
Module: moduleAddr,
ProviderConfig: addrs.LocalProviderConfig{
LocalName: defaultProvider.LegacyString(),
},
}
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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}
}
rs = &resourceStateV4{
Module: moduleAddr.String(),
Mode: modeStr,
Type: resAddr.Type,
Name: resAddr.Name,
Instances: []instanceObjectStateV4{},
ProviderConfig: providerAddr.String(),
}
resourceStates[resAddr.String()] = rs
}
// Now we'll deal with the instance itself, which may either be
// the first instance in a resource we just created or an additional
// instance for a resource added on a prior loop.
instKey := instAddr.Key
if isOld := rsOld.Primary; isOld != nil {
isNew, err := upgradeInstanceObjectV3ToV4(rsOld, isOld, instKey, states.NotDeposed)
if err != nil {
return nil, fmt.Errorf("failed to migrate primary generation of %s: %s", instAddr, err)
}
rs.Instances = append(rs.Instances, *isNew)
}
for i, isOld := range rsOld.Deposed {
// When we migrate old instances we'll use sequential deposed
// keys just so that the upgrade result is deterministic. New
// deposed keys allocated moving forward will be pseudorandomly
// selected, but we check for collisions and so these
// non-random ones won't hurt.
deposedKey := states.DeposedKey(fmt.Sprintf("%08x", i+1))
isNew, err := upgradeInstanceObjectV3ToV4(rsOld, isOld, instKey, deposedKey)
if err != nil {
return nil, fmt.Errorf("failed to migrate deposed generation index %d of %s: %s", i, instAddr, err)
}
rs.Instances = append(rs.Instances, *isNew)
}
if instKey != addrs.NoKey && rs.EachMode == "" {
rs.EachMode = "list"
}
}
for _, rs := range resourceStates {
new.Resources = append(new.Resources, *rs)
}
if len(msOld.Path) == 1 && msOld.Path[0] == "root" {
// We'll migrate the outputs for this module too, then.
for name, oldOS := range msOld.Outputs {
newOS := outputStateV4{
Sensitive: oldOS.Sensitive,
}
valRaw := oldOS.Value
valSrc, err := json.Marshal(valRaw)
if err != nil {
// Should never happen, because this value came from JSON
// in the first place and so we're just round-tripping here.
return nil, fmt.Errorf("failed to serialize output %q value as JSON: %s", name, err)
}
// The "type" field in state V2 wasn't really that useful
// since it was only able to capture string vs. list vs. map.
// For this reason, during upgrade we'll just discard it
// altogether and use cty's idea of the implied type of
// turning our old value into JSON.
ty, err := ctyjson.ImpliedType(valSrc)
if err != nil {
// REALLY should never happen, because we literally just
// encoded this as JSON above!
return nil, fmt.Errorf("failed to parse output %q value from JSON: %s", name, err)
}
// ImpliedType tends to produce structural types, but since older
// version of Terraform didn't support those a collection type
// is probably what was intended, so we'll see if we can
// interpret our value as one.
ty = simplifyImpliedValueType(ty)
tySrc, err := ctyjson.MarshalType(ty)
if err != nil {
return nil, fmt.Errorf("failed to serialize output %q type as JSON: %s", name, err)
}
newOS.ValueRaw = json.RawMessage(valSrc)
newOS.ValueTypeRaw = json.RawMessage(tySrc)
new.RootOutputs[name] = newOS
}
}
}
new.normalize()
return new, nil
}
func upgradeInstanceObjectV3ToV4(rsOld *resourceStateV2, isOld *instanceStateV2, instKey addrs.InstanceKey, deposedKey states.DeposedKey) (*instanceObjectStateV4, error) {
// Schema versions were, in prior formats, a private concern of the provider
// SDK, and not a first-class concept in the state format. Here we're
// sniffing for the pre-0.12 SDK's way of representing schema versions
// and promoting it to our first-class field if we find it. We'll ignore
// it if it doesn't look like what the SDK would've written. If this
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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// sniffing fails then we'll assume schema version 0.
var schemaVersion uint64
migratedSchemaVersion := false
if raw, exists := isOld.Meta["schema_version"]; exists {
switch tv := raw.(type) {
case string:
v, err := strconv.ParseUint(tv, 10, 64)
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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if err == nil {
schemaVersion = v
migratedSchemaVersion = true
}
case int:
schemaVersion = uint64(tv)
migratedSchemaVersion = true
case float64:
schemaVersion = uint64(tv)
migratedSchemaVersion = true
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
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}
}
private := map[string]interface{}{}
for k, v := range isOld.Meta {
if k == "schema_version" && migratedSchemaVersion {
// We're gonna promote this into our first-class schema version field
continue
}
private[k] = v
}
var privateJSON []byte
if len(private) != 0 {
var err error
privateJSON, err = json.Marshal(private)
if err != nil {
// This shouldn't happen, because the Meta values all came from JSON
// originally anyway.
return nil, fmt.Errorf("cannot serialize private instance object data: %s", err)
}
}
var status string
if isOld.Tainted {
status = "tainted"
}
var instKeyRaw interface{}
switch tk := instKey.(type) {
case addrs.IntKey:
instKeyRaw = int(tk)
case addrs.StringKey:
instKeyRaw = string(tk)
default:
if instKeyRaw != nil {
return nil, fmt.Errorf("unsupported instance key: %#v", instKey)
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
2018-06-08 02:35:55 +02:00
}
}
var attributes map[string]string
if isOld.Attributes != nil {
attributes = make(map[string]string, len(isOld.Attributes))
for k, v := range isOld.Attributes {
attributes[k] = v
}
}
if isOld.ID != "" {
// As a special case, if we don't already have an "id" attribute and
// yet there's a non-empty first-class ID on the old object then we'll
// create a synthetic id attribute to avoid losing that first-class id.
// In practice this generally arises only in tests where state literals
// are hand-written in a non-standard way; real code prior to 0.12
// would always force the first-class ID to be copied into the
// id attribute before storing.
if attributes == nil {
attributes = make(map[string]string, len(isOld.Attributes))
}
if idVal := attributes["id"]; idVal == "" {
attributes["id"] = isOld.ID
}
}
dependencies := make([]string, 0, len(rsOld.Dependencies))
for _, v := range rsOld.Dependencies {
depStr, err := parseLegacyDependency(v)
if err != nil {
// We just drop invalid dependencies on the floor here, because
// they tend to get left behind in Terraform 0.11 when resources
// are renamed or moved between modules and there's no automatic
// way to fix them here. In practice it shouldn't hurt to miss
// a few dependency edges in the state because a subsequent plan
// will run a refresh walk first and re-synchronize the
// dependencies with the configuration.
//
// There is one rough edges where this can cause an incorrect
// result, though: If the first command the user runs after
// upgrading to Terraform 0.12 uses -refresh=false and thus
// prevents the dependency reorganization from occurring _and_
// that initial plan discovered "orphaned" resources (not present
// in configuration any longer) then when the plan is applied the
// destroy ordering will be incorrect for the instances of those
// resources. We expect that is a rare enough situation that it
// isn't a big deal, and even when it _does_ occur it's common for
// the apply to succeed anyway unless many separate resources with
// complex inter-dependencies are all orphaned at once.
log.Printf("statefile: ignoring invalid dependency address %q while upgrading from state version 3 to version 4: %s", v, err)
continue
}
dependencies = append(dependencies, depStr)
}
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
2018-06-08 02:35:55 +02:00
return &instanceObjectStateV4{
IndexKey: instKeyRaw,
Status: status,
Deposed: string(deposedKey),
AttributesFlat: attributes,
DependsOn: dependencies,
statefile: New package for loading and saving state files Whereas the parent directory "states" contains the models that represent state in memory, this package's responsibility is in serializing a subset of that data to a JSON-based file format and then reloading that data back into memory later. For reading, this package supports state file formats going back to version 1, using lightly-adapted versions of the migration code previously used in the "terraform" package. State data is upgraded to the latest version step by step and then transformed into the in-memory state representation, which is distinct from any of the file format structs in this package to enable these to evolve separately. For writing, only the latest version (4) is supported, which is a new format that is a slightly-flattened version of the new in-memory state models introduced in the prior commit. This format retains the outputs from only the root module and it flattens out the module and instance parts of the hierarchy by including the identifiers for these inside the child object. The loader then reconstructs the multi-layer structure we use for more convenient access in memory. For now, the only testing in this package is of round-tripping different versions of state through a read and a write, ensuring the output is as desired. This exercises all of the reading, upgrading, and writing functions but should be augmented in later commits to improve coverage and introduce more focused tests for specific parts of the functionality.
2018-06-08 02:35:55 +02:00
SchemaVersion: schemaVersion,
PrivateRaw: privateJSON,
}, nil
}
// parseLegacyResourceAddress parses the different identifier format used
// state formats before version 4, like "instance.name.0".
func parseLegacyResourceAddress(s string) (addrs.ResourceInstance, error) {
var ret addrs.ResourceInstance
// Split based on ".". Every resource address should have at least two
// elements (type and name).
parts := strings.Split(s, ".")
if len(parts) < 2 || len(parts) > 4 {
return ret, fmt.Errorf("invalid internal resource address format: %s", s)
}
// Data resource if we have at least 3 parts and the first one is data
ret.Resource.Mode = addrs.ManagedResourceMode
if len(parts) > 2 && parts[0] == "data" {
ret.Resource.Mode = addrs.DataResourceMode
parts = parts[1:]
}
// If we're not a data resource and we have more than 3, then it is an error
if len(parts) > 3 && ret.Resource.Mode != addrs.DataResourceMode {
return ret, fmt.Errorf("invalid internal resource address format: %s", s)
}
// Build the parts of the resource address that are guaranteed to exist
ret.Resource.Type = parts[0]
ret.Resource.Name = parts[1]
ret.Key = addrs.NoKey
// If we have more parts, then we have an index. Parse that.
if len(parts) > 2 {
idx, err := strconv.ParseInt(parts[2], 0, 0)
if err != nil {
return ret, fmt.Errorf("error parsing resource address %q: %s", s, err)
}
ret.Key = addrs.IntKey(idx)
}
return ret, nil
}
// simplifyImpliedValueType attempts to heuristically simplify a value type
// derived from a legacy stored output value into something simpler that
// is closer to what would've fitted into the pre-v0.12 value type system.
func simplifyImpliedValueType(ty cty.Type) cty.Type {
switch {
case ty.IsTupleType():
// If all of the element types are the same then we'll make this
// a list instead. This is very likely to be true, since prior versions
// of Terraform did not officially support mixed-type collections.
if ty.Equals(cty.EmptyTuple) {
// Don't know what the element type would be, then.
return ty
}
etys := ty.TupleElementTypes()
ety := etys[0]
for _, other := range etys[1:] {
if !other.Equals(ety) {
// inconsistent types
return ty
}
}
ety = simplifyImpliedValueType(ety)
return cty.List(ety)
case ty.IsObjectType():
// If all of the attribute types are the same then we'll make this
// a map instead. This is very likely to be true, since prior versions
// of Terraform did not officially support mixed-type collections.
if ty.Equals(cty.EmptyObject) {
// Don't know what the element type would be, then.
return ty
}
atys := ty.AttributeTypes()
var ety cty.Type
for _, other := range atys {
if ety == cty.NilType {
ety = other
continue
}
if !other.Equals(ety) {
// inconsistent types
return ty
}
}
ety = simplifyImpliedValueType(ety)
return cty.Map(ety)
default:
// No other normalizations are possible
return ty
}
}
func parseLegacyDependency(s string) (string, error) {
parts := strings.Split(s, ".")
ret := parts[0]
for _, part := range parts[1:] {
if part == "*" {
break
}
if i, err := strconv.Atoi(part); err == nil {
ret = ret + fmt.Sprintf("[%d]", i)
break
}
ret = ret + "." + part
}
// The result must parse as a reference, or else we'll create an invalid
// state file.
var diags tfdiags.Diagnostics
_, diags = addrs.ParseRefStr(ret)
if diags.HasErrors() {
return "", diags.Err()
}
return ret, nil
}