terraform/states/statefile/version1.go

168 lines
6.1 KiB
Go
Raw Normal View History

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
package statefile
import (
"encoding/json"
"fmt"
"github.com/hashicorp/terraform/tfdiags"
)
func readStateV1(src []byte) (*File, tfdiags.Diagnostics) {
var diags tfdiags.Diagnostics
sV1 := &stateV1{}
err := json.Unmarshal(src, sV1)
if err != nil {
diags = diags.Append(jsonUnmarshalDiags(err))
return nil, diags
}
file, prepDiags := prepareStateV1(sV1)
diags = diags.Append(prepDiags)
return file, diags
}
func prepareStateV1(sV1 *stateV1) (*File, tfdiags.Diagnostics) {
var diags tfdiags.Diagnostics
sV2, err := upgradeStateV1ToV2(sV1)
if err != nil {
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
upgradeFailed,
fmt.Sprintf("Error upgrading state file format from version 1 to version 2: %s.", err),
))
return nil, diags
}
file, prepDiags := prepareStateV2(sV2)
diags = diags.Append(prepDiags)
return file, diags
}
// stateV1 is a representation of the legacy JSON state format version 1.
//
// It is only used to read version 1 JSON files prior to upgrading them to
// the current format.
type stateV1 struct {
// Version is the protocol version. "1" for a StateV1.
Version int `json:"version"`
// Serial is incremented on any operation that modifies
// the State file. It is used to detect potentially conflicting
// updates.
Serial int64 `json:"serial"`
// Remote is used to track the metadata required to
// pull and push state files from a remote storage endpoint.
Remote *remoteStateV1 `json:"remote,omitempty"`
// Modules contains all the modules in a breadth-first order
Modules []*moduleStateV1 `json:"modules"`
}
type remoteStateV1 struct {
// Type controls the client we use for the remote state
Type string `json:"type"`
// Config is used to store arbitrary configuration that
// is type specific
Config map[string]string `json:"config"`
}
type moduleStateV1 struct {
// Path is the import path from the root module. Modules imports are
// always disjoint, so the path represents amodule tree
Path []string `json:"path"`
// Outputs declared by the module and maintained for each module
// even though only the root module technically needs to be kept.
// This allows operators to inspect values at the boundaries.
Outputs map[string]string `json:"outputs"`
// Resources is a mapping of the logically named resource to
// the state of the resource. Each resource may actually have
// N instances underneath, although a user only needs to think
// about the 1:1 case.
Resources map[string]*resourceStateV1 `json:"resources"`
// Dependencies are a list of things that this module relies on
// existing to remain intact. For example: an module may depend
// on a VPC ID given by an aws_vpc resource.
//
// Terraform uses this information to build valid destruction
// orders and to warn the user if they're destroying a module that
// another resource depends on.
//
// Things can be put into this list that may not be managed by
// Terraform. If Terraform doesn't find a matching ID in the
// overall state, then it assumes it isn't managed and doesn't
// worry about it.
Dependencies []string `json:"depends_on,omitempty"`
}
type resourceStateV1 struct {
// This is filled in and managed by Terraform, and is the resource
// type itself such as "mycloud_instance". If a resource provider sets
// this value, it won't be persisted.
Type string `json:"type"`
// Dependencies are a list of things that this resource relies on
// existing to remain intact. For example: an AWS instance might
// depend on a subnet (which itself might depend on a VPC, and so
// on).
//
// Terraform uses this information to build valid destruction
// orders and to warn the user if they're destroying a resource that
// another resource depends on.
//
// Things can be put into this list that may not be managed by
// Terraform. If Terraform doesn't find a matching ID in the
// overall state, then it assumes it isn't managed and doesn't
// worry about it.
Dependencies []string `json:"depends_on,omitempty"`
// Primary is the current active instance for this resource.
// It can be replaced but only after a successful creation.
// This is the instances on which providers will act.
Primary *instanceStateV1 `json:"primary"`
// Tainted is used to track any underlying instances that
// have been created but are in a bad or unknown state and
// need to be cleaned up subsequently. In the
// standard case, there is only at most a single instance.
// However, in pathological cases, it is possible for the number
// of instances to accumulate.
Tainted []*instanceStateV1 `json:"tainted,omitempty"`
// Deposed is used in the mechanics of CreateBeforeDestroy: the existing
// Primary is Deposed to get it out of the way for the replacement Primary to
// be created by Apply. If the replacement Primary creates successfully, the
// Deposed instance is cleaned up. If there were problems creating the
// replacement, the instance remains in the Deposed list so it can be
// destroyed in a future run. Functionally, Deposed instances are very
// similar to Tainted instances in that Terraform is only tracking them in
// order to remember to destroy them.
Deposed []*instanceStateV1 `json:"deposed,omitempty"`
// Provider is used when a resource is connected to a provider with an alias.
// If this string is empty, the resource is connected to the default provider,
// e.g. "aws_instance" goes with the "aws" provider.
// If the resource block contained a "provider" key, that value will be set here.
Provider string `json:"provider,omitempty"`
}
type instanceStateV1 struct {
// A unique ID for this resource. This is opaque to Terraform
// and is only meant as a lookup mechanism for the providers.
ID string `json:"id"`
// Attributes are basic information about the resource. Any keys here
// are accessible in variable format within Terraform configurations:
// ${resourcetype.name.attribute}.
Attributes map[string]string `json:"attributes,omitempty"`
// Meta is a simple K/V map that is persisted to the State but otherwise
// ignored by Terraform core. It's meant to be used for accounting by
// external client code.
Meta map[string]string `json:"meta,omitempty"`
}