opentofu/terraform/transform_reference.go
Martin Atkins a3403f2766 terraform: Ugly huge change to weave in new State and Plan types
Due to how often the state and plan types are referenced throughout
Terraform, there isn't a great way to switch them out gradually. As a
consequence, this huge commit gets us from the old world to a _compilable_
new world, but still has a large number of known test failures due to
key functionality being stubbed out.

The stubs here are for anything that interacts with providers, since we
now need to do the follow-up work to similarly replace the old
terraform.ResourceProvider interface with its replacement in the new
"providers" package. That work, along with work to fix the remaining
failing tests, will follow in subsequent commits.

The aim here was to replace all references to terraform.State and its
downstream types with states.State, terraform.Plan with plans.Plan,
state.State with statemgr.State, and switch to the new implementations of
the state and plan file formats. However, due to the number of times those
types are used, this also ended up affecting numerous other parts of core
such as terraform.Hook, the backend.Backend interface, and most of the CLI
commands.

Just as with 5861dbf3fc49b19587a31816eb06f511ab861bb4 before, I apologize
in advance to the person who inevitably just found this huge commit while
spelunking through the commit history.
2018-10-16 19:11:09 -07:00

496 lines
15 KiB
Go

package terraform
import (
"fmt"
"log"
"github.com/hashicorp/hcl2/hcl"
"github.com/hashicorp/terraform/configs/configschema"
"github.com/hashicorp/terraform/lang"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/config"
"github.com/hashicorp/terraform/dag"
)
// GraphNodeReferenceable must be implemented by any node that represents
// a Terraform thing that can be referenced (resource, module, etc.).
//
// Even if the thing has no name, this should return an empty list. By
// implementing this and returning a non-nil result, you say that this CAN
// be referenced and other methods of referencing may still be possible (such
// as by path!)
type GraphNodeReferenceable interface {
GraphNodeSubPath
// ReferenceableAddrs returns a list of addresses through which this can be
// referenced.
ReferenceableAddrs() []addrs.Referenceable
}
// GraphNodeReferencer must be implemented by nodes that reference other
// Terraform items and therefore depend on them.
type GraphNodeReferencer interface {
GraphNodeSubPath
// References returns a list of references made by this node, which
// include both a referenced address and source location information for
// the reference.
References() []*addrs.Reference
}
// GraphNodeReferenceOutside is an interface that can optionally be implemented.
// A node that implements it can specify that its own referenceable addresses
// and/or the addresses it references are in a different module than the
// node itself.
//
// Any referenceable addresses returned by ReferenceableAddrs are interpreted
// relative to the returned selfPath.
//
// Any references returned by References are interpreted relative to the
// returned referencePath.
//
// It is valid but not required for either of these paths to match what is
// returned by method Path, though if both match the main Path then there
// is no reason to implement this method.
//
// The primary use-case for this is the nodes representing module input
// variables, since their expressions are resolved in terms of their calling
// module, but they are still referenced from their own module.
type GraphNodeReferenceOutside interface {
// ReferenceOutside returns a path in which any references from this node
// are resolved.
ReferenceOutside() (selfPath, referencePath addrs.ModuleInstance)
}
// ReferenceTransformer is a GraphTransformer that connects all the
// nodes that reference each other in order to form the proper ordering.
type ReferenceTransformer struct{}
func (t *ReferenceTransformer) Transform(g *Graph) error {
// Build a reference map so we can efficiently look up the references
vs := g.Vertices()
m := NewReferenceMap(vs)
// Find the things that reference things and connect them
for _, v := range vs {
parents, _ := m.References(v)
parentsDbg := make([]string, len(parents))
for i, v := range parents {
parentsDbg[i] = dag.VertexName(v)
}
log.Printf(
"[DEBUG] ReferenceTransformer: %q references: %v",
dag.VertexName(v), parentsDbg)
for _, parent := range parents {
g.Connect(dag.BasicEdge(v, parent))
}
}
return nil
}
// DestroyReferenceTransformer is a GraphTransformer that reverses the edges
// for locals and outputs that depend on other nodes which will be
// removed during destroy. If a destroy node is evaluated before the local or
// output value, it will be removed from the state, and the later interpolation
// will fail.
type DestroyValueReferenceTransformer struct{}
func (t *DestroyValueReferenceTransformer) Transform(g *Graph) error {
vs := g.Vertices()
for _, v := range vs {
switch v.(type) {
case *NodeApplyableOutput, *NodeLocal:
// OK
default:
continue
}
// reverse any outgoing edges so that the value is evaluated first.
for _, e := range g.EdgesFrom(v) {
target := e.Target()
// only destroy nodes will be evaluated in reverse
if _, ok := target.(GraphNodeDestroyer); !ok {
continue
}
log.Printf("[TRACE] output dep: %s", dag.VertexName(target))
g.RemoveEdge(e)
g.Connect(&DestroyEdge{S: target, T: v})
}
}
return nil
}
// PruneUnusedValuesTransformer is s GraphTransformer that removes local and
// output values which are not referenced in the graph. Since outputs and
// locals always need to be evaluated, if they reference a resource that is not
// available in the state the interpolation could fail.
type PruneUnusedValuesTransformer struct{}
func (t *PruneUnusedValuesTransformer) Transform(g *Graph) error {
// this might need multiple runs in order to ensure that pruning a value
// doesn't effect a previously checked value.
for removed := 0; ; removed = 0 {
for _, v := range g.Vertices() {
switch v.(type) {
case *NodeApplyableOutput, *NodeLocal:
// OK
default:
continue
}
dependants := g.UpEdges(v)
switch dependants.Len() {
case 0:
// nothing at all depends on this
g.Remove(v)
removed++
case 1:
// because an output's destroy node always depends on the output,
// we need to check for the case of a single destroy node.
d := dependants.List()[0]
if _, ok := d.(*NodeDestroyableOutput); ok {
g.Remove(v)
removed++
}
}
}
if removed == 0 {
break
}
}
return nil
}
// ReferenceMap is a structure that can be used to efficiently check
// for references on a graph.
type ReferenceMap struct {
// vertices is a map from internal reference keys (as produced by the
// mapKey method) to one or more vertices that are identified by each key.
//
// A particular reference key might actually identify multiple vertices,
// e.g. in situations where one object is contained inside another.
vertices map[string][]dag.Vertex
// edges is a map whose keys are a subset of the internal reference keys
// from "vertices", and whose values are the nodes that refer to each
// key. The values in this map are the referrers, while values in
// "verticies" are the referents. The keys in both cases are referents.
edges map[string][]dag.Vertex
}
// References returns the set of vertices that the given vertex refers to,
// and any referenced addresses that do not have corresponding vertices.
func (m *ReferenceMap) References(v dag.Vertex) ([]dag.Vertex, []addrs.Referenceable) {
rn, ok := v.(GraphNodeReferencer)
if !ok {
return nil, nil
}
if _, ok := v.(GraphNodeSubPath); !ok {
return nil, nil
}
var matches []dag.Vertex
var missing []addrs.Referenceable
for _, ref := range rn.References() {
subject := ref.Subject
key := m.referenceMapKey(v, subject)
if _, exists := m.vertices[key]; !exists {
// If what we were looking for was a ResourceInstance then we
// might be in a resource-oriented graph rather than an
// instance-oriented graph, and so we'll see if we have the
// resource itself instead.
switch ri := subject.(type) {
case addrs.ResourceInstance:
subject = ri.ContainingResource()
case addrs.ResourceInstancePhase:
subject = ri.ContainingResource()
}
key = m.referenceMapKey(v, subject)
}
vertices := m.vertices[key]
for _, rv := range vertices {
// don't include self-references
if rv == v {
continue
}
matches = append(matches, rv)
}
if len(vertices) == 0 {
missing = append(missing, ref.Subject)
}
}
return matches, missing
}
// Referrers returns the set of vertices that refer to the given vertex.
func (m *ReferenceMap) Referrers(v dag.Vertex) []dag.Vertex {
rn, ok := v.(GraphNodeReferenceable)
if !ok {
return nil
}
sp, ok := v.(GraphNodeSubPath)
if !ok {
return nil
}
var matches []dag.Vertex
for _, addr := range rn.ReferenceableAddrs() {
key := m.mapKey(sp.Path(), addr)
referrers, ok := m.edges[key]
if !ok {
continue
}
// If the referrer set includes our own given vertex then we skip,
// since we don't want to return self-references.
selfRef := false
for _, p := range referrers {
if p == v {
selfRef = true
break
}
}
if selfRef {
continue
}
matches = append(matches, referrers...)
}
return matches
}
func (m *ReferenceMap) mapKey(path addrs.ModuleInstance, addr addrs.Referenceable) string {
return fmt.Sprintf("%s|%s", path.String(), addr.String())
}
// vertexReferenceablePath returns the path in which the given vertex can be
// referenced. This is the path that its results from ReferenceableAddrs
// are considered to be relative to.
//
// Only GraphNodeSubPath implementations can be referenced, so this method will
// panic if the given vertex does not implement that interface.
func (m *ReferenceMap) vertexReferenceablePath(v dag.Vertex) addrs.ModuleInstance {
sp, ok := v.(GraphNodeSubPath)
if !ok {
// Only nodes with paths can participate in a reference map.
panic(fmt.Errorf("vertexMapKey on vertex type %T which doesn't implement GraphNodeSubPath", sp))
}
if outside, ok := v.(GraphNodeReferenceOutside); ok {
// Vertex is referenced from a different module than where it was
// declared.
path, _ := outside.ReferenceOutside()
return path
}
// Vertex is referenced from the same module as where it was declared.
return sp.Path()
}
// vertexReferencePath returns the path in which references _from_ the given
// vertex must be interpreted.
//
// Only GraphNodeSubPath implementations can have references, so this method
// will panic if the given vertex does not implement that interface.
func vertexReferencePath(referrer dag.Vertex) addrs.ModuleInstance {
sp, ok := referrer.(GraphNodeSubPath)
if !ok {
// Only nodes with paths can participate in a reference map.
panic(fmt.Errorf("vertexReferencePath on vertex type %T which doesn't implement GraphNodeSubPath", sp))
}
var path addrs.ModuleInstance
if outside, ok := referrer.(GraphNodeReferenceOutside); ok {
// Vertex makes references to objects in a different module than where
// it was declared.
_, path = outside.ReferenceOutside()
return path
}
// Vertex makes references to objects in the same module as where it
// was declared.
return sp.Path()
}
// referenceMapKey produces keys for the "edges" map. "referrer" is the vertex
// that the reference is from, and "addr" is the address of the object being
// referenced.
//
// The result is an opaque string that includes both the address of the given
// object and the address of the module instance that object belongs to.
//
// Only GraphNodeSubPath implementations can be referrers, so this method will
// panic if the given vertex does not implement that interface.
func (m *ReferenceMap) referenceMapKey(referrer dag.Vertex, addr addrs.Referenceable) string {
path := vertexReferencePath(referrer)
return m.mapKey(path, addr)
}
// NewReferenceMap is used to create a new reference map for the
// given set of vertices.
func NewReferenceMap(vs []dag.Vertex) *ReferenceMap {
var m ReferenceMap
// Build the lookup table
vertices := make(map[string][]dag.Vertex)
for _, v := range vs {
_, ok := v.(GraphNodeSubPath)
if !ok {
// Only nodes with paths can participate in a reference map.
continue
}
// We're only looking for referenceable nodes
rn, ok := v.(GraphNodeReferenceable)
if !ok {
continue
}
path := m.vertexReferenceablePath(v)
// Go through and cache them
for _, addr := range rn.ReferenceableAddrs() {
key := m.mapKey(path, addr)
vertices[key] = append(vertices[key], v)
}
// Any node can be referenced by the address of the module it belongs
// to or any of that module's ancestors.
for _, addr := range path.Ancestors()[1:] {
// Can be referenced either as the specific call instance (with
// an instance key) or as the bare module call itself (the "module"
// block in the parent module that created the instance).
callPath, call := addr.Call()
callInstPath, callInst := addr.CallInstance()
callKey := m.mapKey(callPath, call)
callInstKey := m.mapKey(callInstPath, callInst)
vertices[callKey] = append(vertices[callKey], v)
vertices[callInstKey] = append(vertices[callInstKey], v)
}
}
// Build the lookup table for referenced by
edges := make(map[string][]dag.Vertex)
for _, v := range vs {
_, ok := v.(GraphNodeSubPath)
if !ok {
// Only nodes with paths can participate in a reference map.
continue
}
rn, ok := v.(GraphNodeReferencer)
if !ok {
// We're only looking for referenceable nodes
continue
}
// Go through and cache them
for _, ref := range rn.References() {
if ref.Subject == nil {
// Should never happen
panic(fmt.Sprintf("%T.References returned reference with nil subject", rn))
}
key := m.referenceMapKey(v, ref.Subject)
edges[key] = append(edges[key], v)
}
}
m.vertices = vertices
m.edges = edges
return &m
}
// ReferencesFromConfig returns the references that a configuration has
// based on the interpolated variables in a configuration.
func ReferencesFromConfig(body hcl.Body, schema *configschema.Block) []*addrs.Reference {
if body == nil {
return nil
}
refs, _ := lang.ReferencesInBlock(body, schema)
return refs
}
// ReferenceFromInterpolatedVar returns the reference from this variable,
// or an empty string if there is no reference.
func ReferenceFromInterpolatedVar(v config.InterpolatedVariable) []string {
switch v := v.(type) {
case *config.ModuleVariable:
return []string{fmt.Sprintf("module.%s.output.%s", v.Name, v.Field)}
case *config.ResourceVariable:
id := v.ResourceId()
// If we have a multi-reference (splat), then we depend on ALL
// resources with this type/name.
if v.Multi && v.Index == -1 {
return []string{fmt.Sprintf("%s.*", id)}
}
// Otherwise, we depend on a specific index.
idx := v.Index
if !v.Multi || v.Index == -1 {
idx = 0
}
// Depend on the index, as well as "N" which represents the
// un-expanded set of resources.
return []string{fmt.Sprintf("%s.%d/%s.N", id, idx, id)}
case *config.UserVariable:
return []string{fmt.Sprintf("var.%s", v.Name)}
case *config.LocalVariable:
return []string{fmt.Sprintf("local.%s", v.Name)}
default:
return nil
}
}
// appendResourceDestroyReferences identifies resource and resource instance
// references in the given slice and appends to it the "destroy-phase"
// equivalents of those references, returning the result.
//
// This can be used in the References implementation for a node which must also
// depend on the destruction of anything it references.
func appendResourceDestroyReferences(refs []*addrs.Reference) []*addrs.Reference {
given := refs
for _, ref := range given {
switch tr := ref.Subject.(type) {
case addrs.Resource:
newRef := *ref // shallow copy
newRef.Subject = tr.Phase(addrs.ResourceInstancePhaseDestroy)
refs = append(refs, &newRef)
case addrs.ResourceInstance:
newRef := *ref // shallow copy
newRef.Subject = tr.Phase(addrs.ResourceInstancePhaseDestroy)
refs = append(refs, &newRef)
}
}
return refs
}
func modulePrefixStr(p addrs.ModuleInstance) string {
return p.String()
}
func modulePrefixList(result []string, prefix string) []string {
if prefix != "" {
for i, v := range result {
result[i] = fmt.Sprintf("%s.%s", prefix, v)
}
}
return result
}