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https://github.com/opentofu/opentofu.git
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99867f0082
Since outputs and local nodes are always evaluated, if the reference a resource form the configuration that isn't in the state, the interpolation could fail. Prune any local or output values that have no references in the graph.
385 lines
9.8 KiB
Go
385 lines
9.8 KiB
Go
package terraform
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import (
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"fmt"
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"log"
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"strings"
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"github.com/hashicorp/terraform/config"
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"github.com/hashicorp/terraform/dag"
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)
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// GraphNodeReferenceable must be implemented by any node that represents
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// a Terraform thing that can be referenced (resource, module, etc.).
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//
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// Even if the thing has no name, this should return an empty list. By
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// implementing this and returning a non-nil result, you say that this CAN
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// be referenced and other methods of referencing may still be possible (such
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// as by path!)
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type GraphNodeReferenceable interface {
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// ReferenceableName is the name by which this can be referenced.
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// This can be either just the type, or include the field. Example:
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// "aws_instance.bar" or "aws_instance.bar.id".
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ReferenceableName() []string
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}
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// GraphNodeReferencer must be implemented by nodes that reference other
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// Terraform items and therefore depend on them.
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type GraphNodeReferencer interface {
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// References are the list of things that this node references. This
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// can include fields or just the type, just like GraphNodeReferenceable
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// above.
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References() []string
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}
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// GraphNodeReferenceGlobal is an interface that can optionally be
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// implemented. If ReferenceGlobal returns true, then the References()
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// and ReferenceableName() must be _fully qualified_ with "module.foo.bar"
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// etc.
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//
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// This allows a node to reference and be referenced by a specific name
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// that may cross module boundaries. This can be very dangerous so use
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// this wisely.
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//
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// The primary use case for this is module boundaries (variables coming in).
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type GraphNodeReferenceGlobal interface {
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// Set to true to signal that references and name are fully
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// qualified. See the above docs for more information.
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ReferenceGlobal() bool
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}
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// ReferenceTransformer is a GraphTransformer that connects all the
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// nodes that reference each other in order to form the proper ordering.
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type ReferenceTransformer struct{}
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func (t *ReferenceTransformer) Transform(g *Graph) error {
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// Build a reference map so we can efficiently look up the references
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vs := g.Vertices()
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m := NewReferenceMap(vs)
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// Find the things that reference things and connect them
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for _, v := range vs {
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parents, _ := m.References(v)
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parentsDbg := make([]string, len(parents))
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for i, v := range parents {
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parentsDbg[i] = dag.VertexName(v)
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}
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log.Printf(
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"[DEBUG] ReferenceTransformer: %q references: %v",
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dag.VertexName(v), parentsDbg)
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for _, parent := range parents {
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g.Connect(dag.BasicEdge(v, parent))
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}
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}
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return nil
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}
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// DestroyReferenceTransformer is a GraphTransformer that reverses the edges
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// for locals and outputs that depend on other nodes which will be
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// removed during destroy. If a destroy node is evaluated before the local or
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// output value, it will be removed from the state, and the later interpolation
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// will fail.
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type DestroyValueReferenceTransformer struct{}
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func (t *DestroyValueReferenceTransformer) Transform(g *Graph) error {
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vs := g.Vertices()
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for _, v := range vs {
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switch v.(type) {
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case *NodeApplyableOutput, *NodeLocal:
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// OK
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default:
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continue
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}
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// reverse any outgoing edges so that the value is evaluated first.
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for _, e := range g.EdgesFrom(v) {
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target := e.Target()
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// only destroy nodes will be evaluated in reverse
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if _, ok := target.(GraphNodeDestroyer); !ok {
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continue
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}
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log.Printf("[TRACE] output dep: %s", dag.VertexName(target))
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g.RemoveEdge(e)
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g.Connect(&DestroyEdge{S: target, T: v})
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}
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}
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return nil
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}
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// PruneUnusedValuesTransformer is s GraphTransformer that removes local and
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// output values which are not referenced in the graph. Since outputs and
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// locals always need to be evaluated, if they reference a resource that is not
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// available in the state the interpolation could fail.
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type PruneUnusedValuesTransformer struct{}
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func (t *PruneUnusedValuesTransformer) Transform(g *Graph) error {
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vs := g.Vertices()
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for _, v := range vs {
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switch v.(type) {
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case *NodeApplyableOutput, *NodeLocal:
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// OK
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default:
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continue
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}
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if len(g.EdgesTo(v)) == 0 {
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g.Remove(v)
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}
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}
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return nil
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}
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// ReferenceMap is a structure that can be used to efficiently check
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// for references on a graph.
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type ReferenceMap struct {
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// m is the mapping of referenceable name to list of verticies that
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// implement that name. This is built on initialization.
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references map[string][]dag.Vertex
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referencedBy map[string][]dag.Vertex
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}
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// References returns the list of vertices that this vertex
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// references along with any missing references.
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func (m *ReferenceMap) References(v dag.Vertex) ([]dag.Vertex, []string) {
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rn, ok := v.(GraphNodeReferencer)
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if !ok {
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return nil, nil
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}
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var matches []dag.Vertex
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var missing []string
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prefix := m.prefix(v)
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for _, ns := range rn.References() {
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found := false
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for _, n := range strings.Split(ns, "/") {
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n = prefix + n
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parents, ok := m.references[n]
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if !ok {
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continue
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}
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// Mark that we found a match
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found = true
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for _, p := range parents {
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// don't include self-references
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if p == v {
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continue
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}
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matches = append(matches, p)
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}
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break
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}
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if !found {
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missing = append(missing, ns)
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}
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}
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return matches, missing
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}
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// ReferencedBy returns the list of vertices that reference the
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// vertex passed in.
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func (m *ReferenceMap) ReferencedBy(v dag.Vertex) []dag.Vertex {
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rn, ok := v.(GraphNodeReferenceable)
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if !ok {
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return nil
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}
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var matches []dag.Vertex
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prefix := m.prefix(v)
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for _, n := range rn.ReferenceableName() {
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n = prefix + n
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children, ok := m.referencedBy[n]
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if !ok {
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continue
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}
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// Make sure this isn't a self reference, which isn't included
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selfRef := false
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for _, p := range children {
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if p == v {
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selfRef = true
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break
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}
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}
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if selfRef {
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continue
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}
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matches = append(matches, children...)
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}
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return matches
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}
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func (m *ReferenceMap) prefix(v dag.Vertex) string {
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// If the node is stating it is already fully qualified then
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// we don't have to create the prefix!
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if gn, ok := v.(GraphNodeReferenceGlobal); ok && gn.ReferenceGlobal() {
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return ""
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}
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// Create the prefix based on the path
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var prefix string
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if pn, ok := v.(GraphNodeSubPath); ok {
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if path := normalizeModulePath(pn.Path()); len(path) > 1 {
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prefix = modulePrefixStr(path) + "."
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}
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}
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return prefix
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}
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// NewReferenceMap is used to create a new reference map for the
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// given set of vertices.
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func NewReferenceMap(vs []dag.Vertex) *ReferenceMap {
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var m ReferenceMap
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// Build the lookup table
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refMap := make(map[string][]dag.Vertex)
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for _, v := range vs {
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// We're only looking for referenceable nodes
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rn, ok := v.(GraphNodeReferenceable)
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if !ok {
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continue
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}
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// Go through and cache them
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prefix := m.prefix(v)
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for _, n := range rn.ReferenceableName() {
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n = prefix + n
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refMap[n] = append(refMap[n], v)
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}
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// If there is a path, it is always referenceable by that. For
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// example, if this is a referenceable thing at path []string{"foo"},
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// then it can be referenced at "module.foo"
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if pn, ok := v.(GraphNodeSubPath); ok {
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for _, p := range ReferenceModulePath(pn.Path()) {
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refMap[p] = append(refMap[p], v)
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}
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}
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}
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// Build the lookup table for referenced by
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refByMap := make(map[string][]dag.Vertex)
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for _, v := range vs {
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// We're only looking for referenceable nodes
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rn, ok := v.(GraphNodeReferencer)
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if !ok {
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continue
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}
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// Go through and cache them
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prefix := m.prefix(v)
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for _, n := range rn.References() {
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n = prefix + n
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refByMap[n] = append(refByMap[n], v)
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}
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}
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m.references = refMap
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m.referencedBy = refByMap
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return &m
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}
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// Returns the reference name for a module path. The path "foo" would return
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// "module.foo". If this is a deeply nested module, it will be every parent
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// as well. For example: ["foo", "bar"] would return both "module.foo" and
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// "module.foo.module.bar"
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func ReferenceModulePath(p []string) []string {
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p = normalizeModulePath(p)
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if len(p) == 1 {
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// Root, no name
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return nil
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}
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result := make([]string, 0, len(p)-1)
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for i := len(p); i > 1; i-- {
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result = append(result, modulePrefixStr(p[:i]))
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}
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return result
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}
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// ReferencesFromConfig returns the references that a configuration has
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// based on the interpolated variables in a configuration.
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func ReferencesFromConfig(c *config.RawConfig) []string {
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var result []string
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for _, v := range c.Variables {
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if r := ReferenceFromInterpolatedVar(v); len(r) > 0 {
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result = append(result, r...)
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}
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}
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return result
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}
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// ReferenceFromInterpolatedVar returns the reference from this variable,
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// or an empty string if there is no reference.
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func ReferenceFromInterpolatedVar(v config.InterpolatedVariable) []string {
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switch v := v.(type) {
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case *config.ModuleVariable:
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return []string{fmt.Sprintf("module.%s.output.%s", v.Name, v.Field)}
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case *config.ResourceVariable:
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id := v.ResourceId()
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// If we have a multi-reference (splat), then we depend on ALL
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// resources with this type/name.
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if v.Multi && v.Index == -1 {
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return []string{fmt.Sprintf("%s.*", id)}
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}
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// Otherwise, we depend on a specific index.
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idx := v.Index
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if !v.Multi || v.Index == -1 {
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idx = 0
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}
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// Depend on the index, as well as "N" which represents the
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// un-expanded set of resources.
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return []string{fmt.Sprintf("%s.%d/%s.N", id, idx, id)}
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case *config.UserVariable:
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return []string{fmt.Sprintf("var.%s", v.Name)}
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case *config.LocalVariable:
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return []string{fmt.Sprintf("local.%s", v.Name)}
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default:
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return nil
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}
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}
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func modulePrefixStr(p []string) string {
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// strip "root"
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if len(p) > 0 && p[0] == rootModulePath[0] {
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p = p[1:]
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}
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parts := make([]string, 0, len(p)*2)
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for _, p := range p {
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parts = append(parts, "module", p)
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}
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return strings.Join(parts, ".")
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}
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func modulePrefixList(result []string, prefix string) []string {
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if prefix != "" {
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for i, v := range result {
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result[i] = fmt.Sprintf("%s.%s", prefix, v)
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}
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}
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return result
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}
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