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terraform/terraform/transform_diff.go

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package terraform
import (
"fmt"
"log"
"github.com/hashicorp/terraform/dag"
"github.com/hashicorp/terraform/plans"
"github.com/hashicorp/terraform/states"
"github.com/hashicorp/terraform/tfdiags"
)
// DiffTransformer is a GraphTransformer that adds graph nodes representing
// each of the resource changes described in the given Changes object.
type DiffTransformer struct {
Concrete ConcreteResourceInstanceNodeFunc
State *states.State
Changes *plans.Changes
}
func (t *DiffTransformer) Transform(g *Graph) error {
if t.Changes == nil || len(t.Changes.Resources) == 0 {
// Nothing to do!
return nil
}
// Go through all the modules in the diff.
log.Printf("[TRACE] DiffTransformer starting")
var diags tfdiags.Diagnostics
state := t.State
changes := t.Changes
// DiffTransformer creates resource _instance_ nodes. If there are any
// whole-resource nodes already in the graph, we must ensure that they
// get evaluated before any of the corresponding instances by creating
// dependency edges, so we'll do some prep work here to ensure we'll only
// create connections to nodes that existed before we started here.
resourceNodes := map[string][]GraphNodeConfigResource{}
for _, node := range g.Vertices() {
rn, ok := node.(GraphNodeConfigResource)
if !ok {
continue
}
// We ignore any instances that _also_ implement
// GraphNodeResourceInstance, since in the unlikely event that they
// do exist we'd probably end up creating cycles by connecting them.
if _, ok := node.(GraphNodeResourceInstance); ok {
continue
}
addr := rn.ResourceAddr().String()
resourceNodes[addr] = append(resourceNodes[addr], rn)
}
for _, rc := range changes.Resources {
addr := rc.Addr
dk := rc.DeposedKey
log.Printf("[TRACE] DiffTransformer: found %s change for %s %s", rc.Action, addr, dk)
// Depending on the action we'll need some different combinations of
// nodes, because destroying uses a special node type separate from
// other actions.
var update, delete, createBeforeDestroy bool
switch rc.Action {
case plans.NoOp:
continue
case plans.Delete:
delete = true
case plans.DeleteThenCreate, plans.CreateThenDelete:
update = true
delete = true
createBeforeDestroy = (rc.Action == plans.CreateThenDelete)
default:
update = true
}
if dk != states.NotDeposed && update {
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
"Invalid planned change for deposed object",
fmt.Sprintf("The plan contains a non-delete change for %s deposed object %s. The only valid action for a deposed object is to destroy it, so this is a bug in Terraform.", addr, dk),
))
continue
}
// If we're going to do a create_before_destroy Replace operation then
// we need to allocate a DeposedKey to use to retain the
// not-yet-destroyed prior object, so that the delete node can destroy
// _that_ rather than the newly-created node, which will be current
// by the time the delete node is visited.
if update && delete && createBeforeDestroy {
// In this case, variable dk will be the _pre-assigned_ DeposedKey
// that must be used if the update graph node deposes the current
// instance, which will then align with the same key we pass
// into the destroy node to ensure we destroy exactly the deposed
// object we expect.
if state != nil {
ris := state.ResourceInstance(addr)
if ris == nil {
// Should never happen, since we don't plan to replace an
// instance that doesn't exist yet.
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
"Invalid planned change",
fmt.Sprintf("The plan contains a replace change for %s, which doesn't exist yet. This is a bug in Terraform.", addr),
))
continue
}
// Allocating a deposed key separately from using it can be racy
// in general, but we assume here that nothing except the apply
// node we instantiate below will actually make new deposed objects
// in practice, and so the set of already-used keys will not change
// between now and then.
dk = ris.FindUnusedDeposedKey()
} else {
// If we have no state at all yet then we can use _any_
// DeposedKey.
dk = states.NewDeposedKey()
}
}
if update {
// All actions except destroying the node type chosen by t.Concrete
abstract := NewNodeAbstractResourceInstance(addr)
var node dag.Vertex = abstract
if f := t.Concrete; f != nil {
node = f(abstract)
}
if createBeforeDestroy {
// We'll attach our pre-allocated DeposedKey to the node if
// it supports that. NodeApplyableResourceInstance is the
// specific concrete node type we are looking for here really,
// since that's the only node type that might depose objects.
if dn, ok := node.(GraphNodeDeposer); ok {
dn.SetPreallocatedDeposedKey(dk)
}
log.Printf("[TRACE] DiffTransformer: %s will be represented by %s, deposing prior object to %s", addr, dag.VertexName(node), dk)
} else {
log.Printf("[TRACE] DiffTransformer: %s will be represented by %s", addr, dag.VertexName(node))
}
g.Add(node)
rsrcAddr := addr.ContainingResource().String()
for _, rsrcNode := range resourceNodes[rsrcAddr] {
g.Connect(dag.BasicEdge(node, rsrcNode))
}
}
if delete {
// Destroying always uses a destroy-specific node type, though
// which one depends on whether we're destroying a current object
// or a deposed object.
var node GraphNodeResourceInstance
abstract := NewNodeAbstractResourceInstance(addr)
if dk == states.NotDeposed {
node = &NodeDestroyResourceInstance{
NodeAbstractResourceInstance: abstract,
DeposedKey: dk,
}
} else {
node = &NodeDestroyDeposedResourceInstanceObject{
NodeAbstractResourceInstance: abstract,
DeposedKey: dk,
}
}
if dk == states.NotDeposed {
log.Printf("[TRACE] DiffTransformer: %s will be represented for destruction by %s", addr, dag.VertexName(node))
} else {
log.Printf("[TRACE] DiffTransformer: %s deposed object %s will be represented for destruction by %s", addr, dk, dag.VertexName(node))
}
g.Add(node)
}
}
log.Printf("[TRACE] DiffTransformer complete")
return diags.Err()
}
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