v1.5.7/internal/terraform/node_output.go - terraform - Git at Google

 // Copyright (c) HashiCorp, Inc.
 // SPDX-License-Identifier: MPL-2.0

 package terraform

 import (
 	"fmt"
 	"log"

 	"github.com/hashicorp/hcl/v2"
 	"github.com/zclconf/go-cty/cty"

 	"github.com/hashicorp/terraform/internal/addrs"
 	"github.com/hashicorp/terraform/internal/configs"
 	"github.com/hashicorp/terraform/internal/dag"
 	"github.com/hashicorp/terraform/internal/lang"
 	"github.com/hashicorp/terraform/internal/lang/marks"
 	"github.com/hashicorp/terraform/internal/plans"
 	"github.com/hashicorp/terraform/internal/states"
 	"github.com/hashicorp/terraform/internal/tfdiags"
 )

 // nodeExpandOutput is the placeholder for a non-root module output that has
 // not yet had its module path expanded.
 type nodeExpandOutput struct {
 	Addr        addrs.OutputValue
 	Module      addrs.Module
 	Config      *configs.Output
 	Destroying  bool
 	RefreshOnly bool

 	// Planning is set to true when this node is in a graph that was produced
 	// by the plan graph builder, as opposed to the apply graph builder.
 	// This quirk is just because we share the same node type between both
 	// phases but in practice there are a few small differences in the actions
 	// we need to take between plan and apply. See method DynamicExpand for
 	// details.
 	Planning bool
 }

 var (
 	_ GraphNodeReferenceable     = (*nodeExpandOutput)(nil)
 	_ GraphNodeReferencer        = (*nodeExpandOutput)(nil)
 	_ GraphNodeReferenceOutside  = (*nodeExpandOutput)(nil)
 	_ GraphNodeDynamicExpandable = (*nodeExpandOutput)(nil)
 	_ graphNodeTemporaryValue    = (*nodeExpandOutput)(nil)
 	_ graphNodeExpandsInstances  = (*nodeExpandOutput)(nil)
 )

 func (n *nodeExpandOutput) expandsInstances() {}

 func (n *nodeExpandOutput) temporaryValue() bool {
 	// non root outputs are temporary
 	return !n.Module.IsRoot()
 }

 func (n *nodeExpandOutput) DynamicExpand(ctx EvalContext) (*Graph, error) {
 	expander := ctx.InstanceExpander()
 	changes := ctx.Changes()

 	// If this is an output value that participates in custom condition checks
 	// (i.e. it has preconditions or postconditions) then the check state
 	// wants to know the addresses of the checkable objects so that it can
 	// treat them as unknown status if we encounter an error before actually
 	// visiting the checks.
 	//
 	// We must do this only during planning, because the apply phase will start
 	// with all of the same checkable objects that were registered during the
 	// planning phase. Consumers of our JSON plan and state formats expect
 	// that the set of checkable objects will be consistent between the plan
 	// and any state snapshots created during apply, and that only the statuses
 	// of those objects will have changed.
 	var checkableAddrs addrs.Set[addrs.Checkable]
 	if n.Planning {
 		if checkState := ctx.Checks(); checkState.ConfigHasChecks(n.Addr.InModule(n.Module)) {
 			checkableAddrs = addrs.MakeSet[addrs.Checkable]()
 		}
 	}

 	var g Graph
 	for _, module := range expander.ExpandModule(n.Module) {
 		absAddr := n.Addr.Absolute(module)
 		if checkableAddrs != nil {
 			checkableAddrs.Add(absAddr)
 		}

 		// Find any recorded change for this output
 		var change *plans.OutputChangeSrc
 		var outputChanges []*plans.OutputChangeSrc
 		if module.IsRoot() {
 			outputChanges = changes.GetRootOutputChanges()
 		} else {
 			parent, call := module.Call()
 			outputChanges = changes.GetOutputChanges(parent, call)
 		}
 		for _, c := range outputChanges {
 			if c.Addr.String() == absAddr.String() {
 				change = c
 				break
 			}
 		}

 		var node dag.Vertex
 		switch {
 		case module.IsRoot() && n.Destroying:
 			node = &NodeDestroyableOutput{
 				Addr:     absAddr,
 				Planning: n.Planning,
 			}

 		default:
 			node = &NodeApplyableOutput{
 				Addr:         absAddr,
 				Config:       n.Config,
 				Change:       change,
 				RefreshOnly:  n.RefreshOnly,
 				DestroyApply: n.Destroying,
 				Planning:     n.Planning,
 			}
 		}

 		log.Printf("[TRACE] Expanding output: adding %s as %T", absAddr.String(), node)
 		g.Add(node)
 	}
 	addRootNodeToGraph(&g)

 	if checkableAddrs != nil {
 		checkState := ctx.Checks()
 		checkState.ReportCheckableObjects(n.Addr.InModule(n.Module), checkableAddrs)
 	}

 	return &g, nil
 }

 func (n *nodeExpandOutput) Name() string {
 	path := n.Module.String()
 	addr := n.Addr.String() + " (expand)"
 	if path != "" {
 		return path + "." + addr
 	}
 	return addr
 }

 // GraphNodeModulePath
 func (n *nodeExpandOutput) ModulePath() addrs.Module {
 	return n.Module
 }

 // GraphNodeReferenceable
 func (n *nodeExpandOutput) ReferenceableAddrs() []addrs.Referenceable {
 	// An output in the root module can't be referenced at all.
 	if n.Module.IsRoot() {
 		return nil
 	}

 	// the output is referenced through the module call, and via the
 	// module itself.
 	_, call := n.Module.Call()
 	callOutput := addrs.ModuleCallOutput{
 		Call: call,
 		Name: n.Addr.Name,
 	}

 	// Otherwise, we can reference the output via the
 	// module call itself
 	return []addrs.Referenceable{call, callOutput}
 }

 // GraphNodeReferenceOutside implementation
 func (n *nodeExpandOutput) ReferenceOutside() (selfPath, referencePath addrs.Module) {
 	// Output values have their expressions resolved in the context of the
 	// module where they are defined.
 	referencePath = n.Module

 	// ...but they are referenced in the context of their calling module.
 	selfPath = referencePath.Parent()

 	return // uses named return values
 }

 // GraphNodeReferencer
 func (n *nodeExpandOutput) References() []*addrs.Reference {
 	// DestroyNodes do not reference anything.
 	if n.Module.IsRoot() && n.Destroying {
 		return nil
 	}

 	return referencesForOutput(n.Config)
 }

 // NodeApplyableOutput represents an output that is "applyable":
 // it is ready to be applied.
 type NodeApplyableOutput struct {
 	Addr   addrs.AbsOutputValue
 	Config *configs.Output // Config is the output in the config
 	// If this is being evaluated during apply, we may have a change recorded already
 	Change *plans.OutputChangeSrc

 	// Refresh-only mode means that any failing output preconditions are
 	// reported as warnings rather than errors
 	RefreshOnly bool

 	// DestroyApply indicates that we are applying a destroy plan, and do not
 	// need to account for conditional blocks.
 	DestroyApply bool

 	Planning bool
 }

 var (
 	_ GraphNodeModuleInstance   = (*NodeApplyableOutput)(nil)
 	_ GraphNodeReferenceable    = (*NodeApplyableOutput)(nil)
 	_ GraphNodeReferencer       = (*NodeApplyableOutput)(nil)
 	_ GraphNodeReferenceOutside = (*NodeApplyableOutput)(nil)
 	_ GraphNodeExecutable       = (*NodeApplyableOutput)(nil)
 	_ graphNodeTemporaryValue   = (*NodeApplyableOutput)(nil)
 	_ dag.GraphNodeDotter       = (*NodeApplyableOutput)(nil)
 )

 func (n *NodeApplyableOutput) temporaryValue() bool {
 	// this must always be evaluated if it is a root module output
 	return !n.Addr.Module.IsRoot()
 }

 func (n *NodeApplyableOutput) Name() string {
 	return n.Addr.String()
 }

 // GraphNodeModuleInstance
 func (n *NodeApplyableOutput) Path() addrs.ModuleInstance {
 	return n.Addr.Module
 }

 // GraphNodeModulePath
 func (n *NodeApplyableOutput) ModulePath() addrs.Module {
 	return n.Addr.Module.Module()
 }

 func referenceOutsideForOutput(addr addrs.AbsOutputValue) (selfPath, referencePath addrs.Module) {
 	// Output values have their expressions resolved in the context of the
 	// module where they are defined.
 	referencePath = addr.Module.Module()

 	// ...but they are referenced in the context of their calling module.
 	selfPath = addr.Module.Parent().Module()

 	return // uses named return values
 }

 // GraphNodeReferenceOutside implementation
 func (n *NodeApplyableOutput) ReferenceOutside() (selfPath, referencePath addrs.Module) {
 	return referenceOutsideForOutput(n.Addr)
 }

 func referenceableAddrsForOutput(addr addrs.AbsOutputValue) []addrs.Referenceable {
 	// An output in the root module can't be referenced at all.
 	if addr.Module.IsRoot() {
 		return nil
 	}

 	// Otherwise, we can be referenced via a reference to our output name
 	// on the parent module's call, or via a reference to the entire call.
 	// e.g. module.foo.bar or just module.foo .
 	// Note that our ReferenceOutside method causes these addresses to be
 	// relative to the calling module, not the module where the output
 	// was declared.
 	_, outp := addr.ModuleCallOutput()
 	_, call := addr.Module.CallInstance()

 	return []addrs.Referenceable{outp, call}
 }

 // GraphNodeReferenceable
 func (n *NodeApplyableOutput) ReferenceableAddrs() []addrs.Referenceable {
 	return referenceableAddrsForOutput(n.Addr)
 }

 func referencesForOutput(c *configs.Output) []*addrs.Reference {
 	var refs []*addrs.Reference

 	impRefs, _ := lang.ReferencesInExpr(c.Expr)
 	expRefs, _ := lang.References(c.DependsOn)

 	refs = append(refs, impRefs...)
 	refs = append(refs, expRefs...)

 	for _, check := range c.Preconditions {
 		condRefs, _ := lang.ReferencesInExpr(check.Condition)
 		refs = append(refs, condRefs...)
 		errRefs, _ := lang.ReferencesInExpr(check.ErrorMessage)
 		refs = append(refs, errRefs...)
 	}

 	return refs
 }

 // GraphNodeReferencer
 func (n *NodeApplyableOutput) References() []*addrs.Reference {
 	return referencesForOutput(n.Config)
 }

 // GraphNodeExecutable
 func (n *NodeApplyableOutput) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
 	state := ctx.State()
 	if state == nil {
 		return
 	}

 	changes := ctx.Changes() // may be nil, if we're not working on a changeset

 	val := cty.UnknownVal(cty.DynamicPseudoType)
 	changeRecorded := n.Change != nil
 	// we we have a change recorded, we don't need to re-evaluate if the value
 	// was known
 	if changeRecorded {
 		change, err := n.Change.Decode()
 		diags = diags.Append(err)
 		if err == nil {
 			val = change.After
 		}
 	}

 	// Checks are not evaluated during a destroy. The checks may fail, may not
 	// be valid, or may not have been registered at all.
 	if !n.DestroyApply {
 		checkRuleSeverity := tfdiags.Error
 		if n.RefreshOnly {
 			checkRuleSeverity = tfdiags.Warning
 		}
 		checkDiags := evalCheckRules(
 			addrs.OutputPrecondition,
 			n.Config.Preconditions,
 			ctx, n.Addr, EvalDataForNoInstanceKey,
 			checkRuleSeverity,
 		)
 		diags = diags.Append(checkDiags)
 		if diags.HasErrors() {
 			return diags // failed preconditions prevent further evaluation
 		}
 	}

 	// If there was no change recorded, or the recorded change was not wholly
 	// known, then we need to re-evaluate the output
 	if !changeRecorded || !val.IsWhollyKnown() {
 		// This has to run before we have a state lock, since evaluation also
 		// reads the state
 		var evalDiags tfdiags.Diagnostics
 		val, evalDiags = ctx.EvaluateExpr(n.Config.Expr, cty.DynamicPseudoType, nil)
 		diags = diags.Append(evalDiags)

 		// We'll handle errors below, after we have loaded the module.
 		// Outputs don't have a separate mode for validation, so validate
 		// depends_on expressions here too
 		diags = diags.Append(validateDependsOn(ctx, n.Config.DependsOn))

 		// For root module outputs in particular, an output value must be
 		// statically declared as sensitive in order to dynamically return
 		// a sensitive result, to help avoid accidental exposure in the state
 		// of a sensitive value that the user doesn't want to include there.
 		if n.Addr.Module.IsRoot() {
 			if !n.Config.Sensitive && marks.Contains(val, marks.Sensitive) {
 				diags = diags.Append(&hcl.Diagnostic{
 					Severity: hcl.DiagError,
 					Summary:  "Output refers to sensitive values",
 					Detail: `To reduce the risk of accidentally exporting sensitive data that was intended to be only internal, Terraform requires that any root module output containing sensitive data be explicitly marked as sensitive, to confirm your intent.

 If you do intend to export this data, annotate the output value as sensitive by adding the following argument:
     sensitive = true`,
 					Subject: n.Config.DeclRange.Ptr(),
 				})
 			}
 		}
 	}

 	// handling the interpolation error
 	if diags.HasErrors() {
 		if flagWarnOutputErrors {
 			log.Printf("[ERROR] Output interpolation %q failed: %s", n.Addr, diags.Err())
 			// if we're continuing, make sure the output is included, and
 			// marked as unknown. If the evaluator was able to find a type
 			// for the value in spite of the error then we'll use it.
 			n.setValue(state, changes, cty.UnknownVal(val.Type()))

 			// Keep existing warnings, while converting errors to warnings.
 			// This is not meant to be the normal path, so there no need to
 			// make the errors pretty.
 			var warnings tfdiags.Diagnostics
 			for _, d := range diags {
 				switch d.Severity() {
 				case tfdiags.Warning:
 					warnings = warnings.Append(d)
 				case tfdiags.Error:
 					desc := d.Description()
 					warnings = warnings.Append(tfdiags.SimpleWarning(fmt.Sprintf("%s:%s", desc.Summary, desc.Detail)))
 				}
 			}

 			return warnings
 		}
 		return diags
 	}
 	n.setValue(state, changes, val)

 	// If we were able to evaluate a new value, we can update that in the
 	// refreshed state as well.
 	if state = ctx.RefreshState(); state != nil && val.IsWhollyKnown() {
 		// we only need to update the state, do not pass in the changes again
 		n.setValue(state, nil, val)
 	}

 	return diags
 }

 // dag.GraphNodeDotter impl.
 func (n *NodeApplyableOutput) DotNode(name string, opts *dag.DotOpts) *dag.DotNode {
 	return &dag.DotNode{
 		Name: name,
 		Attrs: map[string]string{
 			"label": n.Name(),
 			"shape": "note",
 		},
 	}
 }

 // NodeDestroyableOutput represents an output that is "destroyable":
 // its application will remove the output from the state.
 type NodeDestroyableOutput struct {
 	Addr     addrs.AbsOutputValue
 	Planning bool
 }

 var (
 	_ GraphNodeExecutable = (*NodeDestroyableOutput)(nil)
 	_ dag.GraphNodeDotter = (*NodeDestroyableOutput)(nil)
 )

 func (n *NodeDestroyableOutput) Name() string {
 	return fmt.Sprintf("%s (destroy)", n.Addr.String())
 }

 // GraphNodeModulePath
 func (n *NodeDestroyableOutput) ModulePath() addrs.Module {
 	return n.Addr.Module.Module()
 }

 func (n *NodeDestroyableOutput) temporaryValue() bool {
 	// this must always be evaluated if it is a root module output
 	return !n.Addr.Module.IsRoot()
 }

 // GraphNodeExecutable
 func (n *NodeDestroyableOutput) Execute(ctx EvalContext, op walkOperation) tfdiags.Diagnostics {
 	state := ctx.State()
 	if state == nil {
 		return nil
 	}

 	// if this is a root module, try to get a before value from the state for
 	// the diff
 	sensitiveBefore := false
 	before := cty.NullVal(cty.DynamicPseudoType)
 	mod := state.Module(n.Addr.Module)
 	if n.Addr.Module.IsRoot() && mod != nil {
 		if o, ok := mod.OutputValues[n.Addr.OutputValue.Name]; ok {
 			sensitiveBefore = o.Sensitive
 			before = o.Value
 		} else {
 			// If the output was not in state, a delete change would
 			// be meaningless, so exit early.
 			return nil

 		}
 	}

 	changes := ctx.Changes()
 	if changes != nil && n.Planning {
 		change := &plans.OutputChange{
 			Addr:      n.Addr,
 			Sensitive: sensitiveBefore,
 			Change: plans.Change{
 				Action: plans.Delete,
 				Before: before,
 				After:  cty.NullVal(cty.DynamicPseudoType),
 			},
 		}

 		cs, err := change.Encode()
 		if err != nil {
 			// Should never happen, since we just constructed this right above
 			panic(fmt.Sprintf("planned change for %s could not be encoded: %s", n.Addr, err))
 		}
 		log.Printf("[TRACE] NodeDestroyableOutput: Saving %s change for %s in changeset", change.Action, n.Addr)

 		changes.RemoveOutputChange(n.Addr) // remove any existing planned change, if present
 		changes.AppendOutputChange(cs)     // add the new planned change
 	}

 	state.RemoveOutputValue(n.Addr)
 	return nil
 }

 // dag.GraphNodeDotter impl.
 func (n *NodeDestroyableOutput) DotNode(name string, opts *dag.DotOpts) *dag.DotNode {
 	return &dag.DotNode{
 		Name: name,
 		Attrs: map[string]string{
 			"label": n.Name(),
 			"shape": "note",
 		},
 	}
 }

 func (n *NodeApplyableOutput) setValue(state *states.SyncState, changes *plans.ChangesSync, val cty.Value) {
 	if changes != nil && n.Planning {
 		// if this is a root module, try to get a before value from the state for
 		// the diff
 		sensitiveBefore := false
 		before := cty.NullVal(cty.DynamicPseudoType)

 		// is this output new to our state?
 		newOutput := true

 		mod := state.Module(n.Addr.Module)
 		if n.Addr.Module.IsRoot() && mod != nil {
 			for name, o := range mod.OutputValues {
 				if name == n.Addr.OutputValue.Name {
 					before = o.Value
 					sensitiveBefore = o.Sensitive
 					newOutput = false
 					break
 				}
 			}
 		}

 		// We will not show the value if either the before or after are marked
 		// as sensitive. We can show the value again once sensitivity is
 		// removed from both the config and the state.
 		sensitiveChange := sensitiveBefore || n.Config.Sensitive

 		// strip any marks here just to be sure we don't panic on the True comparison
 		unmarkedVal, _ := val.UnmarkDeep()

 		action := plans.Update
 		switch {
 		case val.IsNull() && before.IsNull():
 			// This is separate from the NoOp case below, since we can ignore
 			// sensitivity here when there are only null values.
 			action = plans.NoOp

 		case newOutput:
 			// This output was just added to the configuration
 			action = plans.Create

 		case val.IsWhollyKnown() &&
 			unmarkedVal.Equals(before).True() &&
 			n.Config.Sensitive == sensitiveBefore:
 			// Sensitivity must also match to be a NoOp.
 			// Theoretically marks may not match here, but sensitivity is the
 			// only one we can act on, and the state will have been loaded
 			// without any marks to consider.
 			action = plans.NoOp
 		}

 		change := &plans.OutputChange{
 			Addr:      n.Addr,
 			Sensitive: sensitiveChange,
 			Change: plans.Change{
 				Action: action,
 				Before: before,
 				After:  val,
 			},
 		}

 		cs, err := change.Encode()
 		if err != nil {
 			// Should never happen, since we just constructed this right above
 			panic(fmt.Sprintf("planned change for %s could not be encoded: %s", n.Addr, err))
 		}
 		log.Printf("[TRACE] setValue: Saving %s change for %s in changeset", change.Action, n.Addr)
 		changes.AppendOutputChange(cs) // add the new planned change
 	}

 	if changes != nil && !n.Planning {
 		// During apply there is no longer any change to track, so we must
 		// ensure the state is updated and not overridden by a change.
 		changes.RemoveOutputChange(n.Addr)
 	}

 	// Null outputs must be saved for modules so that they can still be
 	// evaluated. Null root outputs are removed entirely, which is always fine
 	// because they can't be referenced by anything else in the configuration.
 	if n.Addr.Module.IsRoot() && val.IsNull() {
 		log.Printf("[TRACE] setValue: Removing %s from state (it is now null)", n.Addr)
 		state.RemoveOutputValue(n.Addr)
 		return
 	}

 	log.Printf("[TRACE] setValue: Saving value for %s in state", n.Addr)

 	// non-root outputs need to keep sensitive marks for evaluation, but are
 	// not serialized.
 	if n.Addr.Module.IsRoot() {
 		val, _ = val.UnmarkDeep()
 		val = cty.UnknownAsNull(val)
 	}

 	state.SetOutputValue(n.Addr, val, n.Config.Sensitive)
 }
	// Copyright (c) HashiCorp, Inc.
	// SPDX-License-Identifier: MPL-2.0

	package terraform

	import (
	"fmt"
	"log"

	"github.com/hashicorp/hcl/v2"
	"github.com/zclconf/go-cty/cty"

	"github.com/hashicorp/terraform/internal/addrs"
	"github.com/hashicorp/terraform/internal/configs"
	"github.com/hashicorp/terraform/internal/dag"
	"github.com/hashicorp/terraform/internal/lang"
	"github.com/hashicorp/terraform/internal/lang/marks"
	"github.com/hashicorp/terraform/internal/plans"
	"github.com/hashicorp/terraform/internal/states"
	"github.com/hashicorp/terraform/internal/tfdiags"
	)

	// nodeExpandOutput is the placeholder for a non-root module output that has
	// not yet had its module path expanded.
	type nodeExpandOutput struct {
	Addr addrs.OutputValue
	Module addrs.Module
	Config *configs.Output
	Destroying bool
	RefreshOnly bool

	// Planning is set to true when this node is in a graph that was produced
	// by the plan graph builder, as opposed to the apply graph builder.
	// This quirk is just because we share the same node type between both
	// phases but in practice there are a few small differences in the actions
	// we need to take between plan and apply. See method DynamicExpand for
	// details.
	Planning bool
	}

	var (
	_ GraphNodeReferenceable = (*nodeExpandOutput)(nil)
	_ GraphNodeReferencer = (*nodeExpandOutput)(nil)
	_ GraphNodeReferenceOutside = (*nodeExpandOutput)(nil)
	_ GraphNodeDynamicExpandable = (*nodeExpandOutput)(nil)
	_ graphNodeTemporaryValue = (*nodeExpandOutput)(nil)
	_ graphNodeExpandsInstances = (*nodeExpandOutput)(nil)
	)

	func (n *nodeExpandOutput) expandsInstances() {}

	func (n *nodeExpandOutput) temporaryValue() bool {
	// non root outputs are temporary
	return !n.Module.IsRoot()
	}

	func (n nodeExpandOutput) DynamicExpand(ctx EvalContext) (Graph, error) {
	expander := ctx.InstanceExpander()
	changes := ctx.Changes()

	// If this is an output value that participates in custom condition checks
	// (i.e. it has preconditions or postconditions) then the check state
	// wants to know the addresses of the checkable objects so that it can
	// treat them as unknown status if we encounter an error before actually
	// visiting the checks.
	//
	// We must do this only during planning, because the apply phase will start
	// with all of the same checkable objects that were registered during the
	// planning phase. Consumers of our JSON plan and state formats expect
	// that the set of checkable objects will be consistent between the plan
	// and any state snapshots created during apply, and that only the statuses
	// of those objects will have changed.
	var checkableAddrs addrs.Set[addrs.Checkable]
	if n.Planning {
	if checkState := ctx.Checks(); checkState.ConfigHasChecks(n.Addr.InModule(n.Module)) {
	checkableAddrs = addrs.MakeSet[addrs.Checkable]()
	}
	}

	var g Graph
	for _, module := range expander.ExpandModule(n.Module) {
	absAddr := n.Addr.Absolute(module)
	if checkableAddrs != nil {
	checkableAddrs.Add(absAddr)
	}

	// Find any recorded change for this output
	var change *plans.OutputChangeSrc
	var outputChanges []*plans.OutputChangeSrc
	if module.IsRoot() {
	outputChanges = changes.GetRootOutputChanges()
	} else {
	parent, call := module.Call()
	outputChanges = changes.GetOutputChanges(parent, call)
	}
	for _, c := range outputChanges {
	if c.Addr.String() == absAddr.String() {
	change = c
	break
	}
	}

	var node dag.Vertex
	switch {
	case module.IsRoot() && n.Destroying:
	node = &NodeDestroyableOutput{
	Addr: absAddr,
	Planning: n.Planning,
	}

	default:
	node = &NodeApplyableOutput{
	Addr: absAddr,
	Config: n.Config,
	Change: change,
	RefreshOnly: n.RefreshOnly,
	DestroyApply: n.Destroying,
	Planning: n.Planning,
	}
	}

	log.Printf("[TRACE] Expanding output: adding %s as %T", absAddr.String(), node)
	g.Add(node)
	}
	addRootNodeToGraph(&g)

	if checkableAddrs != nil {
	checkState := ctx.Checks()
	checkState.ReportCheckableObjects(n.Addr.InModule(n.Module), checkableAddrs)
	}

	return &g, nil
	}

	func (n *nodeExpandOutput) Name() string {
	path := n.Module.String()
	addr := n.Addr.String() + " (expand)"
	if path != "" {
	return path + "." + addr
	}
	return addr
	}

	// GraphNodeModulePath
	func (n *nodeExpandOutput) ModulePath() addrs.Module {
	return n.Module
	}

	// GraphNodeReferenceable
	func (n *nodeExpandOutput) ReferenceableAddrs() []addrs.Referenceable {
	// An output in the root module can't be referenced at all.
	if n.Module.IsRoot() {
	return nil
	}

	// the output is referenced through the module call, and via the
	// module itself.
	_, call := n.Module.Call()
	callOutput := addrs.ModuleCallOutput{
	Call: call,
	Name: n.Addr.Name,
	}

	// Otherwise, we can reference the output via the
	// module call itself
	return []addrs.Referenceable{call, callOutput}
	}

	// GraphNodeReferenceOutside implementation
	func (n *nodeExpandOutput) ReferenceOutside() (selfPath, referencePath addrs.Module) {
	// Output values have their expressions resolved in the context of the
	// module where they are defined.
	referencePath = n.Module

	// ...but they are referenced in the context of their calling module.
	selfPath = referencePath.Parent()

	return // uses named return values
	}

	// GraphNodeReferencer
	func (n nodeExpandOutput) References() []addrs.Reference {
	// DestroyNodes do not reference anything.
	if n.Module.IsRoot() && n.Destroying {
	return nil
	}

	return referencesForOutput(n.Config)
	}

	// NodeApplyableOutput represents an output that is "applyable":
	// it is ready to be applied.
	type NodeApplyableOutput struct {
	Addr addrs.AbsOutputValue
	Config *configs.Output // Config is the output in the config
	// If this is being evaluated during apply, we may have a change recorded already
	Change *plans.OutputChangeSrc

	// Refresh-only mode means that any failing output preconditions are
	// reported as warnings rather than errors
	RefreshOnly bool

	// DestroyApply indicates that we are applying a destroy plan, and do not
	// need to account for conditional blocks.
	DestroyApply bool

	Planning bool
	}

	var (
	_ GraphNodeModuleInstance = (*NodeApplyableOutput)(nil)
	_ GraphNodeReferenceable = (*NodeApplyableOutput)(nil)
	_ GraphNodeReferencer = (*NodeApplyableOutput)(nil)
	_ GraphNodeReferenceOutside = (*NodeApplyableOutput)(nil)
	_ GraphNodeExecutable = (*NodeApplyableOutput)(nil)
	_ graphNodeTemporaryValue = (*NodeApplyableOutput)(nil)
	_ dag.GraphNodeDotter = (*NodeApplyableOutput)(nil)
	)

	func (n *NodeApplyableOutput) temporaryValue() bool {
	// this must always be evaluated if it is a root module output
	return !n.Addr.Module.IsRoot()
	}

	func (n *NodeApplyableOutput) Name() string {
	return n.Addr.String()
	}

	// GraphNodeModuleInstance
	func (n *NodeApplyableOutput) Path() addrs.ModuleInstance {
	return n.Addr.Module
	}

	// GraphNodeModulePath
	func (n *NodeApplyableOutput) ModulePath() addrs.Module {
	return n.Addr.Module.Module()
	}

	func referenceOutsideForOutput(addr addrs.AbsOutputValue) (selfPath, referencePath addrs.Module) {
	// Output values have their expressions resolved in the context of the
	// module where they are defined.
	referencePath = addr.Module.Module()

	// ...but they are referenced in the context of their calling module.
	selfPath = addr.Module.Parent().Module()

	return // uses named return values
	}

	// GraphNodeReferenceOutside implementation
	func (n *NodeApplyableOutput) ReferenceOutside() (selfPath, referencePath addrs.Module) {
	return referenceOutsideForOutput(n.Addr)
	}

	func referenceableAddrsForOutput(addr addrs.AbsOutputValue) []addrs.Referenceable {
	// An output in the root module can't be referenced at all.
	if addr.Module.IsRoot() {
	return nil
	}

	// Otherwise, we can be referenced via a reference to our output name
	// on the parent module's call, or via a reference to the entire call.
	// e.g. module.foo.bar or just module.foo .
	// Note that our ReferenceOutside method causes these addresses to be
	// relative to the calling module, not the module where the output
	// was declared.
	_, outp := addr.ModuleCallOutput()
	_, call := addr.Module.CallInstance()

	return []addrs.Referenceable{outp, call}
	}

	// GraphNodeReferenceable
	func (n *NodeApplyableOutput) ReferenceableAddrs() []addrs.Referenceable {
	return referenceableAddrsForOutput(n.Addr)
	}

	func referencesForOutput(c configs.Output) []addrs.Reference {
	var refs []*addrs.Reference

	impRefs, _ := lang.ReferencesInExpr(c.Expr)
	expRefs, _ := lang.References(c.DependsOn)

	refs = append(refs, impRefs...)
	refs = append(refs, expRefs...)

	for _, check := range c.Preconditions {
	condRefs, _ := lang.ReferencesInExpr(check.Condition)
	refs = append(refs, condRefs...)
	errRefs, _ := lang.ReferencesInExpr(check.ErrorMessage)
	refs = append(refs, errRefs...)
	}

	return refs
	}

	// GraphNodeReferencer
	func (n NodeApplyableOutput) References() []addrs.Reference {
	return referencesForOutput(n.Config)
	}

	// GraphNodeExecutable
	func (n *NodeApplyableOutput) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
	state := ctx.State()
	if state == nil {
	return
	}

	changes := ctx.Changes() // may be nil, if we're not working on a changeset

	val := cty.UnknownVal(cty.DynamicPseudoType)
	changeRecorded := n.Change != nil
	// we we have a change recorded, we don't need to re-evaluate if the value
	// was known
	if changeRecorded {
	change, err := n.Change.Decode()
	diags = diags.Append(err)
	if err == nil {
	val = change.After
	}
	}

	// Checks are not evaluated during a destroy. The checks may fail, may not
	// be valid, or may not have been registered at all.
	if !n.DestroyApply {
	checkRuleSeverity := tfdiags.Error
	if n.RefreshOnly {
	checkRuleSeverity = tfdiags.Warning
	}
	checkDiags := evalCheckRules(
	addrs.OutputPrecondition,
	n.Config.Preconditions,
	ctx, n.Addr, EvalDataForNoInstanceKey,
	checkRuleSeverity,
	)
	diags = diags.Append(checkDiags)
	if diags.HasErrors() {
	return diags // failed preconditions prevent further evaluation
	}
	}

	// If there was no change recorded, or the recorded change was not wholly
	// known, then we need to re-evaluate the output
	if !changeRecorded \|\| !val.IsWhollyKnown() {
	// This has to run before we have a state lock, since evaluation also
	// reads the state
	var evalDiags tfdiags.Diagnostics
	val, evalDiags = ctx.EvaluateExpr(n.Config.Expr, cty.DynamicPseudoType, nil)
	diags = diags.Append(evalDiags)

	// We'll handle errors below, after we have loaded the module.
	// Outputs don't have a separate mode for validation, so validate
	// depends_on expressions here too
	diags = diags.Append(validateDependsOn(ctx, n.Config.DependsOn))

	// For root module outputs in particular, an output value must be
	// statically declared as sensitive in order to dynamically return
	// a sensitive result, to help avoid accidental exposure in the state
	// of a sensitive value that the user doesn't want to include there.
	if n.Addr.Module.IsRoot() {
	if !n.Config.Sensitive && marks.Contains(val, marks.Sensitive) {
	diags = diags.Append(&hcl.Diagnostic{
	Severity: hcl.DiagError,
	Summary: "Output refers to sensitive values",
	Detail: `To reduce the risk of accidentally exporting sensitive data that was intended to be only internal, Terraform requires that any root module output containing sensitive data be explicitly marked as sensitive, to confirm your intent.

	If you do intend to export this data, annotate the output value as sensitive by adding the following argument:
	sensitive = true`,
	Subject: n.Config.DeclRange.Ptr(),
	})
	}
	}
	}

	// handling the interpolation error
	if diags.HasErrors() {
	if flagWarnOutputErrors {
	log.Printf("[ERROR] Output interpolation %q failed: %s", n.Addr, diags.Err())
	// if we're continuing, make sure the output is included, and
	// marked as unknown. If the evaluator was able to find a type
	// for the value in spite of the error then we'll use it.
	n.setValue(state, changes, cty.UnknownVal(val.Type()))

	// Keep existing warnings, while converting errors to warnings.
	// This is not meant to be the normal path, so there no need to
	// make the errors pretty.
	var warnings tfdiags.Diagnostics
	for _, d := range diags {
	switch d.Severity() {
	case tfdiags.Warning:
	warnings = warnings.Append(d)
	case tfdiags.Error:
	desc := d.Description()
	warnings = warnings.Append(tfdiags.SimpleWarning(fmt.Sprintf("%s:%s", desc.Summary, desc.Detail)))
	}
	}

	return warnings
	}
	return diags
	}
	n.setValue(state, changes, val)

	// If we were able to evaluate a new value, we can update that in the
	// refreshed state as well.
	if state = ctx.RefreshState(); state != nil && val.IsWhollyKnown() {
	// we only need to update the state, do not pass in the changes again
	n.setValue(state, nil, val)
	}

	return diags
	}

	// dag.GraphNodeDotter impl.
	func (n NodeApplyableOutput) DotNode(name string, opts dag.DotOpts) *dag.DotNode {
	return &dag.DotNode{
	Name: name,
	Attrs: map[string]string{
	"label": n.Name(),
	"shape": "note",
	},
	}
	}

	// NodeDestroyableOutput represents an output that is "destroyable":
	// its application will remove the output from the state.
	type NodeDestroyableOutput struct {
	Addr addrs.AbsOutputValue
	Planning bool
	}

	var (
	_ GraphNodeExecutable = (*NodeDestroyableOutput)(nil)
	_ dag.GraphNodeDotter = (*NodeDestroyableOutput)(nil)
	)

	func (n *NodeDestroyableOutput) Name() string {
	return fmt.Sprintf("%s (destroy)", n.Addr.String())
	}

	// GraphNodeModulePath
	func (n *NodeDestroyableOutput) ModulePath() addrs.Module {
	return n.Addr.Module.Module()
	}

	func (n *NodeDestroyableOutput) temporaryValue() bool {
	// this must always be evaluated if it is a root module output
	return !n.Addr.Module.IsRoot()
	}

	// GraphNodeExecutable
	func (n *NodeDestroyableOutput) Execute(ctx EvalContext, op walkOperation) tfdiags.Diagnostics {
	state := ctx.State()
	if state == nil {
	return nil
	}

	// if this is a root module, try to get a before value from the state for
	// the diff
	sensitiveBefore := false
	before := cty.NullVal(cty.DynamicPseudoType)
	mod := state.Module(n.Addr.Module)
	if n.Addr.Module.IsRoot() && mod != nil {
	if o, ok := mod.OutputValues[n.Addr.OutputValue.Name]; ok {
	sensitiveBefore = o.Sensitive
	before = o.Value
	} else {
	// If the output was not in state, a delete change would
	// be meaningless, so exit early.
	return nil

	}
	}

	changes := ctx.Changes()
	if changes != nil && n.Planning {
	change := &plans.OutputChange{
	Addr: n.Addr,
	Sensitive: sensitiveBefore,
	Change: plans.Change{
	Action: plans.Delete,
	Before: before,
	After: cty.NullVal(cty.DynamicPseudoType),
	},
	}

	cs, err := change.Encode()
	if err != nil {
	// Should never happen, since we just constructed this right above
	panic(fmt.Sprintf("planned change for %s could not be encoded: %s", n.Addr, err))
	}
	log.Printf("[TRACE] NodeDestroyableOutput: Saving %s change for %s in changeset", change.Action, n.Addr)

	changes.RemoveOutputChange(n.Addr) // remove any existing planned change, if present
	changes.AppendOutputChange(cs) // add the new planned change
	}

	state.RemoveOutputValue(n.Addr)
	return nil
	}

	// dag.GraphNodeDotter impl.
	func (n NodeDestroyableOutput) DotNode(name string, opts dag.DotOpts) *dag.DotNode {
	return &dag.DotNode{
	Name: name,
	Attrs: map[string]string{
	"label": n.Name(),
	"shape": "note",
	},
	}
	}

	func (n NodeApplyableOutput) setValue(state states.SyncState, changes *plans.ChangesSync, val cty.Value) {
	if changes != nil && n.Planning {
	// if this is a root module, try to get a before value from the state for
	// the diff
	sensitiveBefore := false
	before := cty.NullVal(cty.DynamicPseudoType)

	// is this output new to our state?
	newOutput := true

	mod := state.Module(n.Addr.Module)
	if n.Addr.Module.IsRoot() && mod != nil {
	for name, o := range mod.OutputValues {
	if name == n.Addr.OutputValue.Name {
	before = o.Value
	sensitiveBefore = o.Sensitive
	newOutput = false
	break
	}
	}
	}

	// We will not show the value if either the before or after are marked
	// as sensitive. We can show the value again once sensitivity is
	// removed from both the config and the state.
	sensitiveChange := sensitiveBefore \|\| n.Config.Sensitive

	// strip any marks here just to be sure we don't panic on the True comparison
	unmarkedVal, _ := val.UnmarkDeep()

	action := plans.Update
	switch {
	case val.IsNull() && before.IsNull():
	// This is separate from the NoOp case below, since we can ignore
	// sensitivity here when there are only null values.
	action = plans.NoOp

	case newOutput:
	// This output was just added to the configuration
	action = plans.Create

	case val.IsWhollyKnown() &&
	unmarkedVal.Equals(before).True() &&
	n.Config.Sensitive == sensitiveBefore:
	// Sensitivity must also match to be a NoOp.
	// Theoretically marks may not match here, but sensitivity is the
	// only one we can act on, and the state will have been loaded
	// without any marks to consider.
	action = plans.NoOp
	}

	change := &plans.OutputChange{
	Addr: n.Addr,
	Sensitive: sensitiveChange,
	Change: plans.Change{
	Action: action,
	Before: before,
	After: val,
	},
	}

	cs, err := change.Encode()
	if err != nil {
	// Should never happen, since we just constructed this right above
	panic(fmt.Sprintf("planned change for %s could not be encoded: %s", n.Addr, err))
	}
	log.Printf("[TRACE] setValue: Saving %s change for %s in changeset", change.Action, n.Addr)
	changes.AppendOutputChange(cs) // add the new planned change
	}

	if changes != nil && !n.Planning {
	// During apply there is no longer any change to track, so we must
	// ensure the state is updated and not overridden by a change.
	changes.RemoveOutputChange(n.Addr)
	}

	// Null outputs must be saved for modules so that they can still be
	// evaluated. Null root outputs are removed entirely, which is always fine
	// because they can't be referenced by anything else in the configuration.
	if n.Addr.Module.IsRoot() && val.IsNull() {
	log.Printf("[TRACE] setValue: Removing %s from state (it is now null)", n.Addr)
	state.RemoveOutputValue(n.Addr)
	return
	}

	log.Printf("[TRACE] setValue: Saving value for %s in state", n.Addr)

	// non-root outputs need to keep sensitive marks for evaluation, but are
	// not serialized.
	if n.Addr.Module.IsRoot() {
	val, _ = val.UnmarkDeep()
	val = cty.UnknownAsNull(val)
	}

	state.SetOutputValue(n.Addr, val, n.Config.Sensitive)
	}