v1.4.7/internal/terraform/node_resource_destroy_deposed.go - terraform - Git at Google

 package terraform

 import (
 	"fmt"
 	"log"

 	"github.com/hashicorp/terraform/internal/addrs"
 	"github.com/hashicorp/terraform/internal/dag"
 	"github.com/hashicorp/terraform/internal/instances"
 	"github.com/hashicorp/terraform/internal/plans"
 	"github.com/hashicorp/terraform/internal/states"
 	"github.com/hashicorp/terraform/internal/tfdiags"
 )

 // ConcreteResourceInstanceDeposedNodeFunc is a callback type used to convert
 // an abstract resource instance to a concrete one of some type that has
 // an associated deposed object key.
 type ConcreteResourceInstanceDeposedNodeFunc func(*NodeAbstractResourceInstance, states.DeposedKey) dag.Vertex

 type GraphNodeDeposedResourceInstanceObject interface {
 	DeposedInstanceObjectKey() states.DeposedKey
 }

 // NodePlanDeposedResourceInstanceObject represents deposed resource
 // instance objects during plan. These are distinct from the primary object
 // for each resource instance since the only valid operation to do with them
 // is to destroy them.
 //
 // This node type is also used during the refresh walk to ensure that the
 // record of a deposed object is up-to-date before we plan to destroy it.
 type NodePlanDeposedResourceInstanceObject struct {
 	*NodeAbstractResourceInstance
 	DeposedKey states.DeposedKey

 	// skipRefresh indicates that we should skip refreshing individual instances
 	skipRefresh bool

 	// skipPlanChanges indicates we should skip trying to plan change actions
 	// for any instances.
 	skipPlanChanges bool
 }

 var (
 	_ GraphNodeDeposedResourceInstanceObject = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeConfigResource                = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeResourceInstance              = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeReferenceable                 = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeReferencer                    = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeExecutable                    = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeProviderConsumer              = (*NodePlanDeposedResourceInstanceObject)(nil)
 	_ GraphNodeProvisionerConsumer           = (*NodePlanDeposedResourceInstanceObject)(nil)
 )

 func (n *NodePlanDeposedResourceInstanceObject) Name() string {
 	return fmt.Sprintf("%s (deposed %s)", n.ResourceInstanceAddr().String(), n.DeposedKey)
 }

 func (n *NodePlanDeposedResourceInstanceObject) DeposedInstanceObjectKey() states.DeposedKey {
 	return n.DeposedKey
 }

 // GraphNodeReferenceable implementation, overriding the one from NodeAbstractResourceInstance
 func (n *NodePlanDeposedResourceInstanceObject) ReferenceableAddrs() []addrs.Referenceable {
 	// Deposed objects don't participate in references.
 	return nil
 }

 // GraphNodeReferencer implementation, overriding the one from NodeAbstractResourceInstance
 func (n *NodePlanDeposedResourceInstanceObject) References() []*addrs.Reference {
 	// We don't evaluate configuration for deposed objects, so they effectively
 	// make no references.
 	return nil
 }

 // GraphNodeEvalable impl.
 func (n *NodePlanDeposedResourceInstanceObject) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
 	log.Printf("[TRACE] NodePlanDeposedResourceInstanceObject: planning %s deposed object %s", n.Addr, n.DeposedKey)

 	// Read the state for the deposed resource instance
 	state, err := n.readResourceInstanceStateDeposed(ctx, n.Addr, n.DeposedKey)
 	diags = diags.Append(err)
 	if diags.HasErrors() {
 		return diags
 	}

 	// Note any upgrades that readResourceInstanceState might've done in the
 	// prevRunState, so that it'll conform to current schema.
 	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, prevRunState))
 	if diags.HasErrors() {
 		return diags
 	}
 	// Also the refreshState, because that should still reflect schema upgrades
 	// even if not refreshing.
 	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, refreshState))
 	if diags.HasErrors() {
 		return diags
 	}

 	// We don't refresh during the planDestroy walk, since that is only adding
 	// the destroy changes to the plan and the provider will not be configured
 	// at this point. The other nodes use separate types for plan and destroy,
 	// while deposed instances are always a destroy operation, so the logic
 	// here is a bit overloaded.
 	if !n.skipRefresh && op != walkPlanDestroy {
 		// Refresh this object even though it is going to be destroyed, in
 		// case it's already been deleted outside of Terraform. If this is a
 		// normal plan, providers expect a Read request to remove missing
 		// resources from the plan before apply, and may not handle a missing
 		// resource during Delete correctly. If this is a simple refresh,
 		// Terraform is expected to remove the missing resource from the state
 		// entirely
 		refreshedState, refreshDiags := n.refresh(ctx, n.DeposedKey, state)
 		diags = diags.Append(refreshDiags)
 		if diags.HasErrors() {
 			return diags
 		}

 		diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, refreshedState, refreshState))
 		if diags.HasErrors() {
 			return diags
 		}

 		// If we refreshed then our subsequent planning should be in terms of
 		// the new object, not the original object.
 		state = refreshedState
 	}

 	if !n.skipPlanChanges {
 		var change *plans.ResourceInstanceChange
 		change, destroyPlanDiags := n.planDestroy(ctx, state, n.DeposedKey)
 		diags = diags.Append(destroyPlanDiags)
 		if diags.HasErrors() {
 			return diags
 		}

 		// NOTE: We don't check prevent_destroy for deposed objects, even
 		// though we would do so here for a "current" object, because
 		// if we've reached a point where an object is already deposed then
 		// we've already planned and partially-executed a create_before_destroy
 		// replace and we would've checked prevent_destroy at that point. We're
 		// now just need to get the deposed object destroyed, because there
 		// should be a new object already serving as its replacement.

 		diags = diags.Append(n.writeChange(ctx, change, n.DeposedKey))
 		if diags.HasErrors() {
 			return diags
 		}

 		diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, nil, workingState))
 	} else {
 		// The working state should at least be updated with the result
 		// of upgrading and refreshing from above.
 		diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, workingState))
 	}

 	return diags
 }

 // NodeDestroyDeposedResourceInstanceObject represents deposed resource
 // instance objects during apply. Nodes of this type are inserted by
 // DiffTransformer when the planned changeset contains "delete" changes for
 // deposed instance objects, and its only supported operation is to destroy
 // and then forget the associated object.
 type NodeDestroyDeposedResourceInstanceObject struct {
 	*NodeAbstractResourceInstance
 	DeposedKey states.DeposedKey
 }

 var (
 	_ GraphNodeDeposedResourceInstanceObject = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeConfigResource                = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeResourceInstance              = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeDestroyer                     = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeDestroyerCBD                  = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeReferenceable                 = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeReferencer                    = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeExecutable                    = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeProviderConsumer              = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 	_ GraphNodeProvisionerConsumer           = (*NodeDestroyDeposedResourceInstanceObject)(nil)
 )

 func (n *NodeDestroyDeposedResourceInstanceObject) Name() string {
 	return fmt.Sprintf("%s (destroy deposed %s)", n.ResourceInstanceAddr(), n.DeposedKey)
 }

 func (n *NodeDestroyDeposedResourceInstanceObject) DeposedInstanceObjectKey() states.DeposedKey {
 	return n.DeposedKey
 }

 // GraphNodeReferenceable implementation, overriding the one from NodeAbstractResourceInstance
 func (n *NodeDestroyDeposedResourceInstanceObject) ReferenceableAddrs() []addrs.Referenceable {
 	// Deposed objects don't participate in references.
 	return nil
 }

 // GraphNodeReferencer implementation, overriding the one from NodeAbstractResourceInstance
 func (n *NodeDestroyDeposedResourceInstanceObject) References() []*addrs.Reference {
 	// We don't evaluate configuration for deposed objects, so they effectively
 	// make no references.
 	return nil
 }

 // GraphNodeDestroyer
 func (n *NodeDestroyDeposedResourceInstanceObject) DestroyAddr() *addrs.AbsResourceInstance {
 	addr := n.ResourceInstanceAddr()
 	return &addr
 }

 // GraphNodeDestroyerCBD
 func (n *NodeDestroyDeposedResourceInstanceObject) CreateBeforeDestroy() bool {
 	// A deposed instance is always CreateBeforeDestroy by definition, since
 	// we use deposed only to handle create-before-destroy.
 	return true
 }

 // GraphNodeDestroyerCBD
 func (n *NodeDestroyDeposedResourceInstanceObject) ModifyCreateBeforeDestroy(v bool) error {
 	if !v {
 		// Should never happen: deposed instances are _always_ create_before_destroy.
 		return fmt.Errorf("can't deactivate create_before_destroy for a deposed instance")
 	}
 	return nil
 }

 // GraphNodeExecutable impl.
 func (n *NodeDestroyDeposedResourceInstanceObject) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
 	var change *plans.ResourceInstanceChange

 	// Read the state for the deposed resource instance
 	state, err := n.readResourceInstanceStateDeposed(ctx, n.Addr, n.DeposedKey)
 	if err != nil {
 		return diags.Append(err)
 	}

 	if state == nil {
 		diags = diags.Append(fmt.Errorf("missing deposed state for %s (%s)", n.Addr, n.DeposedKey))
 		return diags
 	}

 	change, destroyPlanDiags := n.planDestroy(ctx, state, n.DeposedKey)
 	diags = diags.Append(destroyPlanDiags)
 	if diags.HasErrors() {
 		return diags
 	}

 	// Call pre-apply hook
 	diags = diags.Append(n.preApplyHook(ctx, change))
 	if diags.HasErrors() {
 		return diags
 	}

 	// we pass a nil configuration to apply because we are destroying
 	state, applyDiags := n.apply(ctx, state, change, nil, instances.RepetitionData{}, false)
 	diags = diags.Append(applyDiags)
 	// don't return immediately on errors, we need to handle the state

 	// Always write the resource back to the state deposed. If it
 	// was successfully destroyed it will be pruned. If it was not, it will
 	// be caught on the next run.
 	writeDiags := n.writeResourceInstanceState(ctx, state)
 	diags.Append(writeDiags)
 	if diags.HasErrors() {
 		return diags
 	}

 	diags = diags.Append(n.postApplyHook(ctx, state, diags.Err()))

 	return diags.Append(updateStateHook(ctx))
 }

 // GraphNodeDeposer is an optional interface implemented by graph nodes that
 // might create a single new deposed object for a specific associated resource
 // instance, allowing a caller to optionally pre-allocate a DeposedKey for
 // it.
 type GraphNodeDeposer interface {
 	// SetPreallocatedDeposedKey will be called during graph construction
 	// if a particular node must use a pre-allocated deposed key if/when it
 	// "deposes" the current object of its associated resource instance.
 	SetPreallocatedDeposedKey(key states.DeposedKey)
 }

 // graphNodeDeposer is an embeddable implementation of GraphNodeDeposer.
 // Embed it in a node type to get automatic support for it, and then access
 // the field PreallocatedDeposedKey to access any pre-allocated key.
 type graphNodeDeposer struct {
 	PreallocatedDeposedKey states.DeposedKey
 }

 func (n *graphNodeDeposer) SetPreallocatedDeposedKey(key states.DeposedKey) {
 	n.PreallocatedDeposedKey = key
 }

 func (n *NodeDestroyDeposedResourceInstanceObject) writeResourceInstanceState(ctx EvalContext, obj *states.ResourceInstanceObject) error {
 	absAddr := n.Addr
 	key := n.DeposedKey
 	state := ctx.State()

 	if key == states.NotDeposed {
 		// should never happen
 		return fmt.Errorf("can't save deposed object for %s without a deposed key; this is a bug in Terraform that should be reported", absAddr)
 	}

 	if obj == nil {
 		// No need to encode anything: we'll just write it directly.
 		state.SetResourceInstanceDeposed(absAddr, key, nil, n.ResolvedProvider)
 		log.Printf("[TRACE] writeResourceInstanceStateDeposed: removing state object for %s deposed %s", absAddr, key)
 		return nil
 	}

 	_, providerSchema, err := getProvider(ctx, n.ResolvedProvider)
 	if err != nil {
 		return err
 	}
 	if providerSchema == nil {
 		// Should never happen, unless our state object is nil
 		panic("writeResourceInstanceStateDeposed used with no ProviderSchema object")
 	}

 	schema, currentVersion := providerSchema.SchemaForResourceAddr(absAddr.ContainingResource().Resource)
 	if schema == nil {
 		// It shouldn't be possible to get this far in any real scenario
 		// without a schema, but we might end up here in contrived tests that
 		// fail to set up their world properly.
 		return fmt.Errorf("failed to encode %s in state: no resource type schema available", absAddr)
 	}
 	src, err := obj.Encode(schema.ImpliedType(), currentVersion)
 	if err != nil {
 		return fmt.Errorf("failed to encode %s in state: %s", absAddr, err)
 	}

 	log.Printf("[TRACE] writeResourceInstanceStateDeposed: writing state object for %s deposed %s", absAddr, key)
 	state.SetResourceInstanceDeposed(absAddr, key, src, n.ResolvedProvider)
 	return nil
 }
	package terraform

	import (
	"fmt"
	"log"

	"github.com/hashicorp/terraform/internal/addrs"
	"github.com/hashicorp/terraform/internal/dag"
	"github.com/hashicorp/terraform/internal/instances"
	"github.com/hashicorp/terraform/internal/plans"
	"github.com/hashicorp/terraform/internal/states"
	"github.com/hashicorp/terraform/internal/tfdiags"
	)

	// ConcreteResourceInstanceDeposedNodeFunc is a callback type used to convert
	// an abstract resource instance to a concrete one of some type that has
	// an associated deposed object key.
	type ConcreteResourceInstanceDeposedNodeFunc func(*NodeAbstractResourceInstance, states.DeposedKey) dag.Vertex

	type GraphNodeDeposedResourceInstanceObject interface {
	DeposedInstanceObjectKey() states.DeposedKey
	}

	// NodePlanDeposedResourceInstanceObject represents deposed resource
	// instance objects during plan. These are distinct from the primary object
	// for each resource instance since the only valid operation to do with them
	// is to destroy them.
	//
	// This node type is also used during the refresh walk to ensure that the
	// record of a deposed object is up-to-date before we plan to destroy it.
	type NodePlanDeposedResourceInstanceObject struct {
	*NodeAbstractResourceInstance
	DeposedKey states.DeposedKey

	// skipRefresh indicates that we should skip refreshing individual instances
	skipRefresh bool

	// skipPlanChanges indicates we should skip trying to plan change actions
	// for any instances.
	skipPlanChanges bool
	}

	var (
	_ GraphNodeDeposedResourceInstanceObject = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeConfigResource = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeResourceInstance = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeReferenceable = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeReferencer = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeExecutable = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeProviderConsumer = (*NodePlanDeposedResourceInstanceObject)(nil)
	_ GraphNodeProvisionerConsumer = (*NodePlanDeposedResourceInstanceObject)(nil)
	)

	func (n *NodePlanDeposedResourceInstanceObject) Name() string {
	return fmt.Sprintf("%s (deposed %s)", n.ResourceInstanceAddr().String(), n.DeposedKey)
	}

	func (n *NodePlanDeposedResourceInstanceObject) DeposedInstanceObjectKey() states.DeposedKey {
	return n.DeposedKey
	}

	// GraphNodeReferenceable implementation, overriding the one from NodeAbstractResourceInstance
	func (n *NodePlanDeposedResourceInstanceObject) ReferenceableAddrs() []addrs.Referenceable {
	// Deposed objects don't participate in references.
	return nil
	}

	// GraphNodeReferencer implementation, overriding the one from NodeAbstractResourceInstance
	func (n NodePlanDeposedResourceInstanceObject) References() []addrs.Reference {
	// We don't evaluate configuration for deposed objects, so they effectively
	// make no references.
	return nil
	}

	// GraphNodeEvalable impl.
	func (n *NodePlanDeposedResourceInstanceObject) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
	log.Printf("[TRACE] NodePlanDeposedResourceInstanceObject: planning %s deposed object %s", n.Addr, n.DeposedKey)

	// Read the state for the deposed resource instance
	state, err := n.readResourceInstanceStateDeposed(ctx, n.Addr, n.DeposedKey)
	diags = diags.Append(err)
	if diags.HasErrors() {
	return diags
	}

	// Note any upgrades that readResourceInstanceState might've done in the
	// prevRunState, so that it'll conform to current schema.
	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, prevRunState))
	if diags.HasErrors() {
	return diags
	}
	// Also the refreshState, because that should still reflect schema upgrades
	// even if not refreshing.
	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, refreshState))
	if diags.HasErrors() {
	return diags
	}

	// We don't refresh during the planDestroy walk, since that is only adding
	// the destroy changes to the plan and the provider will not be configured
	// at this point. The other nodes use separate types for plan and destroy,
	// while deposed instances are always a destroy operation, so the logic
	// here is a bit overloaded.
	if !n.skipRefresh && op != walkPlanDestroy {
	// Refresh this object even though it is going to be destroyed, in
	// case it's already been deleted outside of Terraform. If this is a
	// normal plan, providers expect a Read request to remove missing
	// resources from the plan before apply, and may not handle a missing
	// resource during Delete correctly. If this is a simple refresh,
	// Terraform is expected to remove the missing resource from the state
	// entirely
	refreshedState, refreshDiags := n.refresh(ctx, n.DeposedKey, state)
	diags = diags.Append(refreshDiags)
	if diags.HasErrors() {
	return diags
	}

	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, refreshedState, refreshState))
	if diags.HasErrors() {
	return diags
	}

	// If we refreshed then our subsequent planning should be in terms of
	// the new object, not the original object.
	state = refreshedState
	}

	if !n.skipPlanChanges {
	var change *plans.ResourceInstanceChange
	change, destroyPlanDiags := n.planDestroy(ctx, state, n.DeposedKey)
	diags = diags.Append(destroyPlanDiags)
	if diags.HasErrors() {
	return diags
	}

	// NOTE: We don't check prevent_destroy for deposed objects, even
	// though we would do so here for a "current" object, because
	// if we've reached a point where an object is already deposed then
	// we've already planned and partially-executed a create_before_destroy
	// replace and we would've checked prevent_destroy at that point. We're
	// now just need to get the deposed object destroyed, because there
	// should be a new object already serving as its replacement.

	diags = diags.Append(n.writeChange(ctx, change, n.DeposedKey))
	if diags.HasErrors() {
	return diags
	}

	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, nil, workingState))
	} else {
	// The working state should at least be updated with the result
	// of upgrading and refreshing from above.
	diags = diags.Append(n.writeResourceInstanceStateDeposed(ctx, n.DeposedKey, state, workingState))
	}

	return diags
	}

	// NodeDestroyDeposedResourceInstanceObject represents deposed resource
	// instance objects during apply. Nodes of this type are inserted by
	// DiffTransformer when the planned changeset contains "delete" changes for
	// deposed instance objects, and its only supported operation is to destroy
	// and then forget the associated object.
	type NodeDestroyDeposedResourceInstanceObject struct {
	*NodeAbstractResourceInstance
	DeposedKey states.DeposedKey
	}

	var (
	_ GraphNodeDeposedResourceInstanceObject = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeConfigResource = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeResourceInstance = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeDestroyer = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeDestroyerCBD = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeReferenceable = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeReferencer = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeExecutable = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeProviderConsumer = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	_ GraphNodeProvisionerConsumer = (*NodeDestroyDeposedResourceInstanceObject)(nil)
	)

	func (n *NodeDestroyDeposedResourceInstanceObject) Name() string {
	return fmt.Sprintf("%s (destroy deposed %s)", n.ResourceInstanceAddr(), n.DeposedKey)
	}

	func (n *NodeDestroyDeposedResourceInstanceObject) DeposedInstanceObjectKey() states.DeposedKey {
	return n.DeposedKey
	}

	// GraphNodeReferenceable implementation, overriding the one from NodeAbstractResourceInstance
	func (n *NodeDestroyDeposedResourceInstanceObject) ReferenceableAddrs() []addrs.Referenceable {
	// Deposed objects don't participate in references.
	return nil
	}

	// GraphNodeReferencer implementation, overriding the one from NodeAbstractResourceInstance
	func (n NodeDestroyDeposedResourceInstanceObject) References() []addrs.Reference {
	// We don't evaluate configuration for deposed objects, so they effectively
	// make no references.
	return nil
	}

	// GraphNodeDestroyer
	func (n NodeDestroyDeposedResourceInstanceObject) DestroyAddr() addrs.AbsResourceInstance {
	addr := n.ResourceInstanceAddr()
	return &addr
	}

	// GraphNodeDestroyerCBD
	func (n *NodeDestroyDeposedResourceInstanceObject) CreateBeforeDestroy() bool {
	// A deposed instance is always CreateBeforeDestroy by definition, since
	// we use deposed only to handle create-before-destroy.
	return true
	}

	// GraphNodeDestroyerCBD
	func (n *NodeDestroyDeposedResourceInstanceObject) ModifyCreateBeforeDestroy(v bool) error {
	if !v {
	// Should never happen: deposed instances are _always_ create_before_destroy.
	return fmt.Errorf("can't deactivate create_before_destroy for a deposed instance")
	}
	return nil
	}

	// GraphNodeExecutable impl.
	func (n *NodeDestroyDeposedResourceInstanceObject) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
	var change *plans.ResourceInstanceChange

	// Read the state for the deposed resource instance
	state, err := n.readResourceInstanceStateDeposed(ctx, n.Addr, n.DeposedKey)
	if err != nil {
	return diags.Append(err)
	}

	if state == nil {
	diags = diags.Append(fmt.Errorf("missing deposed state for %s (%s)", n.Addr, n.DeposedKey))
	return diags
	}

	change, destroyPlanDiags := n.planDestroy(ctx, state, n.DeposedKey)
	diags = diags.Append(destroyPlanDiags)
	if diags.HasErrors() {
	return diags
	}

	// Call pre-apply hook
	diags = diags.Append(n.preApplyHook(ctx, change))
	if diags.HasErrors() {
	return diags
	}

	// we pass a nil configuration to apply because we are destroying
	state, applyDiags := n.apply(ctx, state, change, nil, instances.RepetitionData{}, false)
	diags = diags.Append(applyDiags)
	// don't return immediately on errors, we need to handle the state

	// Always write the resource back to the state deposed. If it
	// was successfully destroyed it will be pruned. If it was not, it will
	// be caught on the next run.
	writeDiags := n.writeResourceInstanceState(ctx, state)
	diags.Append(writeDiags)
	if diags.HasErrors() {
	return diags
	}

	diags = diags.Append(n.postApplyHook(ctx, state, diags.Err()))

	return diags.Append(updateStateHook(ctx))
	}

	// GraphNodeDeposer is an optional interface implemented by graph nodes that
	// might create a single new deposed object for a specific associated resource
	// instance, allowing a caller to optionally pre-allocate a DeposedKey for
	// it.
	type GraphNodeDeposer interface {
	// SetPreallocatedDeposedKey will be called during graph construction
	// if a particular node must use a pre-allocated deposed key if/when it
	// "deposes" the current object of its associated resource instance.
	SetPreallocatedDeposedKey(key states.DeposedKey)
	}

	// graphNodeDeposer is an embeddable implementation of GraphNodeDeposer.
	// Embed it in a node type to get automatic support for it, and then access
	// the field PreallocatedDeposedKey to access any pre-allocated key.
	type graphNodeDeposer struct {
	PreallocatedDeposedKey states.DeposedKey
	}

	func (n *graphNodeDeposer) SetPreallocatedDeposedKey(key states.DeposedKey) {
	n.PreallocatedDeposedKey = key
	}

	func (n NodeDestroyDeposedResourceInstanceObject) writeResourceInstanceState(ctx EvalContext, obj states.ResourceInstanceObject) error {
	absAddr := n.Addr
	key := n.DeposedKey
	state := ctx.State()

	if key == states.NotDeposed {
	// should never happen
	return fmt.Errorf("can't save deposed object for %s without a deposed key; this is a bug in Terraform that should be reported", absAddr)
	}

	if obj == nil {
	// No need to encode anything: we'll just write it directly.
	state.SetResourceInstanceDeposed(absAddr, key, nil, n.ResolvedProvider)
	log.Printf("[TRACE] writeResourceInstanceStateDeposed: removing state object for %s deposed %s", absAddr, key)
	return nil
	}

	_, providerSchema, err := getProvider(ctx, n.ResolvedProvider)
	if err != nil {
	return err
	}
	if providerSchema == nil {
	// Should never happen, unless our state object is nil
	panic("writeResourceInstanceStateDeposed used with no ProviderSchema object")
	}

	schema, currentVersion := providerSchema.SchemaForResourceAddr(absAddr.ContainingResource().Resource)
	if schema == nil {
	// It shouldn't be possible to get this far in any real scenario
	// without a schema, but we might end up here in contrived tests that
	// fail to set up their world properly.
	return fmt.Errorf("failed to encode %s in state: no resource type schema available", absAddr)
	}
	src, err := obj.Encode(schema.ImpliedType(), currentVersion)
	if err != nil {
	return fmt.Errorf("failed to encode %s in state: %s", absAddr, err)
	}

	log.Printf("[TRACE] writeResourceInstanceStateDeposed: writing state object for %s deposed %s", absAddr, key)
	state.SetResourceInstanceDeposed(absAddr, key, src, n.ResolvedProvider)
	return nil
	}