v1.2.3/internal/states/sync.go - terraform - Git at Google

 package states

 import (
 	"log"
 	"sync"

 	"github.com/hashicorp/terraform/internal/addrs"
 	"github.com/zclconf/go-cty/cty"
 )

 // SyncState is a wrapper around State that provides concurrency-safe access to
 // various common operations that occur during a Terraform graph walk, or other
 // similar concurrent contexts.
 //
 // When a SyncState wrapper is in use, no concurrent direct access to the
 // underlying objects is permitted unless the caller first acquires an explicit
 // lock, using the Lock and Unlock methods. Most callers should _not_
 // explicitly lock, and should instead use the other methods of this type that
 // handle locking automatically.
 //
 // Since SyncState is able to safely consolidate multiple updates into a single
 // atomic operation, many of its methods are at a higher level than those
 // of the underlying types, and operate on the state as a whole rather than
 // on individual sub-structures of the state.
 //
 // SyncState can only protect against races within its own methods. It cannot
 // provide any guarantees about the order in which concurrent operations will
 // be processed, so callers may still need to employ higher-level techniques
 // for ensuring correct operation sequencing, such as building and walking
 // a dependency graph.
 type SyncState struct {
 	state *State
 	lock  sync.RWMutex
 }

 // Module returns a snapshot of the state of the module instance with the given
 // address, or nil if no such module is tracked.
 //
 // The return value is a pointer to a copy of the module state, which the
 // caller may then freely access and mutate. However, since the module state
 // tends to be a large data structure with many child objects, where possible
 // callers should prefer to use a more granular accessor to access a child
 // module directly, and thus reduce the amount of copying required.
 func (s *SyncState) Module(addr addrs.ModuleInstance) *Module {
 	s.lock.RLock()
 	ret := s.state.Module(addr).DeepCopy()
 	s.lock.RUnlock()
 	return ret
 }

 // ModuleOutputs returns the set of OutputValues that matches the given path.
 func (s *SyncState) ModuleOutputs(parentAddr addrs.ModuleInstance, module addrs.ModuleCall) []*OutputValue {
 	s.lock.RLock()
 	defer s.lock.RUnlock()
 	var os []*OutputValue

 	for _, o := range s.state.ModuleOutputs(parentAddr, module) {
 		os = append(os, o.DeepCopy())
 	}
 	return os
 }

 // RemoveModule removes the entire state for the given module, taking with
 // it any resources associated with the module. This should generally be
 // called only for modules whose resources have all been destroyed, but
 // that is not enforced by this method.
 func (s *SyncState) RemoveModule(addr addrs.ModuleInstance) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	s.state.RemoveModule(addr)
 }

 // OutputValue returns a snapshot of the state of the output value with the
 // given address, or nil if no such output value is tracked.
 //
 // The return value is a pointer to a copy of the output value state, which the
 // caller may then freely access and mutate.
 func (s *SyncState) OutputValue(addr addrs.AbsOutputValue) *OutputValue {
 	s.lock.RLock()
 	ret := s.state.OutputValue(addr).DeepCopy()
 	s.lock.RUnlock()
 	return ret
 }

 // SetOutputValue writes a given output value into the state, overwriting
 // any existing value of the same name.
 //
 // If the module containing the output is not yet tracked in state then it
 // be added as a side-effect.
 func (s *SyncState) SetOutputValue(addr addrs.AbsOutputValue, value cty.Value, sensitive bool) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.SetOutputValue(addr.OutputValue.Name, value, sensitive)
 }

 // RemoveOutputValue removes the stored value for the output value with the
 // given address.
 //
 // If this results in its containing module being empty, the module will be
 // pruned from the state as a side-effect.
 func (s *SyncState) RemoveOutputValue(addr addrs.AbsOutputValue) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return
 	}
 	ms.RemoveOutputValue(addr.OutputValue.Name)
 	s.maybePruneModule(addr.Module)
 }

 // LocalValue returns the current value associated with the given local value
 // address.
 func (s *SyncState) LocalValue(addr addrs.AbsLocalValue) cty.Value {
 	s.lock.RLock()
 	// cty.Value is immutable, so we don't need any extra copying here.
 	ret := s.state.LocalValue(addr)
 	s.lock.RUnlock()
 	return ret
 }

 // SetLocalValue writes a given output value into the state, overwriting
 // any existing value of the same name.
 //
 // If the module containing the local value is not yet tracked in state then it
 // will be added as a side-effect.
 func (s *SyncState) SetLocalValue(addr addrs.AbsLocalValue, value cty.Value) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.SetLocalValue(addr.LocalValue.Name, value)
 }

 // RemoveLocalValue removes the stored value for the local value with the
 // given address.
 //
 // If this results in its containing module being empty, the module will be
 // pruned from the state as a side-effect.
 func (s *SyncState) RemoveLocalValue(addr addrs.AbsLocalValue) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return
 	}
 	ms.RemoveLocalValue(addr.LocalValue.Name)
 	s.maybePruneModule(addr.Module)
 }

 // Resource returns a snapshot of the state of the resource with the given
 // address, or nil if no such resource is tracked.
 //
 // The return value is a pointer to a copy of the resource state, which the
 // caller may then freely access and mutate.
 func (s *SyncState) Resource(addr addrs.AbsResource) *Resource {
 	s.lock.RLock()
 	ret := s.state.Resource(addr).DeepCopy()
 	s.lock.RUnlock()
 	return ret
 }

 // ResourceInstance returns a snapshot of the state the resource instance with
 // the given address, or nil if no such instance is tracked.
 //
 // The return value is a pointer to a copy of the instance state, which the
 // caller may then freely access and mutate.
 func (s *SyncState) ResourceInstance(addr addrs.AbsResourceInstance) *ResourceInstance {
 	s.lock.RLock()
 	ret := s.state.ResourceInstance(addr).DeepCopy()
 	s.lock.RUnlock()
 	return ret
 }

 // ResourceInstanceObject returns a snapshot of the current instance object
 // of the given generation belonging to the instance with the given address,
 // or nil if no such object is tracked..
 //
 // The return value is a pointer to a copy of the object, which the caller may
 // then freely access and mutate.
 func (s *SyncState) ResourceInstanceObject(addr addrs.AbsResourceInstance, gen Generation) *ResourceInstanceObjectSrc {
 	s.lock.RLock()
 	defer s.lock.RUnlock()

 	inst := s.state.ResourceInstance(addr)
 	if inst == nil {
 		return nil
 	}
 	return inst.GetGeneration(gen).DeepCopy()
 }

 // SetResourceMeta updates the resource-level metadata for the resource at
 // the given address, creating the containing module state and resource state
 // as a side-effect if not already present.
 func (s *SyncState) SetResourceProvider(addr addrs.AbsResource, provider addrs.AbsProviderConfig) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.SetResourceProvider(addr.Resource, provider)
 }

 // RemoveResource removes the entire state for the given resource, taking with
 // it any instances associated with the resource. This should generally be
 // called only for resource objects whose instances have all been destroyed,
 // but that is not enforced by this method. (Use RemoveResourceIfEmpty instead
 // to safely check first.)
 func (s *SyncState) RemoveResource(addr addrs.AbsResource) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.RemoveResource(addr.Resource)
 	s.maybePruneModule(addr.Module)
 }

 // RemoveResourceIfEmpty is similar to RemoveResource but first checks to
 // make sure there are no instances or objects left in the resource.
 //
 // Returns true if the resource was removed, or false if remaining child
 // objects prevented its removal. Returns true also if the resource was
 // already absent, and thus no action needed to be taken.
 func (s *SyncState) RemoveResourceIfEmpty(addr addrs.AbsResource) bool {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return true // nothing to do
 	}
 	rs := ms.Resource(addr.Resource)
 	if rs == nil {
 		return true // nothing to do
 	}
 	if len(rs.Instances) != 0 {
 		// We don't check here for the possibility of instances that exist
 		// but don't have any objects because it's the responsibility of the
 		// instance-mutation methods to prune those away automatically.
 		return false
 	}
 	ms.RemoveResource(addr.Resource)
 	s.maybePruneModule(addr.Module)
 	return true
 }

 // SetResourceInstanceCurrent saves the given instance object as the current
 // generation of the resource instance with the given address, simultaneously
 // updating the recorded provider configuration address, dependencies, and
 // resource EachMode.
 //
 // Any existing current instance object for the given resource is overwritten.
 // Set obj to nil to remove the primary generation object altogether. If there
 // are no deposed objects then the instance as a whole will be removed, which
 // may in turn also remove the containing module if it becomes empty.
 //
 // The caller must ensure that the given ResourceInstanceObject is not
 // concurrently mutated during this call, but may be freely used again once
 // this function returns.
 //
 // The provider address is a resource-wide settings and is updated
 // for all other instances of the same resource as a side-effect of this call.
 //
 // If the containing module for this resource or the resource itself are not
 // already tracked in state then they will be added as a side-effect.
 func (s *SyncState) SetResourceInstanceCurrent(addr addrs.AbsResourceInstance, obj *ResourceInstanceObjectSrc, provider addrs.AbsProviderConfig) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.SetResourceInstanceCurrent(addr.Resource, obj.DeepCopy(), provider)
 	s.maybePruneModule(addr.Module)
 }

 // SetResourceInstanceDeposed saves the given instance object as a deposed
 // generation of the resource instance with the given address and deposed key.
 //
 // Call this method only for pre-existing deposed objects that already have
 // a known DeposedKey. For example, this method is useful if reloading objects
 // that were persisted to a state file. To mark the current object as deposed,
 // use DeposeResourceInstanceObject instead.
 //
 // The caller must ensure that the given ResourceInstanceObject is not
 // concurrently mutated during this call, but may be freely used again once
 // this function returns.
 //
 // The resource that contains the given instance must already exist in the
 // state, or this method will panic. Use Resource to check first if its
 // presence is not already guaranteed.
 //
 // Any existing current instance object for the given resource and deposed key
 // is overwritten. Set obj to nil to remove the deposed object altogether. If
 // the instance is left with no objects after this operation then it will
 // be removed from its containing resource altogether.
 //
 // If the containing module for this resource or the resource itself are not
 // already tracked in state then they will be added as a side-effect.
 func (s *SyncState) SetResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey, obj *ResourceInstanceObjectSrc, provider addrs.AbsProviderConfig) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.EnsureModule(addr.Module)
 	ms.SetResourceInstanceDeposed(addr.Resource, key, obj.DeepCopy(), provider)
 	s.maybePruneModule(addr.Module)
 }

 // DeposeResourceInstanceObject moves the current instance object for the
 // given resource instance address into the deposed set, leaving the instance
 // without a current object.
 //
 // The return value is the newly-allocated deposed key, or NotDeposed if the
 // given instance is already lacking a current object.
 //
 // If the containing module for this resource or the resource itself are not
 // already tracked in state then there cannot be a current object for the
 // given instance, and so NotDeposed will be returned without modifying the
 // state at all.
 func (s *SyncState) DeposeResourceInstanceObject(addr addrs.AbsResourceInstance) DeposedKey {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return NotDeposed
 	}

 	return ms.deposeResourceInstanceObject(addr.Resource, NotDeposed)
 }

 // DeposeResourceInstanceObjectForceKey is like DeposeResourceInstanceObject
 // but uses a pre-allocated key. It's the caller's responsibility to ensure
 // that there aren't any races to use a particular key; this method will panic
 // if the given key is already in use.
 func (s *SyncState) DeposeResourceInstanceObjectForceKey(addr addrs.AbsResourceInstance, forcedKey DeposedKey) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	if forcedKey == NotDeposed {
 		// Usage error: should use DeposeResourceInstanceObject in this case
 		panic("DeposeResourceInstanceObjectForceKey called without forced key")
 	}

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return // Nothing to do, since there can't be any current object either.
 	}

 	ms.deposeResourceInstanceObject(addr.Resource, forcedKey)
 }

 // ForgetResourceInstanceAll removes the record of all objects associated with
 // the specified resource instance, if present. If not present, this is a no-op.
 func (s *SyncState) ForgetResourceInstanceAll(addr addrs.AbsResourceInstance) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return
 	}
 	ms.ForgetResourceInstanceAll(addr.Resource)
 	s.maybePruneModule(addr.Module)
 }

 // ForgetResourceInstanceDeposed removes the record of the deposed object with
 // the given address and key, if present. If not present, this is a no-op.
 func (s *SyncState) ForgetResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		return
 	}
 	ms.ForgetResourceInstanceDeposed(addr.Resource, key)
 	s.maybePruneModule(addr.Module)
 }

 // MaybeRestoreResourceInstanceDeposed will restore the deposed object with the
 // given key on the specified resource as the current object for that instance
 // if and only if that would not cause us to forget an existing current
 // object for that instance.
 //
 // Returns true if the object was restored to current, or false if no change
 // was made at all.
 func (s *SyncState) MaybeRestoreResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey) bool {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	if key == NotDeposed {
 		panic("MaybeRestoreResourceInstanceDeposed called without DeposedKey")
 	}

 	ms := s.state.Module(addr.Module)
 	if ms == nil {
 		// Nothing to do, since the specified deposed object cannot exist.
 		return false
 	}

 	return ms.maybeRestoreResourceInstanceDeposed(addr.Resource, key)
 }

 // RemovePlannedResourceInstanceObjects removes from the state any resource
 // instance objects that have the status ObjectPlanned, indiciating that they
 // are just transient placeholders created during planning.
 //
 // Note that this does not restore any "ready" or "tainted" object that might
 // have been present before the planned object was written. The only real use
 // for this method is in preparing the state created during a refresh walk,
 // where we run the planning step for certain instances just to create enough
 // information to allow correct expression evaluation within provider and
 // data resource blocks. Discarding planned instances in that case is okay
 // because the refresh phase only creates planned objects to stand in for
 // objects that don't exist yet, and thus the planned object must have been
 // absent before by definition.
 func (s *SyncState) RemovePlannedResourceInstanceObjects() {
 	// TODO: Merge together the refresh and plan phases into a single walk,
 	// so we can remove the need to create this "partial plan" during refresh
 	// that we then need to clean up before proceeding.

 	s.lock.Lock()
 	defer s.lock.Unlock()

 	for _, ms := range s.state.Modules {
 		moduleAddr := ms.Addr

 		for _, rs := range ms.Resources {
 			resAddr := rs.Addr.Resource

 			for ik, is := range rs.Instances {
 				instAddr := resAddr.Instance(ik)

 				if is.Current != nil && is.Current.Status == ObjectPlanned {
 					// Setting the current instance to nil removes it from the
 					// state altogether if there are not also deposed instances.
 					ms.SetResourceInstanceCurrent(instAddr, nil, rs.ProviderConfig)
 				}

 				for dk, obj := range is.Deposed {
 					// Deposed objects should never be "planned", but we'll
 					// do this anyway for the sake of completeness.
 					if obj.Status == ObjectPlanned {
 						ms.ForgetResourceInstanceDeposed(instAddr, dk)
 					}
 				}
 			}
 		}

 		// We may have deleted some objects, which means that we may have
 		// left a module empty, and so we must prune to preserve the invariant
 		// that only the root module is allowed to be empty.
 		s.maybePruneModule(moduleAddr)
 	}
 }

 // Lock acquires an explicit lock on the state, allowing direct read and write
 // access to the returned state object. The caller must call Unlock once
 // access is no longer needed, and then immediately discard the state pointer
 // pointer.
 //
 // Most callers should not use this. Instead, use the concurrency-safe
 // accessors and mutators provided directly on SyncState.
 func (s *SyncState) Lock() *State {
 	s.lock.Lock()
 	return s.state
 }

 // Unlock releases a lock previously acquired by Lock, at which point the
 // caller must cease all use of the state pointer that was returned.
 //
 // Do not call this method except to end an explicit lock acquired by
 // Lock. If a caller calls Unlock without first holding the lock, behavior
 // is undefined.
 func (s *SyncState) Unlock() {
 	s.lock.Unlock()
 }

 // Close extracts the underlying state from inside this wrapper, making the
 // wrapper invalid for any future operations.
 func (s *SyncState) Close() *State {
 	s.lock.Lock()
 	ret := s.state
 	s.state = nil // make sure future operations can't still modify it
 	s.lock.Unlock()
 	return ret
 }

 // maybePruneModule will remove a module from the state altogether if it is
 // empty, unless it's the root module which must always be present.
 //
 // This helper method is not concurrency-safe on its own, so must only be
 // called while the caller is already holding the lock for writing.
 func (s *SyncState) maybePruneModule(addr addrs.ModuleInstance) {
 	if addr.IsRoot() {
 		// We never prune the root.
 		return
 	}

 	ms := s.state.Module(addr)
 	if ms == nil {
 		return
 	}

 	if ms.empty() {
 		log.Printf("[TRACE] states.SyncState: pruning %s because it is empty", addr)
 		s.state.RemoveModule(addr)
 	}
 }

 func (s *SyncState) MoveAbsResource(src, dst addrs.AbsResource) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	s.state.MoveAbsResource(src, dst)
 }

 func (s *SyncState) MaybeMoveAbsResource(src, dst addrs.AbsResource) bool {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	return s.state.MaybeMoveAbsResource(src, dst)
 }

 func (s *SyncState) MoveResourceInstance(src, dst addrs.AbsResourceInstance) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	s.state.MoveAbsResourceInstance(src, dst)
 }

 func (s *SyncState) MaybeMoveResourceInstance(src, dst addrs.AbsResourceInstance) bool {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	return s.state.MaybeMoveAbsResourceInstance(src, dst)
 }

 func (s *SyncState) MoveModuleInstance(src, dst addrs.ModuleInstance) {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	s.state.MoveModuleInstance(src, dst)
 }

 func (s *SyncState) MaybeMoveModuleInstance(src, dst addrs.ModuleInstance) bool {
 	s.lock.Lock()
 	defer s.lock.Unlock()

 	return s.state.MaybeMoveModuleInstance(src, dst)
 }
	package states

	import (
	"log"
	"sync"

	"github.com/hashicorp/terraform/internal/addrs"
	"github.com/zclconf/go-cty/cty"
	)

	// SyncState is a wrapper around State that provides concurrency-safe access to
	// various common operations that occur during a Terraform graph walk, or other
	// similar concurrent contexts.
	//
	// When a SyncState wrapper is in use, no concurrent direct access to the
	// underlying objects is permitted unless the caller first acquires an explicit
	// lock, using the Lock and Unlock methods. Most callers should _not_
	// explicitly lock, and should instead use the other methods of this type that
	// handle locking automatically.
	//
	// Since SyncState is able to safely consolidate multiple updates into a single
	// atomic operation, many of its methods are at a higher level than those
	// of the underlying types, and operate on the state as a whole rather than
	// on individual sub-structures of the state.
	//
	// SyncState can only protect against races within its own methods. It cannot
	// provide any guarantees about the order in which concurrent operations will
	// be processed, so callers may still need to employ higher-level techniques
	// for ensuring correct operation sequencing, such as building and walking
	// a dependency graph.
	type SyncState struct {
	state *State
	lock sync.RWMutex
	}

	// Module returns a snapshot of the state of the module instance with the given
	// address, or nil if no such module is tracked.
	//
	// The return value is a pointer to a copy of the module state, which the
	// caller may then freely access and mutate. However, since the module state
	// tends to be a large data structure with many child objects, where possible
	// callers should prefer to use a more granular accessor to access a child
	// module directly, and thus reduce the amount of copying required.
	func (s SyncState) Module(addr addrs.ModuleInstance) Module {
	s.lock.RLock()
	ret := s.state.Module(addr).DeepCopy()
	s.lock.RUnlock()
	return ret
	}

	// ModuleOutputs returns the set of OutputValues that matches the given path.
	func (s SyncState) ModuleOutputs(parentAddr addrs.ModuleInstance, module addrs.ModuleCall) []OutputValue {
	s.lock.RLock()
	defer s.lock.RUnlock()
	var os []*OutputValue

	for _, o := range s.state.ModuleOutputs(parentAddr, module) {
	os = append(os, o.DeepCopy())
	}
	return os
	}

	// RemoveModule removes the entire state for the given module, taking with
	// it any resources associated with the module. This should generally be
	// called only for modules whose resources have all been destroyed, but
	// that is not enforced by this method.
	func (s *SyncState) RemoveModule(addr addrs.ModuleInstance) {
	s.lock.Lock()
	defer s.lock.Unlock()

	s.state.RemoveModule(addr)
	}

	// OutputValue returns a snapshot of the state of the output value with the
	// given address, or nil if no such output value is tracked.
	//
	// The return value is a pointer to a copy of the output value state, which the
	// caller may then freely access and mutate.
	func (s SyncState) OutputValue(addr addrs.AbsOutputValue) OutputValue {
	s.lock.RLock()
	ret := s.state.OutputValue(addr).DeepCopy()
	s.lock.RUnlock()
	return ret
	}

	// SetOutputValue writes a given output value into the state, overwriting
	// any existing value of the same name.
	//
	// If the module containing the output is not yet tracked in state then it
	// be added as a side-effect.
	func (s *SyncState) SetOutputValue(addr addrs.AbsOutputValue, value cty.Value, sensitive bool) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.SetOutputValue(addr.OutputValue.Name, value, sensitive)
	}

	// RemoveOutputValue removes the stored value for the output value with the
	// given address.
	//
	// If this results in its containing module being empty, the module will be
	// pruned from the state as a side-effect.
	func (s *SyncState) RemoveOutputValue(addr addrs.AbsOutputValue) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return
	}
	ms.RemoveOutputValue(addr.OutputValue.Name)
	s.maybePruneModule(addr.Module)
	}

	// LocalValue returns the current value associated with the given local value
	// address.
	func (s *SyncState) LocalValue(addr addrs.AbsLocalValue) cty.Value {
	s.lock.RLock()
	// cty.Value is immutable, so we don't need any extra copying here.
	ret := s.state.LocalValue(addr)
	s.lock.RUnlock()
	return ret
	}

	// SetLocalValue writes a given output value into the state, overwriting
	// any existing value of the same name.
	//
	// If the module containing the local value is not yet tracked in state then it
	// will be added as a side-effect.
	func (s *SyncState) SetLocalValue(addr addrs.AbsLocalValue, value cty.Value) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.SetLocalValue(addr.LocalValue.Name, value)
	}

	// RemoveLocalValue removes the stored value for the local value with the
	// given address.
	//
	// If this results in its containing module being empty, the module will be
	// pruned from the state as a side-effect.
	func (s *SyncState) RemoveLocalValue(addr addrs.AbsLocalValue) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return
	}
	ms.RemoveLocalValue(addr.LocalValue.Name)
	s.maybePruneModule(addr.Module)
	}

	// Resource returns a snapshot of the state of the resource with the given
	// address, or nil if no such resource is tracked.
	//
	// The return value is a pointer to a copy of the resource state, which the
	// caller may then freely access and mutate.
	func (s SyncState) Resource(addr addrs.AbsResource) Resource {
	s.lock.RLock()
	ret := s.state.Resource(addr).DeepCopy()
	s.lock.RUnlock()
	return ret
	}

	// ResourceInstance returns a snapshot of the state the resource instance with
	// the given address, or nil if no such instance is tracked.
	//
	// The return value is a pointer to a copy of the instance state, which the
	// caller may then freely access and mutate.
	func (s SyncState) ResourceInstance(addr addrs.AbsResourceInstance) ResourceInstance {
	s.lock.RLock()
	ret := s.state.ResourceInstance(addr).DeepCopy()
	s.lock.RUnlock()
	return ret
	}

	// ResourceInstanceObject returns a snapshot of the current instance object
	// of the given generation belonging to the instance with the given address,
	// or nil if no such object is tracked..
	//
	// The return value is a pointer to a copy of the object, which the caller may
	// then freely access and mutate.
	func (s SyncState) ResourceInstanceObject(addr addrs.AbsResourceInstance, gen Generation) ResourceInstanceObjectSrc {
	s.lock.RLock()
	defer s.lock.RUnlock()

	inst := s.state.ResourceInstance(addr)
	if inst == nil {
	return nil
	}
	return inst.GetGeneration(gen).DeepCopy()
	}

	// SetResourceMeta updates the resource-level metadata for the resource at
	// the given address, creating the containing module state and resource state
	// as a side-effect if not already present.
	func (s *SyncState) SetResourceProvider(addr addrs.AbsResource, provider addrs.AbsProviderConfig) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.SetResourceProvider(addr.Resource, provider)
	}

	// RemoveResource removes the entire state for the given resource, taking with
	// it any instances associated with the resource. This should generally be
	// called only for resource objects whose instances have all been destroyed,
	// but that is not enforced by this method. (Use RemoveResourceIfEmpty instead
	// to safely check first.)
	func (s *SyncState) RemoveResource(addr addrs.AbsResource) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.RemoveResource(addr.Resource)
	s.maybePruneModule(addr.Module)
	}

	// RemoveResourceIfEmpty is similar to RemoveResource but first checks to
	// make sure there are no instances or objects left in the resource.
	//
	// Returns true if the resource was removed, or false if remaining child
	// objects prevented its removal. Returns true also if the resource was
	// already absent, and thus no action needed to be taken.
	func (s *SyncState) RemoveResourceIfEmpty(addr addrs.AbsResource) bool {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return true // nothing to do
	}
	rs := ms.Resource(addr.Resource)
	if rs == nil {
	return true // nothing to do
	}
	if len(rs.Instances) != 0 {
	// We don't check here for the possibility of instances that exist
	// but don't have any objects because it's the responsibility of the
	// instance-mutation methods to prune those away automatically.
	return false
	}
	ms.RemoveResource(addr.Resource)
	s.maybePruneModule(addr.Module)
	return true
	}

	// SetResourceInstanceCurrent saves the given instance object as the current
	// generation of the resource instance with the given address, simultaneously
	// updating the recorded provider configuration address, dependencies, and
	// resource EachMode.
	//
	// Any existing current instance object for the given resource is overwritten.
	// Set obj to nil to remove the primary generation object altogether. If there
	// are no deposed objects then the instance as a whole will be removed, which
	// may in turn also remove the containing module if it becomes empty.
	//
	// The caller must ensure that the given ResourceInstanceObject is not
	// concurrently mutated during this call, but may be freely used again once
	// this function returns.
	//
	// The provider address is a resource-wide settings and is updated
	// for all other instances of the same resource as a side-effect of this call.
	//
	// If the containing module for this resource or the resource itself are not
	// already tracked in state then they will be added as a side-effect.
	func (s SyncState) SetResourceInstanceCurrent(addr addrs.AbsResourceInstance, obj ResourceInstanceObjectSrc, provider addrs.AbsProviderConfig) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.SetResourceInstanceCurrent(addr.Resource, obj.DeepCopy(), provider)
	s.maybePruneModule(addr.Module)
	}

	// SetResourceInstanceDeposed saves the given instance object as a deposed
	// generation of the resource instance with the given address and deposed key.
	//
	// Call this method only for pre-existing deposed objects that already have
	// a known DeposedKey. For example, this method is useful if reloading objects
	// that were persisted to a state file. To mark the current object as deposed,
	// use DeposeResourceInstanceObject instead.
	//
	// The caller must ensure that the given ResourceInstanceObject is not
	// concurrently mutated during this call, but may be freely used again once
	// this function returns.
	//
	// The resource that contains the given instance must already exist in the
	// state, or this method will panic. Use Resource to check first if its
	// presence is not already guaranteed.
	//
	// Any existing current instance object for the given resource and deposed key
	// is overwritten. Set obj to nil to remove the deposed object altogether. If
	// the instance is left with no objects after this operation then it will
	// be removed from its containing resource altogether.
	//
	// If the containing module for this resource or the resource itself are not
	// already tracked in state then they will be added as a side-effect.
	func (s SyncState) SetResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey, obj ResourceInstanceObjectSrc, provider addrs.AbsProviderConfig) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.EnsureModule(addr.Module)
	ms.SetResourceInstanceDeposed(addr.Resource, key, obj.DeepCopy(), provider)
	s.maybePruneModule(addr.Module)
	}

	// DeposeResourceInstanceObject moves the current instance object for the
	// given resource instance address into the deposed set, leaving the instance
	// without a current object.
	//
	// The return value is the newly-allocated deposed key, or NotDeposed if the
	// given instance is already lacking a current object.
	//
	// If the containing module for this resource or the resource itself are not
	// already tracked in state then there cannot be a current object for the
	// given instance, and so NotDeposed will be returned without modifying the
	// state at all.
	func (s *SyncState) DeposeResourceInstanceObject(addr addrs.AbsResourceInstance) DeposedKey {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return NotDeposed
	}

	return ms.deposeResourceInstanceObject(addr.Resource, NotDeposed)
	}

	// DeposeResourceInstanceObjectForceKey is like DeposeResourceInstanceObject
	// but uses a pre-allocated key. It's the caller's responsibility to ensure
	// that there aren't any races to use a particular key; this method will panic
	// if the given key is already in use.
	func (s *SyncState) DeposeResourceInstanceObjectForceKey(addr addrs.AbsResourceInstance, forcedKey DeposedKey) {
	s.lock.Lock()
	defer s.lock.Unlock()

	if forcedKey == NotDeposed {
	// Usage error: should use DeposeResourceInstanceObject in this case
	panic("DeposeResourceInstanceObjectForceKey called without forced key")
	}

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return // Nothing to do, since there can't be any current object either.
	}

	ms.deposeResourceInstanceObject(addr.Resource, forcedKey)
	}

	// ForgetResourceInstanceAll removes the record of all objects associated with
	// the specified resource instance, if present. If not present, this is a no-op.
	func (s *SyncState) ForgetResourceInstanceAll(addr addrs.AbsResourceInstance) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return
	}
	ms.ForgetResourceInstanceAll(addr.Resource)
	s.maybePruneModule(addr.Module)
	}

	// ForgetResourceInstanceDeposed removes the record of the deposed object with
	// the given address and key, if present. If not present, this is a no-op.
	func (s *SyncState) ForgetResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey) {
	s.lock.Lock()
	defer s.lock.Unlock()

	ms := s.state.Module(addr.Module)
	if ms == nil {
	return
	}
	ms.ForgetResourceInstanceDeposed(addr.Resource, key)
	s.maybePruneModule(addr.Module)
	}

	// MaybeRestoreResourceInstanceDeposed will restore the deposed object with the
	// given key on the specified resource as the current object for that instance
	// if and only if that would not cause us to forget an existing current
	// object for that instance.
	//
	// Returns true if the object was restored to current, or false if no change
	// was made at all.
	func (s *SyncState) MaybeRestoreResourceInstanceDeposed(addr addrs.AbsResourceInstance, key DeposedKey) bool {
	s.lock.Lock()
	defer s.lock.Unlock()

	if key == NotDeposed {
	panic("MaybeRestoreResourceInstanceDeposed called without DeposedKey")
	}

	ms := s.state.Module(addr.Module)
	if ms == nil {
	// Nothing to do, since the specified deposed object cannot exist.
	return false
	}

	return ms.maybeRestoreResourceInstanceDeposed(addr.Resource, key)
	}

	// RemovePlannedResourceInstanceObjects removes from the state any resource
	// instance objects that have the status ObjectPlanned, indiciating that they
	// are just transient placeholders created during planning.
	//
	// Note that this does not restore any "ready" or "tainted" object that might
	// have been present before the planned object was written. The only real use
	// for this method is in preparing the state created during a refresh walk,
	// where we run the planning step for certain instances just to create enough
	// information to allow correct expression evaluation within provider and
	// data resource blocks. Discarding planned instances in that case is okay
	// because the refresh phase only creates planned objects to stand in for
	// objects that don't exist yet, and thus the planned object must have been
	// absent before by definition.
	func (s *SyncState) RemovePlannedResourceInstanceObjects() {
	// TODO: Merge together the refresh and plan phases into a single walk,
	// so we can remove the need to create this "partial plan" during refresh
	// that we then need to clean up before proceeding.

	s.lock.Lock()
	defer s.lock.Unlock()

	for _, ms := range s.state.Modules {
	moduleAddr := ms.Addr

	for _, rs := range ms.Resources {
	resAddr := rs.Addr.Resource

	for ik, is := range rs.Instances {
	instAddr := resAddr.Instance(ik)

	if is.Current != nil && is.Current.Status == ObjectPlanned {
	// Setting the current instance to nil removes it from the
	// state altogether if there are not also deposed instances.
	ms.SetResourceInstanceCurrent(instAddr, nil, rs.ProviderConfig)
	}

	for dk, obj := range is.Deposed {
	// Deposed objects should never be "planned", but we'll
	// do this anyway for the sake of completeness.
	if obj.Status == ObjectPlanned {
	ms.ForgetResourceInstanceDeposed(instAddr, dk)
	}
	}
	}
	}

	// We may have deleted some objects, which means that we may have
	// left a module empty, and so we must prune to preserve the invariant
	// that only the root module is allowed to be empty.
	s.maybePruneModule(moduleAddr)
	}
	}

	// Lock acquires an explicit lock on the state, allowing direct read and write
	// access to the returned state object. The caller must call Unlock once
	// access is no longer needed, and then immediately discard the state pointer
	// pointer.
	//
	// Most callers should not use this. Instead, use the concurrency-safe
	// accessors and mutators provided directly on SyncState.
	func (s SyncState) Lock() State {
	s.lock.Lock()
	return s.state
	}

	// Unlock releases a lock previously acquired by Lock, at which point the
	// caller must cease all use of the state pointer that was returned.
	//
	// Do not call this method except to end an explicit lock acquired by
	// Lock. If a caller calls Unlock without first holding the lock, behavior
	// is undefined.
	func (s *SyncState) Unlock() {
	s.lock.Unlock()
	}

	// Close extracts the underlying state from inside this wrapper, making the
	// wrapper invalid for any future operations.
	func (s SyncState) Close() State {
	s.lock.Lock()
	ret := s.state
	s.state = nil // make sure future operations can't still modify it
	s.lock.Unlock()
	return ret
	}

	// maybePruneModule will remove a module from the state altogether if it is
	// empty, unless it's the root module which must always be present.
	//
	// This helper method is not concurrency-safe on its own, so must only be
	// called while the caller is already holding the lock for writing.
	func (s *SyncState) maybePruneModule(addr addrs.ModuleInstance) {
	if addr.IsRoot() {
	// We never prune the root.
	return
	}

	ms := s.state.Module(addr)
	if ms == nil {
	return
	}

	if ms.empty() {
	log.Printf("[TRACE] states.SyncState: pruning %s because it is empty", addr)
	s.state.RemoveModule(addr)
	}
	}

	func (s *SyncState) MoveAbsResource(src, dst addrs.AbsResource) {
	s.lock.Lock()
	defer s.lock.Unlock()

	s.state.MoveAbsResource(src, dst)
	}

	func (s *SyncState) MaybeMoveAbsResource(src, dst addrs.AbsResource) bool {
	s.lock.Lock()
	defer s.lock.Unlock()

	return s.state.MaybeMoveAbsResource(src, dst)
	}

	func (s *SyncState) MoveResourceInstance(src, dst addrs.AbsResourceInstance) {
	s.lock.Lock()
	defer s.lock.Unlock()

	s.state.MoveAbsResourceInstance(src, dst)
	}

	func (s *SyncState) MaybeMoveResourceInstance(src, dst addrs.AbsResourceInstance) bool {
	s.lock.Lock()
	defer s.lock.Unlock()

	return s.state.MaybeMoveAbsResourceInstance(src, dst)
	}

	func (s *SyncState) MoveModuleInstance(src, dst addrs.ModuleInstance) {
	s.lock.Lock()
	defer s.lock.Unlock()

	s.state.MoveModuleInstance(src, dst)
	}

	func (s *SyncState) MaybeMoveModuleInstance(src, dst addrs.ModuleInstance) bool {
	s.lock.Lock()
	defer s.lock.Unlock()

	return s.state.MaybeMoveModuleInstance(src, dst)
	}