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

 package terraform

 import (
 	"log"

 	"github.com/hashicorp/terraform/internal/checks"
 	"github.com/hashicorp/terraform/internal/configs"
 	"github.com/hashicorp/terraform/internal/instances"
 	"github.com/hashicorp/terraform/internal/plans"
 	"github.com/hashicorp/terraform/internal/refactoring"
 	"github.com/hashicorp/terraform/internal/states"
 	"github.com/hashicorp/terraform/internal/tfdiags"
 )

 // graphWalkOpts captures some transient values we use (and possibly mutate)
 // during a graph walk.
 //
 // The way these options get used unfortunately varies between the different
 // walkOperation types. This is a historical design wart that dates back to
 // us using the same graph structure for all operations; hopefully we'll
 // make the necessary differences between the walk types more explicit someday.
 type graphWalkOpts struct {
 	InputState *states.State
 	Changes    *plans.Changes
 	Config     *configs.Config

 	// PlanTimeCheckResults should be populated during the apply phase with
 	// the snapshot of check results that was generated during the plan step.
 	//
 	// This then propagates the decisions about which checkable objects exist
 	// from the plan phase into the apply phase without having to re-compute
 	// the module and resource expansion.
 	PlanTimeCheckResults *states.CheckResults

 	MoveResults refactoring.MoveResults
 }

 func (c *Context) walk(graph *Graph, operation walkOperation, opts *graphWalkOpts) (*ContextGraphWalker, tfdiags.Diagnostics) {
 	log.Printf("[DEBUG] Starting graph walk: %s", operation.String())

 	walker := c.graphWalker(operation, opts)

 	// Watch for a stop so we can call the provider Stop() API.
 	watchStop, watchWait := c.watchStop(walker)

 	// Walk the real graph, this will block until it completes
 	diags := graph.Walk(walker)

 	// Close the channel so the watcher stops, and wait for it to return.
 	close(watchStop)
 	<-watchWait

 	return walker, diags
 }

 func (c *Context) graphWalker(operation walkOperation, opts *graphWalkOpts) *ContextGraphWalker {
 	var state *states.SyncState
 	var refreshState *states.SyncState
 	var prevRunState *states.SyncState

 	// NOTE: None of the SyncState objects must directly wrap opts.InputState,
 	// because we use those to mutate the state object and opts.InputState
 	// belongs to our caller and thus we must treat it as immutable.
 	//
 	// To account for that, most of our SyncState values created below end up
 	// wrapping a _deep copy_ of opts.InputState instead.
 	inputState := opts.InputState
 	if inputState == nil {
 		// Lots of callers use nil to represent the "empty" case where we've
 		// not run Apply yet, so we tolerate that.
 		inputState = states.NewState()
 	}

 	switch operation {
 	case walkValidate:
 		// validate should not use any state
 		state = states.NewState().SyncWrapper()

 		// validate currently uses the plan graph, so we have to populate the
 		// refreshState and the prevRunState.
 		refreshState = states.NewState().SyncWrapper()
 		prevRunState = states.NewState().SyncWrapper()

 	case walkPlan, walkPlanDestroy, walkImport:
 		state = inputState.DeepCopy().SyncWrapper()
 		refreshState = inputState.DeepCopy().SyncWrapper()
 		prevRunState = inputState.DeepCopy().SyncWrapper()

 		// For both of our new states we'll discard the previous run's
 		// check results, since we can still refer to them from the
 		// prevRunState object if we need to.
 		state.DiscardCheckResults()
 		refreshState.DiscardCheckResults()

 	default:
 		state = inputState.DeepCopy().SyncWrapper()
 		// Only plan-like walks use refreshState and prevRunState

 		// Discard the input state's check results, because we should create
 		// a new set as a result of the graph walk.
 		state.DiscardCheckResults()
 	}

 	changes := opts.Changes
 	if changes == nil {
 		// Several of our non-plan walks end up sharing codepaths with the
 		// plan walk and thus expect to generate planned changes even though
 		// we don't care about them. To avoid those crashing, we'll just
 		// insert a placeholder changes object which'll get discarded
 		// afterwards.
 		changes = plans.NewChanges()
 	}

 	if opts.Config == nil {
 		panic("Context.graphWalker call without Config")
 	}

 	checkState := checks.NewState(opts.Config)
 	if opts.PlanTimeCheckResults != nil {
 		// We'll re-report all of the same objects we determined during the
 		// plan phase so that we can repeat the checks during the apply
 		// phase to finalize them.
 		for _, configElem := range opts.PlanTimeCheckResults.ConfigResults.Elems {
 			if configElem.Value.ObjectAddrsKnown() {
 				configAddr := configElem.Key
 				checkState.ReportCheckableObjects(configAddr, configElem.Value.ObjectResults.Keys())
 			}
 		}
 	}

 	return &ContextGraphWalker{
 		Context:          c,
 		State:            state,
 		Config:           opts.Config,
 		RefreshState:     refreshState,
 		PrevRunState:     prevRunState,
 		Changes:          changes.SyncWrapper(),
 		Checks:           checkState,
 		InstanceExpander: instances.NewExpander(),
 		MoveResults:      opts.MoveResults,
 		Operation:        operation,
 		StopContext:      c.runContext,
 	}
 }
	package terraform

	import (
	"log"

	"github.com/hashicorp/terraform/internal/checks"
	"github.com/hashicorp/terraform/internal/configs"
	"github.com/hashicorp/terraform/internal/instances"
	"github.com/hashicorp/terraform/internal/plans"
	"github.com/hashicorp/terraform/internal/refactoring"
	"github.com/hashicorp/terraform/internal/states"
	"github.com/hashicorp/terraform/internal/tfdiags"
	)

	// graphWalkOpts captures some transient values we use (and possibly mutate)
	// during a graph walk.
	//
	// The way these options get used unfortunately varies between the different
	// walkOperation types. This is a historical design wart that dates back to
	// us using the same graph structure for all operations; hopefully we'll
	// make the necessary differences between the walk types more explicit someday.
	type graphWalkOpts struct {
	InputState *states.State
	Changes *plans.Changes
	Config *configs.Config

	// PlanTimeCheckResults should be populated during the apply phase with
	// the snapshot of check results that was generated during the plan step.
	//
	// This then propagates the decisions about which checkable objects exist
	// from the plan phase into the apply phase without having to re-compute
	// the module and resource expansion.
	PlanTimeCheckResults *states.CheckResults

	MoveResults refactoring.MoveResults
	}

	func (c Context) walk(graph Graph, operation walkOperation, opts graphWalkOpts) (ContextGraphWalker, tfdiags.Diagnostics) {
	log.Printf("[DEBUG] Starting graph walk: %s", operation.String())

	walker := c.graphWalker(operation, opts)

	// Watch for a stop so we can call the provider Stop() API.
	watchStop, watchWait := c.watchStop(walker)

	// Walk the real graph, this will block until it completes
	diags := graph.Walk(walker)

	// Close the channel so the watcher stops, and wait for it to return.
	close(watchStop)
	<-watchWait

	return walker, diags
	}

	func (c Context) graphWalker(operation walkOperation, opts graphWalkOpts) *ContextGraphWalker {
	var state *states.SyncState
	var refreshState *states.SyncState
	var prevRunState *states.SyncState

	// NOTE: None of the SyncState objects must directly wrap opts.InputState,
	// because we use those to mutate the state object and opts.InputState
	// belongs to our caller and thus we must treat it as immutable.
	//
	// To account for that, most of our SyncState values created below end up
	// wrapping a _deep copy_ of opts.InputState instead.
	inputState := opts.InputState
	if inputState == nil {
	// Lots of callers use nil to represent the "empty" case where we've
	// not run Apply yet, so we tolerate that.
	inputState = states.NewState()
	}

	switch operation {
	case walkValidate:
	// validate should not use any state
	state = states.NewState().SyncWrapper()

	// validate currently uses the plan graph, so we have to populate the
	// refreshState and the prevRunState.
	refreshState = states.NewState().SyncWrapper()
	prevRunState = states.NewState().SyncWrapper()

	case walkPlan, walkPlanDestroy, walkImport:
	state = inputState.DeepCopy().SyncWrapper()
	refreshState = inputState.DeepCopy().SyncWrapper()
	prevRunState = inputState.DeepCopy().SyncWrapper()

	// For both of our new states we'll discard the previous run's
	// check results, since we can still refer to them from the
	// prevRunState object if we need to.
	state.DiscardCheckResults()
	refreshState.DiscardCheckResults()

	default:
	state = inputState.DeepCopy().SyncWrapper()
	// Only plan-like walks use refreshState and prevRunState

	// Discard the input state's check results, because we should create
	// a new set as a result of the graph walk.
	state.DiscardCheckResults()
	}

	changes := opts.Changes
	if changes == nil {
	// Several of our non-plan walks end up sharing codepaths with the
	// plan walk and thus expect to generate planned changes even though
	// we don't care about them. To avoid those crashing, we'll just
	// insert a placeholder changes object which'll get discarded
	// afterwards.
	changes = plans.NewChanges()
	}

	if opts.Config == nil {
	panic("Context.graphWalker call without Config")
	}

	checkState := checks.NewState(opts.Config)
	if opts.PlanTimeCheckResults != nil {
	// We'll re-report all of the same objects we determined during the
	// plan phase so that we can repeat the checks during the apply
	// phase to finalize them.
	for _, configElem := range opts.PlanTimeCheckResults.ConfigResults.Elems {
	if configElem.Value.ObjectAddrsKnown() {
	configAddr := configElem.Key
	checkState.ReportCheckableObjects(configAddr, configElem.Value.ObjectResults.Keys())
	}
	}
	}

	return &ContextGraphWalker{
	Context: c,
	State: state,
	Config: opts.Config,
	RefreshState: refreshState,
	PrevRunState: prevRunState,
	Changes: changes.SyncWrapper(),
	Checks: checkState,
	InstanceExpander: instances.NewExpander(),
	MoveResults: opts.MoveResults,
	Operation: operation,
	StopContext: c.runContext,
	}
	}