// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package tofu import ( "log" "github.com/opentofu/opentofu/internal/addrs" "github.com/opentofu/opentofu/internal/configs" "github.com/opentofu/opentofu/internal/dag" "github.com/opentofu/opentofu/internal/states" "github.com/opentofu/opentofu/internal/tfdiags" ) // PlanGraphBuilder is a GraphBuilder implementation that builds a graph for // planning and for other "plan-like" operations which don't require an // already-calculated plan as input. // // Unlike the apply graph builder, this graph builder: // // - Makes its decisions primarily based on the given configuration, which // represents the desired state. // // - Ignores certain lifecycle concerns like create_before_destroy, because // those are only important once we already know what action we're planning // to take against a particular resource instance. type PlanGraphBuilder struct { // Config is the configuration tree to build a plan from. Config *configs.Config // State is the current state State *states.State // RootVariableValues are the raw input values for root input variables // given by the caller, which we'll resolve into final values as part // of the plan walk. RootVariableValues InputValues // Plugins is a library of plug-in components (providers and // provisioners) available for use. Plugins *contextPlugins // Targets are resources to target Targets []addrs.Targetable // ForceReplace are resource instances where if we would normally have // generated a NoOp or Update action then we'll force generating a replace // action instead. Create and Delete actions are not affected. ForceReplace []addrs.AbsResourceInstance // skipRefresh indicates that we should skip refreshing managed resources skipRefresh bool // preDestroyRefresh indicates that we are executing the refresh which // happens immediately before a destroy plan, which happens to use the // normal planing mode so skipPlanChanges cannot be set. preDestroyRefresh bool // skipPlanChanges indicates that we should skip the step of comparing // prior state with configuration and generating planned changes to // resource instances. (This is for the "refresh only" planning mode, // where we _only_ do the refresh step.) skipPlanChanges bool ConcreteProvider ConcreteProviderNodeFunc ConcreteResource ConcreteResourceNodeFunc ConcreteResourceInstance ConcreteResourceInstanceNodeFunc ConcreteResourceOrphan ConcreteResourceInstanceNodeFunc ConcreteResourceInstanceDeposed ConcreteResourceInstanceDeposedNodeFunc ConcreteModule ConcreteModuleNodeFunc // Plan Operation this graph will be used for. Operation walkOperation // ExternalReferences allows the external caller to pass in references to // nodes that should not be pruned even if they are not referenced within // the actual graph. ExternalReferences []*addrs.Reference // ImportTargets are the list of resources to import. ImportTargets []*ImportTarget // GenerateConfig tells OpenTofu where to write and generated config for // any import targets that do not already have configuration. // // If empty, then config will not be generated. GenerateConfigPath string } // See GraphBuilder func (b *PlanGraphBuilder) Build(path addrs.ModuleInstance) (*Graph, tfdiags.Diagnostics) { log.Printf("[TRACE] building graph for %s", b.Operation) return (&BasicGraphBuilder{ Steps: b.Steps(), Name: "PlanGraphBuilder", }).Build(path) } // See GraphBuilder func (b *PlanGraphBuilder) Steps() []GraphTransformer { switch b.Operation { case walkPlan: b.initPlan() case walkPlanDestroy: b.initDestroy() case walkValidate: b.initValidate() case walkImport: b.initImport() default: panic("invalid plan operation: " + b.Operation.String()) } steps := []GraphTransformer{ // Creates all the resources represented in the config &ConfigTransformer{ Concrete: b.ConcreteResource, Config: b.Config, // Resources are not added from the config on destroy. skip: b.Operation == walkPlanDestroy, importTargets: b.ImportTargets, // We only want to generate config during a plan operation. generateConfigPathForImportTargets: b.GenerateConfigPath, }, // Add dynamic values &RootVariableTransformer{Config: b.Config, RawValues: b.RootVariableValues}, &ModuleVariableTransformer{Config: b.Config}, &LocalTransformer{Config: b.Config}, &OutputTransformer{ Config: b.Config, RefreshOnly: b.skipPlanChanges || b.preDestroyRefresh, Destroying: b.Operation == walkPlanDestroy, // NOTE: We currently treat anything built with the plan graph // builder as "planning" for our purposes here, because we share // the same graph node implementation between all of the walk // types and so the pre-planning walks still think they are // producing a plan even though we immediately discard it. Planning: true, }, // Add nodes and edges for the check block assertions. Check block data // sources were added earlier. &checkTransformer{ Config: b.Config, Operation: b.Operation, }, // Add orphan resources &OrphanResourceInstanceTransformer{ Concrete: b.ConcreteResourceOrphan, State: b.State, Config: b.Config, skip: b.Operation == walkPlanDestroy, }, // We also need nodes for any deposed instance objects present in the // state, so we can plan to destroy them. (During plan this will // intentionally skip creating nodes for _current_ objects, since // ConfigTransformer created nodes that will do that during // DynamicExpand.) &StateTransformer{ ConcreteCurrent: b.ConcreteResourceInstance, ConcreteDeposed: b.ConcreteResourceInstanceDeposed, State: b.State, }, // Attach the state &AttachStateTransformer{State: b.State}, // Create orphan output nodes &OrphanOutputTransformer{ Config: b.Config, State: b.State, Planning: true, }, // Attach the configuration to any resources &AttachResourceConfigTransformer{Config: b.Config}, // add providers transformProviders(b.ConcreteProvider, b.Config), // Remove modules no longer present in the config &RemovedModuleTransformer{Config: b.Config, State: b.State}, // Must attach schemas before ReferenceTransformer so that we can // analyze the configuration to find references. &AttachSchemaTransformer{Plugins: b.Plugins, Config: b.Config}, // Create expansion nodes for all of the module calls. This must // come after all other transformers that create nodes representing // objects that can belong to modules. &ModuleExpansionTransformer{Concrete: b.ConcreteModule, Config: b.Config}, // Plug in any external references. &ExternalReferenceTransformer{ ExternalReferences: b.ExternalReferences, }, &ReferenceTransformer{}, &AttachDependenciesTransformer{}, // Make sure data sources are aware of any depends_on from the // configuration &attachDataResourceDependsOnTransformer{}, // DestroyEdgeTransformer is only required during a plan so that the // TargetsTransformer can determine which nodes to keep in the graph. &DestroyEdgeTransformer{ Operation: b.Operation, }, &pruneUnusedNodesTransformer{ skip: b.Operation != walkPlanDestroy, }, // Target &TargetsTransformer{Targets: b.Targets}, // Detect when create_before_destroy must be forced on for a particular // node due to dependency edges, to avoid graph cycles during apply. &ForcedCBDTransformer{}, // Close opened plugin connections &CloseProviderTransformer{}, // Close the root module &CloseRootModuleTransformer{}, // Perform the transitive reduction to make our graph a bit // more understandable if possible (it usually is possible). &TransitiveReductionTransformer{}, } return steps } func (b *PlanGraphBuilder) initPlan() { b.ConcreteProvider = func(a *NodeAbstractProvider) dag.Vertex { return &NodeApplyableProvider{ NodeAbstractProvider: a, } } b.ConcreteResource = func(a *NodeAbstractResource) dag.Vertex { return &nodeExpandPlannableResource{ NodeAbstractResource: a, skipRefresh: b.skipRefresh, skipPlanChanges: b.skipPlanChanges, preDestroyRefresh: b.preDestroyRefresh, forceReplace: b.ForceReplace, } } b.ConcreteResourceOrphan = func(a *NodeAbstractResourceInstance) dag.Vertex { return &NodePlannableResourceInstanceOrphan{ NodeAbstractResourceInstance: a, skipRefresh: b.skipRefresh, skipPlanChanges: b.skipPlanChanges, } } b.ConcreteResourceInstanceDeposed = func(a *NodeAbstractResourceInstance, key states.DeposedKey) dag.Vertex { return &NodePlanDeposedResourceInstanceObject{ NodeAbstractResourceInstance: a, DeposedKey: key, skipRefresh: b.skipRefresh, skipPlanChanges: b.skipPlanChanges, } } } func (b *PlanGraphBuilder) initDestroy() { b.initPlan() b.ConcreteResourceInstance = func(a *NodeAbstractResourceInstance) dag.Vertex { return &NodePlanDestroyableResourceInstance{ NodeAbstractResourceInstance: a, skipRefresh: b.skipRefresh, } } } func (b *PlanGraphBuilder) initValidate() { // Set the provider to the normal provider. This will ask for input. b.ConcreteProvider = func(a *NodeAbstractProvider) dag.Vertex { return &NodeApplyableProvider{ NodeAbstractProvider: a, } } b.ConcreteResource = func(a *NodeAbstractResource) dag.Vertex { return &NodeValidatableResource{ NodeAbstractResource: a, } } b.ConcreteModule = func(n *nodeExpandModule) dag.Vertex { return &nodeValidateModule{ nodeExpandModule: *n, } } } func (b *PlanGraphBuilder) initImport() { b.ConcreteProvider = func(a *NodeAbstractProvider) dag.Vertex { return &NodeApplyableProvider{ NodeAbstractProvider: a, } } b.ConcreteResource = func(a *NodeAbstractResource) dag.Vertex { return &nodeExpandPlannableResource{ NodeAbstractResource: a, // For now we always skip planning changes for import, since we are // not going to combine importing with other changes. This is // temporary to try and maintain existing import behaviors, but // planning will need to be allowed for more complex configurations. skipPlanChanges: true, // We also skip refresh for now, since the plan output is written // as the new state, and users are not expecting the import process // to update any other instances in state. skipRefresh: true, // If we get here, we know that we are in legacy import mode, and // that the user has run the import command rather than plan. // This flag must be propagated down to the // NodePlannableResourceInstance so we can ignore the new import // behaviour. legacyImportMode: true, } } }