opentofu/terraform/graph_builder_plan.go
Mitchell Hashimoto 26ac58bc97
terraform: refactor NodeApplyableProvider to use NodeAbstractProvider
This is important so that the graph looks correct.
2016-12-03 15:27:38 -08:00

128 lines
3.2 KiB
Go

package terraform
import (
"github.com/hashicorp/terraform/config/module"
"github.com/hashicorp/terraform/dag"
)
// PlanGraphBuilder implements GraphBuilder and is responsible for building
// a graph for planning (creating a Terraform Diff).
//
// The primary difference between this graph and others:
//
// * Based on the config since it represents the target state
//
// * Ignores lifecycle options since no lifecycle events occur here. This
// simplifies the graph significantly since complex transforms such as
// create-before-destroy can be completely ignored.
//
type PlanGraphBuilder struct {
// Module is the root module for the graph to build.
Module *module.Tree
// State is the current state
State *State
// Providers is the list of providers supported.
Providers []string
// Targets are resources to target
Targets []string
// DisableReduce, if true, will not reduce the graph. Great for testing.
DisableReduce bool
// Validate will do structural validation of the graph.
Validate bool
}
// See GraphBuilder
func (b *PlanGraphBuilder) Build(path []string) (*Graph, error) {
return (&BasicGraphBuilder{
Steps: b.Steps(),
Validate: b.Validate,
Name: "PlanGraphBuilder",
}).Build(path)
}
// See GraphBuilder
func (b *PlanGraphBuilder) Steps() []GraphTransformer {
// Custom factory for creating providers.
concreteProvider := func(a *NodeAbstractProvider) dag.Vertex {
return &NodeApplyableProvider{
NodeAbstractProvider: a,
}
}
concreteResource := func(a *NodeAbstractResource) dag.Vertex {
return &NodePlannableResource{
NodeAbstractResource: a,
}
}
concreteResourceOrphan := func(a *NodeAbstractResource) dag.Vertex {
return &NodePlannableResourceOrphan{
NodeAbstractResource: a,
}
}
steps := []GraphTransformer{
// Creates all the resources represented in the config
&ConfigTransformer{
Concrete: concreteResource,
Module: b.Module,
},
// Add the outputs
&OutputTransformer{Module: b.Module},
// Add orphan resources
&OrphanResourceTransformer{
Concrete: concreteResourceOrphan,
State: b.State,
Module: b.Module,
},
// Attach the configuration to any resources
&AttachResourceConfigTransformer{Module: b.Module},
// Attach the state
&AttachStateTransformer{State: b.State},
// Connect so that the references are ready for targeting. We'll
// have to connect again later for providers and so on.
&ReferenceTransformer{},
// Target
&TargetsTransformer{Targets: b.Targets},
// Create all the providers
&MissingProviderTransformer{Providers: b.Providers, Concrete: concreteProvider},
&ProviderTransformer{},
&DisableProviderTransformer{},
&ParentProviderTransformer{},
&AttachProviderConfigTransformer{Module: b.Module},
// Add root variables
&RootVariableTransformer{Module: b.Module},
// Add module variables
&ModuleVariableTransformer{Module: b.Module},
// Connect references again to connect the providers, module variables,
// etc. This is idempotent.
&ReferenceTransformer{},
// Single root
&RootTransformer{},
}
if !b.DisableReduce {
// Perform the transitive reduction to make our graph a bit
// more sane if possible (it usually is possible).
steps = append(steps, &TransitiveReductionTransformer{})
}
return steps
}