terraform/terraform/graph_builder_apply.go

213 lines
6.2 KiB
Go

package terraform
import (
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/dag"
"github.com/hashicorp/terraform/plans"
"github.com/hashicorp/terraform/states"
"github.com/hashicorp/terraform/tfdiags"
)
// ApplyGraphBuilder implements GraphBuilder and is responsible for building
// a graph for applying a Terraform diff.
//
// Because the graph is built from the diff (vs. the config or state),
// this helps ensure that the apply-time graph doesn't modify any resources
// that aren't explicitly in the diff. There are other scenarios where the
// diff can be deviated, so this is just one layer of protection.
type ApplyGraphBuilder struct {
// Config is the configuration tree that the diff was built from.
Config *configs.Config
// Changes describes the changes that we need apply.
Changes *plans.Changes
// State is the current state
State *states.State
// Components is a factory for the plug-in components (providers and
// provisioners) available for use.
Components contextComponentFactory
// Schemas is the repository of schemas we will draw from to analyse
// the configuration.
Schemas *Schemas
// Targets are resources to target. This is only required to make sure
// unnecessary outputs aren't included in the apply graph. The plan
// builder successfully handles targeting resources. In the future,
// outputs should go into the diff so that this is unnecessary.
Targets []addrs.Targetable
// DisableReduce, if true, will not reduce the graph. Great for testing.
DisableReduce bool
// Destroy, if true, represents a pure destroy operation
Destroy bool
// Validate will do structural validation of the graph.
Validate bool
}
// See GraphBuilder
func (b *ApplyGraphBuilder) Build(path addrs.ModuleInstance) (*Graph, tfdiags.Diagnostics) {
return (&BasicGraphBuilder{
Steps: b.Steps(),
Validate: b.Validate,
Name: "ApplyGraphBuilder",
}).Build(path)
}
// See GraphBuilder
func (b *ApplyGraphBuilder) Steps() []GraphTransformer {
// Custom factory for creating providers.
concreteProvider := func(a *NodeAbstractProvider) dag.Vertex {
return &NodeApplyableProvider{
NodeAbstractProvider: a,
}
}
concreteResource := func(a *NodeAbstractResource) dag.Vertex {
return &NodeApplyableResource{
NodeAbstractResource: a,
}
}
concreteOrphanResource := func(a *NodeAbstractResource) dag.Vertex {
return &NodeDestroyResource{
NodeAbstractResource: a,
}
}
concreteResourceInstance := func(a *NodeAbstractResourceInstance) dag.Vertex {
return &NodeApplyableResourceInstance{
NodeAbstractResourceInstance: a,
}
}
steps := []GraphTransformer{
// Creates all the resources represented in the config. During apply,
// we use this just to ensure that the whole-resource metadata is
// updated to reflect things such as whether the count argument is
// set in config, or which provider configuration manages each resource.
&ConfigTransformer{
Concrete: concreteResource,
Config: b.Config,
},
// Creates all the resource instances represented in the diff, along
// with dependency edges against the whole-resource nodes added by
// ConfigTransformer above.
&DiffTransformer{
Concrete: concreteResourceInstance,
State: b.State,
Changes: b.Changes,
},
// Creates extra cleanup nodes for any entire resources that are
// no longer present in config, so we can make sure we clean up the
// leftover empty resource states after the instances have been
// destroyed.
// (We don't track this particular type of change in the plan because
// it's just cleanup of our own state object, and so doesn't effect
// any real remote objects or consumable outputs.)
&OrphanResourceTransformer{
Concrete: concreteOrphanResource,
Config: b.Config,
State: b.State,
},
// Create orphan output nodes
&OrphanOutputTransformer{Config: b.Config, State: b.State},
// Attach the configuration to any resources
&AttachResourceConfigTransformer{Config: b.Config},
// Attach the state
&AttachStateTransformer{State: b.State},
// Destruction ordering
&DestroyEdgeTransformer{
Config: b.Config,
State: b.State,
Schemas: b.Schemas,
},
GraphTransformIf(
func() bool { return !b.Destroy },
&CBDEdgeTransformer{
Config: b.Config,
State: b.State,
Schemas: b.Schemas,
},
),
// Provisioner-related transformations
&MissingProvisionerTransformer{Provisioners: b.Components.ResourceProvisioners()},
&ProvisionerTransformer{},
// Add root variables
&RootVariableTransformer{Config: b.Config},
// Add the local values
&LocalTransformer{Config: b.Config},
// Add the outputs
&OutputTransformer{Config: b.Config},
// Add module variables
&ModuleVariableTransformer{Config: b.Config},
// add providers
TransformProviders(b.Components.ResourceProviders(), 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{Schemas: b.Schemas},
// Connect references so ordering is correct
&ReferenceTransformer{},
// Handle destroy time transformations for output and local values.
// Reverse the edges from outputs and locals, so that
// interpolations don't fail during destroy.
// Create a destroy node for outputs to remove them from the state.
// Prune unreferenced values, which may have interpolations that can't
// be resolved.
GraphTransformIf(
func() bool { return b.Destroy },
GraphTransformMulti(
&DestroyValueReferenceTransformer{},
&DestroyOutputTransformer{},
&PruneUnusedValuesTransformer{},
),
),
// Add the node to fix the state count boundaries
&CountBoundaryTransformer{
Config: b.Config,
},
// Target
&TargetsTransformer{Targets: b.Targets},
// Close opened plugin connections
&CloseProviderTransformer{},
&CloseProvisionerTransformer{},
// 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
}