opentofu/terraform/node_resource_abstract.go
James Bardin b3fc0dab94 use addrs.ConfigResource for dependency tracking
We can't get module instances during transformation, so we need to
reduce the Dependencies to using `addrs.ConfigResource` for now.
2020-03-25 17:03:06 -04:00

418 lines
14 KiB
Go

package terraform
import (
"fmt"
"log"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/configs/configschema"
"github.com/hashicorp/terraform/dag"
"github.com/hashicorp/terraform/lang"
"github.com/hashicorp/terraform/states"
)
// ConcreteResourceNodeFunc is a callback type used to convert an
// abstract resource to a concrete one of some type.
type ConcreteResourceNodeFunc func(*NodeAbstractResource) dag.Vertex
// GraphNodeConfigResource is implemented by any nodes that represent a resource.
// The type of operation cannot be assumed, only that this node represents
// the given resource.
type GraphNodeConfigResource interface {
ResourceAddr() addrs.ConfigResource
}
// ConcreteResourceInstanceNodeFunc is a callback type used to convert an
// abstract resource instance to a concrete one of some type.
type ConcreteResourceInstanceNodeFunc func(*NodeAbstractResourceInstance) dag.Vertex
// GraphNodeResourceInstance is implemented by any nodes that represent
// a resource instance. A single resource may have multiple instances if,
// for example, the "count" or "for_each" argument is used for it in
// configuration.
type GraphNodeResourceInstance interface {
ResourceInstanceAddr() addrs.AbsResourceInstance
// StateDependencies returns any inter-resource dependencies that are
// stored in the state.
StateDependencies() []addrs.ConfigResource
}
// NodeAbstractResource represents a resource that has no associated
// operations. It registers all the interfaces for a resource that common
// across multiple operation types.
type NodeAbstractResource struct {
Addr addrs.ConfigResource
// The fields below will be automatically set using the Attach
// interfaces if you're running those transforms, but also be explicitly
// set if you already have that information.
Schema *configschema.Block // Schema for processing the configuration body
SchemaVersion uint64 // Schema version of "Schema", as decided by the provider
Config *configs.Resource // Config is the resource in the config
// ProviderMetas is the provider_meta configs for the module this resource belongs to
ProviderMetas map[addrs.Provider]*configs.ProviderMeta
ProvisionerSchemas map[string]*configschema.Block
Targets []addrs.Targetable // Set from GraphNodeTargetable
// The address of the provider this resource will use
ResolvedProvider addrs.AbsProviderConfig
}
var (
_ GraphNodeReferenceable = (*NodeAbstractResource)(nil)
_ GraphNodeReferencer = (*NodeAbstractResource)(nil)
_ GraphNodeProviderConsumer = (*NodeAbstractResource)(nil)
_ GraphNodeProvisionerConsumer = (*NodeAbstractResource)(nil)
_ GraphNodeConfigResource = (*NodeAbstractResource)(nil)
_ GraphNodeAttachResourceConfig = (*NodeAbstractResource)(nil)
_ GraphNodeAttachResourceSchema = (*NodeAbstractResource)(nil)
_ GraphNodeAttachProvisionerSchema = (*NodeAbstractResource)(nil)
_ GraphNodeAttachProviderMetaConfigs = (*NodeAbstractResource)(nil)
_ GraphNodeTargetable = (*NodeAbstractResource)(nil)
_ dag.GraphNodeDotter = (*NodeAbstractResource)(nil)
)
// NewNodeAbstractResource creates an abstract resource graph node for
// the given absolute resource address.
func NewNodeAbstractResource(addr addrs.ConfigResource) *NodeAbstractResource {
return &NodeAbstractResource{
Addr: addr,
}
}
// NodeAbstractResourceInstance represents a resource instance with no
// associated operations. It embeds NodeAbstractResource but additionally
// contains an instance key, used to identify one of potentially many
// instances that were created from a resource in configuration, e.g. using
// the "count" or "for_each" arguments.
type NodeAbstractResourceInstance struct {
NodeAbstractResource
Addr addrs.AbsResourceInstance
// The fields below will be automatically set using the Attach
// interfaces if you're running those transforms, but also be explicitly
// set if you already have that information.
ResourceState *states.Resource
Dependencies []addrs.ConfigResource
}
var (
_ GraphNodeModuleInstance = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeReferenceable = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeReferencer = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeProviderConsumer = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeProvisionerConsumer = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeConfigResource = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeResourceInstance = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeAttachResourceState = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeAttachResourceConfig = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeAttachResourceSchema = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeAttachProvisionerSchema = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeAttachProviderMetaConfigs = (*NodeAbstractResourceInstance)(nil)
_ GraphNodeTargetable = (*NodeAbstractResourceInstance)(nil)
_ dag.GraphNodeDotter = (*NodeAbstractResourceInstance)(nil)
)
// NewNodeAbstractResourceInstance creates an abstract resource instance graph
// node for the given absolute resource instance address.
func NewNodeAbstractResourceInstance(addr addrs.AbsResourceInstance) *NodeAbstractResourceInstance {
// Due to the fact that we embed NodeAbstractResource, the given address
// actually ends up split between the resource address in the embedded
// object and the InstanceKey field in our own struct. The
// ResourceInstanceAddr method will stick these back together again on
// request.
r := NewNodeAbstractResource(addr.ContainingResource().Config())
return &NodeAbstractResourceInstance{
NodeAbstractResource: *r,
Addr: addr,
}
}
func (n *NodeAbstractResource) Name() string {
return n.ResourceAddr().String()
}
func (n *NodeAbstractResourceInstance) Name() string {
return n.ResourceInstanceAddr().String()
}
func (n *NodeAbstractResourceInstance) Path() addrs.ModuleInstance {
return n.Addr.Module
}
// GraphNodeModulePath
func (n *NodeAbstractResource) ModulePath() addrs.Module {
return n.Addr.Module
}
// GraphNodeReferenceable
func (n *NodeAbstractResource) ReferenceableAddrs() []addrs.Referenceable {
return []addrs.Referenceable{n.Addr.Resource}
}
// GraphNodeReferenceable
func (n *NodeAbstractResourceInstance) ReferenceableAddrs() []addrs.Referenceable {
addr := n.ResourceInstanceAddr()
return []addrs.Referenceable{
addr.Resource,
// A resource instance can also be referenced by the address of its
// containing resource, so that e.g. a reference to aws_instance.foo
// would match both aws_instance.foo[0] and aws_instance.foo[1].
addr.ContainingResource().Resource,
}
}
// GraphNodeReferencer
func (n *NodeAbstractResource) References() []*addrs.Reference {
// If we have a config then we prefer to use that.
if c := n.Config; c != nil {
var result []*addrs.Reference
for _, traversal := range c.DependsOn {
ref, diags := addrs.ParseRef(traversal)
if diags.HasErrors() {
// We ignore this here, because this isn't a suitable place to return
// errors. This situation should be caught and rejected during
// validation.
log.Printf("[ERROR] Can't parse %#v from depends_on as reference: %s", traversal, diags.Err())
continue
}
result = append(result, ref)
}
if n.Schema == nil {
// Should never happens, but we'll log if it does so that we can
// see this easily when debugging.
log.Printf("[WARN] no schema is attached to %s, so config references cannot be detected", n.Name())
}
refs, _ := lang.ReferencesInExpr(c.Count)
result = append(result, refs...)
refs, _ = lang.ReferencesInExpr(c.ForEach)
result = append(result, refs...)
refs, _ = lang.ReferencesInBlock(c.Config, n.Schema)
result = append(result, refs...)
if c.Managed != nil {
if c.Managed.Connection != nil {
refs, _ = lang.ReferencesInBlock(c.Managed.Connection.Config, connectionBlockSupersetSchema)
result = append(result, refs...)
}
for _, p := range c.Managed.Provisioners {
if p.When != configs.ProvisionerWhenCreate {
continue
}
if p.Connection != nil {
refs, _ = lang.ReferencesInBlock(p.Connection.Config, connectionBlockSupersetSchema)
result = append(result, refs...)
}
schema := n.ProvisionerSchemas[p.Type]
if schema == nil {
log.Printf("[WARN] no schema for provisioner %q is attached to %s, so provisioner block references cannot be detected", p.Type, n.Name())
}
refs, _ = lang.ReferencesInBlock(p.Config, schema)
result = append(result, refs...)
}
}
return result
}
// Otherwise, we have no references.
return nil
}
// GraphNodeReferencer
func (n *NodeAbstractResourceInstance) References() []*addrs.Reference {
// If we have a configuration attached then we'll delegate to our
// embedded abstract resource, which knows how to extract dependencies
// from configuration. If there is no config, then the dependencies will
// be connected during destroy from those stored in the state.
if n.Config != nil {
if n.Schema == nil {
// We'll produce a log message about this out here so that
// we can include the full instance address, since the equivalent
// message in NodeAbstractResource.References cannot see it.
log.Printf("[WARN] no schema is attached to %s, so config references cannot be detected", n.Name())
return nil
}
return n.NodeAbstractResource.References()
}
// If we have neither config nor state then we have no references.
return nil
}
// converts an instance address to the legacy dotted notation
func dottedInstanceAddr(tr addrs.ResourceInstance) string {
// The legacy state format uses dot-separated instance keys,
// rather than bracketed as in our modern syntax.
var suffix string
switch tk := tr.Key.(type) {
case addrs.IntKey:
suffix = fmt.Sprintf(".%d", int(tk))
case addrs.StringKey:
suffix = fmt.Sprintf(".%s", string(tk))
}
return tr.Resource.String() + suffix
}
// StateDependencies returns the dependencies saved in the state.
func (n *NodeAbstractResourceInstance) StateDependencies() []addrs.ConfigResource {
if rs := n.ResourceState; rs != nil {
if s := rs.Instance(n.Addr.Resource.Key); s != nil {
if s.Current != nil {
return s.Current.Dependencies
}
}
}
return nil
}
func (n *NodeAbstractResource) SetProvider(p addrs.AbsProviderConfig) {
n.ResolvedProvider = p
}
// GraphNodeProviderConsumer
func (n *NodeAbstractResource) ProvidedBy() (addrs.ProviderConfig, bool) {
// If we have a config we prefer that above all else
if n.Config != nil {
relAddr := n.Config.ProviderConfigAddr()
return addrs.LocalProviderConfig{
LocalName: relAddr.LocalName,
Alias: relAddr.Alias,
}, false
}
// No provider configuration found; return a default address
return addrs.AbsProviderConfig{
Provider: n.Provider(),
Module: n.ModulePath(),
}, false
}
// GraphNodeProviderConsumer
func (n *NodeAbstractResource) Provider() addrs.Provider {
if n.Config != nil {
return n.Config.Provider
}
// FIXME: this will be a default provider
return addrs.NewLegacyProvider(n.Addr.Resource.ImpliedProvider())
}
// GraphNodeProviderConsumer
func (n *NodeAbstractResourceInstance) ProvidedBy() (addrs.ProviderConfig, bool) {
// If we have a config we prefer that above all else
if n.Config != nil {
relAddr := n.Config.ProviderConfigAddr()
return addrs.LocalProviderConfig{
LocalName: relAddr.LocalName,
Alias: relAddr.Alias,
}, false
}
// If we have state, then we will use the provider from there
if n.ResourceState != nil {
// An address from the state must match exactly, since we must ensure
// we refresh/destroy a resource with the same provider configuration
// that created it.
return n.ResourceState.ProviderConfig, true
}
// No provider configuration found; return a default address
return addrs.AbsProviderConfig{
Provider: n.Provider(),
Module: n.ModulePath(),
}, false
}
// GraphNodeProviderConsumer
func (n *NodeAbstractResourceInstance) Provider() addrs.Provider {
if n.Config != nil {
return n.Config.Provider
}
// FIXME: this will be a default provider
return addrs.NewLegacyProvider(n.Addr.Resource.ContainingResource().ImpliedProvider())
}
// GraphNodeProvisionerConsumer
func (n *NodeAbstractResource) ProvisionedBy() []string {
// If we have no configuration, then we have no provisioners
if n.Config == nil || n.Config.Managed == nil {
return nil
}
// Build the list of provisioners we need based on the configuration.
// It is okay to have duplicates here.
result := make([]string, len(n.Config.Managed.Provisioners))
for i, p := range n.Config.Managed.Provisioners {
result[i] = p.Type
}
return result
}
// GraphNodeProvisionerConsumer
func (n *NodeAbstractResource) AttachProvisionerSchema(name string, schema *configschema.Block) {
if n.ProvisionerSchemas == nil {
n.ProvisionerSchemas = make(map[string]*configschema.Block)
}
n.ProvisionerSchemas[name] = schema
}
// GraphNodeResource
func (n *NodeAbstractResource) ResourceAddr() addrs.ConfigResource {
return n.Addr
}
// GraphNodeResourceInstance
func (n *NodeAbstractResourceInstance) ResourceInstanceAddr() addrs.AbsResourceInstance {
return n.Addr
}
// GraphNodeTargetable
func (n *NodeAbstractResource) SetTargets(targets []addrs.Targetable) {
n.Targets = targets
}
// GraphNodeAttachResourceState
func (n *NodeAbstractResourceInstance) AttachResourceState(s *states.Resource) {
n.ResourceState = s
}
// GraphNodeAttachResourceConfig
func (n *NodeAbstractResource) AttachResourceConfig(c *configs.Resource) {
n.Config = c
}
// GraphNodeAttachResourceSchema impl
func (n *NodeAbstractResource) AttachResourceSchema(schema *configschema.Block, version uint64) {
n.Schema = schema
n.SchemaVersion = version
}
// GraphNodeAttachProviderMetaConfigs impl
func (n *NodeAbstractResource) AttachProviderMetaConfigs(c map[addrs.Provider]*configs.ProviderMeta) {
n.ProviderMetas = c
}
// GraphNodeDotter impl.
func (n *NodeAbstractResource) DotNode(name string, opts *dag.DotOpts) *dag.DotNode {
return &dag.DotNode{
Name: name,
Attrs: map[string]string{
"label": n.Name(),
"shape": "box",
},
}
}