opentofu/terraform/node_module_expand.go
James Bardin 6f9d2c51e2 you cannot refer to destroy nodes
Outputs and locals cannot refer to destroy nodes. Since those nodes
types do not have different ordering for create and destroy operations,
connecting them directly to destroy nodes can cause cycles.
2020-07-20 09:49:47 -04:00

291 lines
8.0 KiB
Go

package terraform
import (
"log"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/dag"
"github.com/hashicorp/terraform/lang"
"github.com/hashicorp/terraform/tfdiags"
)
type ConcreteModuleNodeFunc func(n *nodeExpandModule) dag.Vertex
// nodeExpandModule represents a module call in the configuration that
// might expand into multiple module instances depending on how it is
// configured.
type nodeExpandModule struct {
Addr addrs.Module
Config *configs.Module
ModuleCall *configs.ModuleCall
}
var (
_ GraphNodeEvalable = (*nodeExpandModule)(nil)
_ GraphNodeReferencer = (*nodeExpandModule)(nil)
_ GraphNodeReferenceOutside = (*nodeExpandModule)(nil)
_ graphNodeExpandsInstances = (*nodeExpandModule)(nil)
)
func (n *nodeExpandModule) expandsInstances() {}
func (n *nodeExpandModule) Name() string {
return n.Addr.String() + " (expand)"
}
// GraphNodeModulePath implementation
func (n *nodeExpandModule) ModulePath() addrs.Module {
return n.Addr
}
// GraphNodeReferencer implementation
func (n *nodeExpandModule) References() []*addrs.Reference {
var refs []*addrs.Reference
if n.ModuleCall == nil {
return nil
}
refs = append(refs, n.DependsOn()...)
// Expansion only uses the count and for_each expressions, so this
// particular graph node only refers to those.
// Individual variable values in the module call definition might also
// refer to other objects, but that's handled by
// NodeApplyableModuleVariable.
//
// Because our Path method returns the module instance that contains
// our call, these references will be correctly interpreted as being
// in the calling module's namespace, not the namespaces of any of the
// child module instances we might expand to during our evaluation.
if n.ModuleCall.Count != nil {
countRefs, _ := lang.ReferencesInExpr(n.ModuleCall.Count)
refs = append(refs, countRefs...)
}
if n.ModuleCall.ForEach != nil {
forEachRefs, _ := lang.ReferencesInExpr(n.ModuleCall.ForEach)
refs = append(refs, forEachRefs...)
}
return refs
}
func (n *nodeExpandModule) DependsOn() []*addrs.Reference {
if n.ModuleCall == nil {
return nil
}
var refs []*addrs.Reference
for _, traversal := range n.ModuleCall.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
}
refs = append(refs, ref)
}
return refs
}
// GraphNodeReferenceOutside
func (n *nodeExpandModule) ReferenceOutside() (selfPath, referencePath addrs.Module) {
return n.Addr, n.Addr.Parent()
}
// GraphNodeEvalable
func (n *nodeExpandModule) EvalTree() EvalNode {
return &evalPrepareModuleExpansion{
Addr: n.Addr,
Config: n.Config,
ModuleCall: n.ModuleCall,
}
}
// nodeCloseModule represents an expanded module during apply, and is visited
// after all other module instance nodes. This node will depend on all module
// instance resource and outputs, and anything depending on the module should
// wait on this node.
// Besides providing a root node for dependency ordering, nodeCloseModule also
// cleans up state after all the module nodes have been evaluated, removing
// empty resources and modules from the state.
type nodeCloseModule struct {
Addr addrs.Module
}
var (
_ GraphNodeReferenceable = (*nodeCloseModule)(nil)
_ GraphNodeReferenceOutside = (*nodeCloseModule)(nil)
)
func (n *nodeCloseModule) ModulePath() addrs.Module {
return n.Addr
}
func (n *nodeCloseModule) ReferenceOutside() (selfPath, referencePath addrs.Module) {
return n.Addr.Parent(), n.Addr
}
func (n *nodeCloseModule) ReferenceableAddrs() []addrs.Referenceable {
_, call := n.Addr.Call()
return []addrs.Referenceable{
call,
}
}
func (n *nodeCloseModule) Name() string {
if len(n.Addr) == 0 {
return "root"
}
return n.Addr.String() + " (close)"
}
func (n *nodeCloseModule) EvalTree() EvalNode {
return &EvalSequence{
Nodes: []EvalNode{
&EvalOpFilter{
Ops: []walkOperation{walkApply, walkDestroy},
Node: &evalCloseModule{
Addr: n.Addr,
},
},
},
}
}
type evalCloseModule struct {
Addr addrs.Module
}
func (n *evalCloseModule) Eval(ctx EvalContext) (interface{}, error) {
// We need the full, locked state, because SyncState does not provide a way to
// transact over multiple module instances at the moment.
state := ctx.State().Lock()
defer ctx.State().Unlock()
for modKey, mod := range state.Modules {
if !n.Addr.Equal(mod.Addr.Module()) {
continue
}
// clean out any empty resources
for resKey, res := range mod.Resources {
if len(res.Instances) == 0 {
delete(mod.Resources, resKey)
}
}
// empty child modules are always removed
if len(mod.Resources) == 0 && !mod.Addr.IsRoot() {
delete(state.Modules, modKey)
}
}
return nil, nil
}
// evalPrepareModuleExpansion is an EvalNode implementation
// that sets the count or for_each on the instance expander
type evalPrepareModuleExpansion struct {
Addr addrs.Module
Config *configs.Module
ModuleCall *configs.ModuleCall
}
func (n *evalPrepareModuleExpansion) Eval(ctx EvalContext) (interface{}, error) {
expander := ctx.InstanceExpander()
_, call := n.Addr.Call()
// nodeExpandModule itself does not have visibility into how its ancestors
// were expanded, so we use the expander here to provide all possible paths
// to our module, and register module instances with each of them.
for _, module := range expander.ExpandModule(n.Addr.Parent()) {
ctx = ctx.WithPath(module)
switch {
case n.ModuleCall.Count != nil:
count, diags := evaluateCountExpression(n.ModuleCall.Count, ctx)
if diags.HasErrors() {
return nil, diags.Err()
}
expander.SetModuleCount(module, call, count)
case n.ModuleCall.ForEach != nil:
forEach, diags := evaluateForEachExpression(n.ModuleCall.ForEach, ctx)
if diags.HasErrors() {
return nil, diags.Err()
}
expander.SetModuleForEach(module, call, forEach)
default:
expander.SetModuleSingle(module, call)
}
}
return nil, nil
}
// nodeValidateModule wraps a nodeExpand module for validation, ensuring that
// no expansion is attempted during evaluation, when count and for_each
// expressions may not be known.
type nodeValidateModule struct {
nodeExpandModule
}
// GraphNodeEvalable
func (n *nodeValidateModule) EvalTree() EvalNode {
return &evalValidateModule{
Addr: n.Addr,
Config: n.Config,
ModuleCall: n.ModuleCall,
}
}
type evalValidateModule struct {
Addr addrs.Module
Config *configs.Module
ModuleCall *configs.ModuleCall
}
func (n *evalValidateModule) Eval(ctx EvalContext) (interface{}, error) {
_, call := n.Addr.Call()
var diags tfdiags.Diagnostics
expander := ctx.InstanceExpander()
// Modules all evaluate to single instances during validation, only to
// create a proper context within which to evaluate. All parent modules
// will be a single instance, but still get our address in the expected
// manner anyway to ensure they've been registered correctly.
for _, module := range expander.ExpandModule(n.Addr.Parent()) {
ctx = ctx.WithPath(module)
// Validate our for_each and count expressions at a basic level
// We skip validation on known, because there will be unknown values before
// a full expansion, presuming these errors will be caught in later steps
switch {
case n.ModuleCall.Count != nil:
_, countDiags := evaluateCountExpressionValue(n.ModuleCall.Count, ctx)
diags = diags.Append(countDiags)
case n.ModuleCall.ForEach != nil:
_, forEachDiags := evaluateForEachExpressionValue(n.ModuleCall.ForEach, ctx)
diags = diags.Append(forEachDiags)
}
diags = diags.Append(validateDependsOn(ctx, n.ModuleCall.DependsOn))
// now set our own mode to single
expander.SetModuleSingle(module, call)
}
if diags.HasErrors() {
return nil, diags.ErrWithWarnings()
}
return nil, nil
}