opentofu/internal/tofu/node_module_variable.go
Christian Mesh 0903aeff58
Split variable evaluation / validation scope (#2199)
Signed-off-by: Christian Mesh <christianmesh1@gmail.com>
2024-12-02 09:18:07 -05:00

243 lines
7.8 KiB
Go

// Copyright (c) The OpenTofu Authors
// SPDX-License-Identifier: MPL-2.0
// Copyright (c) 2023 HashiCorp, Inc.
// SPDX-License-Identifier: MPL-2.0
package tofu
import (
"fmt"
"log"
"github.com/hashicorp/hcl/v2"
"github.com/zclconf/go-cty/cty"
"github.com/opentofu/opentofu/internal/addrs"
"github.com/opentofu/opentofu/internal/configs"
"github.com/opentofu/opentofu/internal/dag"
"github.com/opentofu/opentofu/internal/instances"
"github.com/opentofu/opentofu/internal/lang"
"github.com/opentofu/opentofu/internal/tfdiags"
)
// nodeExpandModuleVariable is the placeholder for an variable that has not yet had
// its module path expanded.
type nodeExpandModuleVariable struct {
Addr addrs.InputVariable
Module addrs.Module
Config *configs.Variable
Expr hcl.Expression
}
var (
_ GraphNodeDynamicExpandable = (*nodeExpandModuleVariable)(nil)
_ GraphNodeReferenceOutside = (*nodeExpandModuleVariable)(nil)
_ GraphNodeReferenceable = (*nodeExpandModuleVariable)(nil)
_ GraphNodeReferencer = (*nodeExpandModuleVariable)(nil)
_ graphNodeTemporaryValue = (*nodeExpandModuleVariable)(nil)
_ graphNodeExpandsInstances = (*nodeExpandModuleVariable)(nil)
)
func (n *nodeExpandModuleVariable) expandsInstances() {}
func (n *nodeExpandModuleVariable) temporaryValue() bool {
return true
}
func (n *nodeExpandModuleVariable) DynamicExpand(ctx EvalContext) (*Graph, error) {
var g Graph
expander := ctx.InstanceExpander()
for _, module := range expander.ExpandModule(n.Module) {
addr := n.Addr.Absolute(module)
o := &nodeModuleVariable{
Addr: addr,
Config: n.Config,
Expr: n.Expr,
ModuleInstance: module,
}
g.Add(o)
}
addRootNodeToGraph(&g)
return &g, nil
}
func (n *nodeExpandModuleVariable) Name() string {
return fmt.Sprintf("%s.%s (expand, input)", n.Module, n.Addr.String())
}
// GraphNodeModulePath
func (n *nodeExpandModuleVariable) ModulePath() addrs.Module {
return n.Module
}
// GraphNodeReferencer
func (n *nodeExpandModuleVariable) References() []*addrs.Reference {
// If we have no value expression, we cannot depend on anything.
if n.Expr == nil {
return nil
}
// Variables in the root don't depend on anything, because their values
// are gathered prior to the graph walk and recorded in the context.
if len(n.Module) == 0 {
return nil
}
// Otherwise, we depend on anything referenced by our value expression.
// We ignore diagnostics here under the assumption that we'll re-eval
// all these things later and catch them then; for our purposes here,
// we only care about valid references.
//
// Due to our GraphNodeReferenceOutside implementation, the addresses
// returned by this function are interpreted in the _parent_ module from
// where our associated variable was declared, which is correct because
// our value expression is assigned within a "module" block in the parent
// module.
refs, _ := lang.ReferencesInExpr(addrs.ParseRef, n.Expr)
return refs
}
// GraphNodeReferenceOutside implementation
func (n *nodeExpandModuleVariable) ReferenceOutside() (selfPath, referencePath addrs.Module) {
return n.Module, n.Module.Parent()
}
// GraphNodeReferenceable
func (n *nodeExpandModuleVariable) ReferenceableAddrs() []addrs.Referenceable {
return []addrs.Referenceable{n.Addr}
}
// nodeModuleVariable represents a module variable input during
// the apply step.
type nodeModuleVariable struct {
Addr addrs.AbsInputVariableInstance
Config *configs.Variable // Config is the var in the config
Expr hcl.Expression // Expr is the value expression given in the call
// ModuleInstance in order to create the appropriate context for evaluating
// ModuleCallArguments, ex. so count.index and each.key can resolve
ModuleInstance addrs.ModuleInstance
}
// Ensure that we are implementing all of the interfaces we think we are
// implementing.
var (
_ GraphNodeModuleInstance = (*nodeModuleVariable)(nil)
_ GraphNodeExecutable = (*nodeModuleVariable)(nil)
_ graphNodeTemporaryValue = (*nodeModuleVariable)(nil)
_ dag.GraphNodeDotter = (*nodeModuleVariable)(nil)
)
func (n *nodeModuleVariable) temporaryValue() bool {
return true
}
func (n *nodeModuleVariable) Name() string {
return n.Addr.String() + "(input)"
}
// GraphNodeModuleInstance
func (n *nodeModuleVariable) Path() addrs.ModuleInstance {
// We execute in the parent scope (above our own module) because
// expressions in our value are resolved in that context.
return n.Addr.Module.Parent()
}
// GraphNodeModulePath
func (n *nodeModuleVariable) ModulePath() addrs.Module {
return n.Addr.Module.Module()
}
// GraphNodeExecutable
func (n *nodeModuleVariable) Execute(ctx EvalContext, op walkOperation) (diags tfdiags.Diagnostics) {
log.Printf("[TRACE] nodeModuleVariable: evaluating %s", n.Addr)
val, err := n.evalModuleVariable(ctx, op == walkValidate)
diags = diags.Append(err)
if diags.HasErrors() {
return diags
}
// Set values for arguments of a child module call, for later retrieval
// during expression evaluation.
_, call := n.Addr.Module.CallInstance()
ctx.SetModuleCallArgument(call, n.Addr.Variable, val)
return diags
}
// dag.GraphNodeDotter impl.
func (n *nodeModuleVariable) DotNode(name string, opts *dag.DotOpts) *dag.DotNode {
return &dag.DotNode{
Name: name,
Attrs: map[string]string{
"label": n.Name(),
"shape": "note",
},
}
}
// evalModuleVariable produces the value for a particular variable as will
// be used by a child module instance.
//
// The result is written into a map, with its key set to the local name of the
// variable, disregarding the module instance address. A map is returned instead
// of a single value as a result of trying to be convenient for use with
// EvalContext.SetModuleCallArguments, which expects a map to merge in with any
// existing arguments.
//
// validateOnly indicates that this evaluation is only for config
// validation, and we will not have any expansion module instance
// repetition data.
func (n *nodeModuleVariable) evalModuleVariable(ctx EvalContext, validateOnly bool) (cty.Value, error) {
var diags tfdiags.Diagnostics
var givenVal cty.Value
var errSourceRange tfdiags.SourceRange
if expr := n.Expr; expr != nil {
var moduleInstanceRepetitionData instances.RepetitionData
switch {
case validateOnly:
// the instance expander does not track unknown expansion values, so we
// have to assume all RepetitionData is unknown.
moduleInstanceRepetitionData = instances.RepetitionData{
CountIndex: cty.UnknownVal(cty.Number),
EachKey: cty.UnknownVal(cty.String),
EachValue: cty.DynamicVal,
}
default:
// Get the repetition data for this module instance,
// so we can create the appropriate scope for evaluating our expression
moduleInstanceRepetitionData = ctx.InstanceExpander().GetModuleInstanceRepetitionData(n.ModuleInstance)
}
scope := ctx.EvaluationScope(nil, nil, moduleInstanceRepetitionData)
val, moreDiags := scope.EvalExpr(expr, cty.DynamicPseudoType)
diags = diags.Append(moreDiags)
if moreDiags.HasErrors() {
return cty.DynamicVal, diags.ErrWithWarnings()
}
givenVal = val
errSourceRange = tfdiags.SourceRangeFromHCL(expr.Range())
} else {
// We'll use cty.NilVal to represent the variable not being set at all.
givenVal = cty.NilVal
errSourceRange = tfdiags.SourceRangeFromHCL(n.Config.DeclRange) // we use the declaration range as a fallback for an undefined variable
}
// We construct a synthetic InputValue here to pretend as if this were
// a root module variable set from outside, just as a convenience so we
// can reuse the InputValue type for this.
rawVal := &InputValue{
Value: givenVal,
SourceType: ValueFromConfig,
SourceRange: errSourceRange,
}
finalVal, moreDiags := prepareFinalInputVariableValue(n.Addr, rawVal, n.Config)
diags = diags.Append(moreDiags)
return finalVal, diags.ErrWithWarnings()
}