474 lines
16 KiB
Go
474 lines
16 KiB
Go
package lang
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import (
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"fmt"
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"log"
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"strconv"
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"github.com/hashicorp/hcl/v2"
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"github.com/hashicorp/hcl/v2/ext/dynblock"
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"github.com/hashicorp/hcl/v2/hcldec"
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"github.com/hashicorp/terraform/addrs"
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"github.com/hashicorp/terraform/configs/configschema"
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"github.com/hashicorp/terraform/lang/blocktoattr"
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"github.com/hashicorp/terraform/tfdiags"
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"github.com/zclconf/go-cty/cty"
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"github.com/zclconf/go-cty/cty/convert"
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)
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// ExpandBlock expands any "dynamic" blocks present in the given body. The
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// result is a body with those blocks expanded, ready to be evaluated with
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// EvalBlock.
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//
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// If the returned diagnostics contains errors then the result may be
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// incomplete or invalid.
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func (s *Scope) ExpandBlock(body hcl.Body, schema *configschema.Block) (hcl.Body, tfdiags.Diagnostics) {
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spec := schema.DecoderSpec()
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traversals := dynblock.ExpandVariablesHCLDec(body, spec)
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refs, diags := References(traversals)
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ctx, ctxDiags := s.EvalContext(refs)
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diags = diags.Append(ctxDiags)
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return dynblock.Expand(body, ctx), diags
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}
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// EvalBlock evaluates the given body using the given block schema and returns
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// a cty object value representing its contents. The type of the result conforms
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// to the implied type of the given schema.
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//
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// This function does not automatically expand "dynamic" blocks within the
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// body. If that is desired, first call the ExpandBlock method to obtain
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// an expanded body to pass to this method.
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//
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// If the returned diagnostics contains errors then the result may be
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// incomplete or invalid.
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func (s *Scope) EvalBlock(body hcl.Body, schema *configschema.Block) (cty.Value, tfdiags.Diagnostics) {
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spec := schema.DecoderSpec()
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refs, diags := ReferencesInBlock(body, schema)
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ctx, ctxDiags := s.EvalContext(refs)
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diags = diags.Append(ctxDiags)
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if diags.HasErrors() {
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// We'll stop early if we found problems in the references, because
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// it's likely evaluation will produce redundant copies of the same errors.
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return cty.UnknownVal(schema.ImpliedType()), diags
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}
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// HACK: In order to remain compatible with some assumptions made in
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// Terraform v0.11 and earlier about the approximate equivalence of
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// attribute vs. block syntax, we do a just-in-time fixup here to allow
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// any attribute in the schema that has a list-of-objects or set-of-objects
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// kind to potentially be populated instead by one or more nested blocks
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// whose type is the attribute name.
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body = blocktoattr.FixUpBlockAttrs(body, schema)
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val, evalDiags := hcldec.Decode(body, spec, ctx)
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diags = diags.Append(evalDiags)
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return val, diags
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}
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// EvalExpr evaluates a single expression in the receiving context and returns
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// the resulting value. The value will be converted to the given type before
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// it is returned if possible, or else an error diagnostic will be produced
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// describing the conversion error.
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//
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// Pass an expected type of cty.DynamicPseudoType to skip automatic conversion
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// and just obtain the returned value directly.
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//
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// If the returned diagnostics contains errors then the result may be
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// incomplete, but will always be of the requested type.
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func (s *Scope) EvalExpr(expr hcl.Expression, wantType cty.Type) (cty.Value, tfdiags.Diagnostics) {
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refs, diags := ReferencesInExpr(expr)
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ctx, ctxDiags := s.EvalContext(refs)
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diags = diags.Append(ctxDiags)
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if diags.HasErrors() {
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// We'll stop early if we found problems in the references, because
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// it's likely evaluation will produce redundant copies of the same errors.
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return cty.UnknownVal(wantType), diags
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}
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val, evalDiags := expr.Value(ctx)
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diags = diags.Append(evalDiags)
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if wantType != cty.DynamicPseudoType {
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var convErr error
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val, convErr = convert.Convert(val, wantType)
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if convErr != nil {
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val = cty.UnknownVal(wantType)
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Incorrect value type",
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Detail: fmt.Sprintf("Invalid expression value: %s.", tfdiags.FormatError(convErr)),
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Subject: expr.Range().Ptr(),
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})
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}
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}
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return val, diags
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}
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// EvalReference evaluates the given reference in the receiving scope and
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// returns the resulting value. The value will be converted to the given type before
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// it is returned if possible, or else an error diagnostic will be produced
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// describing the conversion error.
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//
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// Pass an expected type of cty.DynamicPseudoType to skip automatic conversion
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// and just obtain the returned value directly.
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//
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// If the returned diagnostics contains errors then the result may be
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// incomplete, but will always be of the requested type.
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func (s *Scope) EvalReference(ref *addrs.Reference, wantType cty.Type) (cty.Value, tfdiags.Diagnostics) {
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var diags tfdiags.Diagnostics
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// We cheat a bit here and just build an EvalContext for our requested
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// reference with the "self" address overridden, and then pull the "self"
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// result out of it to return.
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ctx, ctxDiags := s.evalContext([]*addrs.Reference{ref}, ref.Subject)
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diags = diags.Append(ctxDiags)
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val := ctx.Variables["self"]
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if val == cty.NilVal {
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val = cty.DynamicVal
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}
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var convErr error
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val, convErr = convert.Convert(val, wantType)
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if convErr != nil {
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val = cty.UnknownVal(wantType)
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Incorrect value type",
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Detail: fmt.Sprintf("Invalid expression value: %s.", tfdiags.FormatError(convErr)),
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Subject: ref.SourceRange.ToHCL().Ptr(),
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})
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}
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return val, diags
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}
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// EvalContext constructs a HCL expression evaluation context whose variable
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// scope contains sufficient values to satisfy the given set of references.
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//
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// Most callers should prefer to use the evaluation helper methods that
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// this type offers, but this is here for less common situations where the
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// caller will handle the evaluation calls itself.
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func (s *Scope) EvalContext(refs []*addrs.Reference) (*hcl.EvalContext, tfdiags.Diagnostics) {
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return s.evalContext(refs, s.SelfAddr)
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}
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func (s *Scope) evalContext(refs []*addrs.Reference, selfAddr addrs.Referenceable) (*hcl.EvalContext, tfdiags.Diagnostics) {
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if s == nil {
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panic("attempt to construct EvalContext for nil Scope")
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}
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var diags tfdiags.Diagnostics
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vals := make(map[string]cty.Value)
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funcs := s.Functions()
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ctx := &hcl.EvalContext{
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Variables: vals,
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Functions: funcs,
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}
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if len(refs) == 0 {
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// Easy path for common case where there are no references at all.
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return ctx, diags
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}
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// First we'll do static validation of the references. This catches things
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// early that might otherwise not get caught due to unknown values being
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// present in the scope during planning.
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if staticDiags := s.Data.StaticValidateReferences(refs, selfAddr); staticDiags.HasErrors() {
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diags = diags.Append(staticDiags)
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return ctx, diags
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}
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// The reference set we are given has not been de-duped, and so there can
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// be redundant requests in it for two reasons:
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// - The same item is referenced multiple times
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// - Both an item and that item's container are separately referenced.
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// We will still visit every reference here and ask our data source for
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// it, since that allows us to gather a full set of any errors and
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// warnings, but once we've gathered all the data we'll then skip anything
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// that's redundant in the process of populating our values map.
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dataResources := map[string]map[string]cty.Value{}
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managedResources := map[string]map[string]cty.Value{}
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wholeModules := map[string]map[addrs.InstanceKey]cty.Value{}
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moduleOutputs := map[string]map[addrs.InstanceKey]map[string]cty.Value{}
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inputVariables := map[string]cty.Value{}
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localValues := map[string]cty.Value{}
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pathAttrs := map[string]cty.Value{}
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terraformAttrs := map[string]cty.Value{}
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countAttrs := map[string]cty.Value{}
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forEachAttrs := map[string]cty.Value{}
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var self cty.Value
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for _, ref := range refs {
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rng := ref.SourceRange
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rawSubj := ref.Subject
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if rawSubj == addrs.Self {
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if selfAddr == nil {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: `Invalid "self" reference`,
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// This detail message mentions some current practice that
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// this codepath doesn't really "know about". If the "self"
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// object starts being supported in more contexts later then
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// we'll need to adjust this message.
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Detail: `The "self" object is not available in this context. This object can be used only in resource provisioner and connection blocks.`,
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Subject: ref.SourceRange.ToHCL().Ptr(),
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})
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continue
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}
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if selfAddr == addrs.Self {
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// Programming error: the self address cannot alias itself.
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panic("scope SelfAddr attempting to alias itself")
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}
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// self can only be used within a resource instance
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subj := selfAddr.(addrs.ResourceInstance)
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val, valDiags := normalizeRefValue(s.Data.GetResource(subj.ContainingResource(), rng))
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diags = diags.Append(valDiags)
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// Self is an exception in that it must always resolve to a
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// particular instance. We will still insert the full resource into
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// the context below.
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switch k := subj.Key.(type) {
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case addrs.IntKey:
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self = val.Index(cty.NumberIntVal(int64(k)))
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case addrs.StringKey:
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self = val.Index(cty.StringVal(string(k)))
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default:
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self = val
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}
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continue
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}
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// This type switch must cover all of the "Referenceable" implementations
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// in package addrs, however we are removing the possibility of
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// ResourceInstance beforehand.
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if addr, ok := rawSubj.(addrs.ResourceInstance); ok {
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rawSubj = addr.ContainingResource()
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}
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switch subj := rawSubj.(type) {
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case addrs.Resource:
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var into map[string]map[string]cty.Value
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switch subj.Mode {
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case addrs.ManagedResourceMode:
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into = managedResources
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case addrs.DataResourceMode:
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into = dataResources
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default:
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panic(fmt.Errorf("unsupported ResourceMode %s", subj.Mode))
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}
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val, valDiags := normalizeRefValue(s.Data.GetResource(subj, rng))
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diags = diags.Append(valDiags)
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r := subj
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if into[r.Type] == nil {
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into[r.Type] = make(map[string]cty.Value)
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}
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into[r.Type][r.Name] = val
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case addrs.ModuleCallInstance:
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val, valDiags := normalizeRefValue(s.Data.GetModuleInstance(subj, rng))
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diags = diags.Append(valDiags)
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if wholeModules[subj.Call.Name] == nil {
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wholeModules[subj.Call.Name] = make(map[addrs.InstanceKey]cty.Value)
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}
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wholeModules[subj.Call.Name][subj.Key] = val
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case addrs.ModuleCallOutput:
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val, valDiags := normalizeRefValue(s.Data.GetModuleInstanceOutput(subj, rng))
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diags = diags.Append(valDiags)
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callName := subj.Call.Call.Name
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callKey := subj.Call.Key
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if moduleOutputs[callName] == nil {
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moduleOutputs[callName] = make(map[addrs.InstanceKey]map[string]cty.Value)
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}
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if moduleOutputs[callName][callKey] == nil {
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moduleOutputs[callName][callKey] = make(map[string]cty.Value)
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}
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moduleOutputs[callName][callKey][subj.Name] = val
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case addrs.InputVariable:
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val, valDiags := normalizeRefValue(s.Data.GetInputVariable(subj, rng))
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diags = diags.Append(valDiags)
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inputVariables[subj.Name] = val
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case addrs.LocalValue:
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val, valDiags := normalizeRefValue(s.Data.GetLocalValue(subj, rng))
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diags = diags.Append(valDiags)
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localValues[subj.Name] = val
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case addrs.PathAttr:
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val, valDiags := normalizeRefValue(s.Data.GetPathAttr(subj, rng))
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diags = diags.Append(valDiags)
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pathAttrs[subj.Name] = val
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case addrs.TerraformAttr:
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val, valDiags := normalizeRefValue(s.Data.GetTerraformAttr(subj, rng))
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diags = diags.Append(valDiags)
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terraformAttrs[subj.Name] = val
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case addrs.CountAttr:
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val, valDiags := normalizeRefValue(s.Data.GetCountAttr(subj, rng))
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diags = diags.Append(valDiags)
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countAttrs[subj.Name] = val
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case addrs.ForEachAttr:
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val, valDiags := normalizeRefValue(s.Data.GetForEachAttr(subj, rng))
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diags = diags.Append(valDiags)
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forEachAttrs[subj.Name] = val
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default:
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// Should never happen
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panic(fmt.Errorf("Scope.buildEvalContext cannot handle address type %T", rawSubj))
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}
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}
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for k, v := range buildResourceObjects(managedResources) {
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vals[k] = v
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}
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vals["data"] = cty.ObjectVal(buildResourceObjects(dataResources))
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vals["module"] = cty.ObjectVal(buildModuleObjects(wholeModules, moduleOutputs))
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vals["var"] = cty.ObjectVal(inputVariables)
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vals["local"] = cty.ObjectVal(localValues)
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vals["path"] = cty.ObjectVal(pathAttrs)
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vals["terraform"] = cty.ObjectVal(terraformAttrs)
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vals["count"] = cty.ObjectVal(countAttrs)
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vals["each"] = cty.ObjectVal(forEachAttrs)
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if self != cty.NilVal {
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vals["self"] = self
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}
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return ctx, diags
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}
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func buildResourceObjects(resources map[string]map[string]cty.Value) map[string]cty.Value {
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vals := make(map[string]cty.Value)
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for typeName, nameVals := range resources {
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vals[typeName] = cty.ObjectVal(nameVals)
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}
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return vals
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}
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func buildModuleObjects(wholeModules map[string]map[addrs.InstanceKey]cty.Value, moduleOutputs map[string]map[addrs.InstanceKey]map[string]cty.Value) map[string]cty.Value {
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vals := make(map[string]cty.Value)
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for name, keys := range wholeModules {
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vals[name] = buildInstanceObjects(keys)
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}
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for name, keys := range moduleOutputs {
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if _, exists := wholeModules[name]; exists {
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// If we also have a whole module value for this name then we'll
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// skip this since the individual outputs are embedded in that result.
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continue
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}
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// The shape of this collection isn't compatible with buildInstanceObjects,
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// but rather than replicating most of the buildInstanceObjects logic
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// here we'll instead first transform the structure to be what that
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// function expects and then use it. This is a little wasteful, but
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// we do not expect this these maps to be large and so the extra work
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// here should not hurt too much.
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flattened := make(map[addrs.InstanceKey]cty.Value, len(keys))
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for k, vals := range keys {
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flattened[k] = cty.ObjectVal(vals)
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}
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vals[name] = buildInstanceObjects(flattened)
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}
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return vals
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}
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func buildInstanceObjects(keys map[addrs.InstanceKey]cty.Value) cty.Value {
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if val, exists := keys[addrs.NoKey]; exists {
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// If present, a "no key" value supersedes all other values,
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// since they should be embedded inside it.
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return val
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}
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// If we only have individual values then we need to construct
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// either a list or a map, depending on what sort of keys we
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// have.
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haveInt := false
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haveString := false
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maxInt := 0
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for k := range keys {
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switch tk := k.(type) {
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case addrs.IntKey:
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haveInt = true
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if int(tk) > maxInt {
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maxInt = int(tk)
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}
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case addrs.StringKey:
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haveString = true
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}
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}
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// We should either have ints or strings and not both, but
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// if we have both then we'll prefer strings and let the
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// language interpreter try to convert the int keys into
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// strings in a map.
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switch {
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case haveString:
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vals := make(map[string]cty.Value)
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for k, v := range keys {
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switch tk := k.(type) {
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case addrs.StringKey:
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vals[string(tk)] = v
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case addrs.IntKey:
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sk := strconv.Itoa(int(tk))
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vals[sk] = v
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}
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}
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return cty.ObjectVal(vals)
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case haveInt:
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// We'll make a tuple that is long enough for our maximum
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// index value. It doesn't matter if we end up shorter than
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// the number of instances because if length(...) were
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// being evaluated we would've got a NoKey reference and
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// thus not ended up in this codepath at all.
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vals := make([]cty.Value, maxInt+1)
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for i := range vals {
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if v, exists := keys[addrs.IntKey(i)]; exists {
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vals[i] = v
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} else {
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// Just a placeholder, since nothing will access this anyway
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vals[i] = cty.DynamicVal
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}
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}
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return cty.TupleVal(vals)
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default:
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// Should never happen because there are no other key types.
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log.Printf("[ERROR] strange makeInstanceObjects call with no supported key types")
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return cty.EmptyObjectVal
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}
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}
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func normalizeRefValue(val cty.Value, diags tfdiags.Diagnostics) (cty.Value, tfdiags.Diagnostics) {
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if diags.HasErrors() {
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// If there are errors then we will force an unknown result so that
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// we can still evaluate and catch type errors but we'll avoid
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// producing redundant re-statements of the same errors we've already
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// dealt with here.
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return cty.UnknownVal(val.Type()), diags
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}
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return val, diags
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}
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