mirror of
https://github.com/opentofu/opentofu.git
synced 2024-12-30 10:47:14 -06:00
b9a93a0fe7
This is part of a general effort to move all of Terraform's non-library package surface under internal in order to reinforce that these are for internal use within Terraform only. If you were previously importing packages under this prefix into an external codebase, you could pin to an earlier release tag as an interim solution until you've make a plan to achieve the same functionality some other way.
497 lines
14 KiB
Go
497 lines
14 KiB
Go
package addrs
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import (
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"fmt"
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"strings"
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"github.com/hashicorp/hcl/v2"
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"github.com/hashicorp/hcl/v2/hclsyntax"
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"github.com/zclconf/go-cty/cty"
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"github.com/zclconf/go-cty/cty/gocty"
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"github.com/hashicorp/terraform/internal/tfdiags"
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)
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// ModuleInstance is an address for a particular module instance within the
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// dynamic module tree. This is an extension of the static traversals
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// represented by type Module that deals with the possibility of a single
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// module call producing multiple instances via the "count" and "for_each"
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// arguments.
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//
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// Although ModuleInstance is a slice, it should be treated as immutable after
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// creation.
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type ModuleInstance []ModuleInstanceStep
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var (
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_ Targetable = ModuleInstance(nil)
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)
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func ParseModuleInstance(traversal hcl.Traversal) (ModuleInstance, tfdiags.Diagnostics) {
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mi, remain, diags := parseModuleInstancePrefix(traversal)
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if len(remain) != 0 {
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if len(remain) == len(traversal) {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid module instance address",
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Detail: "A module instance address must begin with \"module.\".",
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Subject: remain.SourceRange().Ptr(),
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})
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} else {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid module instance address",
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Detail: "The module instance address is followed by additional invalid content.",
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Subject: remain.SourceRange().Ptr(),
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})
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}
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}
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return mi, diags
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}
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// ParseModuleInstanceStr is a helper wrapper around ParseModuleInstance
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// that takes a string and parses it with the HCL native syntax traversal parser
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// before interpreting it.
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//
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// This should be used only in specialized situations since it will cause the
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// created references to not have any meaningful source location information.
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// If a reference string is coming from a source that should be identified in
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// error messages then the caller should instead parse it directly using a
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// suitable function from the HCL API and pass the traversal itself to
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// ParseModuleInstance.
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//
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// Error diagnostics are returned if either the parsing fails or the analysis
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// of the traversal fails. There is no way for the caller to distinguish the
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// two kinds of diagnostics programmatically. If error diagnostics are returned
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// then the returned address is invalid.
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func ParseModuleInstanceStr(str string) (ModuleInstance, tfdiags.Diagnostics) {
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var diags tfdiags.Diagnostics
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traversal, parseDiags := hclsyntax.ParseTraversalAbs([]byte(str), "", hcl.Pos{Line: 1, Column: 1})
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diags = diags.Append(parseDiags)
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if parseDiags.HasErrors() {
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return nil, diags
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}
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addr, addrDiags := ParseModuleInstance(traversal)
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diags = diags.Append(addrDiags)
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return addr, diags
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}
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func parseModuleInstancePrefix(traversal hcl.Traversal) (ModuleInstance, hcl.Traversal, tfdiags.Diagnostics) {
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remain := traversal
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var mi ModuleInstance
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var diags tfdiags.Diagnostics
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LOOP:
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for len(remain) > 0 {
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var next string
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switch tt := remain[0].(type) {
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case hcl.TraverseRoot:
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next = tt.Name
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case hcl.TraverseAttr:
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next = tt.Name
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default:
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid address operator",
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Detail: "Module address prefix must be followed by dot and then a name.",
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Subject: remain[0].SourceRange().Ptr(),
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})
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break LOOP
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}
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if next != "module" {
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break
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}
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kwRange := remain[0].SourceRange()
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remain = remain[1:]
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// If we have the prefix "module" then we should be followed by an
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// module call name, as an attribute, and then optionally an index step
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// giving the instance key.
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if len(remain) == 0 {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid address operator",
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Detail: "Prefix \"module.\" must be followed by a module name.",
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Subject: &kwRange,
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})
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break
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}
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var moduleName string
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switch tt := remain[0].(type) {
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case hcl.TraverseAttr:
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moduleName = tt.Name
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default:
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid address operator",
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Detail: "Prefix \"module.\" must be followed by a module name.",
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Subject: remain[0].SourceRange().Ptr(),
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})
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break LOOP
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}
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remain = remain[1:]
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step := ModuleInstanceStep{
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Name: moduleName,
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}
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if len(remain) > 0 {
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if idx, ok := remain[0].(hcl.TraverseIndex); ok {
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remain = remain[1:]
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switch idx.Key.Type() {
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case cty.String:
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step.InstanceKey = StringKey(idx.Key.AsString())
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case cty.Number:
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var idxInt int
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err := gocty.FromCtyValue(idx.Key, &idxInt)
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if err == nil {
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step.InstanceKey = IntKey(idxInt)
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} else {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid address operator",
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Detail: fmt.Sprintf("Invalid module index: %s.", err),
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Subject: idx.SourceRange().Ptr(),
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})
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}
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default:
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// Should never happen, because no other types are allowed in traversal indices.
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Invalid address operator",
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Detail: "Invalid module key: must be either a string or an integer.",
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Subject: idx.SourceRange().Ptr(),
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})
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}
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}
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}
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mi = append(mi, step)
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}
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var retRemain hcl.Traversal
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if len(remain) > 0 {
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retRemain = make(hcl.Traversal, len(remain))
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copy(retRemain, remain)
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// The first element here might be either a TraverseRoot or a
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// TraverseAttr, depending on whether we had a module address on the
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// front. To make life easier for callers, we'll normalize to always
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// start with a TraverseRoot.
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if tt, ok := retRemain[0].(hcl.TraverseAttr); ok {
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retRemain[0] = hcl.TraverseRoot{
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Name: tt.Name,
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SrcRange: tt.SrcRange,
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}
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}
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}
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return mi, retRemain, diags
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}
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// UnkeyedInstanceShim is a shim method for converting a Module address to the
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// equivalent ModuleInstance address that assumes that no modules have
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// keyed instances.
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//
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// This is a temporary allowance for the fact that Terraform does not presently
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// support "count" and "for_each" on modules, and thus graph building code that
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// derives graph nodes from configuration must just assume unkeyed modules
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// in order to construct the graph. At a later time when "count" and "for_each"
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// support is added for modules, all callers of this method will need to be
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// reworked to allow for keyed module instances.
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func (m Module) UnkeyedInstanceShim() ModuleInstance {
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path := make(ModuleInstance, len(m))
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for i, name := range m {
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path[i] = ModuleInstanceStep{Name: name}
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}
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return path
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}
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// ModuleInstanceStep is a single traversal step through the dynamic module
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// tree. It is used only as part of ModuleInstance.
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type ModuleInstanceStep struct {
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Name string
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InstanceKey InstanceKey
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}
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// RootModuleInstance is the module instance address representing the root
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// module, which is also the zero value of ModuleInstance.
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var RootModuleInstance ModuleInstance
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// IsRoot returns true if the receiver is the address of the root module instance,
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// or false otherwise.
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func (m ModuleInstance) IsRoot() bool {
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return len(m) == 0
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}
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// Child returns the address of a child module instance of the receiver,
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// identified by the given name and key.
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func (m ModuleInstance) Child(name string, key InstanceKey) ModuleInstance {
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ret := make(ModuleInstance, 0, len(m)+1)
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ret = append(ret, m...)
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return append(ret, ModuleInstanceStep{
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Name: name,
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InstanceKey: key,
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})
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}
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// Parent returns the address of the parent module instance of the receiver, or
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// the receiver itself if there is no parent (if it's the root module address).
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func (m ModuleInstance) Parent() ModuleInstance {
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if len(m) == 0 {
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return m
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}
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return m[:len(m)-1]
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}
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// String returns a string representation of the receiver, in the format used
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// within e.g. user-provided resource addresses.
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//
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// The address of the root module has the empty string as its representation.
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func (m ModuleInstance) String() string {
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if len(m) == 0 {
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return ""
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}
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// Calculate minimal necessary space (no instance keys).
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l := 0
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for _, step := range m {
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l += len(step.Name)
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}
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buf := strings.Builder{}
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// 8 is len(".module.") which separates entries.
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buf.Grow(l + len(m)*8)
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sep := ""
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for _, step := range m {
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buf.WriteString(sep)
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buf.WriteString("module.")
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buf.WriteString(step.Name)
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if step.InstanceKey != NoKey {
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buf.WriteString(step.InstanceKey.String())
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}
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sep = "."
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}
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return buf.String()
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}
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// Equal returns true if the receiver and the given other value
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// contains the exact same parts.
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func (m ModuleInstance) Equal(o ModuleInstance) bool {
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if len(m) != len(o) {
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return false
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}
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for i := range m {
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if m[i] != o[i] {
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return false
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}
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}
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return true
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}
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// Less returns true if the receiver should sort before the given other value
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// in a sorted list of addresses.
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func (m ModuleInstance) Less(o ModuleInstance) bool {
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if len(m) != len(o) {
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// Shorter path sorts first.
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return len(m) < len(o)
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}
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for i := range m {
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mS, oS := m[i], o[i]
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switch {
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case mS.Name != oS.Name:
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return mS.Name < oS.Name
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case mS.InstanceKey != oS.InstanceKey:
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return InstanceKeyLess(mS.InstanceKey, oS.InstanceKey)
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}
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}
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return false
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}
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// Ancestors returns a slice containing the receiver and all of its ancestor
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// module instances, all the way up to (and including) the root module.
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// The result is ordered by depth, with the root module always first.
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//
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// Since the result always includes the root module, a caller may choose to
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// ignore it by slicing the result with [1:].
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func (m ModuleInstance) Ancestors() []ModuleInstance {
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ret := make([]ModuleInstance, 0, len(m)+1)
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for i := 0; i <= len(m); i++ {
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ret = append(ret, m[:i])
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}
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return ret
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}
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// IsAncestor returns true if the receiver is an ancestor of the given
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// other value.
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func (m ModuleInstance) IsAncestor(o ModuleInstance) bool {
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// Longer or equal sized paths means the receiver cannot
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// be an ancestor of the given module insatnce.
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if len(m) >= len(o) {
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return false
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}
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for i, ms := range m {
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if ms.Name != o[i].Name {
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return false
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}
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if ms.InstanceKey != NoKey && ms.InstanceKey != o[i].InstanceKey {
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return false
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}
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}
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return true
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}
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// Call returns the module call address that corresponds to the given module
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// instance, along with the address of the module instance that contains it.
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//
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// There is no call for the root module, so this method will panic if called
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// on the root module address.
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//
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// A single module call can produce potentially many module instances, so the
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// result discards any instance key that might be present on the last step
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// of the instance. To retain this, use CallInstance instead.
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//
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// In practice, this just turns the last element of the receiver into a
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// ModuleCall and then returns a slice of the receiever that excludes that
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// last part. This is just a convenience for situations where a call address
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// is required, such as when dealing with *Reference and Referencable values.
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func (m ModuleInstance) Call() (ModuleInstance, ModuleCall) {
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if len(m) == 0 {
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panic("cannot produce ModuleCall for root module")
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}
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inst, lastStep := m[:len(m)-1], m[len(m)-1]
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return inst, ModuleCall{
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Name: lastStep.Name,
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}
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}
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// CallInstance returns the module call instance address that corresponds to
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// the given module instance, along with the address of the module instance
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// that contains it.
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//
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// There is no call for the root module, so this method will panic if called
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// on the root module address.
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//
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// In practice, this just turns the last element of the receiver into a
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// ModuleCallInstance and then returns a slice of the receiever that excludes
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// that last part. This is just a convenience for situations where a call\
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// address is required, such as when dealing with *Reference and Referencable
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// values.
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func (m ModuleInstance) CallInstance() (ModuleInstance, ModuleCallInstance) {
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if len(m) == 0 {
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panic("cannot produce ModuleCallInstance for root module")
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}
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inst, lastStep := m[:len(m)-1], m[len(m)-1]
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return inst, ModuleCallInstance{
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Call: ModuleCall{
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Name: lastStep.Name,
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},
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Key: lastStep.InstanceKey,
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}
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}
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// TargetContains implements Targetable by returning true if the given other
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// address either matches the receiver, is a sub-module-instance of the
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// receiver, or is a targetable absolute address within a module that
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// is contained within the reciever.
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func (m ModuleInstance) TargetContains(other Targetable) bool {
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switch to := other.(type) {
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case Module:
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if len(to) < len(m) {
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// Can't be contained if the path is shorter
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return false
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}
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// Other is contained if its steps match for the length of our own path.
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for i, ourStep := range m {
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otherStep := to[i]
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// We can't contain an entire module if we have a specific instance
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// key. The case of NoKey is OK because this address is either
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// meant to address an unexpanded module, or a single instance of
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// that module, and both of those are a covered in-full by the
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// Module address.
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if ourStep.InstanceKey != NoKey {
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return false
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}
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if ourStep.Name != otherStep {
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return false
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}
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}
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// If we fall out here then the prefixed matched, so it's contained.
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return true
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case ModuleInstance:
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if len(to) < len(m) {
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return false
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}
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for i, ourStep := range m {
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otherStep := to[i]
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if ourStep.Name != otherStep.Name {
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return false
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}
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// if this is our last step, because all targets are parsed as
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// instances, this may be a ModuleInstance intended to be used as a
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// Module.
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if i == len(m)-1 {
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if ourStep.InstanceKey == NoKey {
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// If the other step is a keyed instance, then we contain that
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// step, and if it isn't it's a match, which is true either way
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return true
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}
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}
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if ourStep.InstanceKey != otherStep.InstanceKey {
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return false
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}
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}
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return true
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case ConfigResource:
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return m.TargetContains(to.Module)
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case AbsResource:
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return m.TargetContains(to.Module)
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case AbsResourceInstance:
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return m.TargetContains(to.Module)
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default:
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return false
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}
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}
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// Module returns the address of the module that this instance is an instance
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// of.
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func (m ModuleInstance) Module() Module {
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if len(m) == 0 {
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return nil
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}
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ret := make(Module, len(m))
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for i, step := range m {
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ret[i] = step.Name
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}
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return ret
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}
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func (m ModuleInstance) targetableSigil() {
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// ModuleInstance is targetable
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}
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func (s ModuleInstanceStep) String() string {
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if s.InstanceKey != NoKey {
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return s.Name + s.InstanceKey.String()
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}
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return s.Name
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}
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