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https://github.com/opentofu/opentofu.git
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f40800b3a4
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.
278 lines
7.9 KiB
Go
278 lines
7.9 KiB
Go
package states
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import (
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"bufio"
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"bytes"
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"encoding/json"
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"fmt"
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"sort"
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"strings"
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ctyjson "github.com/zclconf/go-cty/cty/json"
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"github.com/hashicorp/terraform/internal/addrs"
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"github.com/hashicorp/terraform/internal/configs/hcl2shim"
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)
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// String returns a rather-odd string representation of the entire state.
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//
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// This is intended to match the behavior of the older terraform.State.String
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// method that is used in lots of existing tests. It should not be used in
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// new tests: instead, use "cmp" to directly compare the state data structures
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// and print out a diff if they do not match.
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//
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// This method should never be used in non-test code, whether directly by call
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// or indirectly via a %s or %q verb in package fmt.
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func (s *State) String() string {
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if s == nil {
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return "<nil>"
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}
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// sort the modules by name for consistent output
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modules := make([]string, 0, len(s.Modules))
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for m := range s.Modules {
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modules = append(modules, m)
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}
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sort.Strings(modules)
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var buf bytes.Buffer
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for _, name := range modules {
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m := s.Modules[name]
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mStr := m.testString()
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// If we're the root module, we just write the output directly.
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if m.Addr.IsRoot() {
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buf.WriteString(mStr + "\n")
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continue
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}
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// We need to build out a string that resembles the not-quite-standard
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// format that terraform.State.String used to use, where there's a
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// "module." prefix but then just a chain of all of the module names
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// without any further "module." portions.
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buf.WriteString("module")
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for _, step := range m.Addr {
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buf.WriteByte('.')
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buf.WriteString(step.Name)
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if step.InstanceKey != addrs.NoKey {
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buf.WriteString(step.InstanceKey.String())
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}
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}
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buf.WriteString(":\n")
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s := bufio.NewScanner(strings.NewReader(mStr))
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for s.Scan() {
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text := s.Text()
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if text != "" {
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text = " " + text
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}
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buf.WriteString(fmt.Sprintf("%s\n", text))
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}
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}
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return strings.TrimSpace(buf.String())
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}
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// testString is used to produce part of the output of State.String. It should
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// never be used directly.
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func (ms *Module) testString() string {
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var buf bytes.Buffer
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if len(ms.Resources) == 0 {
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buf.WriteString("<no state>")
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}
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// We use AbsResourceInstance here, even though everything belongs to
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// the same module, just because we have a sorting behavior defined
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// for those but not for just ResourceInstance.
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addrsOrder := make([]addrs.AbsResourceInstance, 0, len(ms.Resources))
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for _, rs := range ms.Resources {
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for ik := range rs.Instances {
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addrsOrder = append(addrsOrder, rs.Addr.Instance(ik))
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}
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}
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sort.Slice(addrsOrder, func(i, j int) bool {
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return addrsOrder[i].Less(addrsOrder[j])
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})
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for _, fakeAbsAddr := range addrsOrder {
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addr := fakeAbsAddr.Resource
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rs := ms.Resource(addr.ContainingResource())
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is := ms.ResourceInstance(addr)
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// Here we need to fake up a legacy-style address as the old state
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// types would've used, since that's what our tests against those
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// old types expect. The significant difference is that instancekey
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// is dot-separated rather than using index brackets.
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k := addr.ContainingResource().String()
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if addr.Key != addrs.NoKey {
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switch tk := addr.Key.(type) {
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case addrs.IntKey:
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k = fmt.Sprintf("%s.%d", k, tk)
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default:
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// No other key types existed for the legacy types, so we
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// can do whatever we want here. We'll just use our standard
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// syntax for these.
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k = k + tk.String()
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}
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}
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id := LegacyInstanceObjectID(is.Current)
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taintStr := ""
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if is.Current != nil && is.Current.Status == ObjectTainted {
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taintStr = " (tainted)"
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}
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deposedStr := ""
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if len(is.Deposed) > 0 {
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deposedStr = fmt.Sprintf(" (%d deposed)", len(is.Deposed))
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}
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buf.WriteString(fmt.Sprintf("%s:%s%s\n", k, taintStr, deposedStr))
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buf.WriteString(fmt.Sprintf(" ID = %s\n", id))
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buf.WriteString(fmt.Sprintf(" provider = %s\n", rs.ProviderConfig.String()))
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// Attributes were a flatmap before, but are not anymore. To preserve
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// our old output as closely as possible we need to do a conversion
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// to flatmap. Normally we'd want to do this with schema for
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// accuracy, but for our purposes here it only needs to be approximate.
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// This should produce an identical result for most cases, though
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// in particular will differ in a few cases:
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// - The keys used for elements in a set will be different
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// - Values for attributes of type cty.DynamicPseudoType will be
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// misinterpreted (but these weren't possible in old world anyway)
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var attributes map[string]string
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if obj := is.Current; obj != nil {
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switch {
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case obj.AttrsFlat != nil:
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// Easy (but increasingly unlikely) case: the state hasn't
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// actually been upgraded to the new form yet.
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attributes = obj.AttrsFlat
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case obj.AttrsJSON != nil:
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ty, err := ctyjson.ImpliedType(obj.AttrsJSON)
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if err == nil {
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val, err := ctyjson.Unmarshal(obj.AttrsJSON, ty)
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if err == nil {
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attributes = hcl2shim.FlatmapValueFromHCL2(val)
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}
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}
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}
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}
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attrKeys := make([]string, 0, len(attributes))
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for ak, val := range attributes {
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if ak == "id" {
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continue
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}
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// don't show empty containers in the output
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if val == "0" && (strings.HasSuffix(ak, ".#") || strings.HasSuffix(ak, ".%")) {
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continue
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}
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attrKeys = append(attrKeys, ak)
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}
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sort.Strings(attrKeys)
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for _, ak := range attrKeys {
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av := attributes[ak]
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buf.WriteString(fmt.Sprintf(" %s = %s\n", ak, av))
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}
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// CAUTION: Since deposed keys are now random strings instead of
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// incrementing integers, this result will not be deterministic
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// if there is more than one deposed object.
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i := 1
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for _, t := range is.Deposed {
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id := LegacyInstanceObjectID(t)
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taintStr := ""
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if t.Status == ObjectTainted {
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taintStr = " (tainted)"
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}
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buf.WriteString(fmt.Sprintf(" Deposed ID %d = %s%s\n", i, id, taintStr))
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i++
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}
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if obj := is.Current; obj != nil && len(obj.Dependencies) > 0 {
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buf.WriteString("\n Dependencies:\n")
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for _, dep := range obj.Dependencies {
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buf.WriteString(fmt.Sprintf(" %s\n", dep.String()))
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}
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}
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}
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if len(ms.OutputValues) > 0 {
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buf.WriteString("\nOutputs:\n\n")
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ks := make([]string, 0, len(ms.OutputValues))
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for k := range ms.OutputValues {
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ks = append(ks, k)
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}
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sort.Strings(ks)
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for _, k := range ks {
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v := ms.OutputValues[k]
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lv := hcl2shim.ConfigValueFromHCL2(v.Value)
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switch vTyped := lv.(type) {
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case string:
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buf.WriteString(fmt.Sprintf("%s = %s\n", k, vTyped))
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case []interface{}:
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buf.WriteString(fmt.Sprintf("%s = %s\n", k, vTyped))
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case map[string]interface{}:
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var mapKeys []string
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for key := range vTyped {
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mapKeys = append(mapKeys, key)
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}
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sort.Strings(mapKeys)
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var mapBuf bytes.Buffer
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mapBuf.WriteString("{")
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for _, key := range mapKeys {
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mapBuf.WriteString(fmt.Sprintf("%s:%s ", key, vTyped[key]))
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}
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mapBuf.WriteString("}")
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buf.WriteString(fmt.Sprintf("%s = %s\n", k, mapBuf.String()))
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default:
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buf.WriteString(fmt.Sprintf("%s = %#v\n", k, lv))
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}
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}
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}
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return buf.String()
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}
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// LegacyInstanceObjectID is a helper for extracting an object id value from
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// an instance object in a way that approximates how we used to do this
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// for the old state types. ID is no longer first-class, so this is preserved
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// only for compatibility with old tests that include the id as part of their
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// expected value.
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func LegacyInstanceObjectID(obj *ResourceInstanceObjectSrc) string {
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if obj == nil {
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return "<not created>"
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}
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if obj.AttrsJSON != nil {
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type WithID struct {
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ID string `json:"id"`
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}
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var withID WithID
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err := json.Unmarshal(obj.AttrsJSON, &withID)
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if err == nil {
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return withID.ID
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}
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} else if obj.AttrsFlat != nil {
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if flatID, exists := obj.AttrsFlat["id"]; exists {
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return flatID
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}
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}
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// For resource types created after we removed id as special there may
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// not actually be one at all. This is okay because older tests won't
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// encounter this, and new tests shouldn't be using ids.
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return "<none>"
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}
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