271 lines
7.7 KiB
Go
271 lines
7.7 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/addrs"
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"github.com/hashicorp/terraform/config/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.WriteByte('[')
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buf.WriteString(step.InstanceKey.String())
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buf.WriteByte(']')
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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 (m *Module) testString() string {
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var buf bytes.Buffer
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if len(m.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(m.Resources))
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for _, rs := range m.Resources {
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for ik := range rs.Instances {
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addrsOrder = append(addrsOrder, rs.Addr.Instance(ik).Absolute(addrs.RootModuleInstance))
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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 := m.Resource(addr.ContainingResource())
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is := m.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, _ := range attributes {
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if ak == "id" {
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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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for k, 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 %s = %s%s\n", k, id, taintStr))
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}
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if obj := is.Current; obj != nil && len(obj.Dependencies) > 0 {
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buf.WriteString(fmt.Sprintf("\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(m.OutputValues) > 0 {
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buf.WriteString("\nOutputs:\n\n")
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ks := make([]string, 0, len(m.OutputValues))
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for k := range m.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 := m.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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}
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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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