opentofu/terraform/context_test.go
Martin Atkins 5802953ab6 core: Improve realism of map representation in testDiffFn
The diffs created by testDiffFn use the flatmap package directly, rather
than running the diff-generation logic in helper/schema. It turns out that
flatmap itself can generate the k+".#" keys used to indicate the length
of a list, but only helper/schema itself knew how to generate the
corresponding k+".%" keys used for maps.

Rather than modifying the now-deprecated flatmap code directly (and risk
breaking assumptions in shims elsewhere), here we just synthesize the
extra required map element within the testDiffFn implementation, which
then in turn allows the MockProvider diffFn shim to correctly recognize
it as a map and convert it into a real cty.Map value to return.
2018-10-16 19:14:11 -07:00

1069 lines
24 KiB
Go

package terraform
import (
"bufio"
"bytes"
"fmt"
"io/ioutil"
"os"
"path/filepath"
"sort"
"strconv"
"strings"
"testing"
"time"
"github.com/google/go-cmp/cmp"
"github.com/google/go-cmp/cmp/cmpopts"
"github.com/hashicorp/go-version"
"github.com/hashicorp/hil"
"github.com/zclconf/go-cty/cty"
"github.com/hashicorp/terraform/config"
"github.com/hashicorp/terraform/config/hcl2shim"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/configs/configload"
"github.com/hashicorp/terraform/configs/configschema"
"github.com/hashicorp/terraform/flatmap"
"github.com/hashicorp/terraform/plans"
"github.com/hashicorp/terraform/plans/planfile"
"github.com/hashicorp/terraform/providers"
"github.com/hashicorp/terraform/provisioners"
"github.com/hashicorp/terraform/states"
"github.com/hashicorp/terraform/states/statefile"
"github.com/hashicorp/terraform/tfdiags"
tfversion "github.com/hashicorp/terraform/version"
)
var (
equateEmpty = cmpopts.EquateEmpty()
typeComparer = cmp.Comparer(cty.Type.Equals)
valueComparer = cmp.Comparer(cty.Value.RawEquals)
)
func TestNewContextRequiredVersion(t *testing.T) {
cases := []struct {
Name string
Module string
Version string
Value string
Err bool
}{
{
"no requirement",
"",
"0.1.0",
"",
false,
},
{
"doesn't match",
"",
"0.1.0",
"> 0.6.0",
true,
},
{
"matches",
"",
"0.7.0",
"> 0.6.0",
false,
},
{
"module matches",
"context-required-version-module",
"0.5.0",
"",
false,
},
{
"module doesn't match",
"context-required-version-module",
"0.4.0",
"",
true,
},
}
for i, tc := range cases {
t.Run(fmt.Sprintf("%d-%s", i, tc.Name), func(t *testing.T) {
// Reset the version for the tests
old := tfversion.SemVer
tfversion.SemVer = version.Must(version.NewVersion(tc.Version))
defer func() { tfversion.SemVer = old }()
name := "context-required-version"
if tc.Module != "" {
name = tc.Module
}
mod := testModule(t, name)
if tc.Value != "" {
constraint, err := version.NewConstraint(tc.Value)
if err != nil {
t.Fatalf("can't parse %q as version constraint", tc.Value)
}
mod.Module.CoreVersionConstraints = append(mod.Module.CoreVersionConstraints, configs.VersionConstraint{
Required: constraint,
})
}
_, diags := NewContext(&ContextOpts{
Config: mod,
})
if diags.HasErrors() != tc.Err {
t.Fatalf("err: %s", diags.Err())
}
})
}
}
func testContext2(t *testing.T, opts *ContextOpts) *Context {
t.Helper()
ctx, diags := NewContext(opts)
if diags.HasErrors() {
t.Fatalf("failed to create test context\n\n%s\n", diags.Err())
}
return ctx
}
func testDataApplyFn(
info *InstanceInfo,
d *InstanceDiff) (*InstanceState, error) {
return testApplyFn(info, new(InstanceState), d)
}
func testDataDiffFn(
info *InstanceInfo,
c *ResourceConfig) (*InstanceDiff, error) {
return testDiffFn(info, new(InstanceState), c)
}
func testApplyFn(
info *InstanceInfo,
s *InstanceState,
d *InstanceDiff) (*InstanceState, error) {
if d.Destroy {
return nil, nil
}
// find the OLD id, which is probably in the ID field for now, but eventually
// ID should only be in one place.
id := s.ID
if id == "" {
id = s.Attributes["id"]
}
if idAttr, ok := d.Attributes["id"]; ok && !idAttr.NewComputed {
id = idAttr.New
}
if id == "" || id == config.UnknownVariableValue {
id = "foo"
}
result := &InstanceState{
ID: id,
Attributes: make(map[string]string),
}
// Copy all the prior attributes
for k, v := range s.Attributes {
result.Attributes[k] = v
}
if d != nil {
result = result.MergeDiff(d)
}
return result, nil
}
func testDiffFn(
info *InstanceInfo,
s *InstanceState,
c *ResourceConfig) (*InstanceDiff, error) {
diff := new(InstanceDiff)
diff.Attributes = make(map[string]*ResourceAttrDiff)
if s != nil {
diff.DestroyTainted = s.Tainted
}
for k, v := range c.Raw {
// Ignore __-prefixed keys since they're used for magic
if k[0] == '_' && k[1] == '_' {
continue
}
if k == "nil" {
return nil, nil
}
// This key is used for other purposes
if k == "compute_value" {
continue
}
if k == "compute" {
if v == hil.UnknownValue || v == "unknown" {
// compute wasn't set in the config, so don't use these
// computed values from the schema.
delete(c.Raw, k)
delete(c.Raw, "compute_value")
// we need to remove this from the list of ComputedKeys too,
// since it would get re-added to the diff further down
newComputed := make([]string, 0, len(c.ComputedKeys))
for _, ck := range c.ComputedKeys {
if ck == "compute" || ck == "compute_value" {
continue
}
newComputed = append(newComputed, ck)
}
c.ComputedKeys = newComputed
if v == "unknown" {
diff.Attributes["unknown"] = &ResourceAttrDiff{
Old: "",
New: "",
NewComputed: true,
}
c.ComputedKeys = append(c.ComputedKeys, "unknown")
}
continue
}
attrDiff := &ResourceAttrDiff{
Old: "",
New: "",
NewComputed: true,
}
if cv, ok := c.Config["compute_value"]; ok {
if cv.(string) == "1" {
attrDiff.NewComputed = false
attrDiff.New = fmt.Sprintf("computed_%s", v.(string))
}
}
diff.Attributes[v.(string)] = attrDiff
}
// If this key is not computed, then look it up in the
// cleaned config.
found := false
for _, ck := range c.ComputedKeys {
if ck == k {
found = true
break
}
}
if !found {
v = c.Config[k]
}
for k, attrDiff := range testFlatAttrDiffs(k, v) {
// we need to ignore 'id' for now, since it's always inferred to be
// computed.
if k == "id" {
continue
}
if k == "require_new" {
attrDiff.RequiresNew = true
}
if _, ok := c.Raw["__"+k+"_requires_new"]; ok {
attrDiff.RequiresNew = true
}
if attr, ok := s.Attributes[k]; ok {
attrDiff.Old = attr
}
diff.Attributes[k] = attrDiff
}
}
for _, k := range c.ComputedKeys {
if k == "id" {
continue
}
diff.Attributes[k] = &ResourceAttrDiff{
Old: "",
NewComputed: true,
}
}
// If we recreate this resource because it's tainted, we keep all attrs
if !diff.RequiresNew() {
for k, v := range diff.Attributes {
if v.NewComputed {
continue
}
old, ok := s.Attributes[k]
if !ok {
continue
}
if old == v.New {
delete(diff.Attributes, k)
}
}
}
if !diff.Empty() {
diff.Attributes["type"] = &ResourceAttrDiff{
Old: "",
New: info.Type,
}
}
return diff, nil
}
// generate ResourceAttrDiffs for nested data structures in tests
func testFlatAttrDiffs(k string, i interface{}) map[string]*ResourceAttrDiff {
diffs := make(map[string]*ResourceAttrDiff)
// check for strings and empty containers first
switch t := i.(type) {
case string:
diffs[k] = &ResourceAttrDiff{New: t}
return diffs
case map[string]interface{}:
if len(t) == 0 {
diffs[k] = &ResourceAttrDiff{New: ""}
return diffs
}
case []interface{}:
if len(t) == 0 {
diffs[k] = &ResourceAttrDiff{New: ""}
return diffs
}
}
flat := flatmap.Flatten(map[string]interface{}{k: i})
for k, v := range flat {
attrDiff := &ResourceAttrDiff{
Old: "",
New: v,
}
diffs[k] = attrDiff
}
// The legacy flatmap-based diff producing done by helper/schema would
// additionally insert a k+".%" key here recording the length of the map,
// which is for some reason not also done by flatmap.Flatten. To make our
// mock shims helper/schema-compatible, we'll just fake that up here.
switch t := i.(type) {
case map[string]interface{}:
attrDiff := &ResourceAttrDiff{
Old: "",
New: strconv.Itoa(len(t)),
}
diffs[k+".%"] = attrDiff
}
return diffs
}
func testProvider(prefix string) *MockProvider {
p := new(MockProvider)
p.ReadResourceFn = func(req providers.ReadResourceRequest) providers.ReadResourceResponse {
return providers.ReadResourceResponse{NewState: req.PriorState}
}
p.GetSchemaReturn = testProviderSchema(prefix)
return p
}
func testProvisioner() *MockProvisioner {
p := new(MockProvisioner)
p.GetSchemaResponse = provisioners.GetSchemaResponse{
Provisioner: &configschema.Block{
Attributes: map[string]*configschema.Attribute{
"command": {
Type: cty.String,
Optional: true,
},
"order": {
Type: cty.String,
Optional: true,
},
"when": {
Type: cty.String,
Optional: true,
},
},
},
}
return p
}
func checkStateString(t *testing.T, state *states.State, expected string) {
t.Helper()
actual := strings.TrimSpace(state.String())
expected = strings.TrimSpace(expected)
if actual != expected {
t.Fatalf("incorrect state\ngot:\n%s\n\nwant:\n%s", actual, expected)
}
}
func resourceState(resourceType, resourceID string) *ResourceState {
providerResource := strings.Split(resourceType, "_")
return &ResourceState{
Type: resourceType,
Primary: &InstanceState{
ID: resourceID,
Attributes: map[string]string{
"id": resourceID,
},
},
Provider: "provider." + providerResource[0],
}
}
// Test helper that gives a function 3 seconds to finish, assumes deadlock and
// fails test if it does not.
func testCheckDeadlock(t *testing.T, f func()) {
t.Helper()
timeout := make(chan bool, 1)
done := make(chan bool, 1)
go func() {
time.Sleep(3 * time.Second)
timeout <- true
}()
go func(f func(), done chan bool) {
defer func() { done <- true }()
f()
}(f, done)
select {
case <-timeout:
t.Fatalf("timed out! probably deadlock")
case <-done:
// ok
}
}
func testProviderSchema(name string) *ProviderSchema {
return &ProviderSchema{
Provider: &configschema.Block{
Attributes: map[string]*configschema.Attribute{
"region": {
Type: cty.String,
Optional: true,
},
"foo": {
Type: cty.String,
Optional: true,
},
"value": {
Type: cty.String,
Optional: true,
},
"root": {
Type: cty.Number,
Optional: true,
},
},
},
ResourceTypes: map[string]*configschema.Block{
name + "_instance": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Computed: true,
},
"ami": {
Type: cty.String,
Optional: true,
},
"dep": {
Type: cty.String,
Optional: true,
},
"num": {
Type: cty.Number,
Optional: true,
},
"require_new": {
Type: cty.String,
Optional: true,
},
"var": {
Type: cty.String,
Optional: true,
},
"foo": {
Type: cty.String,
Optional: true,
},
"bar": {
Type: cty.String,
Optional: true,
},
"compute": {
Type: cty.String,
Optional: true,
Computed: true,
},
"compute_value": {
Type: cty.String,
Optional: true,
Computed: true,
},
"value": {
Type: cty.String,
Optional: true,
},
"output": {
Type: cty.String,
Optional: true,
},
"write": {
Type: cty.String,
Optional: true,
},
"instance": {
Type: cty.String,
Optional: true,
},
"vpc_id": {
Type: cty.String,
Optional: true,
},
"type": {
Type: cty.String,
Computed: true,
},
// Generated by testDiffFn if compute = "unknown" is set in the test config
"unknown": {
Type: cty.String,
Computed: true,
},
},
},
name + "_eip": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Computed: true,
},
"instance": {
Type: cty.String,
Optional: true,
},
},
},
name + "_resource": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Computed: true,
},
"value": {
Type: cty.String,
Optional: true,
},
"random": {
Type: cty.String,
Optional: true,
},
},
},
name + "_ami_list": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"ids": {
Type: cty.List(cty.String),
Optional: true,
},
},
},
name + "_remote_state": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"foo": {
Type: cty.String,
Optional: true,
},
"output": {
Type: cty.Map(cty.String),
Computed: true,
},
},
},
name + "_file": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"template": {
Type: cty.String,
Optional: true,
},
"rendered": {
Type: cty.String,
Computed: true,
},
"__template_requires_new": {
Type: cty.String,
Optional: true,
},
},
},
},
DataSources: map[string]*configschema.Block{
name + "_data_source": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"foo": {
Type: cty.String,
Optional: true,
},
},
},
name + "_remote_state": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"foo": {
Type: cty.String,
Optional: true,
},
"output": {
Type: cty.Map(cty.String),
Optional: true,
},
},
},
name + "_file": {
Attributes: map[string]*configschema.Attribute{
"id": {
Type: cty.String,
Optional: true,
},
"template": {
Type: cty.String,
Optional: true,
},
"rendered": {
Type: cty.String,
Computed: true,
},
},
},
},
}
}
// contextForPlanViaFile is a helper that creates a temporary plan file, then
// reads it back in again and produces a ContextOpts object containing the
// planned changes, prior state and config from the plan file.
//
// This is intended for testing the separated plan/apply workflow in a more
// convenient way than spelling out all of these steps every time. Normally
// only the command and backend packages need to deal with such things, but
// our context tests try to exercise lots of stuff at once and so having them
// round-trip things through on-disk files is often an important part of
// fully representing an old bug in a regression test.
func contextOptsForPlanViaFile(configSnap *configload.Snapshot, state *states.State, plan *plans.Plan) (*ContextOpts, error) {
dir, err := ioutil.TempDir("", "terraform-contextForPlanViaFile")
if err != nil {
return nil, err
}
defer os.RemoveAll(dir)
// We'll just create a dummy statefile.File here because we're not going
// to run through any of the codepaths that care about Lineage/Serial/etc
// here anyway.
stateFile := &statefile.File{
State: state,
}
filename := filepath.Join(dir, "tfplan")
err = planfile.Create(filename, configSnap, stateFile, plan)
if err != nil {
return nil, err
}
pr, err := planfile.Open(filename)
if err != nil {
return nil, err
}
config, diags := pr.ReadConfig()
if diags.HasErrors() {
return nil, diags.Err()
}
stateFile, err = pr.ReadStateFile()
if err != nil {
return nil, err
}
plan, err = pr.ReadPlan()
if err != nil {
return nil, err
}
vars := make(InputValues)
for name, vv := range plan.VariableValues {
val, err := vv.Decode(cty.DynamicPseudoType)
if err != nil {
return nil, fmt.Errorf("can't decode value for variable %q: %s", name, err)
}
vars[name] = &InputValue{
Value: val,
SourceType: ValueFromPlan,
}
}
return &ContextOpts{
Config: config,
State: stateFile.State,
Changes: plan.Changes,
Variables: vars,
Targets: plan.TargetAddrs,
ProviderSHA256s: plan.ProviderSHA256s,
}, nil
}
// shimLegacyState is a helper that takes the legacy state type and
// converts it to the new state type.
//
// This is implemented as a state file upgrade, so it will not preserve
// parts of the state structure that are not included in a serialized state,
// such as the resolved results of any local values, outputs in non-root
// modules, etc.
func shimLegacyState(legacy *State) (*states.State, error) {
if legacy == nil {
return nil, nil
}
var buf bytes.Buffer
err := WriteState(legacy, &buf)
if err != nil {
return nil, err
}
f, err := statefile.Read(&buf)
if err != nil {
return nil, err
}
return f.State, err
}
// mustShimLegacyState is a wrapper around ShimLegacyState that panics if
// the conversion does not succeed. This is primarily intended for tests where
// the given legacy state is an object constructed within the test.
func mustShimLegacyState(legacy *State) *states.State {
ret, err := shimLegacyState(legacy)
if err != nil {
panic(err)
}
return ret
}
// legacyPlanComparisonString produces a string representation of the changes
// from a plan and a given state togther, as was formerly produced by the
// String method of terraform.Plan.
//
// This is here only for compatibility with existing tests that predate our
// new plan and state types, and should not be used in new tests. Instead, use
// a library like "cmp" to do a deep equality check and diff on the two
// data structures.
func legacyPlanComparisonString(state *states.State, changes *plans.Changes) string {
return fmt.Sprintf(
"DIFF:\n\n%s\n\nSTATE:\n\n%s",
legacyDiffComparisonString(changes),
state.String(),
)
}
// legacyDiffComparisonString produces a string representation of the changes
// from a planned changes object, as was formerly produced by the String method
// of terraform.Diff.
//
// This is here only for compatibility with existing tests that predate our
// new plan types, and should not be used in new tests. Instead, use a library
// like "cmp" to do a deep equality check and diff on the two data structures.
func legacyDiffComparisonString(changes *plans.Changes) string {
// The old string representation of a plan was grouped by module, but
// our new plan structure is not grouped in that way and so we'll need
// to preprocess it in order to produce that grouping.
type ResourceChanges struct {
Current *plans.ResourceInstanceChangeSrc
Deposed map[states.DeposedKey]*plans.ResourceInstanceChangeSrc
}
byModule := map[string]map[string]*ResourceChanges{}
resourceKeys := map[string][]string{}
var moduleKeys []string
for _, rc := range changes.Resources {
moduleKey := rc.Addr.Module.String()
if _, exists := byModule[moduleKey]; !exists {
moduleKeys = append(moduleKeys, moduleKey)
byModule[moduleKey] = make(map[string]*ResourceChanges)
}
resourceKey := rc.Addr.Resource.String()
if _, exists := byModule[moduleKey][resourceKey]; !exists {
resourceKeys[moduleKey] = append(resourceKeys[moduleKey], resourceKey)
byModule[moduleKey][resourceKey] = &ResourceChanges{
Deposed: make(map[states.DeposedKey]*plans.ResourceInstanceChangeSrc),
}
}
if rc.DeposedKey == states.NotDeposed {
byModule[moduleKey][resourceKey].Current = rc
} else {
byModule[moduleKey][resourceKey].Deposed[rc.DeposedKey] = rc
}
}
sort.Strings(moduleKeys)
for _, ks := range resourceKeys {
sort.Strings(ks)
}
var buf bytes.Buffer
for _, moduleKey := range moduleKeys {
rcs := byModule[moduleKey]
var mBuf bytes.Buffer
for _, resourceKey := range resourceKeys[moduleKey] {
rc := rcs[resourceKey]
crud := "UPDATE"
if rc.Current != nil {
switch rc.Current.Action {
case plans.Replace:
crud = "DESTROY/CREATE"
case plans.Delete:
crud = "DESTROY"
case plans.Create:
crud = "CREATE"
}
} else {
// We must be working on a deposed object then, in which
// case destroying is the only possible action.
crud = "DESTROY"
}
extra := ""
if rc.Current == nil && len(rc.Deposed) > 0 {
extra = " (deposed only)"
}
fmt.Fprintf(
&mBuf, "%s: %s%s\n",
crud, resourceKey, extra,
)
attrNames := map[string]bool{}
var oldAttrs map[string]string
var newAttrs map[string]string
if before := rc.Current.Before; before != nil {
ty, err := before.ImpliedType()
if err == nil {
val, err := before.Decode(ty)
if err == nil {
oldAttrs = hcl2shim.FlatmapValueFromHCL2(val)
for k := range oldAttrs {
attrNames[k] = true
}
}
}
}
if after := rc.Current.After; after != nil {
ty, err := after.ImpliedType()
if err == nil {
val, err := after.Decode(ty)
if err == nil {
newAttrs = hcl2shim.FlatmapValueFromHCL2(val)
for k := range newAttrs {
attrNames[k] = true
}
}
}
}
if oldAttrs == nil {
oldAttrs = make(map[string]string)
}
if newAttrs == nil {
newAttrs = make(map[string]string)
}
attrNamesOrder := make([]string, 0, len(attrNames))
keyLen := 0
for n := range attrNames {
attrNamesOrder = append(attrNamesOrder, n)
if len(n) > keyLen {
keyLen = len(n)
}
}
for _, attrK := range attrNamesOrder {
v := newAttrs[attrK]
u := oldAttrs[attrK]
if v == config.UnknownVariableValue {
v = "<computed>"
}
// NOTE: we don't support <sensitive> here because we would
// need schema to do that. Excluding sensitive values
// is now done at the UI layer, and so should not be tested
// at the core layer.
updateMsg := ""
// TODO: Mark " (forces new resource)" in updateMsg when appropriate.
fmt.Fprintf(
&mBuf, " %s:%s %#v => %#v%s\n",
attrK,
strings.Repeat(" ", keyLen-len(attrK)),
u, v,
updateMsg,
)
}
}
if moduleKey == "" { // root module
buf.Write(mBuf.Bytes())
buf.WriteByte('\n')
continue
}
fmt.Fprintf(&buf, "%s:\n", moduleKey)
s := bufio.NewScanner(&mBuf)
for s.Scan() {
buf.WriteString(fmt.Sprintf(" %s\n", s.Text()))
}
}
return buf.String()
}
// assertNoDiagnostics fails the test in progress (using t.Fatal) if the given
// diagnostics is non-empty.
func assertNoDiagnostics(t *testing.T, diags tfdiags.Diagnostics) {
t.Helper()
if len(diags) == 0 {
return
}
logDiagnostics(t, diags)
t.FailNow()
}
// assertNoDiagnostics fails the test in progress (using t.Fatal) if the given
// diagnostics has any errors.
func assertNoErrors(t *testing.T, diags tfdiags.Diagnostics) {
t.Helper()
if !diags.HasErrors() {
return
}
logDiagnostics(t, diags)
t.FailNow()
}
// logDiagnostics is a test helper that logs the given diagnostics to to the
// given testing.T using t.Log, in a way that is hopefully useful in debugging
// a test. It does not generate any errors or fail the test. See
// assertNoDiagnostics and assertNoErrors for more specific helpers that can
// also fail the test.
func logDiagnostics(t *testing.T, diags tfdiags.Diagnostics) {
t.Helper()
for _, diag := range diags {
desc := diag.Description()
rng := diag.Source()
var severity string
switch diag.Severity() {
case tfdiags.Error:
severity = "ERROR"
case tfdiags.Warning:
severity = "WARN"
default:
severity = "???" // should never happen
}
if subj := rng.Subject; subj != nil {
if desc.Detail == "" {
t.Logf("[%s@%s] %s", severity, subj.StartString(), desc.Summary)
} else {
t.Logf("[%s@%s] %s: %s", severity, subj.StartString(), desc.Summary, desc.Detail)
}
} else {
if desc.Detail == "" {
t.Logf("[%s] %s", severity, desc.Summary)
} else {
t.Logf("[%s] %s: %s", severity, desc.Summary, desc.Detail)
}
}
}
}
const testContextGraph = `
root: root
aws_instance.bar
aws_instance.bar -> provider.aws
aws_instance.foo
aws_instance.foo -> provider.aws
provider.aws
root
root -> aws_instance.bar
root -> aws_instance.foo
`
const testContextRefreshModuleStr = `
aws_instance.web: (tainted)
ID = bar
provider = provider.aws
module.child:
aws_instance.web:
ID = new
provider = provider.aws
`
const testContextRefreshOutputStr = `
aws_instance.web:
ID = foo
provider = provider.aws
foo = bar
Outputs:
foo = bar
`
const testContextRefreshOutputPartialStr = `
<no state>
`
const testContextRefreshTaintedStr = `
aws_instance.web: (tainted)
ID = foo
provider = provider.aws
`