opentofu/terraform/context_test.go
Alex Pilon 77757d9f5b
prune references to config/module
delete config/module
prune references to config except in terraform/resource.go
move, cleanup, and delete inert code
2019-08-07 17:50:59 -04:00

1117 lines
26 KiB
Go

package terraform
import (
"bufio"
"bytes"
"fmt"
"io/ioutil"
"log"
"os"
"path/filepath"
"sort"
"strconv"
"strings"
"testing"
"time"
"github.com/davecgh/go-spew/spew"
"github.com/google/go-cmp/cmp"
"github.com/google/go-cmp/cmp/cmpopts"
"github.com/hashicorp/go-version"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/configs/configload"
"github.com/hashicorp/terraform/configs/configschema"
"github.com/hashicorp/terraform/configs/hcl2shim"
"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"
"github.com/zclconf/go-cty/cty"
)
var (
equateEmpty = cmpopts.EquateEmpty()
typeComparer = cmp.Comparer(cty.Type.Equals)
valueComparer = cmp.Comparer(cty.Value.RawEquals)
valueTrans = cmp.Transformer("hcl2shim", hcl2shim.ConfigValueFromHCL2)
)
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 == hcl2shim.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)
}
// The id attribute always matches ID for the sake of this mock
// implementation, since it's following the pre-0.12 assumptions where
// these two were treated as synonyms.
result.Attributes["id"] = result.ID
return result, nil
}
func testDiffFn(
info *InstanceInfo,
s *InstanceState,
c *ResourceConfig) (*InstanceDiff, error) {
diff := new(InstanceDiff)
diff.Attributes = make(map[string]*ResourceAttrDiff)
defer func() {
log.Printf("[TRACE] testDiffFn: generated diff is:\n%s", spew.Sdump(diff))
}()
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] == '_' {
// ...though we do still need to include them in the diff, to
// simulate normal provider behaviors.
old := s.Attributes[k]
var new string
switch tv := v.(type) {
case string:
new = tv
default:
new = fmt.Sprintf("%#v", v)
}
if new == hcl2shim.UnknownVariableValue {
diff.Attributes[k] = &ResourceAttrDiff{
Old: old,
New: "",
NewComputed: true,
}
} else {
diff.Attributes[k] = &ResourceAttrDiff{
Old: old,
New: new,
}
}
continue
}
if k == "nil" {
return nil, nil
}
// This key is used for other purposes
if k == "compute_value" {
if old, ok := s.Attributes["compute_value"]; !ok || old != v.(string) {
diff.Attributes["compute_value"] = &ResourceAttrDiff{
Old: old,
New: v.(string),
}
}
continue
}
if k == "compute" {
// The "compute" value itself must be included in the diff if it
// has changed since prior.
if old, ok := s.Attributes["compute"]; !ok || old != v.(string) {
diff.Attributes["compute"] = &ResourceAttrDiff{
Old: old,
New: v.(string),
}
}
if v == hcl2shim.UnknownVariableValue || 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
continue
}
// 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
}
old := ""
if s != nil {
old = s.Attributes[k]
}
diff.Attributes[k] = &ResourceAttrDiff{
Old: 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,
}
if s != nil && s.Attributes != nil {
diff.Attributes["type"].Old = s.Attributes["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,
Computed: true,
},
"bar": {
Type: cty.String,
Optional: true,
},
"compute": {
Type: cty.String,
Optional: true,
Computed: false,
},
"compute_value": {
Type: cty.String,
Optional: true,
Computed: true,
},
"value": {
Type: cty.String,
Optional: true,
Computed: 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,
Computed: true,
},
"ids": {
Type: cty.List(cty.String),
Optional: true,
Computed: 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,
}
// To make life a little easier for test authors, we'll populate a simple
// backend configuration if they didn't set one, since the backend is
// usually dealt with in a calling package and so tests in this package
// don't really care about it.
if plan.Backend.Config == nil {
cfg, err := plans.NewDynamicValue(cty.EmptyObjectVal, cty.EmptyObject)
if err != nil {
panic(fmt.Sprintf("NewDynamicValue failed: %s", err)) // shouldn't happen because we control the inputs
}
plan.Backend.Type = "local"
plan.Backend.Config = cfg
plan.Backend.Workspace = "default"
}
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
}
// 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 {
if rc.Action == plans.NoOp {
// We won't mention no-op changes here at all, since the old plan
// model we are emulating here didn't have such a concept.
continue
}
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.DeleteThenCreate:
crud = "DESTROY/CREATE"
case plans.CreateThenDelete:
crud = "CREATE/DESTROY"
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 rc.Current != nil {
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)
}
}
sort.Strings(attrNamesOrder)
for _, attrK := range attrNamesOrder {
v := newAttrs[attrK]
u := oldAttrs[attrK]
if v == hcl2shim.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
`