terraform/internal/command/command_test.go

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package command
import (
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"bytes"
"crypto/md5"
"encoding/base64"
"encoding/json"
"fmt"
"io"
"io/ioutil"
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"net/http"
"net/http/httptest"
"os"
"os/exec"
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"path/filepath"
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"strings"
"syscall"
"testing"
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svchost "github.com/hashicorp/terraform-svchost"
"github.com/hashicorp/terraform-svchost/disco"
"github.com/hashicorp/terraform/internal/addrs"
backendInit "github.com/hashicorp/terraform/internal/backend/init"
backendLocal "github.com/hashicorp/terraform/internal/backend/local"
"github.com/hashicorp/terraform/internal/command/views"
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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"github.com/hashicorp/terraform/internal/command/workdir"
"github.com/hashicorp/terraform/internal/configs"
"github.com/hashicorp/terraform/internal/configs/configload"
"github.com/hashicorp/terraform/internal/configs/configschema"
"github.com/hashicorp/terraform/internal/copy"
backend/local: Check dependency lock consistency before any operations In historical versions of Terraform the responsibility to check this was inside the terraform.NewContext function, along with various other assorted concerns that made that function particularly complicated. More recently, we reduced the responsibility of the "terraform" package only to instantiating particular named plugins, assuming that its caller is responsible for selecting appropriate versions of any providers that _are_ external. However, until this commit we were just assuming that "terraform init" had correctly selected appropriate plugins and recorded them in the lock file, and so nothing was dealing with the problem of ensuring that there haven't been any changes to the lock file or config since the most recent "terraform init" which would cause us to need to re-evaluate those decisions. Part of the game here is to slightly extend the role of the dependency locks object to also carry information about a subset of provider addresses whose lock entries we're intentionally disregarding as part of the various little edge-case features we have for overridding providers: dev_overrides, "unmanaged providers", and the testing overrides in our own unit tests. This is an in-memory-only annotation, never included in the serialized plan files on disk. I had originally intended to create a new package to encapsulate all of this plugin-selection logic, including both the version constraint checking here and also the handling of the provider factory functions, but as an interim step I've just made version constraint consistency checks the responsibility of the backend/local package, which means that we'll always catch problems as part of preparing for local operations, while not imposing these additional checks on commands that _don't_ run local operations, such as "terraform apply" when in remote operations mode.
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"github.com/hashicorp/terraform/internal/depsfile"
"github.com/hashicorp/terraform/internal/getproviders"
"github.com/hashicorp/terraform/internal/initwd"
legacy "github.com/hashicorp/terraform/internal/legacy/terraform"
_ "github.com/hashicorp/terraform/internal/logging"
"github.com/hashicorp/terraform/internal/plans"
"github.com/hashicorp/terraform/internal/plans/planfile"
"github.com/hashicorp/terraform/internal/providers"
"github.com/hashicorp/terraform/internal/registry"
"github.com/hashicorp/terraform/internal/states"
"github.com/hashicorp/terraform/internal/states/statefile"
"github.com/hashicorp/terraform/internal/states/statemgr"
"github.com/hashicorp/terraform/internal/terminal"
"github.com/hashicorp/terraform/internal/terraform"
"github.com/hashicorp/terraform/version"
"github.com/zclconf/go-cty/cty"
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)
// These are the directories for our test data and fixtures.
var (
fixtureDir = "./testdata"
testDataDir = "./testdata"
)
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// a top level temp directory which will be cleaned after all tests
var testingDir string
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func init() {
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test = true
// Initialize the backends
backendInit.Init(nil)
// Expand the data and fixture dirs on init because
// we change the working directory in some tests.
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var err error
fixtureDir, err = filepath.Abs(fixtureDir)
if err != nil {
panic(err)
}
testDataDir, err = filepath.Abs(testDataDir)
if err != nil {
panic(err)
}
testingDir, err = ioutil.TempDir(testingDir, "tf")
if err != nil {
panic(err)
}
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}
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func TestMain(m *testing.M) {
defer os.RemoveAll(testingDir)
// Make sure backend init is initialized, since our tests tend to assume it.
backendInit.Init(nil)
os.Exit(m.Run())
}
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func tempDir(t *testing.T) string {
t.Helper()
dir, err := ioutil.TempDir(testingDir, "tf")
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if err != nil {
t.Fatalf("err: %s", err)
}
dir, err = filepath.EvalSymlinks(dir)
if err != nil {
t.Fatal(err)
}
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if err := os.RemoveAll(dir); err != nil {
t.Fatalf("err: %s", err)
}
return dir
}
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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// tempWorkingDir constructs a workdir.Dir object referring to a newly-created
// temporary directory, and returns that object along with a cleanup function
// to call once the calling test is complete.
//
// Although workdir.Dir is built to support arbitrary base directories, the
// not-yet-migrated behaviors in command.Meta tend to expect the root module
// directory to be the real process working directory, and so if you intend
// to use the result inside a command.Meta object you must use a pattern
// similar to the following when initializing your test:
//
// wd, cleanup := tempWorkingDir(t)
// defer cleanup()
// defer testChdir(t, wd.RootModuleDir())()
//
// Note that testChdir modifies global state for the test process, and so a
// test using this pattern must never call t.Parallel().
func tempWorkingDir(t *testing.T) (*workdir.Dir, func() error) {
t.Helper()
dirPath, err := os.MkdirTemp("", "tf-command-test-")
if err != nil {
t.Fatal(err)
}
done := func() error {
return os.RemoveAll(dirPath)
}
t.Logf("temporary directory %s", dirPath)
return workdir.NewDir(dirPath), done
}
// tempWorkingDirFixture is like tempWorkingDir but it also copies the content
// from a fixture directory into the temporary directory before returning it.
//
// The same caveats about working directory apply as for testWorkingDir. See
// the testWorkingDir commentary for an example of how to use this function
// along with testChdir to meet the expectations of command.Meta legacy
// functionality.
func tempWorkingDirFixture(t *testing.T, fixtureName string) *workdir.Dir {
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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t.Helper()
dirPath := testTempDir(t)
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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t.Logf("temporary directory %s with fixture %q", dirPath, fixtureName)
fixturePath := testFixturePath(fixtureName)
testCopyDir(t, fixturePath, dirPath)
// NOTE: Unfortunately because testCopyDir immediately aborts the test
// on failure, a failure to copy will prevent us from cleaning up the
// temporary directory. Oh well. :(
return workdir.NewDir(dirPath)
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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}
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func testFixturePath(name string) string {
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return filepath.Join(fixtureDir, name)
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}
func metaOverridesForProvider(p providers.Interface) *testingOverrides {
return &testingOverrides{
Providers: map[addrs.Provider]providers.Factory{
addrs.NewDefaultProvider("test"): providers.FactoryFixed(p),
},
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}
}
func testModuleWithSnapshot(t *testing.T, name string) (*configs.Config, *configload.Snapshot) {
t.Helper()
dir := filepath.Join(fixtureDir, name)
// FIXME: We're not dealing with the cleanup function here because
// this testModule function is used all over and so we don't want to
// change its interface at this late stage.
loader, _ := configload.NewLoaderForTests(t)
// Test modules usually do not refer to remote sources, and for local
// sources only this ultimately just records all of the module paths
// in a JSON file so that we can load them below.
inst := initwd.NewModuleInstaller(loader.ModulesDir(), registry.NewClient(nil, nil))
command: "terraform init" can partially initialize for 0.12upgrade There are a few constructs from 0.11 and prior that cause 0.12 parsing to fail altogether, which previously created a chicken/egg problem because we need to install the providers in order to run "terraform 0.12upgrade" and thus fix the problem. This changes "terraform init" to use the new "early configuration" loader for module and provider installation. This is built on the more permissive parser in the terraform-config-inspect package, and so it allows us to read out the top-level blocks from the configuration while accepting legacy HCL syntax. In the long run this will let us do version compatibility detection before attempting a "real" config load, giving us better error messages for any future syntax additions, but in the short term the key thing is that it allows us to install the dependencies even if the configuration isn't fully valid. Because backend init still requires full configuration, this introduces a new mode of terraform init where it detects heuristically if it seems like we need to do a configuration upgrade and does a partial init if so, before finally directing the user to run "terraform 0.12upgrade" before running any other commands. The heuristic here is based on two assumptions: - If the "early" loader finds no errors but the normal loader does, the configuration is likely to be valid for Terraform 0.11 but not 0.12. - If there's already a version constraint in the configuration that excludes Terraform versions prior to v0.12 then the configuration is probably _already_ upgraded and so it's just a normal syntax error, even if the early loader didn't detect it. Once the upgrade process is removed in 0.13.0 (users will be required to go stepwise 0.11 -> 0.12 -> 0.13 to upgrade after that), some of this can be simplified to remove that special mode, but the idea of doing the dependency version checks against the liberal parser will remain valuable to increase our chances of reporting version-based incompatibilities rather than syntax errors as we add new features in future.
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_, instDiags := inst.InstallModules(dir, true, initwd.ModuleInstallHooksImpl{})
if instDiags.HasErrors() {
t.Fatal(instDiags.Err())
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}
config, snap, diags := loader.LoadConfigWithSnapshot(dir)
if diags.HasErrors() {
t.Fatal(diags.Error())
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}
return config, snap
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}
// testPlan returns a non-nil noop plan.
func testPlan(t *testing.T) *plans.Plan {
t.Helper()
// This is what an empty configuration block would look like after being
// decoded with the schema of the "local" backend.
backendConfig := cty.ObjectVal(map[string]cty.Value{
"path": cty.NullVal(cty.String),
"workspace_dir": cty.NullVal(cty.String),
})
backendConfigRaw, err := plans.NewDynamicValue(backendConfig, backendConfig.Type())
if err != nil {
t.Fatal(err)
}
return &plans.Plan{
Backend: plans.Backend{
// This is just a placeholder so that the plan file can be written
// out. Caller may wish to override it to something more "real"
// where the plan will actually be subsequently applied.
Type: "local",
Config: backendConfigRaw,
},
Changes: plans.NewChanges(),
}
}
func testPlanFile(t *testing.T, configSnap *configload.Snapshot, state *states.State, plan *plans.Plan) string {
t.Helper()
stateFile := &statefile.File{
Lineage: "",
State: state,
TerraformVersion: version.SemVer,
}
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prevStateFile := &statefile.File{
Lineage: "",
State: state, // we just assume no changes detected during refresh
TerraformVersion: version.SemVer,
}
path := testTempFile(t)
err := planfile.Create(path, planfile.CreateArgs{
ConfigSnapshot: configSnap,
PreviousRunStateFile: prevStateFile,
StateFile: stateFile,
Plan: plan,
backend/local: Check dependency lock consistency before any operations In historical versions of Terraform the responsibility to check this was inside the terraform.NewContext function, along with various other assorted concerns that made that function particularly complicated. More recently, we reduced the responsibility of the "terraform" package only to instantiating particular named plugins, assuming that its caller is responsible for selecting appropriate versions of any providers that _are_ external. However, until this commit we were just assuming that "terraform init" had correctly selected appropriate plugins and recorded them in the lock file, and so nothing was dealing with the problem of ensuring that there haven't been any changes to the lock file or config since the most recent "terraform init" which would cause us to need to re-evaluate those decisions. Part of the game here is to slightly extend the role of the dependency locks object to also carry information about a subset of provider addresses whose lock entries we're intentionally disregarding as part of the various little edge-case features we have for overridding providers: dev_overrides, "unmanaged providers", and the testing overrides in our own unit tests. This is an in-memory-only annotation, never included in the serialized plan files on disk. I had originally intended to create a new package to encapsulate all of this plugin-selection logic, including both the version constraint checking here and also the handling of the provider factory functions, but as an interim step I've just made version constraint consistency checks the responsibility of the backend/local package, which means that we'll always catch problems as part of preparing for local operations, while not imposing these additional checks on commands that _don't_ run local operations, such as "terraform apply" when in remote operations mode.
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DependencyLocks: depsfile.NewLocks(),
})
if err != nil {
t.Fatalf("failed to create temporary plan file: %s", err)
}
return path
}
// testPlanFileNoop is a shortcut function that creates a plan file that
// represents no changes and returns its path. This is useful when a test
// just needs any plan file, and it doesn't matter what is inside it.
func testPlanFileNoop(t *testing.T) string {
snap := &configload.Snapshot{
Modules: map[string]*configload.SnapshotModule{
"": {
Dir: ".",
Files: map[string][]byte{
"main.tf": nil,
},
},
},
}
state := states.NewState()
plan := testPlan(t)
return testPlanFile(t, snap, state, plan)
}
func testReadPlan(t *testing.T, path string) *plans.Plan {
t.Helper()
f, err := planfile.Open(path)
if err != nil {
t.Fatalf("error opening plan file %q: %s", path, err)
}
defer f.Close()
p, err := f.ReadPlan()
if err != nil {
t.Fatalf("error reading plan from plan file %q: %s", path, err)
}
return p
}
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// testState returns a test State structure that we use for a lot of tests.
func testState() *states.State {
return states.BuildState(func(s *states.SyncState) {
s.SetResourceInstanceCurrent(
addrs.Resource{
Mode: addrs.ManagedResourceMode,
Type: "test_instance",
Name: "foo",
}.Instance(addrs.NoKey).Absolute(addrs.RootModuleInstance),
&states.ResourceInstanceObjectSrc{
// The weird whitespace here is reflective of how this would
// get written out in a real state file, due to the indentation
// of all of the containing wrapping objects and arrays.
AttrsJSON: []byte("{\n \"id\": \"bar\"\n }"),
Status: states.ObjectReady,
Dependencies: []addrs.ConfigResource{},
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},
addrs.AbsProviderConfig{
Provider: addrs.NewDefaultProvider("test"),
Module: addrs.RootModule,
},
)
// DeepCopy is used here to ensure our synthetic state matches exactly
// with a state that will have been copied during the command
// operation, and all fields have been copied correctly.
}).DeepCopy()
}
// writeStateForTesting is a helper that writes the given naked state to the
// given writer, generating a stub *statefile.File wrapper which is then
// immediately discarded.
func writeStateForTesting(state *states.State, w io.Writer) error {
sf := &statefile.File{
Serial: 0,
Lineage: "fake-for-testing",
State: state,
}
return statefile.Write(sf, w)
}
// testStateMgrCurrentLineage returns the current lineage for the given state
// manager, or the empty string if it does not use lineage. This is primarily
// for testing against the local backend, which always supports lineage.
func testStateMgrCurrentLineage(mgr statemgr.Persistent) string {
if pm, ok := mgr.(statemgr.PersistentMeta); ok {
m := pm.StateSnapshotMeta()
return m.Lineage
}
return ""
}
// markStateForMatching is a helper that writes a specific marker value to
// a state so that it can be recognized later with getStateMatchingMarker.
//
// Internally this just sets a root module output value called "testing_mark"
// to the given string value. If the state is being checked in other ways,
// the test code may need to compensate for the addition or overwriting of this
// special output value name.
//
// The given mark string is returned verbatim, to allow the following pattern
// in tests:
//
// mark := markStateForMatching(state, "foo")
// // (do stuff to the state)
// assertStateHasMarker(state, mark)
func markStateForMatching(state *states.State, mark string) string {
state.RootModule().SetOutputValue("testing_mark", cty.StringVal(mark), false)
return mark
}
// getStateMatchingMarker is used with markStateForMatching to retrieve the
// mark string previously added to the given state. If no such mark is present,
// the result is an empty string.
func getStateMatchingMarker(state *states.State) string {
os := state.RootModule().OutputValues["testing_mark"]
if os == nil {
return ""
}
v := os.Value
if v.Type() == cty.String && v.IsKnown() && !v.IsNull() {
return v.AsString()
}
return ""
}
// stateHasMarker is a helper around getStateMatchingMarker that also includes
// the equality test, for more convenient use in test assertion branches.
func stateHasMarker(state *states.State, want string) bool {
return getStateMatchingMarker(state) == want
}
// assertStateHasMarker wraps stateHasMarker to automatically generate a
// fatal test result (i.e. t.Fatal) if the marker doesn't match.
func assertStateHasMarker(t *testing.T, state *states.State, want string) {
if !stateHasMarker(state, want) {
t.Fatalf("wrong state marker\ngot: %q\nwant: %q", getStateMatchingMarker(state), want)
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}
}
func testStateFile(t *testing.T, s *states.State) string {
t.Helper()
path := testTempFile(t)
f, err := os.Create(path)
if err != nil {
t.Fatalf("failed to create temporary state file %s: %s", path, err)
}
defer f.Close()
err = writeStateForTesting(s, f)
if err != nil {
t.Fatalf("failed to write state to temporary file %s: %s", path, err)
}
return path
}
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// testStateFileDefault writes the state out to the default statefile
// in the cwd. Use `testCwd` to change into a temp cwd.
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func testStateFileDefault(t *testing.T, s *states.State) {
t.Helper()
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f, err := os.Create(DefaultStateFilename)
if err != nil {
t.Fatalf("err: %s", err)
}
defer f.Close()
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if err := writeStateForTesting(s, f); err != nil {
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t.Fatalf("err: %s", err)
}
}
// testStateFileWorkspaceDefault writes the state out to the default statefile
// for the given workspace in the cwd. Use `testCwd` to change into a temp cwd.
func testStateFileWorkspaceDefault(t *testing.T, workspace string, s *states.State) string {
t.Helper()
workspaceDir := filepath.Join(backendLocal.DefaultWorkspaceDir, workspace)
err := os.MkdirAll(workspaceDir, os.ModePerm)
if err != nil {
t.Fatalf("err: %s", err)
}
path := filepath.Join(workspaceDir, DefaultStateFilename)
f, err := os.Create(path)
if err != nil {
t.Fatalf("err: %s", err)
}
defer f.Close()
if err := writeStateForTesting(s, f); err != nil {
t.Fatalf("err: %s", err)
}
return path
}
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// testStateFileRemote writes the state out to the remote statefile
// in the cwd. Use `testCwd` to change into a temp cwd.
func testStateFileRemote(t *testing.T, s *legacy.State) string {
t.Helper()
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path := filepath.Join(DefaultDataDir, DefaultStateFilename)
if err := os.MkdirAll(filepath.Dir(path), 0755); err != nil {
t.Fatalf("err: %s", err)
}
f, err := os.Create(path)
if err != nil {
t.Fatalf("err: %s", err)
}
defer f.Close()
if err := legacy.WriteState(s, f); err != nil {
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t.Fatalf("err: %s", err)
}
return path
}
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// testStateRead reads the state from a file
func testStateRead(t *testing.T, path string) *states.State {
t.Helper()
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f, err := os.Open(path)
if err != nil {
t.Fatalf("err: %s", err)
}
defer f.Close()
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sf, err := statefile.Read(f)
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if err != nil {
t.Fatalf("err: %s", err)
}
return sf.State
}
// testDataStateRead reads a "data state", which is a file format resembling
// our state format v3 that is used only to track current backend settings.
//
// This old format still uses *legacy.State, but should be replaced with
// a more specialized type in a later release.
func testDataStateRead(t *testing.T, path string) *legacy.State {
t.Helper()
f, err := os.Open(path)
if err != nil {
t.Fatalf("err: %s", err)
}
defer f.Close()
s, err := legacy.ReadState(f)
if err != nil {
t.Fatalf("err: %s", err)
}
return s
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}
// testStateOutput tests that the state at the given path contains
// the expected state string.
func testStateOutput(t *testing.T, path string, expected string) {
t.Helper()
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newState := testStateRead(t, path)
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actual := strings.TrimSpace(newState.String())
expected = strings.TrimSpace(expected)
if actual != expected {
t.Fatalf("expected:\n%s\nactual:\n%s", expected, actual)
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}
}
func testProvider() *terraform.MockProvider {
p := new(terraform.MockProvider)
p.PlanResourceChangeFn = func(req providers.PlanResourceChangeRequest) (resp providers.PlanResourceChangeResponse) {
resp.PlannedState = req.ProposedNewState
return resp
}
p.ReadResourceFn = func(req providers.ReadResourceRequest) providers.ReadResourceResponse {
return providers.ReadResourceResponse{
NewState: req.PriorState,
}
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}
return p
}
func testTempFile(t *testing.T) string {
t.Helper()
return filepath.Join(testTempDir(t), "state.tfstate")
}
func testTempDir(t *testing.T) string {
t.Helper()
d := t.TempDir()
d, err := filepath.EvalSymlinks(d)
if err != nil {
t.Fatal(err)
}
return d
}
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// testChdir changes the directory and returns a function to defer to
// revert the old cwd.
func testChdir(t *testing.T, new string) func() {
t.Helper()
old, err := os.Getwd()
if err != nil {
t.Fatalf("err: %s", err)
}
if err := os.Chdir(new); err != nil {
t.Fatalf("err: %v", err)
}
return func() {
// Re-run the function ignoring the defer result
testChdir(t, old)
}
}
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// testCwd is used to change the current working directory
// into a test directory that should be removed after
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func testCwd(t *testing.T) (string, string) {
t.Helper()
tmp, err := ioutil.TempDir(testingDir, "tf")
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if err != nil {
t.Fatalf("err: %v", err)
}
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cwd, err := os.Getwd()
if err != nil {
t.Fatalf("err: %v", err)
}
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if err := os.Chdir(tmp); err != nil {
t.Fatalf("err: %v", err)
}
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return tmp, cwd
}
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// testFixCwd is used to as a defer to testDir
func testFixCwd(t *testing.T, tmp, cwd string) {
t.Helper()
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if err := os.Chdir(cwd); err != nil {
t.Fatalf("err: %v", err)
}
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if err := os.RemoveAll(tmp); err != nil {
t.Fatalf("err: %v", err)
}
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}
// testStdinPipe changes os.Stdin to be a pipe that sends the data from
// the reader before closing the pipe.
//
// The returned function should be deferred to properly clean up and restore
// the original stdin.
func testStdinPipe(t *testing.T, src io.Reader) func() {
t.Helper()
r, w, err := os.Pipe()
if err != nil {
t.Fatalf("err: %s", err)
}
// Modify stdin to point to our new pipe
old := os.Stdin
os.Stdin = r
// Copy the data from the reader to the pipe
go func() {
defer w.Close()
io.Copy(w, src)
}()
return func() {
// Close our read end
r.Close()
// Reset stdin
os.Stdin = old
}
}
// Modify os.Stdout to write to the given buffer. Note that this is generally
// not useful since the commands are configured to write to a cli.Ui, not
// Stdout directly. Commands like `console` though use the raw stdout.
func testStdoutCapture(t *testing.T, dst io.Writer) func() {
t.Helper()
r, w, err := os.Pipe()
if err != nil {
t.Fatalf("err: %s", err)
}
// Modify stdout
old := os.Stdout
os.Stdout = w
// Copy
doneCh := make(chan struct{})
go func() {
defer close(doneCh)
defer r.Close()
io.Copy(dst, r)
}()
return func() {
// Close the writer end of the pipe
w.Sync()
w.Close()
// Reset stdout
os.Stdout = old
// Wait for the data copy to complete to avoid a race reading data
<-doneCh
}
}
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// testInteractiveInput configures tests so that the answers given are sent
// in order to interactive prompts. The returned function must be called
// in a defer to clean up.
func testInteractiveInput(t *testing.T, answers []string) func() {
t.Helper()
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// Disable test mode so input is called
test = false
// Set up reader/writers
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testInputResponse = answers
defaultInputReader = bytes.NewBufferString("")
defaultInputWriter = new(bytes.Buffer)
// Return the cleanup
return func() {
test = true
testInputResponse = nil
}
}
// testInputMap configures tests so that the given answers are returned
// for calls to Input when the right question is asked. The key is the
// question "Id" that is used.
func testInputMap(t *testing.T, answers map[string]string) func() {
t.Helper()
// Disable test mode so input is called
test = false
// Set up reader/writers
defaultInputReader = bytes.NewBufferString("")
defaultInputWriter = new(bytes.Buffer)
// Setup answers
testInputResponse = nil
testInputResponseMap = answers
// Return the cleanup
return func() {
var unusedAnswers = testInputResponseMap
// First, clean up!
test = true
testInputResponseMap = nil
if len(unusedAnswers) > 0 {
t.Fatalf("expected no unused answers provided to command.testInputMap, got: %v", unusedAnswers)
}
}
}
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// testBackendState is used to make a test HTTP server to test a configured
// backend. This returns the complete state that can be saved. Use
// `testStateFileRemote` to write the returned state.
//
// When using this function, the configuration fixture for the test must
// include an empty configuration block for the HTTP backend, like this:
//
// terraform {
// backend "http" {
// }
// }
//
// If such a block isn't present, or if it isn't empty, then an error will
// be returned about the backend configuration having changed and that
// "terraform init" must be run, since the test backend config cache created
// by this function contains the hash for an empty configuration.
func testBackendState(t *testing.T, s *states.State, c int) (*legacy.State, *httptest.Server) {
t.Helper()
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var b64md5 string
buf := bytes.NewBuffer(nil)
cb := func(resp http.ResponseWriter, req *http.Request) {
if req.Method == "PUT" {
resp.WriteHeader(c)
return
}
if s == nil {
resp.WriteHeader(404)
return
}
resp.Header().Set("Content-MD5", b64md5)
resp.Write(buf.Bytes())
}
// If a state was given, make sure we calculate the proper b64md5
if s != nil {
err := statefile.Write(&statefile.File{State: s}, buf)
if err != nil {
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t.Fatalf("err: %v", err)
}
md5 := md5.Sum(buf.Bytes())
b64md5 = base64.StdEncoding.EncodeToString(md5[:16])
}
srv := httptest.NewServer(http.HandlerFunc(cb))
backendConfig := &configs.Backend{
Type: "http",
Config: configs.SynthBody("<testBackendState>", map[string]cty.Value{}),
}
b := backendInit.Backend("http")()
configSchema := b.ConfigSchema()
hash := backendConfig.Hash(configSchema)
state := legacy.NewState()
state.Backend = &legacy.BackendState{
Type: "http",
ConfigRaw: json.RawMessage(fmt.Sprintf(`{"address":%q}`, srv.URL)),
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Hash: uint64(hash),
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}
return state, srv
}
// testRemoteState is used to make a test HTTP server to return a given
// state file that can be used for testing legacy remote state.
//
// The return values are a *legacy.State instance that should be written
// as the "data state" (really: backend state) and the server that the
// returned data state refers to.
func testRemoteState(t *testing.T, s *states.State, c int) (*legacy.State, *httptest.Server) {
t.Helper()
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var b64md5 string
buf := bytes.NewBuffer(nil)
cb := func(resp http.ResponseWriter, req *http.Request) {
if req.Method == "PUT" {
resp.WriteHeader(c)
return
}
if s == nil {
resp.WriteHeader(404)
return
}
resp.Header().Set("Content-MD5", b64md5)
resp.Write(buf.Bytes())
}
retState := legacy.NewState()
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srv := httptest.NewServer(http.HandlerFunc(cb))
b := &legacy.BackendState{
Type: "http",
}
b.SetConfig(cty.ObjectVal(map[string]cty.Value{
"address": cty.StringVal(srv.URL),
}), &configschema.Block{
Attributes: map[string]*configschema.Attribute{
"address": {
Type: cty.String,
Required: true,
},
},
})
retState.Backend = b
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if s != nil {
err := statefile.Write(&statefile.File{State: s}, buf)
if err != nil {
t.Fatalf("failed to write initial state: %v", err)
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}
}
return retState, srv
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}
// testlockState calls a separate process to the lock the state file at path.
// deferFunc should be called in the caller to properly unlock the file.
// Since many tests change the working directory, the sourcedir argument must be
// supplied to locate the statelocker.go source.
func testLockState(sourceDir, path string) (func(), error) {
// build and run the binary ourselves so we can quickly terminate it for cleanup
buildDir, err := ioutil.TempDir(testingDir, "locker")
if err != nil {
return nil, err
}
cleanFunc := func() {
os.RemoveAll(buildDir)
}
source := filepath.Join(sourceDir, "statelocker.go")
lockBin := filepath.Join(buildDir, "statelocker")
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cmd := exec.Command("go", "build", "-o", lockBin, source)
cmd.Dir = filepath.Dir(sourceDir)
out, err := cmd.CombinedOutput()
if err != nil {
cleanFunc()
return nil, fmt.Errorf("%s %s", err, out)
}
locker := exec.Command(lockBin, path)
pr, pw, err := os.Pipe()
if err != nil {
cleanFunc()
return nil, err
}
defer pr.Close()
defer pw.Close()
locker.Stderr = pw
locker.Stdout = pw
if err := locker.Start(); err != nil {
return nil, err
}
deferFunc := func() {
cleanFunc()
locker.Process.Signal(syscall.SIGTERM)
locker.Wait()
}
// wait for the process to lock
buf := make([]byte, 1024)
n, err := pr.Read(buf)
if err != nil {
return deferFunc, fmt.Errorf("read from statelocker returned: %s", err)
}
output := string(buf[:n])
if !strings.HasPrefix(output, "LOCKID") {
return deferFunc, fmt.Errorf("statelocker wrote: %s", string(buf[:n]))
}
return deferFunc, nil
}
// testCopyDir recursively copies a directory tree, attempting to preserve
workdir: Start of a new package for working directory state management Thus far our various interactions with the bits of state we keep associated with a working directory have all been implemented directly inside the "command" package -- often in the huge command.Meta type -- and not managed collectively via a single component. There's too many little codepaths reading and writing from the working directory and data directory to refactor it all in one step, but this is an attempt at a first step towards a future where everything that reads and writes from the current working directory would do so via an object that encapsulates the implementation details and offers a high-level API to read and write all of these session-persistent settings. The design here continues our gradual path towards using a dependency injection style where "package main" is solely responsible for directly interacting with the OS command line, the OS environment, the OS working directory, the stdio streams, and the CLI configuration, and then communicating the resulting information to the rest of Terraform by wiring together objects. It seems likely that eventually we'll have enough wiring code in package main to justify a more explicit organization of that code, but for this commit the new "workdir.Dir" object is just wired directly in place of its predecessors, without any significant change of code organization at that top layer. This first commit focuses on the main files and directories we use to find provider plugins, because a subsequent commit will lightly reorganize the separation of concerns for plugin launching with a similar goal of collecting all of the relevant logic together into one spot.
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// permissions. Source directory must exist, destination directory may exist
// but will be created if not; it should typically be a temporary directory,
// and thus already created using os.MkdirTemp or similar.
// Symlinks are ignored and skipped.
func testCopyDir(t *testing.T, src, dst string) {
t.Helper()
src = filepath.Clean(src)
dst = filepath.Clean(dst)
si, err := os.Stat(src)
if err != nil {
t.Fatal(err)
}
if !si.IsDir() {
t.Fatal("source is not a directory")
}
_, err = os.Stat(dst)
if err != nil && !os.IsNotExist(err) {
t.Fatal(err)
}
err = os.MkdirAll(dst, si.Mode())
if err != nil {
t.Fatal(err)
}
entries, err := ioutil.ReadDir(src)
if err != nil {
return
}
for _, entry := range entries {
srcPath := filepath.Join(src, entry.Name())
dstPath := filepath.Join(dst, entry.Name())
// If the entry is a symlink, we copy the contents
for entry.Mode()&os.ModeSymlink != 0 {
target, err := os.Readlink(srcPath)
if err != nil {
t.Fatal(err)
}
entry, err = os.Stat(target)
if err != nil {
t.Fatal(err)
}
}
if entry.IsDir() {
testCopyDir(t, srcPath, dstPath)
} else {
err = copy.CopyFile(srcPath, dstPath)
if err != nil {
t.Fatal(err)
}
}
}
}
// normalizeJSON removes all insignificant whitespace from the given JSON buffer
// and returns it as a string for easier comparison.
func normalizeJSON(t *testing.T, src []byte) string {
t.Helper()
var buf bytes.Buffer
err := json.Compact(&buf, src)
if err != nil {
t.Fatalf("error normalizing JSON: %s", err)
}
return buf.String()
}
func mustResourceAddr(s string) addrs.ConfigResource {
addr, diags := addrs.ParseAbsResourceStr(s)
if diags.HasErrors() {
panic(diags.Err())
}
return addr.Config()
}
func mustProviderConfig(s string) addrs.AbsProviderConfig {
p, diags := addrs.ParseAbsProviderConfigStr(s)
if diags.HasErrors() {
panic(diags.Err())
}
return p
}
// This map from provider type name to namespace is used by the fake registry
// when called via LookupLegacyProvider. Providers not in this map will return
// a 404 Not Found error.
var legacyProviderNamespaces = map[string]string{
"foo": "hashicorp",
"bar": "hashicorp",
"baz": "terraform-providers",
"qux": "hashicorp",
}
// This map is used to mock the provider redirect feature.
var movedProviderNamespaces = map[string]string{
"qux": "acme",
}
// testServices starts up a local HTTP server running a fake provider registry
// service which responds only to discovery requests and legacy provider lookup
// API calls.
//
// The final return value is a function to call at the end of a test function
// to shut down the test server. After you call that function, the discovery
// object becomes useless.
func testServices(t *testing.T) (services *disco.Disco, cleanup func()) {
server := httptest.NewServer(http.HandlerFunc(fakeRegistryHandler))
services = disco.New()
services.ForceHostServices(svchost.Hostname("registry.terraform.io"), map[string]interface{}{
"providers.v1": server.URL + "/providers/v1/",
})
return services, func() {
server.Close()
}
}
// testRegistrySource is a wrapper around testServices that uses the created
// discovery object to produce a Source instance that is ready to use with the
// fake registry services.
//
// As with testServices, the final return value is a function to call at the end
// of your test in order to shut down the test server.
func testRegistrySource(t *testing.T) (source *getproviders.RegistrySource, cleanup func()) {
services, close := testServices(t)
source = getproviders.NewRegistrySource(services)
return source, close
}
func fakeRegistryHandler(resp http.ResponseWriter, req *http.Request) {
path := req.URL.EscapedPath()
if !strings.HasPrefix(path, "/providers/v1/") {
resp.WriteHeader(404)
resp.Write([]byte(`not a provider registry endpoint`))
return
}
pathParts := strings.Split(path, "/")[3:]
if len(pathParts) != 3 {
resp.WriteHeader(404)
resp.Write([]byte(`unrecognized path scheme`))
return
}
if pathParts[2] != "versions" {
resp.WriteHeader(404)
resp.Write([]byte(`this registry only supports legacy namespace lookup requests`))
return
}
name := pathParts[1]
// Legacy lookup
if pathParts[0] == "-" {
if namespace, ok := legacyProviderNamespaces[name]; ok {
resp.Header().Set("Content-Type", "application/json")
resp.WriteHeader(200)
if movedNamespace, ok := movedProviderNamespaces[name]; ok {
resp.Write([]byte(fmt.Sprintf(`{"id":"%s/%s","moved_to":"%s/%s","versions":[{"version":"1.0.0","protocols":["4"]}]}`, namespace, name, movedNamespace, name)))
} else {
resp.Write([]byte(fmt.Sprintf(`{"id":"%s/%s","versions":[{"version":"1.0.0","protocols":["4"]}]}`, namespace, name)))
}
} else {
resp.WriteHeader(404)
resp.Write([]byte(`provider not found`))
}
return
}
// Also return versions for redirect target
if namespace, ok := movedProviderNamespaces[name]; ok && pathParts[0] == namespace {
resp.Header().Set("Content-Type", "application/json")
resp.WriteHeader(200)
resp.Write([]byte(fmt.Sprintf(`{"id":"%s/%s","versions":[{"version":"1.0.0","protocols":["4"]}]}`, namespace, name)))
} else {
resp.WriteHeader(404)
resp.Write([]byte(`provider not found`))
}
}
func testView(t *testing.T) (*views.View, func(*testing.T) *terminal.TestOutput) {
streams, done := terminal.StreamsForTesting(t)
return views.NewView(streams), done
}