package command import ( "context" "fmt" "os" "path/filepath" "sort" "github.com/hashicorp/hcl/v2" "github.com/hashicorp/hcl/v2/hclsyntax" "github.com/hashicorp/terraform-config-inspect/tfconfig" "github.com/hashicorp/terraform/configs" "github.com/hashicorp/terraform/configs/configload" "github.com/hashicorp/terraform/configs/configschema" "github.com/hashicorp/terraform/internal/earlyconfig" "github.com/hashicorp/terraform/internal/initwd" "github.com/hashicorp/terraform/registry" "github.com/hashicorp/terraform/terraform" "github.com/hashicorp/terraform/tfdiags" "github.com/zclconf/go-cty/cty" "github.com/zclconf/go-cty/cty/convert" ) // normalizePath normalizes a given path so that it is, if possible, relative // to the current working directory. This is primarily used to prepare // paths used to load configuration, because we want to prefer recording // relative paths in source code references within the configuration. func (m *Meta) normalizePath(path string) string { var err error // First we will make it absolute so that we have a consistent place // to start. path, err = filepath.Abs(path) if err != nil { // We'll just accept what we were given, then. return path } cwd, err := os.Getwd() if err != nil || !filepath.IsAbs(cwd) { return path } ret, err := filepath.Rel(cwd, path) if err != nil { return path } return ret } // loadConfig reads a configuration from the given directory, which should // contain a root module and have already have any required descendent modules // installed. func (m *Meta) loadConfig(rootDir string) (*configs.Config, tfdiags.Diagnostics) { var diags tfdiags.Diagnostics rootDir = m.normalizePath(rootDir) loader, err := m.initConfigLoader() if err != nil { diags = diags.Append(err) return nil, diags } config, hclDiags := loader.LoadConfig(rootDir) diags = diags.Append(hclDiags) return config, diags } // loadSingleModule reads configuration from the given directory and returns // a description of that module only, without attempting to assemble a module // tree for referenced child modules. // // Most callers should use loadConfig. This method exists to support early // initialization use-cases where the root module must be inspected in order // to determine what else needs to be installed before the full configuration // can be used. func (m *Meta) loadSingleModule(dir string) (*configs.Module, tfdiags.Diagnostics) { var diags tfdiags.Diagnostics dir = m.normalizePath(dir) loader, err := m.initConfigLoader() if err != nil { diags = diags.Append(err) return nil, diags } module, hclDiags := loader.Parser().LoadConfigDir(dir) diags = diags.Append(hclDiags) return module, diags } // loadSingleModuleEarly is a variant of loadSingleModule that uses the special // "early config" loader that is more forgiving of unexpected constructs and // legacy syntax. // // Early-loaded config is not registered in the source code cache, so // diagnostics produced from it may render without source code snippets. In // practice this is not a big concern because the early config loader also // cannot generate detailed source locations, so it prefers to produce // diagnostics without explicit source location information and instead includes // approximate locations in the message text. // // Most callers should use loadConfig. This method exists to support early // initialization use-cases where the root module must be inspected in order // to determine what else needs to be installed before the full configuration // can be used. func (m *Meta) loadSingleModuleEarly(dir string) (*tfconfig.Module, tfdiags.Diagnostics) { var diags tfdiags.Diagnostics dir = m.normalizePath(dir) module, moreDiags := earlyconfig.LoadModule(dir) diags = diags.Append(moreDiags) return module, diags } // dirIsConfigPath checks if the given path is a directory that contains at // least one Terraform configuration file (.tf or .tf.json), returning true // if so. // // In the unlikely event that the underlying config loader cannot be initalized, // this function optimistically returns true, assuming that the caller will // then do some other operation that requires the config loader and get an // error at that point. func (m *Meta) dirIsConfigPath(dir string) bool { loader, err := m.initConfigLoader() if err != nil { return true } return loader.IsConfigDir(dir) } // loadBackendConfig reads configuration from the given directory and returns // the backend configuration defined by that module, if any. Nil is returned // if the specified module does not have an explicit backend configuration. // // This is a convenience method for command code that will delegate to the // configured backend to do most of its work, since in that case it is the // backend that will do the full configuration load. // // Although this method returns only the backend configuration, at present it // actually loads and validates the entire configuration first. Therefore errors // returned may be about other aspects of the configuration. This behavior may // change in future, so callers must not rely on it. (That is, they must expect // that a call to loadSingleModule or loadConfig could fail on the same // directory even if loadBackendConfig succeeded.) func (m *Meta) loadBackendConfig(rootDir string) (*configs.Backend, tfdiags.Diagnostics) { mod, diags := m.loadSingleModule(rootDir) // Only return error diagnostics at this point. Any warnings will be caught // again later and duplicated in the output. if diags.HasErrors() { return nil, diags } return mod.Backend, nil } // loadHCLFile reads an arbitrary HCL file and returns the unprocessed body // representing its toplevel. Most callers should use one of the more // specialized "load..." methods to get a higher-level representation. func (m *Meta) loadHCLFile(filename string) (hcl.Body, tfdiags.Diagnostics) { var diags tfdiags.Diagnostics filename = m.normalizePath(filename) loader, err := m.initConfigLoader() if err != nil { diags = diags.Append(err) return nil, diags } body, hclDiags := loader.Parser().LoadHCLFile(filename) diags = diags.Append(hclDiags) return body, diags } // installModules reads a root module from the given directory and attempts // recursively install all of its descendent modules. // // The given hooks object will be notified of installation progress, which // can then be relayed to the end-user. The moduleUiInstallHooks type in // this package has a reasonable implementation for displaying notifications // via a provided cli.Ui. func (m *Meta) installModules(rootDir string, upgrade bool, hooks initwd.ModuleInstallHooks) tfdiags.Diagnostics { var diags tfdiags.Diagnostics rootDir = m.normalizePath(rootDir) err := os.MkdirAll(m.modulesDir(), os.ModePerm) if err != nil { diags = diags.Append(fmt.Errorf("failed to create local modules directory: %s", err)) return diags } inst := m.moduleInstaller() _, moreDiags := inst.InstallModules(rootDir, upgrade, hooks) diags = diags.Append(moreDiags) return diags } // initDirFromModule initializes the given directory (which should be // pre-verified as empty by the caller) by copying the source code from the // given module address. // // Internally this runs similar steps to installModules. // The given hooks object will be notified of installation progress, which // can then be relayed to the end-user. The moduleUiInstallHooks type in // this package has a reasonable implementation for displaying notifications // via a provided cli.Ui. func (m *Meta) initDirFromModule(targetDir string, addr string, hooks initwd.ModuleInstallHooks) tfdiags.Diagnostics { var diags tfdiags.Diagnostics targetDir = m.normalizePath(targetDir) moreDiags := initwd.DirFromModule(targetDir, m.modulesDir(), addr, m.registryClient(), hooks) diags = diags.Append(moreDiags) return diags } // inputForSchema uses interactive prompts to try to populate any // not-yet-populated required attributes in the given object value to // comply with the given schema. // // An error will be returned if input is disabled for this meta or if // values cannot be obtained for some other operational reason. Errors are // not returned for invalid input since the input loop itself will report // that interactively. // // It is not guaranteed that the result will be valid, since certain attribute // types and nested blocks are not supported for input. // // The given value must conform to the given schema. If not, this method will // panic. func (m *Meta) inputForSchema(given cty.Value, schema *configschema.Block) (cty.Value, error) { if given.IsNull() || !given.IsKnown() { // This is not reasonable input, but we'll tolerate it anyway and // just pass it through for the caller to handle downstream. return given, nil } retVals := given.AsValueMap() names := make([]string, 0, len(schema.Attributes)) for name, attrS := range schema.Attributes { if attrS.Required && retVals[name].IsNull() && attrS.Type.IsPrimitiveType() { names = append(names, name) } } sort.Strings(names) input := m.UIInput() for _, name := range names { attrS := schema.Attributes[name] for { strVal, err := input.Input(context.Background(), &terraform.InputOpts{ Id: name, Query: name, Description: attrS.Description, }) if err != nil { return cty.UnknownVal(schema.ImpliedType()), fmt.Errorf("%s: %s", name, err) } val := cty.StringVal(strVal) val, err = convert.Convert(val, attrS.Type) if err != nil { m.showDiagnostics(fmt.Errorf("Invalid value: %s", err)) continue } retVals[name] = val break } } return cty.ObjectVal(retVals), nil } // configSources returns the source cache from the receiver's config loader, // which the caller must not modify. // // If a config loader has not yet been instantiated then no files could have // been loaded already, so this method returns a nil map in that case. func (m *Meta) configSources() map[string][]byte { if m.configLoader == nil { return nil } return m.configLoader.Sources() } func (m *Meta) modulesDir() string { return filepath.Join(m.DataDir(), "modules") } // registerSynthConfigSource allows commands to add synthetic additional source // buffers to the config loader's cache of sources (as returned by // configSources), which is useful when a command is directly parsing something // from the command line that may produce diagnostics, so that diagnostic // snippets can still be produced. // // If this is called before a configLoader has been initialized then it will // try to initialize the loader but ignore any initialization failure, turning // the call into a no-op. (We presume that a caller will later call a different // function that also initializes the config loader as a side effect, at which // point those errors can be returned.) func (m *Meta) registerSynthConfigSource(filename string, src []byte) { loader, err := m.initConfigLoader() if err != nil || loader == nil { return // treated as no-op, since this is best-effort } loader.Parser().ForceFileSource(filename, src) } // initConfigLoader initializes the shared configuration loader if it isn't // already initialized. // // If the loader cannot be created for some reason then an error is returned // and no loader is created. Subsequent calls will presumably see the same // error. Loader initialization errors will tend to prevent any further use // of most Terraform features, so callers should report any error and safely // terminate. func (m *Meta) initConfigLoader() (*configload.Loader, error) { if m.configLoader == nil { loader, err := configload.NewLoader(&configload.Config{ ModulesDir: m.modulesDir(), Services: m.Services, }) if err != nil { return nil, err } m.configLoader = loader if m.View != nil { m.View.SetConfigSources(loader.Sources) } } return m.configLoader, nil } // moduleInstaller instantiates and returns a module installer for use by // "terraform init" (directly or indirectly). func (m *Meta) moduleInstaller() *initwd.ModuleInstaller { reg := m.registryClient() return initwd.NewModuleInstaller(m.modulesDir(), reg) } // registryClient instantiates and returns a new Terraform Registry client. func (m *Meta) registryClient() *registry.Client { return registry.NewClient(m.Services, nil) } // configValueFromCLI parses a configuration value that was provided in a // context in the CLI where only strings can be provided, such as on the // command line or in an environment variable, and returns the resulting // value. func configValueFromCLI(synthFilename, rawValue string, wantType cty.Type) (cty.Value, tfdiags.Diagnostics) { var diags tfdiags.Diagnostics switch { case wantType.IsPrimitiveType(): // Primitive types are handled as conversions from string. val := cty.StringVal(rawValue) var err error val, err = convert.Convert(val, wantType) if err != nil { diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Invalid backend configuration value", fmt.Sprintf("Invalid backend configuration argument %s: %s", synthFilename, err), )) val = cty.DynamicVal // just so we return something valid-ish } return val, diags default: // Non-primitives are parsed as HCL expressions src := []byte(rawValue) expr, hclDiags := hclsyntax.ParseExpression(src, synthFilename, hcl.Pos{Line: 1, Column: 1}) diags = diags.Append(hclDiags) if hclDiags.HasErrors() { return cty.DynamicVal, diags } val, hclDiags := expr.Value(nil) diags = diags.Append(hclDiags) if hclDiags.HasErrors() { val = cty.DynamicVal } return val, diags } } // rawFlags is a flag.Value implementation that just appends raw flag // names and values to a slice. type rawFlags struct { flagName string items *[]rawFlag } func newRawFlags(flagName string) rawFlags { var items []rawFlag return rawFlags{ flagName: flagName, items: &items, } } func (f rawFlags) Empty() bool { if f.items == nil { return true } return len(*f.items) == 0 } func (f rawFlags) AllItems() []rawFlag { if f.items == nil { return nil } return *f.items } func (f rawFlags) Alias(flagName string) rawFlags { return rawFlags{ flagName: flagName, items: f.items, } } func (f rawFlags) String() string { return "" } func (f rawFlags) Set(str string) error { *f.items = append(*f.items, rawFlag{ Name: f.flagName, Value: str, }) return nil } type rawFlag struct { Name string Value string } func (f rawFlag) String() string { return fmt.Sprintf("%s=%q", f.Name, f.Value) }