package terraform import ( "fmt" "github.com/hashicorp/hcl/v2" "github.com/zclconf/go-cty/cty" "github.com/zclconf/go-cty/cty/convert" "github.com/hashicorp/terraform/configs" "github.com/hashicorp/terraform/tfdiags" ) // InputValue represents a value for a variable in the root module, provided // as part of the definition of an operation. type InputValue struct { Value cty.Value SourceType ValueSourceType // SourceRange provides source location information for values whose // SourceType is either ValueFromConfig or ValueFromFile. It is not // populated for other source types, and so should not be used. SourceRange tfdiags.SourceRange } // ValueSourceType describes what broad category of source location provided // a particular value. type ValueSourceType rune const ( // ValueFromUnknown is the zero value of ValueSourceType and is not valid. ValueFromUnknown ValueSourceType = 0 // ValueFromConfig indicates that a value came from a .tf or .tf.json file, // e.g. the default value defined for a variable. ValueFromConfig ValueSourceType = 'C' // ValueFromAutoFile indicates that a value came from a "values file", like // a .tfvars file, that was implicitly loaded by naming convention. ValueFromAutoFile ValueSourceType = 'F' // ValueFromNamedFile indicates that a value came from a named "values file", // like a .tfvars file, that was passed explicitly on the command line (e.g. // -var-file=foo.tfvars). ValueFromNamedFile ValueSourceType = 'N' // ValueFromCLIArg indicates that the value was provided directly in // a CLI argument. The name of this argument is not recorded and so it must // be inferred from context. ValueFromCLIArg ValueSourceType = 'A' // ValueFromEnvVar indicates that the value was provided via an environment // variable. The name of the variable is not recorded and so it must be // inferred from context. ValueFromEnvVar ValueSourceType = 'E' // ValueFromInput indicates that the value was provided at an interactive // input prompt. ValueFromInput ValueSourceType = 'I' // ValueFromPlan indicates that the value was retrieved from a stored plan. ValueFromPlan ValueSourceType = 'P' // ValueFromCaller indicates that the value was explicitly overridden by // a caller to Context.SetVariable after the context was constructed. ValueFromCaller ValueSourceType = 'S' ) func (v *InputValue) GoString() string { if (v.SourceRange != tfdiags.SourceRange{}) { return fmt.Sprintf("&terraform.InputValue{Value: %#v, SourceType: %#v, SourceRange: %#v}", v.Value, v.SourceType, v.SourceRange) } else { return fmt.Sprintf("&terraform.InputValue{Value: %#v, SourceType: %#v}", v.Value, v.SourceType) } } func (v ValueSourceType) GoString() string { return fmt.Sprintf("terraform.%s", v) } //go:generate go run golang.org/x/tools/cmd/stringer -type ValueSourceType // InputValues is a map of InputValue instances. type InputValues map[string]*InputValue // InputValuesFromCaller turns the given map of naked values into an // InputValues that attributes each value to "a caller", using the source // type ValueFromCaller. This is primarily useful for testing purposes. // // This should not be used as a general way to convert map[string]cty.Value // into InputValues, since in most real cases we want to set a suitable // other SourceType and possibly SourceRange value. func InputValuesFromCaller(vals map[string]cty.Value) InputValues { ret := make(InputValues, len(vals)) for k, v := range vals { ret[k] = &InputValue{ Value: v, SourceType: ValueFromCaller, } } return ret } // Override merges the given value maps with the receiver, overriding any // conflicting keys so that the latest definition wins. func (vv InputValues) Override(others ...InputValues) InputValues { // FIXME: This should check to see if any of the values are maps and // merge them if so, in order to preserve the behavior from prior to // Terraform 0.12. ret := make(InputValues) for k, v := range vv { ret[k] = v } for _, other := range others { for k, v := range other { ret[k] = v } } return ret } // JustValues returns a map that just includes the values, discarding the // source information. func (vv InputValues) JustValues() map[string]cty.Value { ret := make(map[string]cty.Value, len(vv)) for k, v := range vv { ret[k] = v.Value } return ret } // DefaultVariableValues returns an InputValues map representing the default // values specified for variables in the given configuration map. func DefaultVariableValues(configs map[string]*configs.Variable) InputValues { ret := make(InputValues) for k, c := range configs { if c.Default == cty.NilVal { continue } ret[k] = &InputValue{ Value: c.Default, SourceType: ValueFromConfig, SourceRange: tfdiags.SourceRangeFromHCL(c.DeclRange), } } return ret } // SameValues returns true if the given InputValues has the same values as // the receiever, disregarding the source types and source ranges. // // Values are compared using the cty "RawEquals" method, which means that // unknown values can be considered equal to one another if they are of the // same type. func (vv InputValues) SameValues(other InputValues) bool { if len(vv) != len(other) { return false } for k, v := range vv { ov, exists := other[k] if !exists { return false } if !v.Value.RawEquals(ov.Value) { return false } } return true } // HasValues returns true if the reciever has the same values as in the given // map, disregarding the source types and source ranges. // // Values are compared using the cty "RawEquals" method, which means that // unknown values can be considered equal to one another if they are of the // same type. func (vv InputValues) HasValues(vals map[string]cty.Value) bool { if len(vv) != len(vals) { return false } for k, v := range vv { oVal, exists := vals[k] if !exists { return false } if !v.Value.RawEquals(oVal) { return false } } return true } // Identical returns true if the given InputValues has the same values, // source types, and source ranges as the receiver. // // Values are compared using the cty "RawEquals" method, which means that // unknown values can be considered equal to one another if they are of the // same type. // // This method is primarily for testing. For most practical purposes, it's // better to use SameValues or HasValues. func (vv InputValues) Identical(other InputValues) bool { if len(vv) != len(other) { return false } for k, v := range vv { ov, exists := other[k] if !exists { return false } if !v.Value.RawEquals(ov.Value) { return false } if v.SourceType != ov.SourceType { return false } if v.SourceRange != ov.SourceRange { return false } } return true } // checkInputVariables ensures that variable values supplied at the UI conform // to their corresponding declarations in configuration. // // The set of values is considered valid only if the returned diagnostics // does not contain errors. A valid set of values may still produce warnings, // which should be returned to the user. func checkInputVariables(vcs map[string]*configs.Variable, vs InputValues) tfdiags.Diagnostics { var diags tfdiags.Diagnostics for name, vc := range vcs { val, isSet := vs[name] if !isSet { // Always an error, since the caller should already have included // default values from the configuration in the values map. diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Unassigned variable", fmt.Sprintf("The input variable %q has not been assigned a value. This is a bug in Terraform; please report it in a GitHub issue.", name), )) continue } wantType := vc.Type // A given value is valid if it can convert to the desired type. _, err := convert.Convert(val.Value, wantType) if err != nil { switch val.SourceType { case ValueFromConfig, ValueFromAutoFile, ValueFromNamedFile: // We have source location information for these. diags = diags.Append(&hcl.Diagnostic{ Severity: hcl.DiagError, Summary: "Invalid value for input variable", Detail: fmt.Sprintf("The given value is not valid for variable %q: %s.", name, err), Subject: val.SourceRange.ToHCL().Ptr(), }) case ValueFromEnvVar: diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Invalid value for input variable", fmt.Sprintf("The environment variable TF_VAR_%s does not contain a valid value for variable %q: %s.", name, name, err), )) case ValueFromCLIArg: diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Invalid value for input variable", fmt.Sprintf("The argument -var=\"%s=...\" does not contain a valid value for variable %q: %s.", name, name, err), )) case ValueFromInput: diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Invalid value for input variable", fmt.Sprintf("The value entered for variable %q is not valid: %s.", name, err), )) default: // The above gets us good coverage for the situations users // are likely to encounter with their own inputs. The other // cases are generally implementation bugs, so we'll just // use a generic error for these. diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Invalid value for input variable", fmt.Sprintf("The value provided for variable %q is not valid: %s.", name, err), )) } } } // Check for any variables that are assigned without being configured. // This is always an implementation error in the caller, because we // expect undefined variables to be caught during context construction // where there is better context to report it well. for name := range vs { if _, defined := vcs[name]; !defined { diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Value assigned to undeclared variable", fmt.Sprintf("A value was assigned to an undeclared input variable %q.", name), )) } } return diags }