package configupgrade import ( "bytes" "fmt" "io" "log" "sort" "strings" version "github.com/hashicorp/go-version" hcl1ast "github.com/hashicorp/hcl/hcl/ast" hcl1parser "github.com/hashicorp/hcl/hcl/parser" hcl1printer "github.com/hashicorp/hcl/hcl/printer" hcl1token "github.com/hashicorp/hcl/hcl/token" hcl2 "github.com/hashicorp/hcl2/hcl" "github.com/zclconf/go-cty/cty" "github.com/hashicorp/terraform/addrs" backendinit "github.com/hashicorp/terraform/backend/init" "github.com/hashicorp/terraform/configs/configschema" "github.com/hashicorp/terraform/tfdiags" ) type upgradeFileResult struct { Content []byte ProviderRequirements map[string]version.Constraints } func (u *Upgrader) upgradeNativeSyntaxFile(filename string, src []byte, an *analysis) (upgradeFileResult, tfdiags.Diagnostics) { var result upgradeFileResult var diags tfdiags.Diagnostics log.Printf("[TRACE] configupgrade: Working on %q", filename) var buf bytes.Buffer f, err := hcl1parser.Parse(src) if err != nil { return result, diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Syntax error in configuration file", Detail: fmt.Sprintf("Error while parsing: %s", err), Subject: hcl1ErrSubjectRange(filename, err), }) } rootList := f.Node.(*hcl1ast.ObjectList) rootItems := rootList.Items adhocComments := collectAdhocComments(f) for _, item := range rootItems { comments := adhocComments.TakeBefore(item) for _, group := range comments { printComments(&buf, group) buf.WriteByte('\n') // Extra separator after each group } blockType := item.Keys[0].Token.Value().(string) labels := make([]string, len(item.Keys)-1) for i, key := range item.Keys[1:] { labels[i] = key.Token.Value().(string) } body, isObject := item.Val.(*hcl1ast.ObjectType) if !isObject { // Should never happen for valid input, since we don't expect // any non-block items at our top level. diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagWarning, Summary: "Unsupported top-level attribute", Detail: fmt.Sprintf("Attribute %q is not expected here, so its expression was not upgraded.", blockType), Subject: hcl1PosRange(filename, item.Keys[0].Pos()).Ptr(), }) // Preserve the item as-is, using the hcl1printer package. buf.WriteString("# TF-UPGRADE-TODO: Top-level attributes are not valid, so this was not automatically upgraded.\n") hcl1printer.Fprint(&buf, item) buf.WriteString("\n\n") continue } declRange := hcl1PosRange(filename, item.Keys[0].Pos()) switch blockType { case "resource", "data": if len(labels) != 2 { // Should never happen for valid input. diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must have two labels: the type and the name.", blockType), Subject: &declRange, }) continue } rAddr := addrs.Resource{ Mode: addrs.ManagedResourceMode, Type: labels[0], Name: labels[1], } if blockType == "data" { rAddr.Mode = addrs.DataResourceMode } log.Printf("[TRACE] configupgrade: Upgrading %s at %s", rAddr, declRange) moreDiags := u.upgradeNativeSyntaxResource(filename, &buf, rAddr, item, an, adhocComments) diags = diags.Append(moreDiags) case "provider": if len(labels) != 1 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must have one label: the provider type.", blockType), Subject: &declRange, }) continue } pType := labels[0] log.Printf("[TRACE] configupgrade: Upgrading provider.%s at %s", pType, declRange) moreDiags := u.upgradeNativeSyntaxProvider(filename, &buf, pType, item, an, adhocComments) diags = diags.Append(moreDiags) case "terraform": if len(labels) != 0 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must not have any labels.", blockType), Subject: &declRange, }) continue } moreDiags := u.upgradeNativeSyntaxTerraformBlock(filename, &buf, item, an, adhocComments) diags = diags.Append(moreDiags) case "variable": if len(labels) != 1 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must have one label: the variable name.", blockType), Subject: &declRange, }) continue } printComments(&buf, item.LeadComment) printBlockOpen(&buf, blockType, labels, item.LineComment) rules := bodyContentRules{ "description": noInterpAttributeRule(filename, cty.String, an), "default": noInterpAttributeRule(filename, cty.DynamicPseudoType, an), "type": maybeBareKeywordAttributeRule(filename, an, map[string]string{ // "list" and "map" in older versions were documented to // mean list and map of strings, so we'll migrate to that // and let the user adjust it to some other type if desired. "list": `list(string)`, "map": `map(string)`, }), } log.Printf("[TRACE] configupgrade: Upgrading var.%s at %s", labels[0], declRange) bodyDiags := upgradeBlockBody(filename, fmt.Sprintf("var.%s", labels[0]), &buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") case "output": if len(labels) != 1 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must have one label: the output name.", blockType), Subject: &declRange, }) continue } printComments(&buf, item.LeadComment) printBlockOpen(&buf, blockType, labels, item.LineComment) rules := bodyContentRules{ "description": noInterpAttributeRule(filename, cty.String, an), "value": normalAttributeRule(filename, cty.DynamicPseudoType, an), "sensitive": noInterpAttributeRule(filename, cty.Bool, an), "depends_on": dependsOnAttributeRule(filename, an), } log.Printf("[TRACE] configupgrade: Upgrading output.%s at %s", labels[0], declRange) bodyDiags := upgradeBlockBody(filename, fmt.Sprintf("output.%s", labels[0]), &buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") case "module": if len(labels) != 1 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: fmt.Sprintf("Invalid %s block", blockType), Detail: fmt.Sprintf("A %s block must have one label: the module call name.", blockType), Subject: &declRange, }) continue } // Since upgrading is a single-module endeavor, we don't have access // to the configuration of the child module here, but we know that // in practice all arguments that aren't reserved meta-arguments // in a module block are normal expression attributes so we'll // start with the straightforward mapping of those and override // the special lifecycle arguments below. rules := justAttributesBodyRules(filename, body, an) rules["source"] = noInterpAttributeRule(filename, cty.String, an) rules["version"] = noInterpAttributeRule(filename, cty.String, an) rules["providers"] = func(buf *bytes.Buffer, blockAddr string, item *hcl1ast.ObjectItem) tfdiags.Diagnostics { var diags tfdiags.Diagnostics subBody, ok := item.Val.(*hcl1ast.ObjectType) if !ok { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Invalid providers argument", Detail: `The "providers" argument must be a map from provider addresses in the child module to corresponding provider addresses in this module.`, Subject: &declRange, }) return diags } // We're gonna cheat here and use justAttributesBodyRules to // find all the attribute names but then just rewrite them all // to be our specialized traversal-style mapping instead. subRules := justAttributesBodyRules(filename, subBody, an) for k := range subRules { subRules[k] = maybeBareTraversalAttributeRule(filename, an) } buf.WriteString("providers = {\n") bodyDiags := upgradeBlockBody(filename, blockAddr, buf, subBody.List.Items, body.Rbrace, subRules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n") return diags } printComments(&buf, item.LeadComment) printBlockOpen(&buf, blockType, labels, item.LineComment) log.Printf("[TRACE] configupgrade: Upgrading module.%s at %s", labels[0], declRange) bodyDiags := upgradeBlockBody(filename, fmt.Sprintf("module.%s", labels[0]), &buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") case "locals": log.Printf("[TRACE] configupgrade: Upgrading locals block at %s", declRange) printComments(&buf, item.LeadComment) printBlockOpen(&buf, blockType, labels, item.LineComment) // The "locals" block contents are free-form declarations, so // we'll just use the default attribute mapping rule for everything // inside it. rules := justAttributesBodyRules(filename, body, an) log.Printf("[TRACE] configupgrade: Upgrading locals block at %s", declRange) bodyDiags := upgradeBlockBody(filename, "locals", &buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") default: // Should never happen for valid input, because the above cases // are exhaustive for valid blocks as of Terraform 0.11. diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagWarning, Summary: "Unsupported root block type", Detail: fmt.Sprintf("The block type %q is not expected here, so its content was not upgraded.", blockType), Subject: hcl1PosRange(filename, item.Keys[0].Pos()).Ptr(), }) // Preserve the block as-is, using the hcl1printer package. buf.WriteString("# TF-UPGRADE-TODO: Block type was not recognized, so this block and its contents were not automatically upgraded.\n") hcl1printer.Fprint(&buf, item) buf.WriteString("\n\n") continue } } // Print out any leftover comments for _, group := range *adhocComments { printComments(&buf, group) } result.Content = buf.Bytes() return result, diags } func (u *Upgrader) upgradeNativeSyntaxResource(filename string, buf *bytes.Buffer, addr addrs.Resource, item *hcl1ast.ObjectItem, an *analysis, adhocComments *commentQueue) tfdiags.Diagnostics { var diags tfdiags.Diagnostics body := item.Val.(*hcl1ast.ObjectType) declRange := hcl1PosRange(filename, item.Keys[0].Pos()) // We should always have a schema for each provider in our analysis // object. If not, it's a bug in the analyzer. providerType, ok := an.ResourceProviderType[addr] if !ok { panic(fmt.Sprintf("unknown provider type for %s", addr.String())) } providerSchema, ok := an.ProviderSchemas[providerType] if !ok { panic(fmt.Sprintf("missing schema for provider type %q", providerType)) } schema, _ := providerSchema.SchemaForResourceAddr(addr) if schema == nil { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Unknown resource type", Detail: fmt.Sprintf("The resource type %q is not known to the currently-selected version of provider %q.", addr.Type, providerType), Subject: &declRange, }) return diags } var blockType string switch addr.Mode { case addrs.ManagedResourceMode: blockType = "resource" case addrs.DataResourceMode: blockType = "data" } labels := []string{addr.Type, addr.Name} rules := schemaDefaultBodyRules(filename, schema, an, adhocComments) rules["count"] = normalAttributeRule(filename, cty.Number, an) rules["depends_on"] = dependsOnAttributeRule(filename, an) rules["provider"] = maybeBareTraversalAttributeRule(filename, an) rules["lifecycle"] = nestedBlockRule(filename, lifecycleBlockBodyRules(filename, an), an, adhocComments) rules["connection"] = func(buf *bytes.Buffer, blockAddr string, item *hcl1ast.ObjectItem) tfdiags.Diagnostics { // TODO: For the few resource types that were setting ConnInfo in // state after create/update in prior versions, generate the additional // explicit connection settings that are now required if and only if // there's at least one provisioner block. // For now, we just pass this through as-is. hcl1printer.Fprint(buf, item) buf.WriteByte('\n') return nil } rules["provisioner"] = func(buf *bytes.Buffer, blockAddr string, item *hcl1ast.ObjectItem) tfdiags.Diagnostics { // TODO: Look up the provisioner schema and map this properly to ensure // any references get properly updated. // For now, we just pass this through as-is. hcl1printer.Fprint(buf, item) buf.WriteByte('\n') return nil } printComments(buf, item.LeadComment) printBlockOpen(buf, blockType, labels, item.LineComment) bodyDiags := upgradeBlockBody(filename, addr.String(), buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") return diags } func (u *Upgrader) upgradeNativeSyntaxProvider(filename string, buf *bytes.Buffer, typeName string, item *hcl1ast.ObjectItem, an *analysis, adhocComments *commentQueue) tfdiags.Diagnostics { var diags tfdiags.Diagnostics body := item.Val.(*hcl1ast.ObjectType) // We should always have a schema for each provider in our analysis // object. If not, it's a bug in the analyzer. providerSchema, ok := an.ProviderSchemas[typeName] if !ok { panic(fmt.Sprintf("missing schema for provider type %q", typeName)) } schema := providerSchema.Provider rules := schemaDefaultBodyRules(filename, schema, an, adhocComments) rules["alias"] = noInterpAttributeRule(filename, cty.String, an) rules["version"] = noInterpAttributeRule(filename, cty.String, an) printComments(buf, item.LeadComment) printBlockOpen(buf, "provider", []string{typeName}, item.LineComment) bodyDiags := upgradeBlockBody(filename, fmt.Sprintf("provider.%s", typeName), buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") return diags } func (u *Upgrader) upgradeNativeSyntaxTerraformBlock(filename string, buf *bytes.Buffer, item *hcl1ast.ObjectItem, an *analysis, adhocComments *commentQueue) tfdiags.Diagnostics { var diags tfdiags.Diagnostics body := item.Val.(*hcl1ast.ObjectType) rules := bodyContentRules{ "required_version": noInterpAttributeRule(filename, cty.String, an), "backend": func(buf *bytes.Buffer, blockAddr string, item *hcl1ast.ObjectItem) tfdiags.Diagnostics { var diags tfdiags.Diagnostics declRange := hcl1PosRange(filename, item.Keys[0].Pos()) if len(item.Keys) != 2 { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: `Invalid backend block`, Detail: `A backend block must have one label: the backend type name.`, Subject: &declRange, }) return diags } typeName := item.Keys[1].Token.Value().(string) beFn := backendinit.Backend(typeName) if beFn == nil { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Unsupported backend type", Detail: fmt.Sprintf("Terraform does not support a backend type named %q.", typeName), Subject: &declRange, }) return diags } be := beFn() schema := be.ConfigSchema() rules := schemaNoInterpBodyRules(filename, schema, an, adhocComments) body := item.Val.(*hcl1ast.ObjectType) printComments(buf, item.LeadComment) printBlockOpen(buf, "backend", []string{typeName}, item.LineComment) bodyDiags := upgradeBlockBody(filename, fmt.Sprintf("terraform.backend.%s", typeName), buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n") return diags }, } printComments(buf, item.LeadComment) printBlockOpen(buf, "terraform", nil, item.LineComment) bodyDiags := upgradeBlockBody(filename, "terraform", buf, body.List.Items, body.Rbrace, rules, adhocComments) diags = diags.Append(bodyDiags) buf.WriteString("}\n\n") return diags } func upgradeBlockBody(filename string, blockAddr string, buf *bytes.Buffer, args []*hcl1ast.ObjectItem, end hcl1token.Pos, rules bodyContentRules, adhocComments *commentQueue) tfdiags.Diagnostics { var diags tfdiags.Diagnostics for i, arg := range args { comments := adhocComments.TakeBefore(arg) for _, group := range comments { printComments(buf, group) buf.WriteByte('\n') // Extra separator after each group } printComments(buf, arg.LeadComment) name := arg.Keys[0].Token.Value().(string) rule, expected := rules[name] if !expected { if arg.Assign.IsValid() { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Unrecognized attribute name", Detail: fmt.Sprintf("No attribute named %q is expected in %s.", name, blockAddr), Subject: hcl1PosRange(filename, arg.Keys[0].Pos()).Ptr(), }) } else { diags = diags.Append(&hcl2.Diagnostic{ Severity: hcl2.DiagError, Summary: "Unrecognized block type", Detail: fmt.Sprintf("Blocks of type %q are not expected in %s.", name, blockAddr), Subject: hcl1PosRange(filename, arg.Keys[0].Pos()).Ptr(), }) } continue } itemDiags := rule(buf, blockAddr, arg) diags = diags.Append(itemDiags) // If we have another item and it's more than one line away // from the current one then we'll print an extra blank line // to retain that separation. if (i + 1) < len(args) { next := args[i+1] thisPos := hcl1NodeEndPos(arg) nextPos := next.Pos() if nextPos.Line-thisPos.Line > 1 { buf.WriteByte('\n') } } } // Before we return, we must also print any remaining adhocComments that // appear between our last item and the closing brace. comments := adhocComments.TakeBeforePos(end) for i, group := range comments { printComments(buf, group) if i < len(comments)-1 { buf.WriteByte('\n') // Extra separator after each group } } return diags } // printDynamicBody prints out a conservative, exhaustive dynamic block body // for every attribute and nested block in the given schema, for situations // when a dynamic expression was being assigned to a block type name in input // configuration and so we can assume it's a list of maps but can't make // any assumptions about what subset of the schema-specified keys might be // present in the map values. func printDynamicBlockBody(buf *bytes.Buffer, iterName string, schema *configschema.Block) tfdiags.Diagnostics { var diags tfdiags.Diagnostics attrNames := make([]string, 0, len(schema.Attributes)) for name := range schema.Attributes { attrNames = append(attrNames, name) } sort.Strings(attrNames) for _, name := range attrNames { attrS := schema.Attributes[name] if !(attrS.Required || attrS.Optional) { // no Computed-only attributes continue } if attrS.Required { // For required attributes we can generate a simpler expression // that just assumes the presence of the key representing the // attribute value. printAttribute(buf, name, []byte(fmt.Sprintf(`%s.value.%s`, iterName, name)), nil) } else { // Otherwise we must be conservative and generate a conditional // lookup that will just populate nothing at all if the expected // key is not present. printAttribute(buf, name, []byte(fmt.Sprintf(`lookup(%s.value, %q, null)`, iterName, name)), nil) } } blockTypeNames := make([]string, 0, len(schema.BlockTypes)) for name := range schema.BlockTypes { blockTypeNames = append(blockTypeNames, name) } sort.Strings(blockTypeNames) for i, name := range blockTypeNames { blockS := schema.BlockTypes[name] // We'll disregard any block type that consists only of computed // attributes, since otherwise we'll just create weird empty blocks // that do nothing except create confusion. if !schemaHasSettableArguments(&blockS.Block) { continue } if i > 0 || len(attrNames) > 0 { buf.WriteByte('\n') } printBlockOpen(buf, "dynamic", []string{name}, nil) switch blockS.Nesting { case configschema.NestingMap: printAttribute(buf, "for_each", []byte(fmt.Sprintf(`lookup(%s.value, %q, {})`, iterName, name)), nil) printAttribute(buf, "labels", []byte(fmt.Sprintf(`[%s.key]`, name)), nil) case configschema.NestingSingle: printAttribute(buf, "for_each", []byte(fmt.Sprintf(`lookup(%s.value, %q, null) != null ? [%s.value.%s] : []`, iterName, name, iterName, name)), nil) default: printAttribute(buf, "for_each", []byte(fmt.Sprintf(`lookup(%s.value, %q, [])`, iterName, name)), nil) } printBlockOpen(buf, "content", nil, nil) moreDiags := printDynamicBlockBody(buf, name, &blockS.Block) diags = diags.Append(moreDiags) buf.WriteString("}\n") buf.WriteString("}\n") } return diags } func printComments(buf *bytes.Buffer, group *hcl1ast.CommentGroup) { if group == nil { return } for _, comment := range group.List { buf.WriteString(comment.Text) buf.WriteByte('\n') } } func printBlockOpen(buf *bytes.Buffer, blockType string, labels []string, commentGroup *hcl1ast.CommentGroup) { buf.WriteString(blockType) for _, label := range labels { buf.WriteByte(' ') printQuotedString(buf, label) } buf.WriteString(" {") if commentGroup != nil { for _, c := range commentGroup.List { buf.WriteByte(' ') buf.WriteString(c.Text) } } buf.WriteByte('\n') } func printAttribute(buf *bytes.Buffer, name string, valSrc []byte, commentGroup *hcl1ast.CommentGroup) { buf.WriteString(name) buf.WriteString(" = ") buf.Write(valSrc) if commentGroup != nil { for _, c := range commentGroup.List { buf.WriteByte(' ') buf.WriteString(c.Text) } } buf.WriteByte('\n') } func printQuotedString(buf *bytes.Buffer, val string) { buf.WriteByte('"') printStringLiteralFromHILOutput(buf, val) buf.WriteByte('"') } func printStringLiteralFromHILOutput(buf *bytes.Buffer, val string) { val = strings.Replace(val, `\`, `\\`, -1) val = strings.Replace(val, `"`, `\"`, -1) val = strings.Replace(val, "\n", `\n`, -1) val = strings.Replace(val, "\r", `\r`, -1) val = strings.Replace(val, `${`, `$${`, -1) val = strings.Replace(val, `%{`, `%%{`, -1) buf.WriteString(val) } func printHeredocLiteralFromHILOutput(buf *bytes.Buffer, val string) { val = strings.Replace(val, `${`, `$${`, -1) val = strings.Replace(val, `%{`, `%%{`, -1) buf.WriteString(val) } func collectAdhocComments(f *hcl1ast.File) *commentQueue { comments := make(map[hcl1token.Pos]*hcl1ast.CommentGroup) for _, c := range f.Comments { comments[c.Pos()] = c } // We'll remove from our map any comments that are attached to specific // nodes as lead or line comments, since we'll find those during our // walk anyway. hcl1ast.Walk(f, func(nn hcl1ast.Node) (hcl1ast.Node, bool) { switch t := nn.(type) { case *hcl1ast.LiteralType: if t.LeadComment != nil { for _, comment := range t.LeadComment.List { delete(comments, comment.Pos()) } } if t.LineComment != nil { for _, comment := range t.LineComment.List { delete(comments, comment.Pos()) } } case *hcl1ast.ObjectItem: if t.LeadComment != nil { for _, comment := range t.LeadComment.List { delete(comments, comment.Pos()) } } if t.LineComment != nil { for _, comment := range t.LineComment.List { delete(comments, comment.Pos()) } } } return nn, true }) if len(comments) == 0 { var ret commentQueue return &ret } ret := make([]*hcl1ast.CommentGroup, 0, len(comments)) for _, c := range comments { ret = append(ret, c) } sort.Slice(ret, func(i, j int) bool { return ret[i].Pos().Before(ret[j].Pos()) }) queue := commentQueue(ret) return &queue } type commentQueue []*hcl1ast.CommentGroup func (q *commentQueue) TakeBeforeToken(token hcl1token.Token) []*hcl1ast.CommentGroup { return q.TakeBeforePos(token.Pos) } func (q *commentQueue) TakeBefore(node hcl1ast.Node) []*hcl1ast.CommentGroup { return q.TakeBeforePos(node.Pos()) } func (q *commentQueue) TakeBeforePos(pos hcl1token.Pos) []*hcl1ast.CommentGroup { toPos := pos var i int for i = 0; i < len(*q); i++ { if (*q)[i].Pos().After(toPos) { break } } if i == 0 { return nil } ret := (*q)[:i] *q = (*q)[i:] return ret } // hcl1NodeEndPos tries to find the latest possible position in the given // node. This is primarily to try to find the last line number of a multi-line // construct and is a best-effort sort of thing because HCL1 only tracks // start positions for tokens and has no generalized way to find the full // range for a single node. func hcl1NodeEndPos(node hcl1ast.Node) hcl1token.Pos { switch tn := node.(type) { case *hcl1ast.ObjectItem: if tn.LineComment != nil && len(tn.LineComment.List) > 0 { return tn.LineComment.List[len(tn.LineComment.List)-1].Start } return hcl1NodeEndPos(tn.Val) case *hcl1ast.ListType: return tn.Rbrack case *hcl1ast.ObjectType: return tn.Rbrace default: // If all else fails, we'll just return the position of what we were given. return tn.Pos() } } func hcl1ErrSubjectRange(filename string, err error) *hcl2.Range { if pe, isPos := err.(*hcl1parser.PosError); isPos { return hcl1PosRange(filename, pe.Pos).Ptr() } return nil } func hcl1PosRange(filename string, pos hcl1token.Pos) hcl2.Range { return hcl2.Range{ Filename: filename, Start: hcl2.Pos{ Line: pos.Line, Column: pos.Column, Byte: pos.Offset, }, End: hcl2.Pos{ Line: pos.Line, Column: pos.Column, Byte: pos.Offset, }, } } func passthruBlockTodo(w io.Writer, node hcl1ast.Node, msg string) { fmt.Fprintf(w, "\n# TF-UPGRADE-TODO: %s\n", msg) hcl1printer.Fprint(w, node) w.Write([]byte{'\n', '\n'}) } func schemaHasSettableArguments(schema *configschema.Block) bool { for _, attrS := range schema.Attributes { if attrS.Optional || attrS.Required { return true } } for _, blockS := range schema.BlockTypes { if schemaHasSettableArguments(&blockS.Block) { return true } } return false }