// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Stateify provides a simple way to generate Load/Save methods based on // existing types and struct tags. package main import ( "flag" "fmt" "go/ast" "go/parser" "go/token" "os" "path/filepath" "reflect" "strings" "sync" "gvisor.dev/gvisor/tools/constraintutil" ) var ( fullPkg = flag.String("fullpkg", "", "fully qualified output package") imports = flag.String("imports", "", "extra imports for the output file") output = flag.String("output", "", "output file") statePkg = flag.String("statepkg", "", "state import package; defaults to empty") ) // resolveTypeName returns a qualified type name. func resolveTypeName(typ ast.Expr) (field string, qualified string) { for done := false; !done; { // Resolve star expressions. switch rs := typ.(type) { case *ast.StarExpr: qualified += "*" typ = rs.X case *ast.ArrayType: if rs.Len == nil { // Slice type declaration. qualified += "[]" } else { // Array type declaration. qualified += "[" + rs.Len.(*ast.BasicLit).Value + "]" } typ = rs.Elt default: // No more descent. done = true } } // Resolve a package selector. sel, ok := typ.(*ast.SelectorExpr) if ok { qualified = qualified + sel.X.(*ast.Ident).Name + "." typ = sel.Sel } // Figure out actual type name. field = typ.(*ast.Ident).Name qualified = qualified + field return } // extractStateTag pulls the relevant state tag. func extractStateTag(tag *ast.BasicLit) string { if tag == nil { return "" } if len(tag.Value) < 2 { return "" } return reflect.StructTag(tag.Value[1 : len(tag.Value)-1]).Get("state") } // scanFunctions is a set of functions passed to scanFields. type scanFunctions struct { zerovalue func(name string) normal func(name string) wait func(name string) value func(name, typName string) } // scanFields scans the fields of a struct. // // Each provided function will be applied to appropriately tagged fields, or // skipped if nil. // // Fields tagged nosave are skipped. func scanFields(ss *ast.StructType, prefix string, fn scanFunctions) { if ss.Fields.List == nil { // No fields. return } // Scan all fields. for _, field := range ss.Fields.List { // Calculate the name. name := "" if field.Names != nil { // It's a named field; override. name = field.Names[0].Name } else { // Anonymous types can't be embedded, so we don't need // to worry about providing a useful name here. name, _ = resolveTypeName(field.Type) } // Skip _ fields. if name == "_" { continue } // Is this a anonymous struct? If yes, then continue the // recursion with the given prefix. We don't pay attention to // any tags on the top-level struct field. tag := extractStateTag(field.Tag) if anon, ok := field.Type.(*ast.StructType); ok && tag == "" { scanFields(anon, name+".", fn) continue } switch tag { case "zerovalue": if fn.zerovalue != nil { fn.zerovalue(name) } case "": if fn.normal != nil { fn.normal(name) } case "wait": if fn.wait != nil { fn.wait(name) } case "manual", "nosave", "ignore": // Do nothing. default: if strings.HasPrefix(tag, ".(") && strings.HasSuffix(tag, ")") { if fn.value != nil { fn.value(name, tag[2:len(tag)-1]) } } } } } func camelCased(name string) string { return strings.ToUpper(name[:1]) + name[1:] } func main() { // Parse flags. flag.Usage = func() { fmt.Fprintf(os.Stderr, "Usage: %s [options]\n", os.Args[0]) flag.PrintDefaults() } flag.Parse() if len(flag.Args()) == 0 { flag.Usage() os.Exit(1) } if *fullPkg == "" { fmt.Fprintf(os.Stderr, "Error: package required.") os.Exit(1) } // Open the output file. var ( outputFile *os.File err error ) if *output == "" || *output == "-" { outputFile = os.Stdout } else { outputFile, err = os.OpenFile(*output, os.O_CREATE|os.O_WRONLY|os.O_TRUNC, 0644) if err != nil { fmt.Fprintf(os.Stderr, "Error opening output %q: %v", *output, err) } defer outputFile.Close() } // Set the statePrefix for below, depending on the import. statePrefix := "" if *statePkg != "" { parts := strings.Split(*statePkg, "/") statePrefix = parts[len(parts)-1] + "." } // initCalls is dumped at the end. var initCalls []string // Common closures. emitRegister := func(name string) { initCalls = append(initCalls, fmt.Sprintf("%sRegister((*%s)(nil))", statePrefix, name)) } // Automated warning. fmt.Fprint(outputFile, "// automatically generated by stateify.\n\n") // Emit build constraints. bcexpr, err := constraintutil.CombineFromFiles(flag.Args()) if err != nil { fmt.Fprintf(os.Stderr, "Failed to infer build constraints: %v", err) os.Exit(1) } outputFile.WriteString(constraintutil.Lines(bcexpr)) // Emit the package name. _, pkg := filepath.Split(*fullPkg) fmt.Fprintf(outputFile, "package %s\n\n", pkg) // Emit the imports lazily. var once sync.Once maybeEmitImports := func() { once.Do(func() { // Emit the imports. fmt.Fprint(outputFile, "import (\n") if *statePkg != "" { fmt.Fprintf(outputFile, " \"%s\"\n", *statePkg) } if *imports != "" { for _, i := range strings.Split(*imports, ",") { fmt.Fprintf(outputFile, " \"%s\"\n", i) } } fmt.Fprint(outputFile, ")\n\n") }) } files := make([]*ast.File, 0, len(flag.Args())) // Parse the input files. for _, filename := range flag.Args() { // Parse the file. fset := token.NewFileSet() f, err := parser.ParseFile(fset, filename, nil, parser.ParseComments) if err != nil { // Not a valid input file? fmt.Fprintf(os.Stderr, "Input %q can't be parsed: %v\n", filename, err) os.Exit(1) } files = append(files, f) } type method struct { typeName string methodName string } // Search for and add all method to a set. We auto-detecting several // different methods (and insert them if we don't find them, in order // to ensure that expectations match reality). // // While we do this, figure out the right receiver name. If there are // multiple distinct receivers, then we will just pick the last one. simpleMethods := make(map[method]struct{}) receiverNames := make(map[string]string) for _, f := range files { // Go over all functions. for _, decl := range f.Decls { d, ok := decl.(*ast.FuncDecl) if !ok { continue } if d.Recv == nil || len(d.Recv.List) != 1 { // Not a named method. continue } // Save the method and the receiver. name, _ := resolveTypeName(d.Recv.List[0].Type) simpleMethods[method{ typeName: name, methodName: d.Name.Name, }] = struct{}{} if len(d.Recv.List[0].Names) > 0 { receiverNames[name] = d.Recv.List[0].Names[0].Name } } } for _, f := range files { // Go over all named types. for _, decl := range f.Decls { d, ok := decl.(*ast.GenDecl) if !ok || d.Tok != token.TYPE { continue } // Only generate code for types marked "// +stateify // savable" in one of the proceeding comment lines. If // the line is marked "// +stateify type" then only // generate type information and register the type. if d.Doc == nil { continue } var ( generateTypeInfo = false generateSaverLoader = false ) for _, l := range d.Doc.List { if l.Text == "// +stateify savable" { generateTypeInfo = true generateSaverLoader = true break } if l.Text == "// +stateify type" { generateTypeInfo = true } } if !generateTypeInfo && !generateSaverLoader { continue } for _, gs := range d.Specs { ts := gs.(*ast.TypeSpec) recv, ok := receiverNames[ts.Name.Name] if !ok { // Maybe no methods were defined? recv = strings.ToLower(ts.Name.Name[:1]) } switch x := ts.Type.(type) { case *ast.StructType: maybeEmitImports() // Record the slot for each field. fieldCount := 0 fields := make(map[string]int) emitField := func(name string) { fmt.Fprintf(outputFile, " \"%s\",\n", name) fields[name] = fieldCount fieldCount++ } emitFieldValue := func(name string, _ string) { emitField(name) } emitLoadValue := func(name, typName string) { fmt.Fprintf(outputFile, " stateSourceObject.LoadValue(%d, new(%s), func(y interface{}) { %s.load%s(y.(%s)) })\n", fields[name], typName, recv, camelCased(name), typName) } emitLoad := func(name string) { fmt.Fprintf(outputFile, " stateSourceObject.Load(%d, &%s.%s)\n", fields[name], recv, name) } emitLoadWait := func(name string) { fmt.Fprintf(outputFile, " stateSourceObject.LoadWait(%d, &%s.%s)\n", fields[name], recv, name) } emitSaveValue := func(name, typName string) { fmt.Fprintf(outputFile, " var %sValue %s = %s.save%s()\n", name, typName, recv, camelCased(name)) fmt.Fprintf(outputFile, " stateSinkObject.SaveValue(%d, %sValue)\n", fields[name], name) } emitSave := func(name string) { fmt.Fprintf(outputFile, " stateSinkObject.Save(%d, &%s.%s)\n", fields[name], recv, name) } emitZeroCheck := func(name string) { fmt.Fprintf(outputFile, " if !%sIsZeroValue(&%s.%s) { %sFailf(\"%s is %%#v, expected zero\", &%s.%s) }\n", statePrefix, recv, name, statePrefix, name, recv, name) } // Generate the type name method. fmt.Fprintf(outputFile, "func (%s *%s) StateTypeName() string {\n", recv, ts.Name.Name) fmt.Fprintf(outputFile, " return \"%s.%s\"\n", *fullPkg, ts.Name.Name) fmt.Fprintf(outputFile, "}\n\n") // Generate the fields method. fmt.Fprintf(outputFile, "func (%s *%s) StateFields() []string {\n", recv, ts.Name.Name) fmt.Fprintf(outputFile, " return []string{\n") scanFields(x, "", scanFunctions{ normal: emitField, wait: emitField, value: emitFieldValue, }) fmt.Fprintf(outputFile, " }\n") fmt.Fprintf(outputFile, "}\n\n") // Define beforeSave if a definition was not found. This prevents // the code from compiling if a custom beforeSave was defined in a // file not provided to this binary and prevents inherited methods // from being called multiple times by overriding them. if _, ok := simpleMethods[method{ typeName: ts.Name.Name, methodName: "beforeSave", }]; !ok && generateSaverLoader { fmt.Fprintf(outputFile, "func (%s *%s) beforeSave() {}\n\n", recv, ts.Name.Name) } // Generate the save method. // // N.B. For historical reasons, we perform the value saves first, // and perform the value loads last. There should be no dependency // on this specific behavior, but the ability to specify slots // allows a manual implementation to be order-dependent. if generateSaverLoader { fmt.Fprintf(outputFile, "// +checklocksignore\n") fmt.Fprintf(outputFile, "func (%s *%s) StateSave(stateSinkObject %sSink) {\n", recv, ts.Name.Name, statePrefix) fmt.Fprintf(outputFile, " %s.beforeSave()\n", recv) scanFields(x, "", scanFunctions{zerovalue: emitZeroCheck}) scanFields(x, "", scanFunctions{value: emitSaveValue}) scanFields(x, "", scanFunctions{normal: emitSave, wait: emitSave}) fmt.Fprintf(outputFile, "}\n\n") } // Define afterLoad if a definition was not found. We do this for // the same reason that we do it for beforeSave. _, hasAfterLoad := simpleMethods[method{ typeName: ts.Name.Name, methodName: "afterLoad", }] if !hasAfterLoad && generateSaverLoader { fmt.Fprintf(outputFile, "func (%s *%s) afterLoad() {}\n\n", recv, ts.Name.Name) } // Generate the load method. // // N.B. See the comment above for the save method. if generateSaverLoader { fmt.Fprintf(outputFile, "// +checklocksignore\n") fmt.Fprintf(outputFile, "func (%s *%s) StateLoad(stateSourceObject %sSource) {\n", recv, ts.Name.Name, statePrefix) scanFields(x, "", scanFunctions{normal: emitLoad, wait: emitLoadWait}) scanFields(x, "", scanFunctions{value: emitLoadValue}) if hasAfterLoad { // The call to afterLoad is made conditionally, because when // AfterLoad is called, the object encodes a dependency on // referred objects (i.e. fields). This means that afterLoad // will not be called until the other afterLoads are called. fmt.Fprintf(outputFile, " stateSourceObject.AfterLoad(%s.afterLoad)\n", recv) } fmt.Fprintf(outputFile, "}\n\n") } // Add to our registration. emitRegister(ts.Name.Name) case *ast.Ident, *ast.SelectorExpr, *ast.ArrayType: maybeEmitImports() // Generate the info methods. fmt.Fprintf(outputFile, "func (%s *%s) StateTypeName() string {\n", recv, ts.Name.Name) fmt.Fprintf(outputFile, " return \"%s.%s\"\n", *fullPkg, ts.Name.Name) fmt.Fprintf(outputFile, "}\n\n") fmt.Fprintf(outputFile, "func (%s *%s) StateFields() []string {\n", recv, ts.Name.Name) fmt.Fprintf(outputFile, " return nil\n") fmt.Fprintf(outputFile, "}\n\n") // See above. emitRegister(ts.Name.Name) } } } } if len(initCalls) > 0 { // Emit the init() function. fmt.Fprintf(outputFile, "func init() {\n") for _, ic := range initCalls { fmt.Fprintf(outputFile, " %s\n", ic) } fmt.Fprintf(outputFile, "}\n") } }