// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package doc import ( "fmt" "go/ast" "go/token" "internal/lazyregexp" "sort" "strconv" "strings" ) // ---------------------------------------------------------------------------- // function/method sets // // Internally, we treat functions like methods and collect them in method sets. // A methodSet describes a set of methods. Entries where Decl == nil are conflict // entries (more than one method with the same name at the same embedding level). // type methodSet map[string]*Func // recvString returns a string representation of recv of the form "T", "*T", // "T[A, ...]", "*T[A, ...]" or "BADRECV" (if not a proper receiver type). // func recvString(recv ast.Expr) string { switch t := recv.(type) { case *ast.Ident: return t.Name case *ast.StarExpr: return "*" + recvString(t.X) case *ast.IndexExpr: // Generic type with one parameter. return fmt.Sprintf("%s[%s]", recvString(t.X), recvParam(t.Index)) case *ast.IndexListExpr: // Generic type with multiple parameters. if len(t.Indices) > 0 { var b strings.Builder b.WriteString(recvString(t.X)) b.WriteByte('[') b.WriteString(recvParam(t.Indices[0])) for _, e := range t.Indices[1:] { b.WriteString(", ") b.WriteString(recvParam(e)) } b.WriteByte(']') return b.String() } } return "BADRECV" } func recvParam(p ast.Expr) string { if id, ok := p.(*ast.Ident); ok { return id.Name } return "BADPARAM" } // set creates the corresponding Func for f and adds it to mset. // If there are multiple f's with the same name, set keeps the first // one with documentation; conflicts are ignored. The boolean // specifies whether to leave the AST untouched. // func (mset methodSet) set(f *ast.FuncDecl, preserveAST bool) { name := f.Name.Name if g := mset[name]; g != nil && g.Doc != "" { // A function with the same name has already been registered; // since it has documentation, assume f is simply another // implementation and ignore it. This does not happen if the // caller is using go/build.ScanDir to determine the list of // files implementing a package. return } // function doesn't exist or has no documentation; use f recv := "" if f.Recv != nil { var typ ast.Expr // be careful in case of incorrect ASTs if list := f.Recv.List; len(list) == 1 { typ = list[0].Type } recv = recvString(typ) } mset[name] = &Func{ Doc: f.Doc.Text(), Name: name, Decl: f, Recv: recv, Orig: recv, } if !preserveAST { f.Doc = nil // doc consumed - remove from AST } } // add adds method m to the method set; m is ignored if the method set // already contains a method with the same name at the same or a higher // level than m. // func (mset methodSet) add(m *Func) { old := mset[m.Name] if old == nil || m.Level < old.Level { mset[m.Name] = m return } if m.Level == old.Level { // conflict - mark it using a method with nil Decl mset[m.Name] = &Func{ Name: m.Name, Level: m.Level, } } } // ---------------------------------------------------------------------------- // Named types // baseTypeName returns the name of the base type of x (or "") // and whether the type is imported or not. // func baseTypeName(x ast.Expr) (name string, imported bool) { switch t := x.(type) { case *ast.Ident: return t.Name, false case *ast.IndexExpr: return baseTypeName(t.X) case *ast.IndexListExpr: return baseTypeName(t.X) case *ast.SelectorExpr: if _, ok := t.X.(*ast.Ident); ok { // only possible for qualified type names; // assume type is imported return t.Sel.Name, true } case *ast.ParenExpr: return baseTypeName(t.X) case *ast.StarExpr: return baseTypeName(t.X) } return "", false } // An embeddedSet describes a set of embedded types. type embeddedSet map[*namedType]bool // A namedType represents a named unqualified (package local, or possibly // predeclared) type. The namedType for a type name is always found via // reader.lookupType. // type namedType struct { doc string // doc comment for type name string // type name decl *ast.GenDecl // nil if declaration hasn't been seen yet isEmbedded bool // true if this type is embedded isStruct bool // true if this type is a struct embedded embeddedSet // true if the embedded type is a pointer // associated declarations values []*Value // consts and vars funcs methodSet methods methodSet } // ---------------------------------------------------------------------------- // AST reader // reader accumulates documentation for a single package. // It modifies the AST: Comments (declaration documentation) // that have been collected by the reader are set to nil // in the respective AST nodes so that they are not printed // twice (once when printing the documentation and once when // printing the corresponding AST node). // type reader struct { mode Mode // package properties doc string // package documentation, if any filenames []string notes map[string][]*Note // declarations imports map[string]int hasDotImp bool // if set, package contains a dot import values []*Value // consts and vars order int // sort order of const and var declarations (when we can't use a name) types map[string]*namedType funcs methodSet // support for package-local shadowing of predeclared types shadowedPredecl map[string]bool fixmap map[string][]*ast.InterfaceType } func (r *reader) isVisible(name string) bool { return r.mode&AllDecls != 0 || token.IsExported(name) } // lookupType returns the base type with the given name. // If the base type has not been encountered yet, a new // type with the given name but no associated declaration // is added to the type map. // func (r *reader) lookupType(name string) *namedType { if name == "" || name == "_" { return nil // no type docs for anonymous types } if typ, found := r.types[name]; found { return typ } // type not found - add one without declaration typ := &namedType{ name: name, embedded: make(embeddedSet), funcs: make(methodSet), methods: make(methodSet), } r.types[name] = typ return typ } // recordAnonymousField registers fieldType as the type of an // anonymous field in the parent type. If the field is imported // (qualified name) or the parent is nil, the field is ignored. // The function returns the field name. // func (r *reader) recordAnonymousField(parent *namedType, fieldType ast.Expr) (fname string) { fname, imp := baseTypeName(fieldType) if parent == nil || imp { return } if ftype := r.lookupType(fname); ftype != nil { ftype.isEmbedded = true _, ptr := fieldType.(*ast.StarExpr) parent.embedded[ftype] = ptr } return } func (r *reader) readDoc(comment *ast.CommentGroup) { // By convention there should be only one package comment // but collect all of them if there are more than one. text := comment.Text() if r.doc == "" { r.doc = text return } r.doc += "\n" + text } func (r *reader) remember(predecl string, typ *ast.InterfaceType) { if r.fixmap == nil { r.fixmap = make(map[string][]*ast.InterfaceType) } r.fixmap[predecl] = append(r.fixmap[predecl], typ) } func specNames(specs []ast.Spec) []string { names := make([]string, 0, len(specs)) // reasonable estimate for _, s := range specs { // s guaranteed to be an *ast.ValueSpec by readValue for _, ident := range s.(*ast.ValueSpec).Names { names = append(names, ident.Name) } } return names } // readValue processes a const or var declaration. // func (r *reader) readValue(decl *ast.GenDecl) { // determine if decl should be associated with a type // Heuristic: For each typed entry, determine the type name, if any. // If there is exactly one type name that is sufficiently // frequent, associate the decl with the respective type. domName := "" domFreq := 0 prev := "" n := 0 for _, spec := range decl.Specs { s, ok := spec.(*ast.ValueSpec) if !ok { continue // should not happen, but be conservative } name := "" switch { case s.Type != nil: // a type is present; determine its name if n, imp := baseTypeName(s.Type); !imp { name = n } case decl.Tok == token.CONST && len(s.Values) == 0: // no type or value is present but we have a constant declaration; // use the previous type name (possibly the empty string) name = prev } if name != "" { // entry has a named type if domName != "" && domName != name { // more than one type name - do not associate // with any type domName = "" break } domName = name domFreq++ } prev = name n++ } // nothing to do w/o a legal declaration if n == 0 { return } // determine values list with which to associate the Value for this decl values := &r.values const threshold = 0.75 if domName != "" && r.isVisible(domName) && domFreq >= int(float64(len(decl.Specs))*threshold) { // typed entries are sufficiently frequent if typ := r.lookupType(domName); typ != nil { values = &typ.values // associate with that type } } *values = append(*values, &Value{ Doc: decl.Doc.Text(), Names: specNames(decl.Specs), Decl: decl, order: r.order, }) if r.mode&PreserveAST == 0 { decl.Doc = nil // doc consumed - remove from AST } // Note: It's important that the order used here is global because the cleanupTypes // methods may move values associated with types back into the global list. If the // order is list-specific, sorting is not deterministic because the same order value // may appear multiple times (was bug, found when fixing #16153). r.order++ } // fields returns a struct's fields or an interface's methods. // func fields(typ ast.Expr) (list []*ast.Field, isStruct bool) { var fields *ast.FieldList switch t := typ.(type) { case *ast.StructType: fields = t.Fields isStruct = true case *ast.InterfaceType: fields = t.Methods } if fields != nil { list = fields.List } return } // readType processes a type declaration. // func (r *reader) readType(decl *ast.GenDecl, spec *ast.TypeSpec) { typ := r.lookupType(spec.Name.Name) if typ == nil { return // no name or blank name - ignore the type } // A type should be added at most once, so typ.decl // should be nil - if it is not, simply overwrite it. typ.decl = decl // compute documentation doc := spec.Doc if doc == nil { // no doc associated with the spec, use the declaration doc, if any doc = decl.Doc } if r.mode&PreserveAST == 0 { spec.Doc = nil // doc consumed - remove from AST decl.Doc = nil // doc consumed - remove from AST } typ.doc = doc.Text() // record anonymous fields (they may contribute methods) // (some fields may have been recorded already when filtering // exports, but that's ok) var list []*ast.Field list, typ.isStruct = fields(spec.Type) for _, field := range list { if len(field.Names) == 0 { r.recordAnonymousField(typ, field.Type) } } } // isPredeclared reports whether n denotes a predeclared type. // func (r *reader) isPredeclared(n string) bool { return predeclaredTypes[n] && r.types[n] == nil } // readFunc processes a func or method declaration. // func (r *reader) readFunc(fun *ast.FuncDecl) { // strip function body if requested. if r.mode&PreserveAST == 0 { fun.Body = nil } // associate methods with the receiver type, if any if fun.Recv != nil { // method if len(fun.Recv.List) == 0 { // should not happen (incorrect AST); (See issue 17788) // don't show this method return } recvTypeName, imp := baseTypeName(fun.Recv.List[0].Type) if imp { // should not happen (incorrect AST); // don't show this method return } if typ := r.lookupType(recvTypeName); typ != nil { typ.methods.set(fun, r.mode&PreserveAST != 0) } // otherwise ignore the method // TODO(gri): There may be exported methods of non-exported types // that can be called because of exported values (consts, vars, or // function results) of that type. Could determine if that is the // case and then show those methods in an appropriate section. return } // Associate factory functions with the first visible result type, as long as // others are predeclared types. if fun.Type.Results.NumFields() >= 1 { var typ *namedType // type to associate the function with numResultTypes := 0 for _, res := range fun.Type.Results.List { factoryType := res.Type if t, ok := factoryType.(*ast.ArrayType); ok { // We consider functions that return slices or arrays of type // T (or pointers to T) as factory functions of T. factoryType = t.Elt } if n, imp := baseTypeName(factoryType); !imp && r.isVisible(n) && !r.isPredeclared(n) { if lookupTypeParam(n, fun.Type.TypeParams) != nil { // Issue #49477: don't associate fun with its type parameter result. // A type parameter is not a defined type. continue } if t := r.lookupType(n); t != nil { typ = t numResultTypes++ if numResultTypes > 1 { break } } } } // If there is exactly one result type, // associate the function with that type. if numResultTypes == 1 { typ.funcs.set(fun, r.mode&PreserveAST != 0) return } } // just an ordinary function r.funcs.set(fun, r.mode&PreserveAST != 0) } // lookupTypeParam searches for type parameters named name within the tparams // field list, returning the relevant identifier if found, or nil if not. func lookupTypeParam(name string, tparams *ast.FieldList) *ast.Ident { if tparams == nil { return nil } for _, field := range tparams.List { for _, id := range field.Names { if id.Name == name { return id } } } return nil } var ( noteMarker = `([A-Z][A-Z]+)\(([^)]+)\):?` // MARKER(uid), MARKER at least 2 chars, uid at least 1 char noteMarkerRx = lazyregexp.New(`^[ \t]*` + noteMarker) // MARKER(uid) at text start noteCommentRx = lazyregexp.New(`^/[/*][ \t]*` + noteMarker) // MARKER(uid) at comment start ) // readNote collects a single note from a sequence of comments. // func (r *reader) readNote(list []*ast.Comment) { text := (&ast.CommentGroup{List: list}).Text() if m := noteMarkerRx.FindStringSubmatchIndex(text); m != nil { // The note body starts after the marker. // We remove any formatting so that we don't // get spurious line breaks/indentation when // showing the TODO body. body := clean(text[m[1]:], keepNL) if body != "" { marker := text[m[2]:m[3]] r.notes[marker] = append(r.notes[marker], &Note{ Pos: list[0].Pos(), End: list[len(list)-1].End(), UID: text[m[4]:m[5]], Body: body, }) } } } // readNotes extracts notes from comments. // A note must start at the beginning of a comment with "MARKER(uid):" // and is followed by the note body (e.g., "// BUG(gri): fix this"). // The note ends at the end of the comment group or at the start of // another note in the same comment group, whichever comes first. // func (r *reader) readNotes(comments []*ast.CommentGroup) { for _, group := range comments { i := -1 // comment index of most recent note start, valid if >= 0 list := group.List for j, c := range list { if noteCommentRx.MatchString(c.Text) { if i >= 0 { r.readNote(list[i:j]) } i = j } } if i >= 0 { r.readNote(list[i:]) } } } // readFile adds the AST for a source file to the reader. // func (r *reader) readFile(src *ast.File) { // add package documentation if src.Doc != nil { r.readDoc(src.Doc) if r.mode&PreserveAST == 0 { src.Doc = nil // doc consumed - remove from AST } } // add all declarations but for functions which are processed in a separate pass for _, decl := range src.Decls { switch d := decl.(type) { case *ast.GenDecl: switch d.Tok { case token.IMPORT: // imports are handled individually for _, spec := range d.Specs { if s, ok := spec.(*ast.ImportSpec); ok { if import_, err := strconv.Unquote(s.Path.Value); err == nil { r.imports[import_] = 1 if s.Name != nil && s.Name.Name == "." { r.hasDotImp = true } } } } case token.CONST, token.VAR: // constants and variables are always handled as a group r.readValue(d) case token.TYPE: // types are handled individually if len(d.Specs) == 1 && !d.Lparen.IsValid() { // common case: single declaration w/o parentheses // (if a single declaration is parenthesized, // create a new fake declaration below, so that // go/doc type declarations always appear w/o // parentheses) if s, ok := d.Specs[0].(*ast.TypeSpec); ok { r.readType(d, s) } break } for _, spec := range d.Specs { if s, ok := spec.(*ast.TypeSpec); ok { // use an individual (possibly fake) declaration // for each type; this also ensures that each type // gets to (re-)use the declaration documentation // if there's none associated with the spec itself fake := &ast.GenDecl{ Doc: d.Doc, // don't use the existing TokPos because it // will lead to the wrong selection range for // the fake declaration if there are more // than one type in the group (this affects // src/cmd/godoc/godoc.go's posLink_urlFunc) TokPos: s.Pos(), Tok: token.TYPE, Specs: []ast.Spec{s}, } r.readType(fake, s) } } } } } // collect MARKER(...): annotations r.readNotes(src.Comments) if r.mode&PreserveAST == 0 { src.Comments = nil // consumed unassociated comments - remove from AST } } func (r *reader) readPackage(pkg *ast.Package, mode Mode) { // initialize reader r.filenames = make([]string, len(pkg.Files)) r.imports = make(map[string]int) r.mode = mode r.types = make(map[string]*namedType) r.funcs = make(methodSet) r.notes = make(map[string][]*Note) // sort package files before reading them so that the // result does not depend on map iteration order i := 0 for filename := range pkg.Files { r.filenames[i] = filename i++ } sort.Strings(r.filenames) // process files in sorted order for _, filename := range r.filenames { f := pkg.Files[filename] if mode&AllDecls == 0 { r.fileExports(f) } r.readFile(f) } // process functions now that we have better type information for _, f := range pkg.Files { for _, decl := range f.Decls { if d, ok := decl.(*ast.FuncDecl); ok { r.readFunc(d) } } } } // ---------------------------------------------------------------------------- // Types func customizeRecv(f *Func, recvTypeName string, embeddedIsPtr bool, level int) *Func { if f == nil || f.Decl == nil || f.Decl.Recv == nil || len(f.Decl.Recv.List) != 1 { return f // shouldn't happen, but be safe } // copy existing receiver field and set new type newField := *f.Decl.Recv.List[0] origPos := newField.Type.Pos() _, origRecvIsPtr := newField.Type.(*ast.StarExpr) newIdent := &ast.Ident{NamePos: origPos, Name: recvTypeName} var typ ast.Expr = newIdent if !embeddedIsPtr && origRecvIsPtr { newIdent.NamePos++ // '*' is one character typ = &ast.StarExpr{Star: origPos, X: newIdent} } newField.Type = typ // copy existing receiver field list and set new receiver field newFieldList := *f.Decl.Recv newFieldList.List = []*ast.Field{&newField} // copy existing function declaration and set new receiver field list newFuncDecl := *f.Decl newFuncDecl.Recv = &newFieldList // copy existing function documentation and set new declaration newF := *f newF.Decl = &newFuncDecl newF.Recv = recvString(typ) // the Orig field never changes newF.Level = level return &newF } // collectEmbeddedMethods collects the embedded methods of typ in mset. // func (r *reader) collectEmbeddedMethods(mset methodSet, typ *namedType, recvTypeName string, embeddedIsPtr bool, level int, visited embeddedSet) { visited[typ] = true for embedded, isPtr := range typ.embedded { // Once an embedded type is embedded as a pointer type // all embedded types in those types are treated like // pointer types for the purpose of the receiver type // computation; i.e., embeddedIsPtr is sticky for this // embedding hierarchy. thisEmbeddedIsPtr := embeddedIsPtr || isPtr for _, m := range embedded.methods { // only top-level methods are embedded if m.Level == 0 { mset.add(customizeRecv(m, recvTypeName, thisEmbeddedIsPtr, level)) } } if !visited[embedded] { r.collectEmbeddedMethods(mset, embedded, recvTypeName, thisEmbeddedIsPtr, level+1, visited) } } delete(visited, typ) } // computeMethodSets determines the actual method sets for each type encountered. // func (r *reader) computeMethodSets() { for _, t := range r.types { // collect embedded methods for t if t.isStruct { // struct r.collectEmbeddedMethods(t.methods, t, t.name, false, 1, make(embeddedSet)) } else { // interface // TODO(gri) fix this } } // For any predeclared names that are declared locally, don't treat them as // exported fields anymore. for predecl := range r.shadowedPredecl { for _, ityp := range r.fixmap[predecl] { removeAnonymousField(predecl, ityp) } } } // cleanupTypes removes the association of functions and methods with // types that have no declaration. Instead, these functions and methods // are shown at the package level. It also removes types with missing // declarations or which are not visible. // func (r *reader) cleanupTypes() { for _, t := range r.types { visible := r.isVisible(t.name) predeclared := predeclaredTypes[t.name] if t.decl == nil && (predeclared || visible && (t.isEmbedded || r.hasDotImp)) { // t.name is a predeclared type (and was not redeclared in this package), // or it was embedded somewhere but its declaration is missing (because // the AST is incomplete), or we have a dot-import (and all bets are off): // move any associated values, funcs, and methods back to the top-level so // that they are not lost. // 1) move values r.values = append(r.values, t.values...) // 2) move factory functions for name, f := range t.funcs { // in a correct AST, package-level function names // are all different - no need to check for conflicts r.funcs[name] = f } // 3) move methods if !predeclared { for name, m := range t.methods { // don't overwrite functions with the same name - drop them if _, found := r.funcs[name]; !found { r.funcs[name] = m } } } } // remove types w/o declaration or which are not visible if t.decl == nil || !visible { delete(r.types, t.name) } } } // ---------------------------------------------------------------------------- // Sorting type data struct { n int swap func(i, j int) less func(i, j int) bool } func (d *data) Len() int { return d.n } func (d *data) Swap(i, j int) { d.swap(i, j) } func (d *data) Less(i, j int) bool { return d.less(i, j) } // sortBy is a helper function for sorting func sortBy(less func(i, j int) bool, swap func(i, j int), n int) { sort.Sort(&data{n, swap, less}) } func sortedKeys(m map[string]int) []string { list := make([]string, len(m)) i := 0 for key := range m { list[i] = key i++ } sort.Strings(list) return list } // sortingName returns the name to use when sorting d into place. // func sortingName(d *ast.GenDecl) string { if len(d.Specs) == 1 { if s, ok := d.Specs[0].(*ast.ValueSpec); ok { return s.Names[0].Name } } return "" } func sortedValues(m []*Value, tok token.Token) []*Value { list := make([]*Value, len(m)) // big enough in any case i := 0 for _, val := range m { if val.Decl.Tok == tok { list[i] = val i++ } } list = list[0:i] sortBy( func(i, j int) bool { if ni, nj := sortingName(list[i].Decl), sortingName(list[j].Decl); ni != nj { return ni < nj } return list[i].order < list[j].order }, func(i, j int) { list[i], list[j] = list[j], list[i] }, len(list), ) return list } func sortedTypes(m map[string]*namedType, allMethods bool) []*Type { list := make([]*Type, len(m)) i := 0 for _, t := range m { list[i] = &Type{ Doc: t.doc, Name: t.name, Decl: t.decl, Consts: sortedValues(t.values, token.CONST), Vars: sortedValues(t.values, token.VAR), Funcs: sortedFuncs(t.funcs, true), Methods: sortedFuncs(t.methods, allMethods), } i++ } sortBy( func(i, j int) bool { return list[i].Name < list[j].Name }, func(i, j int) { list[i], list[j] = list[j], list[i] }, len(list), ) return list } func removeStar(s string) string { if len(s) > 0 && s[0] == '*' { return s[1:] } return s } func sortedFuncs(m methodSet, allMethods bool) []*Func { list := make([]*Func, len(m)) i := 0 for _, m := range m { // determine which methods to include switch { case m.Decl == nil: // exclude conflict entry case allMethods, m.Level == 0, !token.IsExported(removeStar(m.Orig)): // forced inclusion, method not embedded, or method // embedded but original receiver type not exported list[i] = m i++ } } list = list[0:i] sortBy( func(i, j int) bool { return list[i].Name < list[j].Name }, func(i, j int) { list[i], list[j] = list[j], list[i] }, len(list), ) return list } // noteBodies returns a list of note body strings given a list of notes. // This is only used to populate the deprecated Package.Bugs field. // func noteBodies(notes []*Note) []string { var list []string for _, n := range notes { list = append(list, n.Body) } return list } // ---------------------------------------------------------------------------- // Predeclared identifiers // IsPredeclared reports whether s is a predeclared identifier. func IsPredeclared(s string) bool { return predeclaredTypes[s] || predeclaredFuncs[s] || predeclaredConstants[s] } var predeclaredTypes = map[string]bool{ "any": true, "bool": true, "byte": true, "comparable": true, "complex64": true, "complex128": true, "error": true, "float32": true, "float64": true, "int": true, "int8": true, "int16": true, "int32": true, "int64": true, "rune": true, "string": true, "uint": true, "uint8": true, "uint16": true, "uint32": true, "uint64": true, "uintptr": true, } var predeclaredFuncs = map[string]bool{ "append": true, "cap": true, "close": true, "complex": true, "copy": true, "delete": true, "imag": true, "len": true, "make": true, "new": true, "panic": true, "print": true, "println": true, "real": true, "recover": true, } var predeclaredConstants = map[string]bool{ "false": true, "iota": true, "nil": true, "true": true, }