// Method returns the Function implementing method meth, building // wrapper methods on demand. // // Thread-safe. // // EXCLUSIVE_LOCKS_ACQUIRED(prog.methodsMu) // func (prog *Program) Method(meth *types.Selection) *Function { if meth == nil { panic("Method(nil)") } typ := meth.Recv() if prog.mode&LogSource != 0 { defer logStack("Method %s %v", typ, meth)() } prog.methodsMu.Lock() defer prog.methodsMu.Unlock() type methodSet map[string]*Function mset, _ := prog.methodSets.At(typ).(methodSet) if mset == nil { mset = make(methodSet) prog.methodSets.Set(typ, mset) } id := meth.Obj().Id() fn := mset[id] if fn == nil { fn = findMethod(prog, meth) mset[id] = fn } return fn }
// makeThunk returns a thunk, a synthetic function that delegates to a // concrete or interface method denoted by sel.Obj(). The resulting // function has no receiver, but has an additional (first) regular // parameter. // // Precondition: sel.Kind() == types.MethodExpr. // // type T int or: type T interface { meth() } // func (t T) meth() // f := T.meth // var t T // f(t) // calls t.meth() // // f is a synthetic wrapper defined as if by: // // f := func(t T) { return t.meth() } // // TODO(adonovan): opt: currently the stub is created even when used // directly in a function call: C.f(i, 0). This is less efficient // than inlining the stub. // // EXCLUSIVE_LOCKS_ACQUIRED(meth.Prog.methodsMu) // func makeThunk(prog *Program, sel *types.Selection) *Function { if sel.Kind() != types.MethodExpr { panic(sel) } // TODO(adonovan): opt: canonicalize the recv Type to avoid // construct unnecessary duplicate thunks. key := selectionKey{ kind: sel.Kind(), recv: sel.Recv(), obj: sel.Obj(), index: fmt.Sprint(sel.Index()), indirect: sel.Indirect(), } prog.methodsMu.Lock() defer prog.methodsMu.Unlock() fn, ok := prog.thunks[key] if !ok { fn = makeWrapper(prog, sel) if fn.Signature.Recv() != nil { panic(fn) // unexpected receiver } prog.thunks[key] = fn } return fn }
// Method returns the Function implementing method meth, building // wrapper methods on demand. // // Thread-safe. // // EXCLUSIVE_LOCKS_ACQUIRED(prog.methodsMu) // func (prog *Program) Method(meth *types.Selection) *Function { if meth == nil { panic("Method(nil)") } T := meth.Recv() if prog.mode&LogSource != 0 { defer logStack("Method %s %v", T, meth)() } prog.methodsMu.Lock() defer prog.methodsMu.Unlock() return prog.addMethod(prog.createMethodSet(T), meth) }
func translateSelection(sel *types.Selection) string { var selectors []string t := sel.Recv() for _, index := range sel.Index() { if ptr, isPtr := t.(*types.Pointer); isPtr { t = ptr.Elem() } s := t.Underlying().(*types.Struct) field := s.Field(index) selectors = append(selectors, field.Name()) t = field.Type() } return strings.Join(selectors, ".") }
// Method returns the Function implementing method sel, building // wrapper methods on demand. It returns nil if sel denotes an // abstract (interface) method. // // Precondition: sel.Kind() == MethodVal. // // TODO(adonovan): rename this to MethodValue because of the // precondition, and for consistency with functions in source.go. // // Thread-safe. // // EXCLUSIVE_LOCKS_ACQUIRED(prog.methodsMu) // func (prog *Program) Method(sel *types.Selection) *Function { if sel.Kind() != types.MethodVal { panic(fmt.Sprintf("Method(%s) kind != MethodVal", sel)) } T := sel.Recv() if isInterface(T) { return nil // abstract method } if prog.mode&LogSource != 0 { defer logStack("Method %s %v", T, sel)() } prog.methodsMu.Lock() defer prog.methodsMu.Unlock() return prog.addMethod(prog.createMethodSet(T), sel) }
func (c *funcContext) translateSelection(sel *types.Selection) (fields []string, jsTag string) { t := sel.Recv() for _, index := range sel.Index() { if ptr, isPtr := t.(*types.Pointer); isPtr { t = ptr.Elem() } s := t.Underlying().(*types.Struct) if jsTag = getJsTag(s.Tag(index)); jsTag != "" { for i := 0; i < s.NumFields(); i++ { if isJsObject(s.Field(i).Type()) { fields = append(fields, fieldName(s, i)) return } } } fields = append(fields, fieldName(s, index)) t = s.Field(index).Type() } return }
// findMethod returns the concrete Function for the method meth, // synthesizing wrappers as needed. // // EXCLUSIVE_LOCKS_REQUIRED(prog.methodsMu) // func findMethod(prog *Program, meth *types.Selection) *Function { needsPromotion := len(meth.Index()) > 1 obj := meth.Obj().(*types.Func) needsIndirection := !isPointer(recvType(obj)) && isPointer(meth.Recv()) if needsPromotion || needsIndirection { return makeWrapper(prog, meth.Recv(), meth) } if _, ok := meth.Recv().Underlying().(*types.Interface); ok { return interfaceMethodWrapper(prog, meth.Recv(), obj) } return prog.declaredFunc(obj) }
// EXCLUSIVE_LOCKS_REQUIRED(prog.methodsMu) func (prog *Program) addMethod(mset *methodSet, sel *types.Selection) *Function { if sel.Kind() == types.MethodExpr { panic(sel) } id := sel.Obj().Id() fn := mset.mapping[id] if fn == nil { obj := sel.Obj().(*types.Func) needsPromotion := len(sel.Index()) > 1 needsIndirection := !isPointer(recvType(obj)) && isPointer(sel.Recv()) if needsPromotion || needsIndirection { fn = makeWrapper(prog, sel) } else { fn = prog.declaredFunc(obj) } if fn.Signature.Recv() == nil { panic(fn) // missing receiver } mset.mapping[id] = fn } return fn }
func (c *funcContext) translateSelection(sel *types.Selection) ([]string, string) { var fields []string t := sel.Recv() for _, index := range sel.Index() { if ptr, isPtr := t.(*types.Pointer); isPtr { t = ptr.Elem() } s := t.Underlying().(*types.Struct) if jsTag := getJsTag(s.Tag(index)); jsTag != "" { var searchJsObject func(*types.Struct) []string searchJsObject = func(s *types.Struct) []string { for i := 0; i < s.NumFields(); i++ { ft := s.Field(i).Type() if isJsObject(ft) { return []string{fieldName(s, i)} } ft = ft.Underlying() if ptr, ok := ft.(*types.Pointer); ok { ft = ptr.Elem().Underlying() } if s2, ok := ft.(*types.Struct); ok { if f := searchJsObject(s2); f != nil { return append([]string{fieldName(s, i)}, f...) } } } return nil } if jsObjectFields := searchJsObject(s); jsObjectFields != nil { return append(fields, jsObjectFields...), jsTag } } fields = append(fields, fieldName(s, index)) t = s.Field(index).Type() } return fields, "" }
func (w *PkgWalker) LookupObjects(pkg *types.Package, pkgInfo *types.Info, cursor *FileCursor) { var cursorObj types.Object var cursorSelection *types.Selection var cursorObjIsDef bool //lookup defs _ = cursorObjIsDef if cursorObj == nil { for sel, obj := range pkgInfo.Selections { if cursor.pos >= sel.Sel.Pos() && cursor.pos <= sel.Sel.End() { cursorObj = obj.Obj() cursorSelection = obj break } } } if cursorObj == nil { for id, obj := range pkgInfo.Defs { if cursor.pos >= id.Pos() && cursor.pos <= id.End() { cursorObj = obj cursorObjIsDef = true break } } } _ = cursorSelection if cursorObj == nil { for id, obj := range pkgInfo.Uses { if cursor.pos >= id.Pos() && cursor.pos <= id.End() { cursorObj = obj break } } } if cursorObj == nil { return } kind, err := parserObjKind(cursorObj) if err != nil { log.Fatalln(err) } if kind == ObjField { if cursorObj.(*types.Var).Anonymous() { if named, ok := cursorObj.Type().(*types.Named); ok { cursorObj = named.Obj() } } } cursorPkg := cursorObj.Pkg() cursorPos := cursorObj.Pos() var fieldTypeInfo *types.Info var fieldTypeObj types.Object if cursorPkg == pkg { fieldTypeInfo = pkgInfo } cursorIsInterfaceMethod := false var cursorInterfaceTypeName string if kind == ObjMethod && cursorSelection != nil && cursorSelection.Recv() != nil { sig := cursorObj.(*types.Func).Type().Underlying().(*types.Signature) if _, ok := sig.Recv().Type().Underlying().(*types.Interface); ok { named := cursorSelection.Recv().(*types.Named) obj, typ := w.lookupNamedMethod(named, cursorObj.Name()) if obj != nil { cursorObj = obj } if typ != nil { cursorPkg = typ.Obj().Pkg() cursorInterfaceTypeName = typ.Obj().Name() } cursorIsInterfaceMethod = true } } if cursorPkg != nil && cursorPkg != pkg && kind != ObjPkgName && w.isBinaryPkg(cursorPkg.Path()) { conf := &PkgConfig{ IgnoreFuncBodies: true, AllowBinary: true, Info: &types.Info{ Defs: make(map[*ast.Ident]types.Object), }, } pkg, _ := w.Import("", cursorPkg.Path(), conf) if pkg != nil { if cursorIsInterfaceMethod { for _, obj := range conf.Info.Defs { if obj == nil { continue } if fn, ok := obj.(*types.Func); ok { if fn.Name() == cursorObj.Name() { if sig, ok := fn.Type().Underlying().(*types.Signature); ok { if named, ok := sig.Recv().Type().(*types.Named); ok { if named.Obj() != nil && named.Obj().Name() == cursorInterfaceTypeName { cursorPos = obj.Pos() break } } } } } } } else { for _, obj := range conf.Info.Defs { if obj != nil && obj.String() == cursorObj.String() { cursorPos = obj.Pos() break } } } } if kind == ObjField || cursorIsInterfaceMethod { fieldTypeInfo = conf.Info } } if kind == ObjField { fieldTypeObj = w.LookupStructFromField(fieldTypeInfo, cursorPkg, cursorObj, cursorPos) } if typeFindDef { fmt.Println(w.fset.Position(cursorPos)) } if typeFindInfo { if kind == ObjField && fieldTypeObj != nil { typeName := fieldTypeObj.Name() if fieldTypeObj.Pkg() != nil && fieldTypeObj.Pkg() != pkg { typeName = fieldTypeObj.Pkg().Name() + "." + fieldTypeObj.Name() } fmt.Println(typeName, simpleType(cursorObj.String())) } else if kind == ObjBuiltin { fmt.Println(builtinInfo(cursorObj.Name())) } else if cursorIsInterfaceMethod { fmt.Println(strings.Replace(simpleType(cursorObj.String()), "(interface)", cursorPkg.Name()+"."+cursorInterfaceTypeName, 1)) } else { fmt.Println(simpleType(cursorObj.String())) } } //if f, ok := w.parsedFileCache[w.fset.Position(cursorPos).Filename]; ok { // for _, d := range f.Decls { // if inRange(d, cursorPos) { // if fd, ok := d.(*ast.FuncDecl); ok { // fd.Body = nil // } // commentMap := ast.NewCommentMap(w.fset, f, f.Comments) // commentedNode := printer.CommentedNode{Node: d} // if comments := commentMap.Filter(d).Comments(); comments != nil { // commentedNode.Comments = comments // } // var b bytes.Buffer // printer.Fprint(&b, w.fset, &commentedNode) // b.Write([]byte("\n\n")) // Add a blank line between entries if we print documentation. // log.Println(w.nodeString(d)) // } // } //} if !typeFindUse { return } var usages []int if kind == ObjPkgName { for id, obj := range pkgInfo.Uses { if obj != nil && obj.Id() == cursorObj.Id() { //!= nil && cursorObj.Pos() == obj.Pos() { usages = append(usages, int(id.Pos())) } } } else { for id, obj := range pkgInfo.Defs { if obj == cursorObj { //!= nil && cursorObj.Pos() == obj.Pos() { usages = append(usages, int(id.Pos())) } } for id, obj := range pkgInfo.Uses { if obj == cursorObj { //!= nil && cursorObj.Pos() == obj.Pos() { usages = append(usages, int(id.Pos())) } } } (sort.IntSlice(usages)).Sort() for _, pos := range usages { fmt.Println(w.fset.Position(token.Pos(pos))) } }
// makeWrapper returns a synthetic method that delegates to the // declared method denoted by meth.Obj(), first performing any // necessary pointer indirections or field selections implied by meth. // // The resulting method's receiver type is meth.Recv(). // // This function is versatile but quite subtle! Consider the // following axes of variation when making changes: // - optional receiver indirection // - optional implicit field selections // - meth.Obj() may denote a concrete or an interface method // - the result may be a thunk or a wrapper. // // EXCLUSIVE_LOCKS_REQUIRED(prog.methodsMu) // func makeWrapper(prog *Program, meth *types.Selection) *Function { obj := meth.Obj().(*types.Func) // the declared function sig := meth.Type().(*types.Signature) // type of this wrapper var recv *types.Var // wrapper's receiver or thunk's params[0] name := obj.Name() var description string var start int // first regular param if meth.Kind() == types.MethodExpr { name += "$thunk" description = "thunk" recv = sig.Params().At(0) start = 1 } else { description = "wrapper" recv = sig.Recv() } description = fmt.Sprintf("%s for %s", description, meth.Obj()) if prog.mode&LogSource != 0 { defer logStack("make %s to (%s)", description, recv.Type())() } fn := &Function{ name: name, method: meth, object: obj, Signature: sig, Synthetic: description, Prog: prog, pos: obj.Pos(), } fn.startBody() fn.addSpilledParam(recv) createParams(fn, start) indices := meth.Index() var v Value = fn.Locals[0] // spilled receiver if isPointer(meth.Recv()) { v = emitLoad(fn, v) // For simple indirection wrappers, perform an informative nil-check: // "value method (T).f called using nil *T pointer" if len(indices) == 1 && !isPointer(recvType(obj)) { var c Call c.Call.Value = &Builtin{ name: "ssa:wrapnilchk", sig: types.NewSignature(nil, nil, types.NewTuple(anonVar(meth.Recv()), anonVar(tString), anonVar(tString)), types.NewTuple(anonVar(meth.Recv())), false), } c.Call.Args = []Value{ v, stringConst(deref(meth.Recv()).String()), stringConst(meth.Obj().Name()), } c.setType(v.Type()) v = fn.emit(&c) } } // Invariant: v is a pointer, either // value of *A receiver param, or // address of A spilled receiver. // We use pointer arithmetic (FieldAddr possibly followed by // Load) in preference to value extraction (Field possibly // preceded by Load). v = emitImplicitSelections(fn, v, indices[:len(indices)-1]) // Invariant: v is a pointer, either // value of implicit *C field, or // address of implicit C field. var c Call if r := recvType(obj); !isInterface(r) { // concrete method if !isPointer(r) { v = emitLoad(fn, v) } c.Call.Value = prog.declaredFunc(obj) c.Call.Args = append(c.Call.Args, v) } else { c.Call.Method = obj c.Call.Value = emitLoad(fn, v) } for _, arg := range fn.Params[1:] { c.Call.Args = append(c.Call.Args, arg) } emitTailCall(fn, &c) fn.finishBody() return fn }