// Copyright 2013 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 pointer import ( "bytes" "fmt" "go/types" "log" "os" "os/exec" "runtime" "time" "golang.org/x/tools/container/intsets" ) // CanPoint reports whether the type T is pointerlike, // for the purposes of this analysis. func CanPoint(T types.Type) bool { switch T := T.(type) { case *types.Named: if obj := T.Obj(); obj.Name() == "Value" && obj.Pkg().Path() == "reflect" { return true // treat reflect.Value like interface{} } return CanPoint(T.Underlying()) case *types.Pointer, *types.Interface, *types.Map, *types.Chan, *types.Signature, *types.Slice: return true } return false // array struct tuple builtin basic } // CanHaveDynamicTypes reports whether the type T can "hold" dynamic types, // i.e. is an interface (incl. reflect.Type) or a reflect.Value. // func CanHaveDynamicTypes(T types.Type) bool { switch T := T.(type) { case *types.Named: if obj := T.Obj(); obj.Name() == "Value" && obj.Pkg().Path() == "reflect" { return true // reflect.Value } return CanHaveDynamicTypes(T.Underlying()) case *types.Interface: return true } return false } func isInterface(T types.Type) bool { return types.IsInterface(T) } // mustDeref returns the element type of its argument, which must be a // pointer; panic ensues otherwise. func mustDeref(typ types.Type) types.Type { return typ.Underlying().(*types.Pointer).Elem() } // deref returns a pointer's element type; otherwise it returns typ. func deref(typ types.Type) types.Type { if p, ok := typ.Underlying().(*types.Pointer); ok { return p.Elem() } return typ } // A fieldInfo describes one subelement (node) of the flattening-out // of a type T: the subelement's type and its path from the root of T. // // For example, for this type: // type line struct{ points []struct{x, y int} } // flatten() of the inner struct yields the following []fieldInfo: // struct{ x, y int } "" // int ".x" // int ".y" // and flatten(line) yields: // struct{ points []struct{x, y int} } "" // struct{ x, y int } ".points[*]" // int ".points[*].x // int ".points[*].y" // type fieldInfo struct { typ types.Type // op and tail describe the path to the element (e.g. ".a#2.b[*].c"). op interface{} // *Array: true; *Tuple: int; *Struct: *types.Var; *Named: nil tail *fieldInfo } // path returns a user-friendly string describing the subelement path. // func (fi *fieldInfo) path() string { var buf bytes.Buffer for p := fi; p != nil; p = p.tail { switch op := p.op.(type) { case bool: fmt.Fprintf(&buf, "[*]") case int: fmt.Fprintf(&buf, "#%d", op) case *types.Var: fmt.Fprintf(&buf, ".%s", op.Name()) } } return buf.String() } // flatten returns a list of directly contained fields in the preorder // traversal of the type tree of t. The resulting elements are all // scalars (basic types or pointerlike types), except for struct/array // "identity" nodes, whose type is that of the aggregate. // // reflect.Value is considered pointerlike, similar to interface{}. // // Callers must not mutate the result. // func (a *analysis) flatten(t types.Type) []*fieldInfo { fl, ok := a.flattenMemo[t] if !ok { switch t := t.(type) { case *types.Named: u := t.Underlying() if isInterface(u) { // Debuggability hack: don't remove // the named type from interfaces as // they're very verbose. fl = append(fl, &fieldInfo{typ: t}) } else { fl = a.flatten(u) } case *types.Basic, *types.Signature, *types.Chan, *types.Map, *types.Interface, *types.Slice, *types.Pointer: fl = append(fl, &fieldInfo{typ: t}) case *types.Array: fl = append(fl, &fieldInfo{typ: t}) // identity node for _, fi := range a.flatten(t.Elem()) { fl = append(fl, &fieldInfo{typ: fi.typ, op: true, tail: fi}) } case *types.Struct: fl = append(fl, &fieldInfo{typ: t}) // identity node for i, n := 0, t.NumFields(); i < n; i++ { f := t.Field(i) for _, fi := range a.flatten(f.Type()) { fl = append(fl, &fieldInfo{typ: fi.typ, op: f, tail: fi}) } } case *types.Tuple: // No identity node: tuples are never address-taken. n := t.Len() if n == 1 { // Don't add a fieldInfo link for singletons, // e.g. in params/results. fl = append(fl, a.flatten(t.At(0).Type())...) } else { for i := 0; i < n; i++ { f := t.At(i) for _, fi := range a.flatten(f.Type()) { fl = append(fl, &fieldInfo{typ: fi.typ, op: i, tail: fi}) } } } default: panic(fmt.Sprintf("cannot flatten unsupported type %T", t)) } a.flattenMemo[t] = fl } return fl } // sizeof returns the number of pointerlike abstractions (nodes) in the type t. func (a *analysis) sizeof(t types.Type) uint32 { return uint32(len(a.flatten(t))) } // shouldTrack reports whether object type T contains (recursively) // any fields whose addresses should be tracked. func (a *analysis) shouldTrack(T types.Type) bool { if a.track == trackAll { return true // fast path } track, ok := a.trackTypes[T] if !ok { a.trackTypes[T] = true // break cycles conservatively // NB: reflect.Value, reflect.Type are pre-populated to true. for _, fi := range a.flatten(T) { switch ft := fi.typ.Underlying().(type) { case *types.Interface, *types.Signature: track = true // needed for callgraph case *types.Basic: // no-op case *types.Chan: track = a.track&trackChan != 0 || a.shouldTrack(ft.Elem()) case *types.Map: track = a.track&trackMap != 0 || a.shouldTrack(ft.Key()) || a.shouldTrack(ft.Elem()) case *types.Slice: track = a.track&trackSlice != 0 || a.shouldTrack(ft.Elem()) case *types.Pointer: track = a.track&trackPtr != 0 || a.shouldTrack(ft.Elem()) case *types.Array, *types.Struct: // No need to look at field types since they will follow (flattened). default: // Includes *types.Tuple, which are never address-taken. panic(ft) } if track { break } } a.trackTypes[T] = track if !track && a.log != nil { fmt.Fprintf(a.log, "\ttype not tracked: %s\n", T) } } return track } // offsetOf returns the (abstract) offset of field index within struct // or tuple typ. func (a *analysis) offsetOf(typ types.Type, index int) uint32 { var offset uint32 switch t := typ.Underlying().(type) { case *types.Tuple: for i := 0; i < index; i++ { offset += a.sizeof(t.At(i).Type()) } case *types.Struct: offset++ // the node for the struct itself for i := 0; i < index; i++ { offset += a.sizeof(t.Field(i).Type()) } default: panic(fmt.Sprintf("offsetOf(%s : %T)", typ, typ)) } return offset } // sliceToArray returns the type representing the arrays to which // slice type slice points. func sliceToArray(slice types.Type) *types.Array { return types.NewArray(slice.Underlying().(*types.Slice).Elem(), 1) } // Node set ------------------------------------------------------------------- type nodeset struct { intsets.Sparse } func (ns *nodeset) String() string { var buf bytes.Buffer buf.WriteRune('{') var space [50]int for i, n := range ns.AppendTo(space[:0]) { if i > 0 { buf.WriteString(", ") } buf.WriteRune('n') fmt.Fprintf(&buf, "%d", n) } buf.WriteRune('}') return buf.String() } func (ns *nodeset) add(n nodeid) bool { return ns.Sparse.Insert(int(n)) } func (ns *nodeset) addAll(y *nodeset) bool { return ns.UnionWith(&y.Sparse) } // Profiling & debugging ------------------------------------------------------- var timers = make(map[string]time.Time) func start(name string) { if debugTimers { timers[name] = time.Now() log.Printf("%s...\n", name) } } func stop(name string) { if debugTimers { log.Printf("%s took %s\n", name, time.Since(timers[name])) } } // diff runs the command "diff a b" and reports its success. func diff(a, b string) bool { var cmd *exec.Cmd switch runtime.GOOS { case "plan9": cmd = exec.Command("/bin/diff", "-c", a, b) default: cmd = exec.Command("/usr/bin/diff", "-u", a, b) } cmd.Stdout = os.Stderr cmd.Stderr = os.Stderr return cmd.Run() == nil }