// 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 main import ( "fmt" "go/ast" "go/token" "go/types" "sort" "golang.org/x/tools/cmd/guru/serial" "golang.org/x/tools/go/ast/astutil" "golang.org/x/tools/go/loader" "golang.org/x/tools/go/pointer" "golang.org/x/tools/go/ssa" "golang.org/x/tools/go/ssa/ssautil" ) // pointsto runs the pointer analysis on the selected expression, // and reports its points-to set (for a pointer-like expression) // or its dynamic types (for an interface, reflect.Value, or // reflect.Type expression) and their points-to sets. // // All printed sets are sorted to ensure determinism. // func pointsto(q *Query) error { lconf := loader.Config{Build: q.Build} if err := setPTAScope(&lconf, q.Scope); err != nil { return err } // Load/parse/type-check the program. lprog, err := loadWithSoftErrors(&lconf) if err != nil { return err } qpos, err := parseQueryPos(lprog, q.Pos, true) // needs exact pos if err != nil { return err } prog := ssautil.CreateProgram(lprog, ssa.GlobalDebug) ptaConfig, err := setupPTA(prog, lprog, q.PTALog, q.Reflection) if err != nil { return err } path, action := findInterestingNode(qpos.info, qpos.path) if action != actionExpr { return fmt.Errorf("pointer analysis wants an expression; got %s", astutil.NodeDescription(qpos.path[0])) } var expr ast.Expr var obj types.Object switch n := path[0].(type) { case *ast.ValueSpec: // ambiguous ValueSpec containing multiple names return fmt.Errorf("multiple value specification") case *ast.Ident: obj = qpos.info.ObjectOf(n) expr = n case ast.Expr: expr = n default: // TODO(adonovan): is this reachable? return fmt.Errorf("unexpected AST for expr: %T", n) } // Reject non-pointerlike types (includes all constants---except nil). // TODO(adonovan): reject nil too. typ := qpos.info.TypeOf(expr) if !pointer.CanPoint(typ) { return fmt.Errorf("pointer analysis wants an expression of reference type; got %s", typ) } // Determine the ssa.Value for the expression. var value ssa.Value var isAddr bool if obj != nil { // def/ref of func/var object value, isAddr, err = ssaValueForIdent(prog, qpos.info, obj, path) } else { value, isAddr, err = ssaValueForExpr(prog, qpos.info, path) } if err != nil { return err // e.g. trivially dead code } // Defer SSA construction till after errors are reported. prog.Build() // Run the pointer analysis. ptrs, err := runPTA(ptaConfig, value, isAddr) if err != nil { return err // e.g. analytically unreachable } q.Output(lprog.Fset, &pointstoResult{ qpos: qpos, typ: typ, ptrs: ptrs, }) return nil } // ssaValueForIdent returns the ssa.Value for the ast.Ident whose path // to the root of the AST is path. isAddr reports whether the // ssa.Value is the address denoted by the ast.Ident, not its value. // func ssaValueForIdent(prog *ssa.Program, qinfo *loader.PackageInfo, obj types.Object, path []ast.Node) (value ssa.Value, isAddr bool, err error) { switch obj := obj.(type) { case *types.Var: pkg := prog.Package(qinfo.Pkg) pkg.Build() if v, addr := prog.VarValue(obj, pkg, path); v != nil { return v, addr, nil } return nil, false, fmt.Errorf("can't locate SSA Value for var %s", obj.Name()) case *types.Func: fn := prog.FuncValue(obj) if fn == nil { return nil, false, fmt.Errorf("%s is an interface method", obj) } // TODO(adonovan): there's no point running PTA on a *Func ident. // Eliminate this feature. return fn, false, nil } panic(obj) } // ssaValueForExpr returns the ssa.Value of the non-ast.Ident // expression whose path to the root of the AST is path. // func ssaValueForExpr(prog *ssa.Program, qinfo *loader.PackageInfo, path []ast.Node) (value ssa.Value, isAddr bool, err error) { pkg := prog.Package(qinfo.Pkg) pkg.SetDebugMode(true) pkg.Build() fn := ssa.EnclosingFunction(pkg, path) if fn == nil { return nil, false, fmt.Errorf("no SSA function built for this location (dead code?)") } if v, addr := fn.ValueForExpr(path[0].(ast.Expr)); v != nil { return v, addr, nil } return nil, false, fmt.Errorf("can't locate SSA Value for expression in %s", fn) } // runPTA runs the pointer analysis of the selected SSA value or address. func runPTA(conf *pointer.Config, v ssa.Value, isAddr bool) (ptrs []pointerResult, err error) { T := v.Type() if isAddr { conf.AddIndirectQuery(v) T = deref(T) } else { conf.AddQuery(v) } ptares := ptrAnalysis(conf) var ptr pointer.Pointer if isAddr { ptr = ptares.IndirectQueries[v] } else { ptr = ptares.Queries[v] } if ptr == (pointer.Pointer{}) { return nil, fmt.Errorf("pointer analysis did not find expression (dead code?)") } pts := ptr.PointsTo() if pointer.CanHaveDynamicTypes(T) { // Show concrete types for interface/reflect.Value expression. if concs := pts.DynamicTypes(); concs.Len() > 0 { concs.Iterate(func(conc types.Type, pta interface{}) { labels := pta.(pointer.PointsToSet).Labels() sort.Sort(byPosAndString(labels)) // to ensure determinism ptrs = append(ptrs, pointerResult{conc, labels}) }) } } else { // Show labels for other expressions. labels := pts.Labels() sort.Sort(byPosAndString(labels)) // to ensure determinism ptrs = append(ptrs, pointerResult{T, labels}) } sort.Sort(byTypeString(ptrs)) // to ensure determinism return ptrs, nil } type pointerResult struct { typ types.Type // type of the pointer (always concrete) labels []*pointer.Label // set of labels } type pointstoResult struct { qpos *queryPos typ types.Type // type of expression ptrs []pointerResult // pointer info (typ is concrete => len==1) } func (r *pointstoResult) PrintPlain(printf printfFunc) { if pointer.CanHaveDynamicTypes(r.typ) { // Show concrete types for interface, reflect.Type or // reflect.Value expression. if len(r.ptrs) > 0 { printf(r.qpos, "this %s may contain these dynamic types:", r.qpos.typeString(r.typ)) for _, ptr := range r.ptrs { var obj types.Object if nt, ok := deref(ptr.typ).(*types.Named); ok { obj = nt.Obj() } if len(ptr.labels) > 0 { printf(obj, "\t%s, may point to:", r.qpos.typeString(ptr.typ)) printLabels(printf, ptr.labels, "\t\t") } else { printf(obj, "\t%s", r.qpos.typeString(ptr.typ)) } } } else { printf(r.qpos, "this %s cannot contain any dynamic types.", r.typ) } } else { // Show labels for other expressions. if ptr := r.ptrs[0]; len(ptr.labels) > 0 { printf(r.qpos, "this %s may point to these objects:", r.qpos.typeString(r.typ)) printLabels(printf, ptr.labels, "\t") } else { printf(r.qpos, "this %s may not point to anything.", r.qpos.typeString(r.typ)) } } } func (r *pointstoResult) JSON(fset *token.FileSet) []byte { var pts []serial.PointsTo for _, ptr := range r.ptrs { var namePos string if nt, ok := deref(ptr.typ).(*types.Named); ok { namePos = fset.Position(nt.Obj().Pos()).String() } var labels []serial.PointsToLabel for _, l := range ptr.labels { labels = append(labels, serial.PointsToLabel{ Pos: fset.Position(l.Pos()).String(), Desc: l.String(), }) } pts = append(pts, serial.PointsTo{ Type: r.qpos.typeString(ptr.typ), NamePos: namePos, Labels: labels, }) } return toJSON(pts) } type byTypeString []pointerResult func (a byTypeString) Len() int { return len(a) } func (a byTypeString) Less(i, j int) bool { return a[i].typ.String() < a[j].typ.String() } func (a byTypeString) Swap(i, j int) { a[i], a[j] = a[j], a[i] } type byPosAndString []*pointer.Label func (a byPosAndString) Len() int { return len(a) } func (a byPosAndString) Less(i, j int) bool { cmp := a[i].Pos() - a[j].Pos() return cmp < 0 || (cmp == 0 && a[i].String() < a[j].String()) } func (a byPosAndString) Swap(i, j int) { a[i], a[j] = a[j], a[i] } func printLabels(printf printfFunc, labels []*pointer.Label, prefix string) { // TODO(adonovan): due to context-sensitivity, many of these // labels may differ only by context, which isn't apparent. for _, label := range labels { printf(label, "%s%s", prefix, label) } }