// 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/loader" "golang.org/x/tools/go/ssa" "golang.org/x/tools/go/ssa/ssautil" ) // peers enumerates, for a given channel send (or receive) operation, // the set of possible receives (or sends) that correspond to it. // // TODO(adonovan): support reflect.{Select,Recv,Send,Close}. // TODO(adonovan): permit the user to query based on a MakeChan (not send/recv), // or the implicit receive in "for v := range ch". func peers(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 := lconf.Load() if err != nil { return err } q.Fset = lprog.Fset qpos, err := parseQueryPos(lprog, q.Pos, false) 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 } opPos := findOp(qpos) if opPos == token.NoPos { return fmt.Errorf("there is no channel operation here") } // Defer SSA construction till after errors are reported. prog.Build() var queryOp chanOp // the originating send or receive operation var ops []chanOp // all sends/receives of opposite direction // Look at all channel operations in the whole ssa.Program. // Build a list of those of same type as the query. allFuncs := ssautil.AllFunctions(prog) for fn := range allFuncs { for _, b := range fn.Blocks { for _, instr := range b.Instrs { for _, op := range chanOps(instr) { ops = append(ops, op) if op.pos == opPos { queryOp = op // we found the query op } } } } } if queryOp.ch == nil { return fmt.Errorf("ssa.Instruction for send/receive not found") } // Discard operations of wrong channel element type. // Build set of channel ssa.Values as query to pointer analysis. // We compare channels by element types, not channel types, to // ignore both directionality and type names. queryType := queryOp.ch.Type() queryElemType := queryType.Underlying().(*types.Chan).Elem() ptaConfig.AddQuery(queryOp.ch) i := 0 for _, op := range ops { if types.Identical(op.ch.Type().Underlying().(*types.Chan).Elem(), queryElemType) { ptaConfig.AddQuery(op.ch) ops[i] = op i++ } } ops = ops[:i] // Run the pointer analysis. ptares := ptrAnalysis(ptaConfig) // Find the points-to set. queryChanPtr := ptares.Queries[queryOp.ch] // Ascertain which make(chan) labels the query's channel can alias. var makes []token.Pos for _, label := range queryChanPtr.PointsTo().Labels() { makes = append(makes, label.Pos()) } sort.Sort(byPos(makes)) // Ascertain which channel operations can alias the same make(chan) labels. var sends, receives, closes []token.Pos for _, op := range ops { if ptr, ok := ptares.Queries[op.ch]; ok && ptr.MayAlias(queryChanPtr) { switch op.dir { case types.SendOnly: sends = append(sends, op.pos) case types.RecvOnly: receives = append(receives, op.pos) case types.SendRecv: closes = append(closes, op.pos) } } } sort.Sort(byPos(sends)) sort.Sort(byPos(receives)) sort.Sort(byPos(closes)) q.result = &peersResult{ queryPos: opPos, queryType: queryType, makes: makes, sends: sends, receives: receives, closes: closes, } return nil } // findOp returns the position of the enclosing send/receive/close op. // For send and receive operations, this is the position of the <- token; // for close operations, it's the Lparen of the function call. // // TODO(adonovan): handle implicit receive operations from 'for...range chan' statements. func findOp(qpos *queryPos) token.Pos { for _, n := range qpos.path { switch n := n.(type) { case *ast.UnaryExpr: if n.Op == token.ARROW { return n.OpPos } case *ast.SendStmt: return n.Arrow case *ast.CallExpr: // close function call can only exist as a direct identifier if close, ok := unparen(n.Fun).(*ast.Ident); ok { if b, ok := qpos.info.Info.Uses[close].(*types.Builtin); ok && b.Name() == "close" { return n.Lparen } } } } return token.NoPos } // chanOp abstracts an ssa.Send, ssa.Unop(ARROW), or a SelectState. type chanOp struct { ch ssa.Value dir types.ChanDir // SendOnly=send, RecvOnly=recv, SendRecv=close pos token.Pos } // chanOps returns a slice of all the channel operations in the instruction. func chanOps(instr ssa.Instruction) []chanOp { // TODO(adonovan): handle calls to reflect.{Select,Recv,Send,Close} too. var ops []chanOp switch instr := instr.(type) { case *ssa.UnOp: if instr.Op == token.ARROW { ops = append(ops, chanOp{instr.X, types.RecvOnly, instr.Pos()}) } case *ssa.Send: ops = append(ops, chanOp{instr.Chan, types.SendOnly, instr.Pos()}) case *ssa.Select: for _, st := range instr.States { ops = append(ops, chanOp{st.Chan, st.Dir, st.Pos}) } case ssa.CallInstruction: cc := instr.Common() if b, ok := cc.Value.(*ssa.Builtin); ok && b.Name() == "close" { ops = append(ops, chanOp{cc.Args[0], types.SendRecv, cc.Pos()}) } } return ops } type peersResult struct { queryPos token.Pos // of queried channel op queryType types.Type // type of queried channel makes, sends, receives, closes []token.Pos // positions of aliased makechan/send/receive/close instrs } func (r *peersResult) display(printf printfFunc) { if len(r.makes) == 0 { printf(r.queryPos, "This channel can't point to anything.") return } printf(r.queryPos, "This channel of type %s may be:", r.queryType) for _, alloc := range r.makes { printf(alloc, "\tallocated here") } for _, send := range r.sends { printf(send, "\tsent to, here") } for _, receive := range r.receives { printf(receive, "\treceived from, here") } for _, clos := range r.closes { printf(clos, "\tclosed, here") } } func (r *peersResult) toSerial(res *serial.Result, fset *token.FileSet) { peers := &serial.Peers{ Pos: fset.Position(r.queryPos).String(), Type: r.queryType.String(), } for _, alloc := range r.makes { peers.Allocs = append(peers.Allocs, fset.Position(alloc).String()) } for _, send := range r.sends { peers.Sends = append(peers.Sends, fset.Position(send).String()) } for _, receive := range r.receives { peers.Receives = append(peers.Receives, fset.Position(receive).String()) } for _, clos := range r.closes { peers.Closes = append(peers.Closes, fset.Position(clos).String()) } res.Peers = peers } // -------- utils -------- // NB: byPos is not deterministic across packages since it depends on load order. // Use lessPos if the tests need it. type byPos []token.Pos func (p byPos) Len() int { return len(p) } func (p byPos) Less(i, j int) bool { return p[i] < p[j] } func (p byPos) Swap(i, j int) { p[i], p[j] = p[j], p[i] }