// Copyright 2020 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Package checkescape allows recursive escape analysis for hot paths. // // The analysis tracks multiple types of escapes, in two categories. First, // 'hard' escapes are explicit allocations. Second, 'soft' escapes are // interface dispatches or dynamic function dispatches; these don't necessarily // escape but they *may* escape. The analysis is capable of making assertions // recursively: soft escapes cannot be analyzed in this way, and therefore // count as escapes for recursive purposes. // // The different types of escapes are as follows, with the category in // parentheses: // // heap: A direct allocation is made on the heap (hard). // builtin: A call is made to a built-in allocation function (hard). // stack: A stack split as part of a function preamble (soft). // interface: A call is made via an interface whicy *may* escape (soft). // dynamic: A dynamic function is dispatched which *may* escape (soft). // // To the use the package, annotate a function-level comment with either the // line "// +checkescape" or "// +checkescape:OPTION[,OPTION]". In the second // case, the OPTION field is either a type above, or one of: // // local: Escape analysis is limited to local hard escapes only. // all: All the escapes are included. // hard: All hard escapes are included. // // If the "// +checkescape" annotation is provided, this is equivalent to // provided the local and hard options. // // Some examples of this syntax are: // // +checkescape:all - Analyzes for all escapes in this function and all calls. // +checkescape:local - Analyzes only for default local hard escapes. // +checkescape:heap - Only analyzes for heap escapes. // +checkescape:interface,dynamic - Only checks for dynamic calls and interface calls. // +checkescape - Does the same as +checkescape:local,hard. // // Note that all of the above can be inverted by using +mustescape. The // +checkescape keyword will ensure failure if the class of escape occurs, // whereas +mustescape will fail if the given class of escape does not occur. // // Local exemptions can be made by a comment of the form "// escapes: reason." // This must appear on the line of the escape and will also apply to callers of // the function as well (for non-local escape analysis). package checkescape import ( "bufio" "bytes" "fmt" "go/ast" "go/token" "go/types" "io" "os" "path/filepath" "strconv" "strings" "golang.org/x/tools/go/analysis" "golang.org/x/tools/go/analysis/passes/buildssa" "golang.org/x/tools/go/ssa" "gvisor.dev/gvisor/tools/nogo/data" ) const ( // magic is the magic annotation. magic = "// +checkescape" // magicParams is the magic annotation with specific parameters. magicParams = magic + ":" // testMagic is the test magic annotation (parameters required). testMagic = "// +mustescape:" // exempt is the exemption annotation. exempt = "// escapes:" ) // escapingBuiltins are builtins known to escape. // // These are lowered at an earlier stage of compilation to explicit function // calls, but are not available for recursive analysis. var escapingBuiltins = []string{ "append", "makemap", "newobject", "mallocgc", } // Analyzer defines the entrypoint. var Analyzer = &analysis.Analyzer{ Name: "checkescape", Doc: "surfaces recursive escape analysis results", Run: run, Requires: []*analysis.Analyzer{buildssa.Analyzer}, FactTypes: []analysis.Fact{(*packageEscapeFacts)(nil)}, } // packageEscapeFacts is the set of all functions in a package, and whether or // not they recursively pass escape analysis. // // All the type names for receivers are encoded in the full key. The key // represents the fully qualified package and type name used at link time. type packageEscapeFacts struct { Funcs map[string][]Escape } // AFact implements analysis.Fact.AFact. func (*packageEscapeFacts) AFact() {} // CallSite is a single call site. // // These can be chained. type CallSite struct { LocalPos token.Pos Resolved LinePosition } // Escape is a single escape instance. type Escape struct { Reason EscapeReason Detail string Chain []CallSite } // LinePosition is a low-resolution token.Position. // // This is used to match against possible exemptions placed in the source. type LinePosition struct { Filename string Line int } // String implements fmt.Stringer.String. func (e *LinePosition) String() string { return fmt.Sprintf("%s:%d", e.Filename, e.Line) } // String implements fmt.Stringer.String. // // Note that this string will contain new lines. func (e *Escape) String() string { var b bytes.Buffer fmt.Fprintf(&b, "%s", e.Reason.String()) for i, cs := range e.Chain { if i == len(e.Chain)-1 { fmt.Fprintf(&b, "\n @ %s → %s", cs.Resolved.String(), e.Detail) } else { fmt.Fprintf(&b, "\n + %s", cs.Resolved.String()) } } return b.String() } // EscapeReason is an escape reason. // // This is a simple enum. type EscapeReason int const ( interfaceInvoke EscapeReason = iota unknownPackage allocation builtin dynamicCall stackSplit reasonCount // Count for below. ) // String returns the string for the EscapeReason. // // Note that this also implicitly defines the reverse string -> EscapeReason // mapping, which is the word before the colon (computed below). func (e EscapeReason) String() string { switch e { case interfaceInvoke: return "interface: function invocation via interface" case unknownPackage: return "unknown: no package information available" case allocation: return "heap: call to runtime heap allocation" case builtin: return "builtin: call to runtime builtin" case dynamicCall: return "dynamic: call via dynamic function" case stackSplit: return "stack: stack split on function entry" default: panic(fmt.Sprintf("unknown reason: %d", e)) } } var hardReasons = []EscapeReason{ allocation, builtin, } var softReasons = []EscapeReason{ interfaceInvoke, unknownPackage, dynamicCall, stackSplit, } var allReasons = append(hardReasons, softReasons...) var escapeTypes = func() map[string]EscapeReason { result := make(map[string]EscapeReason) for _, r := range allReasons { parts := strings.Split(r.String(), ":") result[parts[0]] = r // Key before ':'. } return result }() // EscapeCount counts escapes. // // It is used to avoid accumulating too many escapes for the same reason, for // the same function. We limit each class to 3 instances (arbitrarily). type EscapeCount struct { byReason [reasonCount]uint32 } // maxRecordsPerReason is the number of explicit records. // // See EscapeCount (and usage), and Record implementation. const maxRecordsPerReason = 5 // Record records the reason or returns false if it should not be added. func (ec *EscapeCount) Record(reason EscapeReason) bool { ec.byReason[reason]++ if ec.byReason[reason] > maxRecordsPerReason { return false } return true } // loadObjdump reads the objdump output. // // This records if there is a call any function for every source line. It is // used only to remove false positives for escape analysis. The call will be // elided if escape analysis is able to put the object on the heap exclusively. func loadObjdump() (map[LinePosition]string, error) { f, err := os.Open(data.Objdump) if err != nil { return nil, err } defer f.Close() // Build the map. m := make(map[LinePosition]string) r := bufio.NewReader(f) var ( lastField string lastPos LinePosition ) for { line, err := r.ReadString('\n') if err != nil && err != io.EOF { return nil, err } // We recognize lines corresponding to actual code (not the // symbol name or other metadata) and annotate them if they // correspond to an explicit CALL instruction. We assume that // the lack of a CALL for a given line is evidence that escape // analysis has eliminated an allocation. // // Lines look like this (including the first space): // gohacks_unsafe.go:33 0xa39 488b442408 MOVQ 0x8(SP), AX if len(line) > 0 && line[0] == ' ' { fields := strings.Fields(line) if !strings.Contains(fields[3], "CALL") { continue } // Ignore strings containing duffzero, which is just // used by stack allocations for types that are large // enough to warrant Duff's device. if strings.Contains(line, "runtime.duffzero") { continue } // Ignore the racefuncenter call, which is used for // race builds. This does not escape. if strings.Contains(line, "runtime.racefuncenter") { continue } // Calculate the filename and line. Note that per the // example above, the filename is not a fully qualified // base, just the basename (what we require). if fields[0] != lastField { parts := strings.SplitN(fields[0], ":", 2) lineNum, err := strconv.ParseInt(parts[1], 10, 64) if err != nil { return nil, err } lastPos = LinePosition{ Filename: parts[0], Line: int(lineNum), } lastField = fields[0] } if _, ok := m[lastPos]; ok { continue // Already marked. } // Save the actual call for the detail. m[lastPos] = strings.Join(fields[3:], " ") } if err == io.EOF { break } } return m, nil } // poser is a type that implements Pos. type poser interface { Pos() token.Pos } // run performs the analysis. func run(pass *analysis.Pass) (interface{}, error) { calls, err := loadObjdump() if err != nil { return nil, err } pef := packageEscapeFacts{ Funcs: make(map[string][]Escape), } linePosition := func(inst, parent poser) LinePosition { p := pass.Fset.Position(inst.Pos()) if (p.Filename == "" || p.Line == 0) && parent != nil { p = pass.Fset.Position(parent.Pos()) } return LinePosition{ Filename: filepath.Base(p.Filename), Line: p.Line, } } hasCall := func(inst poser) (string, bool) { p := linePosition(inst, nil) s, ok := calls[p] return s, ok } callSite := func(inst ssa.Instruction) CallSite { return CallSite{ LocalPos: inst.Pos(), Resolved: linePosition(inst, inst.Parent()), } } escapes := func(reason EscapeReason, detail string, inst ssa.Instruction, ec *EscapeCount) []Escape { if !ec.Record(reason) { return nil // Skip. } es := Escape{ Reason: reason, Detail: detail, Chain: []CallSite{callSite(inst)}, } return []Escape{es} } resolve := func(sub []Escape, inst ssa.Instruction, ec *EscapeCount) (es []Escape) { for _, e := range sub { if !ec.Record(e.Reason) { continue // Skip. } es = append(es, Escape{ Reason: e.Reason, Detail: e.Detail, Chain: append([]CallSite{callSite(inst)}, e.Chain...), }) } return es } state := pass.ResultOf[buildssa.Analyzer].(*buildssa.SSA) var loadFunc func(*ssa.Function) []Escape // Used below. analyzeInstruction := func(inst ssa.Instruction, ec *EscapeCount) []Escape { switch x := inst.(type) { case *ssa.Call: if x.Call.IsInvoke() { // This is an interface dispatch. There is no // way to know if this is actually escaping or // not, since we don't know the underlying // type. call, _ := hasCall(inst) return escapes(interfaceInvoke, call, inst, ec) } switch x := x.Call.Value.(type) { case *ssa.Function: if x.Pkg == nil { // Can't resolve the package. return escapes(unknownPackage, "no package", inst, ec) } // Atomic functions are instrinics. We can // assume that they don't escape. if x.Pkg.Pkg.Name() == "atomic" { return nil } // Is this a local function? If yes, call the // function to load the local function. The // local escapes are the escapes found in the // local function. if x.Pkg.Pkg == pass.Pkg { return resolve(loadFunc(x), inst, ec) } // Recursively collect information from // the other analyzers. var imp packageEscapeFacts if !pass.ImportPackageFact(x.Pkg.Pkg, &imp) { // Unable to import the dependency; we must // declare these as escaping. return escapes(unknownPackage, "no analysis", inst, ec) } // The escapes of this instruction are the // escapes of the called function directly. return resolve(imp.Funcs[x.RelString(x.Pkg.Pkg)], inst, ec) case *ssa.Builtin: // Ignore elided escapes. if _, has := hasCall(inst); !has { return nil } // Check if the builtin is escaping. for _, name := range escapingBuiltins { if x.Name() == name { return escapes(builtin, name, inst, ec) } } default: // All dynamic calls are counted as soft // escapes. They are similar to interface // dispatches. We cannot actually look up what // this refers to using static analysis alone. call, _ := hasCall(inst) return escapes(dynamicCall, call, inst, ec) } case *ssa.Alloc: // Ignore non-heap allocations. if !x.Heap { return nil } // Ignore elided escapes. call, has := hasCall(inst) if !has { return nil } // This is a real heap allocation. return escapes(allocation, call, inst, ec) case *ssa.MakeMap: return escapes(builtin, "makemap", inst, ec) case *ssa.MakeSlice: return escapes(builtin, "makeslice", inst, ec) case *ssa.MakeClosure: return escapes(builtin, "makeclosure", inst, ec) case *ssa.MakeChan: return escapes(builtin, "makechan", inst, ec) } return nil // No escapes. } var analyzeBasicBlock func(*ssa.BasicBlock, *EscapeCount) []Escape // Recursive. analyzeBasicBlock = func(block *ssa.BasicBlock, ec *EscapeCount) (rval []Escape) { for _, inst := range block.Instrs { rval = append(rval, analyzeInstruction(inst, ec)...) } return rval // N.B. may be empty. } loadFunc = func(fn *ssa.Function) []Escape { // Is this already available? name := fn.RelString(pass.Pkg) if es, ok := pef.Funcs[name]; ok { return es } // In the case of a true cycle, we assume that the current // function itself has no escapes until the rest of the // analysis is complete. This will trip the above in the case // of a cycle of any kind. pef.Funcs[name] = nil // Perform the basic analysis. var ( es []Escape ec EscapeCount ) if fn.Recover != nil { es = append(es, analyzeBasicBlock(fn.Recover, &ec)...) } for _, block := range fn.Blocks { es = append(es, analyzeBasicBlock(block, &ec)...) } // Check for a stack split. if call, has := hasCall(fn); has { es = append(es, Escape{ Reason: stackSplit, Detail: call, Chain: []CallSite{CallSite{ LocalPos: fn.Pos(), Resolved: linePosition(fn, fn.Parent()), }}, }) } // Save the result and return. pef.Funcs[name] = es return es } // Complete all local functions. for _, fn := range state.SrcFuncs { loadFunc(fn) } // Build the exception list. exemptions := make(map[LinePosition]string) for _, f := range pass.Files { for _, cg := range f.Comments { for _, c := range cg.List { p := pass.Fset.Position(c.Slash) if strings.HasPrefix(c.Text, exempt) { exemptions[LinePosition{ Filename: filepath.Base(p.Filename), Line: p.Line, }] = c.Text[len(exempt):] } } } } // Delete everything matching the excemtions. // // This has the implication that exceptions are applied recursively, // since this now modified set is what will be saved. for name, escapes := range pef.Funcs { var newEscapes []Escape for _, escape := range escapes { isExempt := false for line, _ := range exemptions { // Note that an exemption applies if it is // marked as an exemption anywhere in the call // chain. It need not be marked as escapes in // the function itself, nor in the top-level // caller. for _, callSite := range escape.Chain { if callSite.Resolved == line { isExempt = true break } } if isExempt { break } } if !isExempt { // Record this escape; not an exception. newEscapes = append(newEscapes, escape) } } pef.Funcs[name] = newEscapes // Update. } // Export all findings for future packages. pass.ExportPackageFact(&pef) // Scan all functions for violations. for _, f := range pass.Files { // Scan all declarations. for _, decl := range f.Decls { fdecl, ok := decl.(*ast.FuncDecl) // Function declaration? if !ok { continue } // Is there a comment? if fdecl.Doc == nil { continue } var ( reasons []EscapeReason found bool local bool testReasons = make(map[EscapeReason]bool) // reason -> local? ) // Does the comment contain a +checkescape line? for _, c := range fdecl.Doc.List { if !strings.HasPrefix(c.Text, magic) && !strings.HasPrefix(c.Text, testMagic) { continue } if c.Text == magic { // Default: hard reasons, local only. reasons = hardReasons local = true } else if strings.HasPrefix(c.Text, magicParams) { // Extract specific reasons. types := strings.Split(c.Text[len(magicParams):], ",") found = true // For below. for i := 0; i < len(types); i++ { if types[i] == "local" { // Limit search to local escapes. local = true } else if types[i] == "all" { // Append all reasons. reasons = append(reasons, allReasons...) } else if types[i] == "hard" { // Append all hard reasons. reasons = append(reasons, hardReasons...) } else { r, ok := escapeTypes[types[i]] if !ok { // This is not a valid escape reason. pass.Reportf(fdecl.Pos(), "unknown reason: %v", types[i]) continue } reasons = append(reasons, r) } } } else if strings.HasPrefix(c.Text, testMagic) { types := strings.Split(c.Text[len(testMagic):], ",") local := false for i := 0; i < len(types); i++ { if types[i] == "local" { local = true } else { r, ok := escapeTypes[types[i]] if !ok { // This is not a valid escape reason. pass.Reportf(fdecl.Pos(), "unknown reason: %v", types[i]) continue } if v, ok := testReasons[r]; ok && v { // Already registered as local. continue } testReasons[r] = local } } } } if len(reasons) == 0 && found { // A magic annotation was provided, but no reasons. pass.Reportf(fdecl.Pos(), "no reasons provided") continue } // Scan for matches. fn := pass.TypesInfo.Defs[fdecl.Name].(*types.Func) name := state.Pkg.Prog.FuncValue(fn).RelString(pass.Pkg) es, ok := pef.Funcs[name] if !ok { pass.Reportf(fdecl.Pos(), "internal error: function %s not found.", name) continue } for _, e := range es { for _, r := range reasons { // Is does meet our local requirement? if local && len(e.Chain) > 1 { continue } // Does this match the reason? Emit // with a full stack trace that // explains why this violates our // constraints. if e.Reason == r { pass.Reportf(e.Chain[0].LocalPos, "%s", e.String()) } } } // Scan for test (required) matches. testReasonsFound := make(map[EscapeReason]bool) for _, e := range es { // Is this local? local, ok := testReasons[e.Reason] wantLocal := len(e.Chain) == 1 testReasonsFound[e.Reason] = wantLocal if !ok { continue } if local == wantLocal { delete(testReasons, e.Reason) } } for reason, local := range testReasons { // We didn't find the escapes we wanted. pass.Reportf(fdecl.Pos(), fmt.Sprintf("testescapes not found: reason=%s, local=%t", reason, local)) } if len(testReasons) > 0 { // Dump all reasons found to help in debugging. for _, e := range es { pass.Reportf(e.Chain[0].LocalPos, "escape found: %s", e.String()) } } } } return nil, nil }