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|
// 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 which *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"
"flag"
"fmt"
"go/ast"
"go/token"
"go/types"
"io"
"log"
"os"
"os/exec"
"path/filepath"
"strings"
"golang.org/x/tools/go/analysis"
"golang.org/x/tools/go/analysis/passes/buildssa"
"golang.org/x/tools/go/ssa"
)
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"
)
var (
// Binary is the binary under analysis.
//
// See Reader, below.
binary = flag.String("binary", "", "binary under analysis")
// Reader is the input stream.
//
// This may be set instead of Binary.
Reader io.Reader
// objdumpTool is the tool used to dump a binary.
objdumpTool = flag.String("objdump_tool", "", "tool used to dump a binary")
)
// EscapeReason is an escape reason.
//
// This is a simple enum.
type EscapeReason int
const (
allocation EscapeReason = iota
builtin
interfaceInvoke
dynamicCall
stackSplit
unknownPackage
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: call to potentially allocating function"
case unknownPackage:
return "unknown: no package information available"
case allocation:
return "heap: explicit allocation"
case builtin:
return "builtin: call to potentially allocating builtin"
case dynamicCall:
return "dynamic: call to potentially allocating function"
case stackSplit:
return "stack: possible 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
}()
// 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",
}
// 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.
//
// Note that each Escapes object is a summary. Local findings may be reported
// using more detailed information.
type packageEscapeFacts struct {
Funcs map[string]Escapes
}
// AFact implements analysis.Fact.AFact.
func (*packageEscapeFacts) AFact() {}
// Analyzer includes specific results.
var Analyzer = &analysis.Analyzer{
Name: "checkescape",
Doc: "escape analysis checks based on +checkescape annotations",
Run: runSelectEscapes,
Requires: []*analysis.Analyzer{buildssa.Analyzer},
FactTypes: []analysis.Fact{(*packageEscapeFacts)(nil)},
}
// EscapeAnalyzer includes all local escape results.
var EscapeAnalyzer = &analysis.Analyzer{
Name: "checkescape",
Doc: "complete local escape analysis results (requires Analyzer facts)",
Run: runAllEscapes,
Requires: []*analysis.Analyzer{buildssa.Analyzer},
}
// 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)
}
// Simplified returns the simplified name.
func (e LinePosition) Simplified() string {
return fmt.Sprintf("%s:%d", filepath.Base(e.Filename), e.Line)
}
// CallSite is a single call site.
//
// These can be chained.
type CallSite struct {
LocalPos token.Pos
Resolved LinePosition
}
// IsValid indicates whether the CallSite is valid or not.
func (cs *CallSite) IsValid() bool {
return cs.LocalPos.IsValid()
}
// Escapes is a collection of escapes.
//
// We record at most one escape for each reason, but record the number of
// escapes that were omitted.
//
// This object should be used to summarize all escapes for a single line (local
// analysis) or a single function (package facts).
//
// All fields are exported for gob.
type Escapes struct {
CallSites [reasonCount][]CallSite
Details [reasonCount]string
Omitted [reasonCount]int
}
// add is called by Add and Merge.
func (es *Escapes) add(r EscapeReason, detail string, omitted int, callSites ...CallSite) {
if es.CallSites[r] != nil {
// We will either be replacing the current escape or dropping
// the added one. Either way, we increment omitted by the
// appropriate amount.
es.Omitted[r]++
// If the callSites in the other is only a single element, then
// we will universally favor this. This provides the cleanest
// set of escapes to summarize, and more importantly: if there
if len(es.CallSites) == 1 || len(callSites) != 1 {
return
}
}
es.Details[r] = detail
es.CallSites[r] = callSites
es.Omitted[r] += omitted
}
// Add adds a single escape.
func (es *Escapes) Add(r EscapeReason, detail string, callSites ...CallSite) {
es.add(r, detail, 0, callSites...)
}
// IsEmpty returns true iff this Escapes is empty.
func (es *Escapes) IsEmpty() bool {
for _, cs := range es.CallSites {
if cs != nil {
return false
}
}
return true
}
// Filter filters out all escapes except those matches the given reasons.
//
// If local is set, then non-local escapes will also be filtered.
func (es *Escapes) Filter(reasons []EscapeReason, local bool) {
FilterReasons:
for r := EscapeReason(0); r < reasonCount; r++ {
for i := 0; i < len(reasons); i++ {
if r == reasons[i] {
continue FilterReasons
}
}
// Zap this reason.
es.CallSites[r] = nil
es.Details[r] = ""
es.Omitted[r] = 0
}
if !local {
return
}
for r := EscapeReason(0); r < reasonCount; r++ {
// Is does meet our local requirement?
if len(es.CallSites[r]) > 1 {
es.CallSites[r] = nil
es.Details[r] = ""
es.Omitted[r] = 0
}
}
}
// MergeWithCall merges these escapes with another.
//
// If callSite is nil, no call is added.
func (es *Escapes) MergeWithCall(other Escapes, callSite CallSite) {
for r := EscapeReason(0); r < reasonCount; r++ {
if other.CallSites[r] != nil {
// Construct our new call chain.
newCallSites := other.CallSites[r]
if callSite.IsValid() {
newCallSites = append([]CallSite{callSite}, newCallSites...)
}
// Add (potentially replacing) the underlying escape.
es.add(r, other.Details[r], other.Omitted[r], newCallSites...)
}
}
}
// Reportf will call Reportf for each class of escapes.
func (es *Escapes) Reportf(pass *analysis.Pass) {
var b bytes.Buffer // Reused for all escapes.
for r := EscapeReason(0); r < reasonCount; r++ {
if es.CallSites[r] == nil {
continue
}
b.Reset()
fmt.Fprintf(&b, "%s ", r.String())
if es.Omitted[r] > 0 {
fmt.Fprintf(&b, "(%d omitted) ", es.Omitted[r])
}
for _, cs := range es.CallSites[r][1:] {
fmt.Fprintf(&b, "→ %s ", cs.Resolved.String())
}
fmt.Fprintf(&b, "→ %s", es.Details[r])
pass.Reportf(es.CallSites[r][0].LocalPos, b.String())
}
}
// MergeAll merges a sequence of escapes.
func MergeAll(others []Escapes) (es Escapes) {
for _, other := range others {
es.MergeWithCall(other, CallSite{})
}
return
}
// 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.
//
// Note that the map uses <basename.go>:<line> because that is all that is
// provided in the objdump format. Since this is all local, it is sufficient.
func loadObjdump() (map[string][]string, error) {
var (
args []string
stdin io.Reader
)
if *binary != "" {
args = append(args, *binary)
} else if Reader != nil {
stdin = Reader
} else {
// We have no input stream or binary.
return nil, fmt.Errorf("no binary or reader provided")
}
// Construct our command.
cmd := exec.Command(*objdumpTool, args...)
cmd.Stdin = stdin
cmd.Stderr = os.Stderr
out, err := cmd.StdoutPipe()
if err != nil {
return nil, err
}
if err := cmd.Start(); err != nil {
return nil, err
}
// Identify calls by address or name. Note that this is also
// constructed dynamically below, as we encounted the addresses.
// This is because some of the functions (duffzero) may have
// jump targets in the middle of the function itself.
funcsAllowed := map[string]struct{}{
"runtime.duffzero": struct{}{},
"runtime.duffcopy": struct{}{},
"runtime.racefuncenter": struct{}{},
"runtime.gcWriteBarrier": struct{}{},
"runtime.retpolineAX": struct{}{},
"runtime.retpolineBP": struct{}{},
"runtime.retpolineBX": struct{}{},
"runtime.retpolineCX": struct{}{},
"runtime.retpolineDI": struct{}{},
"runtime.retpolineDX": struct{}{},
"runtime.retpolineR10": struct{}{},
"runtime.retpolineR11": struct{}{},
"runtime.retpolineR12": struct{}{},
"runtime.retpolineR13": struct{}{},
"runtime.retpolineR14": struct{}{},
"runtime.retpolineR15": struct{}{},
"runtime.retpolineR8": struct{}{},
"runtime.retpolineR9": struct{}{},
"runtime.retpolineSI": struct{}{},
"runtime.stackcheck": struct{}{},
"runtime.settls": struct{}{},
}
addrsAllowed := make(map[string]struct{})
// Build the map.
nextFunc := "" // For funcsAllowed.
m := make(map[string][]string)
r := bufio.NewReader(out)
NextLine:
for {
line, err := r.ReadString('\n')
if err != nil && err != io.EOF {
return nil, err
}
fields := strings.Fields(line)
// Is this an "allowed" function definition?
if len(fields) >= 2 && fields[0] == "TEXT" {
nextFunc = strings.TrimSuffix(fields[1], "(SB)")
if _, ok := funcsAllowed[nextFunc]; !ok {
nextFunc = "" // Don't record addresses.
}
}
if nextFunc != "" && len(fields) > 2 {
// Save the given address (in hex form, as it appears).
addrsAllowed[fields[1]] = struct{}{}
}
// 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(fields) >= 5 && line[0] == ' ' {
if !strings.Contains(fields[3], "CALL") {
continue
}
site := fields[0]
target := strings.TrimSuffix(fields[4], "(SB)")
// Ignore strings containing allowed functions.
if _, ok := funcsAllowed[target]; ok {
continue
}
if _, ok := addrsAllowed[target]; ok {
continue
}
if len(fields) > 5 {
// This may be a future relocation. Some
// objdump versions describe this differently.
// If it contains any of the functions allowed
// above as a string, we let it go.
softTarget := strings.Join(fields[5:], " ")
for name := range funcsAllowed {
if strings.Contains(softTarget, name) {
continue NextLine
}
}
}
// Does this exist already?
existing, ok := m[site]
if !ok {
existing = make([]string, 0, 1)
}
for _, other := range existing {
if target == other {
continue NextLine
}
}
existing = append(existing, target)
m[site] = existing // Update.
}
if err == io.EOF {
break
}
}
// Zap any accidental false positives.
final := make(map[string][]string)
for site, calls := range m {
filteredCalls := make([]string, 0, len(calls))
for _, call := range calls {
if _, ok := addrsAllowed[call]; ok {
continue // Omit this call.
}
filteredCalls = append(filteredCalls, call)
}
final[site] = filteredCalls
}
// Wait for the dump to finish.
if err := cmd.Wait(); err != nil {
return nil, err
}
return final, nil
}
// poser is a type that implements Pos.
type poser interface {
Pos() token.Pos
}
// runSelectEscapes runs with only select escapes.
func runSelectEscapes(pass *analysis.Pass) (interface{}, error) {
return run(pass, false)
}
// runAllEscapes runs with all escapes included.
func runAllEscapes(pass *analysis.Pass) (interface{}, error) {
return run(pass, true)
}
// findReasons extracts reasons from the function.
func findReasons(pass *analysis.Pass, fdecl *ast.FuncDecl) ([]EscapeReason, bool, map[EscapeReason]bool) {
// Is there a comment?
if fdecl.Doc == nil {
return nil, false, nil
}
var (
reasons []EscapeReason
local bool
testReasons = make(map[EscapeReason]bool) // reason -> local?
)
// Scan all lines.
found := false
for _, c := range fdecl.Doc.List {
// Does the comment contain a +checkescape line?
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")
}
return reasons, local, testReasons
}
// run performs the analysis.
func run(pass *analysis.Pass, localEscapes bool) (interface{}, error) {
calls, err := loadObjdump()
if err != nil {
// Note that if this analysis fails, then we don't actually
// fail the analyzer itself. We simply report every possible
// escape. In most cases this will work just fine.
log.Printf("WARNING: unable to load objdump: %v", err)
}
allEscapes := make(map[string][]Escapes)
mergedEscapes := make(map[string]Escapes)
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: p.Filename,
Line: p.Line,
}
}
callSite := func(inst ssa.Instruction) CallSite {
return CallSite{
LocalPos: inst.Pos(),
Resolved: linePosition(inst, inst.Parent()),
}
}
hasCall := func(inst poser) (string, bool) {
p := linePosition(inst, nil)
if calls == nil {
// See above: we don't have access to the binary
// itself, so need to include every possible call.
return "(possible)", true
}
s, ok := calls[p.Simplified()]
if !ok {
return "", false
}
// Join all calls together.
return strings.Join(s, " or "), true
}
state := pass.ResultOf[buildssa.Analyzer].(*buildssa.SSA)
// 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(strings.ToLower(c.Text), exempt) {
exemptions[LinePosition{
Filename: p.Filename,
Line: p.Line,
}] = c.Text[len(exempt):]
}
}
}
}
var loadFunc func(*ssa.Function) Escapes // Used below.
analyzeInstruction := func(inst ssa.Instruction) (es Escapes) {
cs := callSite(inst)
if _, ok := exemptions[cs.Resolved]; ok {
return // No 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)
es.Add(interfaceInvoke, call, cs)
return
}
switch x := x.Call.Value.(type) {
case *ssa.Function:
if x.Pkg == nil {
// Can't resolve the package.
es.Add(unknownPackage, "no package", cs)
return
}
// 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 {
es.MergeWithCall(loadFunc(x), cs)
return
}
// 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.
es.Add(unknownPackage, "no analysis", cs)
return
}
// The escapes of this instruction are the
// escapes of the called function directly.
// Note that this may record many escapes.
es.MergeWithCall(imp.Funcs[x.RelString(x.Pkg.Pkg)], cs)
return
case *ssa.Builtin:
// Ignore elided escapes.
if _, has := hasCall(inst); !has {
return
}
// Check if the builtin is escaping.
for _, name := range escapingBuiltins {
if x.Name() == name {
es.Add(builtin, name, cs)
return
}
}
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)
es.Add(dynamicCall, call, cs)
}
case *ssa.Alloc:
// Ignore non-heap allocations.
if !x.Heap {
return
}
// Ignore elided escapes.
call, has := hasCall(inst)
if !has {
return
}
// This is a real heap allocation.
es.Add(allocation, call, cs)
case *ssa.MakeMap:
es.Add(builtin, "makemap", cs)
case *ssa.MakeSlice:
es.Add(builtin, "makeslice", cs)
case *ssa.MakeClosure:
es.Add(builtin, "makeclosure", cs)
case *ssa.MakeChan:
es.Add(builtin, "makechan", cs)
}
return
}
var analyzeBasicBlock func(*ssa.BasicBlock) []Escapes // Recursive.
analyzeBasicBlock = func(block *ssa.BasicBlock) (rval []Escapes) {
for _, inst := range block.Instrs {
if es := analyzeInstruction(inst); !es.IsEmpty() {
rval = append(rval, es)
}
}
return
}
loadFunc = func(fn *ssa.Function) Escapes {
// Is this already available?
name := fn.RelString(pass.Pkg)
if es, ok := mergedEscapes[name]; ok {
return es
}
// In the case of a true cycle, we assume that the current
// function itself has no escapes.
//
// When evaluating the function again, the proper escapes will
// be filled in here.
allEscapes[name] = nil
mergedEscapes[name] = Escapes{}
// Perform the basic analysis.
var es []Escapes
if fn.Recover != nil {
es = append(es, analyzeBasicBlock(fn.Recover)...)
}
for _, block := range fn.Blocks {
es = append(es, analyzeBasicBlock(block)...)
}
// Check for a stack split.
if call, has := hasCall(fn); has {
var ss Escapes
ss.Add(stackSplit, call, CallSite{
LocalPos: fn.Pos(),
Resolved: linePosition(fn, fn.Parent()),
})
es = append(es, ss)
}
// Save the result and return.
//
// Note that we merge the result when saving to the facts. It
// doesn't really matter the specific escapes, as long as we
// have recorded all the appropriate classes of escapes.
summary := MergeAll(es)
allEscapes[name] = es
mergedEscapes[name] = summary
return summary
}
// Complete all local functions.
for _, fn := range state.SrcFuncs {
loadFunc(fn)
}
if !localEscapes {
// Export all findings for future packages. We only do this in
// non-local escapes mode, and expect to run this analysis
// after the SelectAnalysis.
pass.ExportPackageFact(&packageEscapeFacts{
Funcs: mergedEscapes,
})
}
// Scan all functions for violations.
for _, f := range pass.Files {
// Scan all declarations.
for _, decl := range f.Decls {
// Function declaration?
fdecl, ok := decl.(*ast.FuncDecl)
if !ok {
continue
}
var (
reasons []EscapeReason
local bool
testReasons map[EscapeReason]bool
)
if localEscapes {
// Find all hard escapes.
reasons = hardReasons
} else {
// Find all declared reasons.
reasons, local, testReasons = findReasons(pass, fdecl)
}
// Scan for matches.
fn := pass.TypesInfo.Defs[fdecl.Name].(*types.Func)
fv := state.Pkg.Prog.FuncValue(fn)
if fv == nil {
continue
}
name := fv.RelString(pass.Pkg)
all, allOk := allEscapes[name]
merged, mergedOk := mergedEscapes[name]
if !allOk || !mergedOk {
pass.Reportf(fdecl.Pos(), "internal error: function %s not found.", name)
continue
}
// Filter reasons and report.
//
// For the findings, we use all escapes.
for _, es := range all {
es.Filter(reasons, local)
es.Reportf(pass)
}
// Scan for test (required) matches.
//
// For tests we need only the merged escapes.
testReasonsFound := make(map[EscapeReason]bool)
for r := EscapeReason(0); r < reasonCount; r++ {
if merged.CallSites[r] == nil {
continue
}
// Is this local?
wantLocal, ok := testReasons[r]
isLocal := len(merged.CallSites[r]) == 1
testReasonsFound[r] = isLocal
if !ok {
continue
}
if isLocal == wantLocal {
delete(testReasons, r)
}
}
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 {
// Report for debugging.
merged.Reportf(pass)
}
}
}
return nil, nil
}
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