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go / go / 7df09b4a03f9e53334672674ba7983d5e7128646 / . / src / cmd / fix / fix.go
blob: 03c828a5816499590a295bd3ef98cb7b72555708 [file] [log] [blame]
// Copyright 2011 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/parser"
"go/token"
"os"
"path"
"reflect"
"strconv"
"strings"
)
type fix struct {
name string
date string // date that fix was introduced, in YYYY-MM-DD format
f func(*ast.File) bool
desc string
disabled bool // whether this fix should be disabled by default
}
// main runs sort.Sort(byName(fixes)) before printing list of fixes.
type byName []fix
func (f byName) Len() int { return len(f) }
func (f byName) Swap(i, j int) { f[i], f[j] = f[j], f[i] }
func (f byName) Less(i, j int) bool { return f[i].name < f[j].name }
// main runs sort.Sort(byDate(fixes)) before applying fixes.
type byDate []fix
func (f byDate) Len() int { return len(f) }
func (f byDate) Swap(i, j int) { f[i], f[j] = f[j], f[i] }
func (f byDate) Less(i, j int) bool { return f[i].date < f[j].date }
var fixes []fix
func register(f fix) {
fixes = append(fixes, f)
}
// walk traverses the AST x, calling visit(y) for each node y in the tree but
// also with a pointer to each ast.Expr, ast.Stmt, and *ast.BlockStmt,
// in a bottom-up traversal.
func walk(x interface{}, visit func(interface{})) {
walkBeforeAfter(x, nop, visit)
}
func nop(interface{}) {}
// walkBeforeAfter is like walk but calls before(x) before traversing
// x's children and after(x) afterward.
func walkBeforeAfter(x interface{}, before, after func(interface{})) {
before(x)
switch n := x.(type) {
default:
panic(fmt.Errorf("unexpected type %T in walkBeforeAfter", x))
case nil:
// pointers to interfaces
case *ast.Decl:
walkBeforeAfter(*n, before, after)
case *ast.Expr:
walkBeforeAfter(*n, before, after)
case *ast.Spec:
walkBeforeAfter(*n, before, after)
case *ast.Stmt:
walkBeforeAfter(*n, before, after)
// pointers to struct pointers
case **ast.BlockStmt:
walkBeforeAfter(*n, before, after)
case **ast.CallExpr:
walkBeforeAfter(*n, before, after)
case **ast.FieldList:
walkBeforeAfter(*n, before, after)
case **ast.FuncType:
walkBeforeAfter(*n, before, after)
case **ast.Ident:
walkBeforeAfter(*n, before, after)
case **ast.BasicLit:
walkBeforeAfter(*n, before, after)
// pointers to slices
case *[]ast.Decl:
walkBeforeAfter(*n, before, after)
case *[]ast.Expr:
walkBeforeAfter(*n, before, after)
case *[]*ast.File:
walkBeforeAfter(*n, before, after)
case *[]*ast.Ident:
walkBeforeAfter(*n, before, after)
case *[]ast.Spec:
walkBeforeAfter(*n, before, after)
case *[]ast.Stmt:
walkBeforeAfter(*n, before, after)
// These are ordered and grouped to match ../../go/ast/ast.go
case *ast.Field:
walkBeforeAfter(&n.Names, before, after)
walkBeforeAfter(&n.Type, before, after)
walkBeforeAfter(&n.Tag, before, after)
case *ast.FieldList:
for _, field := range n.List {
walkBeforeAfter(field, before, after)
}
case *ast.BadExpr:
case *ast.Ident:
case *ast.Ellipsis:
walkBeforeAfter(&n.Elt, before, after)
case *ast.BasicLit:
case *ast.FuncLit:
walkBeforeAfter(&n.Type, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.CompositeLit:
walkBeforeAfter(&n.Type, before, after)
walkBeforeAfter(&n.Elts, before, after)
case *ast.ParenExpr:
walkBeforeAfter(&n.X, before, after)
case *ast.SelectorExpr:
walkBeforeAfter(&n.X, before, after)
case *ast.IndexExpr:
walkBeforeAfter(&n.X, before, after)
walkBeforeAfter(&n.Index, before, after)
case *ast.SliceExpr:
walkBeforeAfter(&n.X, before, after)
if n.Low != nil {
walkBeforeAfter(&n.Low, before, after)
}
if n.High != nil {
walkBeforeAfter(&n.High, before, after)
}
case *ast.TypeAssertExpr:
walkBeforeAfter(&n.X, before, after)
walkBeforeAfter(&n.Type, before, after)
case *ast.CallExpr:
walkBeforeAfter(&n.Fun, before, after)
walkBeforeAfter(&n.Args, before, after)
case *ast.StarExpr:
walkBeforeAfter(&n.X, before, after)
case *ast.UnaryExpr:
walkBeforeAfter(&n.X, before, after)
case *ast.BinaryExpr:
walkBeforeAfter(&n.X, before, after)
walkBeforeAfter(&n.Y, before, after)
case *ast.KeyValueExpr:
walkBeforeAfter(&n.Key, before, after)
walkBeforeAfter(&n.Value, before, after)
case *ast.ArrayType:
walkBeforeAfter(&n.Len, before, after)
walkBeforeAfter(&n.Elt, before, after)
case *ast.StructType:
walkBeforeAfter(&n.Fields, before, after)
case *ast.FuncType:
walkBeforeAfter(&n.Params, before, after)
if n.Results != nil {
walkBeforeAfter(&n.Results, before, after)
}
case *ast.InterfaceType:
walkBeforeAfter(&n.Methods, before, after)
case *ast.MapType:
walkBeforeAfter(&n.Key, before, after)
walkBeforeAfter(&n.Value, before, after)
case *ast.ChanType:
walkBeforeAfter(&n.Value, before, after)
case *ast.BadStmt:
case *ast.DeclStmt:
walkBeforeAfter(&n.Decl, before, after)
case *ast.EmptyStmt:
case *ast.LabeledStmt:
walkBeforeAfter(&n.Stmt, before, after)
case *ast.ExprStmt:
walkBeforeAfter(&n.X, before, after)
case *ast.SendStmt:
walkBeforeAfter(&n.Chan, before, after)
walkBeforeAfter(&n.Value, before, after)
case *ast.IncDecStmt:
walkBeforeAfter(&n.X, before, after)
case *ast.AssignStmt:
walkBeforeAfter(&n.Lhs, before, after)
walkBeforeAfter(&n.Rhs, before, after)
case *ast.GoStmt:
walkBeforeAfter(&n.Call, before, after)
case *ast.DeferStmt:
walkBeforeAfter(&n.Call, before, after)
case *ast.ReturnStmt:
walkBeforeAfter(&n.Results, before, after)
case *ast.BranchStmt:
case *ast.BlockStmt:
walkBeforeAfter(&n.List, before, after)
case *ast.IfStmt:
walkBeforeAfter(&n.Init, before, after)
walkBeforeAfter(&n.Cond, before, after)
walkBeforeAfter(&n.Body, before, after)
walkBeforeAfter(&n.Else, before, after)
case *ast.CaseClause:
walkBeforeAfter(&n.List, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.SwitchStmt:
walkBeforeAfter(&n.Init, before, after)
walkBeforeAfter(&n.Tag, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.TypeSwitchStmt:
walkBeforeAfter(&n.Init, before, after)
walkBeforeAfter(&n.Assign, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.CommClause:
walkBeforeAfter(&n.Comm, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.SelectStmt:
walkBeforeAfter(&n.Body, before, after)
case *ast.ForStmt:
walkBeforeAfter(&n.Init, before, after)
walkBeforeAfter(&n.Cond, before, after)
walkBeforeAfter(&n.Post, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.RangeStmt:
walkBeforeAfter(&n.Key, before, after)
walkBeforeAfter(&n.Value, before, after)
walkBeforeAfter(&n.X, before, after)
walkBeforeAfter(&n.Body, before, after)
case *ast.ImportSpec:
case *ast.ValueSpec:
walkBeforeAfter(&n.Type, before, after)
walkBeforeAfter(&n.Values, before, after)
walkBeforeAfter(&n.Names, before, after)
case *ast.TypeSpec:
walkBeforeAfter(&n.Type, before, after)
case *ast.BadDecl:
case *ast.GenDecl:
walkBeforeAfter(&n.Specs, before, after)
case *ast.FuncDecl:
if n.Recv != nil {
walkBeforeAfter(&n.Recv, before, after)
}
walkBeforeAfter(&n.Type, before, after)
if n.Body != nil {
walkBeforeAfter(&n.Body, before, after)
}
case *ast.File:
walkBeforeAfter(&n.Decls, before, after)
case *ast.Package:
walkBeforeAfter(&n.Files, before, after)
case []*ast.File:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
case []ast.Decl:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
case []ast.Expr:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
case []*ast.Ident:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
case []ast.Stmt:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
case []ast.Spec:
for i := range n {
walkBeforeAfter(&n[i], before, after)
}
}
after(x)
}
// imports reports whether f imports path.
func imports(f *ast.File, path string) bool {
return importSpec(f, path) != nil
}
// importSpec returns the import spec if f imports path,
// or nil otherwise.
func importSpec(f *ast.File, path string) *ast.ImportSpec {
for _, s := range f.Imports {
if importPath(s) == path {
return s
}
}
return nil
}
// importPath returns the unquoted import path of s,
// or "" if the path is not properly quoted.
func importPath(s *ast.ImportSpec) string {
t, err := strconv.Unquote(s.Path.Value)
if err == nil {
return t
}
return ""
}
// declImports reports whether gen contains an import of path.
func declImports(gen *ast.GenDecl, path string) bool {
if gen.Tok != token.IMPORT {
return false
}
for _, spec := range gen.Specs {
impspec := spec.(*ast.ImportSpec)
if importPath(impspec) == path {
return true
}
}
return false
}
// isPkgDot reports whether t is the expression "pkg.name"
// where pkg is an imported identifier.
func isPkgDot(t ast.Expr, pkg, name string) bool {
sel, ok := t.(*ast.SelectorExpr)
return ok && isTopName(sel.X, pkg) && sel.Sel.String() == name
}
// isPtrPkgDot reports whether f is the expression "*pkg.name"
// where pkg is an imported identifier.
func isPtrPkgDot(t ast.Expr, pkg, name string) bool {
ptr, ok := t.(*ast.StarExpr)
return ok && isPkgDot(ptr.X, pkg, name)
}
// isTopName reports whether n is a top-level unresolved identifier with the given name.
func isTopName(n ast.Expr, name string) bool {
id, ok := n.(*ast.Ident)
return ok && id.Name == name && id.Obj == nil
}
// isName reports whether n is an identifier with the given name.
func isName(n ast.Expr, name string) bool {
id, ok := n.(*ast.Ident)
return ok && id.String() == name
}
// isCall reports whether t is a call to pkg.name.
func isCall(t ast.Expr, pkg, name string) bool {
call, ok := t.(*ast.CallExpr)
return ok && isPkgDot(call.Fun, pkg, name)
}
// If n is an *ast.Ident, isIdent returns it; otherwise isIdent returns nil.
func isIdent(n interface{}) *ast.Ident {
id, _ := n.(*ast.Ident)
return id
}
// refersTo reports whether n is a reference to the same object as x.
func refersTo(n ast.Node, x *ast.Ident) bool {
id, ok := n.(*ast.Ident)
// The test of id.Name == x.Name handles top-level unresolved
// identifiers, which all have Obj == nil.
return ok && id.Obj == x.Obj && id.Name == x.Name
}
// isBlank reports whether n is the blank identifier.
func isBlank(n ast.Expr) bool {
return isName(n, "_")
}
// isEmptyString reports whether n is an empty string literal.
func isEmptyString(n ast.Expr) bool {
lit, ok := n.(*ast.BasicLit)
return ok && lit.Kind == token.STRING && len(lit.Value) == 2
}
func warn(pos token.Pos, msg string, args ...interface{}) {
if pos.IsValid() {
msg = "%s: " + msg
arg1 := []interface{}{fset.Position(pos).String()}
args = append(arg1, args...)
}
fmt.Fprintf(os.Stderr, msg+"\n", args...)
}
// countUses returns the number of uses of the identifier x in scope.
func countUses(x *ast.Ident, scope []ast.Stmt) int {
count := 0
ff := func(n interface{}) {
if n, ok := n.(ast.Node); ok && refersTo(n, x) {
count++
}
}
for _, n := range scope {
walk(n, ff)
}
return count
}
// rewriteUses replaces all uses of the identifier x and !x in scope
// with f(x.Pos()) and fnot(x.Pos()).
func rewriteUses(x *ast.Ident, f, fnot func(token.Pos) ast.Expr, scope []ast.Stmt) {
var lastF ast.Expr
ff := func(n interface{}) {
ptr, ok := n.(*ast.Expr)
if !ok {
return
}
nn := *ptr
// The child node was just walked and possibly replaced.
// If it was replaced and this is a negation, replace with fnot(p).
not, ok := nn.(*ast.UnaryExpr)
if ok && not.Op == token.NOT && not.X == lastF {
*ptr = fnot(nn.Pos())
return
}
if refersTo(nn, x) {
lastF = f(nn.Pos())
*ptr = lastF
}
}
for _, n := range scope {
walk(n, ff)
}
}
// assignsTo reports whether any of the code in scope assigns to or takes the address of x.
func assignsTo(x *ast.Ident, scope []ast.Stmt) bool {
assigned := false
ff := func(n interface{}) {
if assigned {
return
}
switch n := n.(type) {
case *ast.UnaryExpr:
// use of &x
if n.Op == token.AND && refersTo(n.X, x) {
assigned = true
return
}
case *ast.AssignStmt:
for _, l := range n.Lhs {
if refersTo(l, x) {
assigned = true
return
}
}
}
}
for _, n := range scope {
if assigned {
break
}
walk(n, ff)
}
return assigned
}
// newPkgDot returns an ast.Expr referring to "pkg.name" at position pos.
func newPkgDot(pos token.Pos, pkg, name string) ast.Expr {
return &ast.SelectorExpr{
X: &ast.Ident{
NamePos: pos,
Name: pkg,
},
Sel: &ast.Ident{
NamePos: pos,
Name: name,
},
}
}
// renameTop renames all references to the top-level name old.
// It returns true if it makes any changes.
func renameTop(f *ast.File, old, new string) bool {
var fixed bool
// Rename any conflicting imports
// (assuming package name is last element of path).
for _, s := range f.Imports {
if s.Name != nil {
if s.Name.Name == old {
s.Name.Name = new
fixed = true
}
} else {
_, thisName := path.Split(importPath(s))
if thisName == old {
s.Name = ast.NewIdent(new)
fixed = true
}
}
}
// Rename any top-level declarations.
for _, d := range f.Decls {
switch d := d.(type) {
case *ast.FuncDecl:
if d.Recv == nil && d.Name.Name == old {
d.Name.Name = new
d.Name.Obj.Name = new
fixed = true
}
case *ast.GenDecl:
for _, s := range d.Specs {
switch s := s.(type) {
case *ast.TypeSpec:
if s.Name.Name == old {
s.Name.Name = new
s.Name.Obj.Name = new
fixed = true
}
case *ast.ValueSpec:
for _, n := range s.Names {
if n.Name == old {
n.Name = new
n.Obj.Name = new
fixed = true
}
}
}
}
}
}
// Rename top-level old to new, both unresolved names
// (probably defined in another file) and names that resolve
// to a declaration we renamed.
walk(f, func(n interface{}) {
id, ok := n.(*ast.Ident)
if ok && isTopName(id, old) {
id.Name = new
fixed = true
}
if ok && id.Obj != nil && id.Name == old && id.Obj.Name == new {
id.Name = id.Obj.Name
fixed = true
}
})
return fixed
}
// matchLen returns the length of the longest prefix shared by x and y.
func matchLen(x, y string) int {
i := 0
for i < len(x) && i < len(y) && x[i] == y[i] {
i++
}
return i
}
// addImport adds the import path to the file f, if absent.
func addImport(f *ast.File, ipath string) (added bool) {
if imports(f, ipath) {
return false
}
// Determine name of import.
// Assume added imports follow convention of using last element.
_, name := path.Split(ipath)
// Rename any conflicting top-level references from name to name_.
renameTop(f, name, name+"_")
newImport := &ast.ImportSpec{
Path: &ast.BasicLit{
Kind: token.STRING,
Value: strconv.Quote(ipath),
},
}
// Find an import decl to add to.
var (
bestMatch = -1
lastImport = -1
impDecl *ast.GenDecl
impIndex = -1
)
for i, decl := range f.Decls {
gen, ok := decl.(*ast.GenDecl)
if ok && gen.Tok == token.IMPORT {
lastImport = i
// Do not add to import "C", to avoid disrupting the
// association with its doc comment, breaking cgo.
if declImports(gen, "C") {
continue
}
// Compute longest shared prefix with imports in this block.
for j, spec := range gen.Specs {
impspec := spec.(*ast.ImportSpec)
n := matchLen(importPath(impspec), ipath)
if n > bestMatch {
bestMatch = n
impDecl = gen
impIndex = j
}
}
}
}
// If no import decl found, add one after the last import.
if impDecl == nil {
impDecl = &ast.GenDecl{
Tok: token.IMPORT,
}
f.Decls = append(f.Decls, nil)
copy(f.Decls[lastImport+2:], f.Decls[lastImport+1:])
f.Decls[lastImport+1] = impDecl
}
// Ensure the import decl has parentheses, if needed.
if len(impDecl.Specs) > 0 && !impDecl.Lparen.IsValid() {
impDecl.Lparen = impDecl.Pos()
}
insertAt := impIndex + 1
if insertAt == 0 {
insertAt = len(impDecl.Specs)
}
impDecl.Specs = append(impDecl.Specs, nil)
copy(impDecl.Specs[insertAt+1:], impDecl.Specs[insertAt:])
impDecl.Specs[insertAt] = newImport
if insertAt > 0 {
// Assign same position as the previous import,
// so that the sorter sees it as being in the same block.
prev := impDecl.Specs[insertAt-1]
newImport.Path.ValuePos = prev.Pos()
newImport.EndPos = prev.Pos()
}
f.Imports = append(f.Imports, newImport)
return true
}
// deleteImport deletes the import path from the file f, if present.
func deleteImport(f *ast.File, path string) (deleted bool) {
oldImport := importSpec(f, path)
// Find the import node that imports path, if any.
for i, decl := range f.Decls {
gen, ok := decl.(*ast.GenDecl)
if !ok || gen.Tok != token.IMPORT {
continue
}
for j, spec := range gen.Specs {
impspec := spec.(*ast.ImportSpec)
if oldImport != impspec {
continue
}
// We found an import spec that imports path.
// Delete it.
deleted = true
copy(gen.Specs[j:], gen.Specs[j+1:])
gen.Specs = gen.Specs[:len(gen.Specs)-1]
// If this was the last import spec in this decl,
// delete the decl, too.
if len(gen.Specs) == 0 {
copy(f.Decls[i:], f.Decls[i+1:])
f.Decls = f.Decls[:len(f.Decls)-1]
} else if len(gen.Specs) == 1 {
gen.Lparen = token.NoPos // drop parens
}
if j > 0 {
// We deleted an entry but now there will be
// a blank line-sized hole where the import was.
// Close the hole by making the previous
// import appear to "end" where this one did.
gen.Specs[j-1].(*ast.ImportSpec).EndPos = impspec.End()
}
break
}
}
// Delete it from f.Imports.
for i, imp := range f.Imports {
if imp == oldImport {
copy(f.Imports[i:], f.Imports[i+1:])
f.Imports = f.Imports[:len(f.Imports)-1]
break
}
}
return
}
// rewriteImport rewrites any import of path oldPath to path newPath.
func rewriteImport(f *ast.File, oldPath, newPath string) (rewrote bool) {
for _, imp := range f.Imports {
if importPath(imp) == oldPath {
rewrote = true
// record old End, because the default is to compute
// it using the length of imp.Path.Value.
imp.EndPos = imp.End()
imp.Path.Value = strconv.Quote(newPath)
}
}
return
}
func usesImport(f *ast.File, path string) (used bool) {
spec := importSpec(f, path)
if spec == nil {
return
}
name := spec.Name.String()
switch name {
case "<nil>":
// If the package name is not explicitly specified,
// make an educated guess. This is not guaranteed to be correct.
lastSlash := strings.LastIndex(path, "/")
if lastSlash == -1 {
name = path
} else {
name = path[lastSlash+1:]
}
case "_", ".":
// Not sure if this import is used - err on the side of caution.
return true
}
walk(f, func(n interface{}) {
sel, ok := n.(*ast.SelectorExpr)
if ok && isTopName(sel.X, name) {
used = true
}
})
return
}
func expr(s string) ast.Expr {
x, err := parser.ParseExpr(s)
if err != nil {
panic("parsing " + s + ": " + err.Error())
}
// Remove position information to avoid spurious newlines.
killPos(reflect.ValueOf(x))
return x
}
var posType = reflect.TypeOf(token.Pos(0))
func killPos(v reflect.Value) {
switch v.Kind() {
case reflect.Ptr, reflect.Interface:
if !v.IsNil() {
killPos(v.Elem())
}
case reflect.Slice:
n := v.Len()
for i := 0; i < n; i++ {
killPos(v.Index(i))
}
case reflect.Struct:
n := v.NumField()
for i := 0; i < n; i++ {
f := v.Field(i)
if f.Type() == posType {
f.SetInt(0)
continue
}
killPos(f)
}
}
}
// A Rename describes a single renaming.
type rename struct {
OldImport string // only apply rename if this import is present
NewImport string // add this import during rewrite
Old string // old name: p.T or *p.T
New string // new name: p.T or *p.T
}
func renameFix(tab []rename) func(*ast.File) bool {
return func(f *ast.File) bool {
return renameFixTab(f, tab)
}
}
func parseName(s string) (ptr bool, pkg, nam string) {
i := strings.Index(s, ".")
if i < 0 {
panic("parseName: invalid name " + s)
}
if strings.HasPrefix(s, "*") {
ptr = true
s = s[1:]
i--
}
pkg = s[:i]
nam = s[i+1:]
return
}
func renameFixTab(f *ast.File, tab []rename) bool {
fixed := false
added := map[string]bool{}
check := map[string]bool{}
for _, t := range tab {
if !imports(f, t.OldImport) {
continue
}
optr, opkg, onam := parseName(t.Old)
walk(f, func(n interface{}) {
np, ok := n.(*ast.Expr)
if !ok {
return
}
x := *np
if optr {
p, ok := x.(*ast.StarExpr)
if !ok {
return
}
x = p.X
}
if !isPkgDot(x, opkg, onam) {
return
}
if t.NewImport != "" && !added[t.NewImport] {
addImport(f, t.NewImport)
added[t.NewImport] = true
}
*np = expr(t.New)
check[t.OldImport] = true
fixed = true
})
}
for ipath := range check {
if !usesImport(f, ipath) {
deleteImport(f, ipath)
}
}
return fixed
}