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mirror of https://github.com/golang/go synced 2024-11-18 14:14:46 -07:00
go/internal/lsp/source/rename_check.go
Pontus Leitzler dc31b401ab internal/lsp/source: avoid panic in rename check
In a case where the type info for an ast.CompositeLit isn't found in
forEachLexicalRef(...) gopls will panic.

e.g. trying to rename "foo" where it is declared in this case:
func fn() {
	var foo bool
	make(map[string]bool
	if foo {
	}
}

Note the missing ')' after make.

This change will skip ast.CompositeLits if the type can't be found, and
that fixes the panic. But it also do rename the identifier as long as it
is possible, and I'm not convinced that we should allow rename at all if
the source can't be compiled.

Updates golang/go#39614

Change-Id: Ibb50b15ce4b31056f2f1da52a4dcab7b8b91a320
Reviewed-on: https://go-review.googlesource.com/c/tools/+/238042
Reviewed-by: Rebecca Stambler <rstambler@golang.org>
Run-TryBot: Rebecca Stambler <rstambler@golang.org>
2020-06-16 19:50:46 +00:00

951 lines
28 KiB
Go

// Copyright 2019 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.
//
// Taken from golang.org/x/tools/refactor/rename.
package source
import (
"fmt"
"go/ast"
"go/token"
"go/types"
"reflect"
"strconv"
"strings"
"unicode"
"golang.org/x/tools/go/ast/astutil"
"golang.org/x/tools/refactor/satisfy"
)
// errorf reports an error (e.g. conflict) and prevents file modification.
func (r *renamer) errorf(pos token.Pos, format string, args ...interface{}) {
r.hadConflicts = true
r.errors += fmt.Sprintf(format, args...)
}
// check performs safety checks of the renaming of the 'from' object to r.to.
func (r *renamer) check(from types.Object) {
if r.objsToUpdate[from] {
return
}
r.objsToUpdate[from] = true
// NB: order of conditions is important.
if from_, ok := from.(*types.PkgName); ok {
r.checkInFileBlock(from_)
} else if from_, ok := from.(*types.Label); ok {
r.checkLabel(from_)
} else if isPackageLevel(from) {
r.checkInPackageBlock(from)
} else if v, ok := from.(*types.Var); ok && v.IsField() {
r.checkStructField(v)
} else if f, ok := from.(*types.Func); ok && recv(f) != nil {
r.checkMethod(f)
} else if isLocal(from) {
r.checkInLocalScope(from)
} else {
r.errorf(from.Pos(), "unexpected %s object %q (please report a bug)\n",
objectKind(from), from)
}
}
// checkInFileBlock performs safety checks for renames of objects in the file block,
// i.e. imported package names.
func (r *renamer) checkInFileBlock(from *types.PkgName) {
// Check import name is not "init".
if r.to == "init" {
r.errorf(from.Pos(), "%q is not a valid imported package name", r.to)
}
// Check for conflicts between file and package block.
if prev := from.Pkg().Scope().Lookup(r.to); prev != nil {
r.errorf(from.Pos(), "renaming this %s %q to %q would conflict",
objectKind(from), from.Name(), r.to)
r.errorf(prev.Pos(), "\twith this package member %s",
objectKind(prev))
return // since checkInPackageBlock would report redundant errors
}
// Check for conflicts in lexical scope.
r.checkInLexicalScope(from, r.packages[from.Pkg()])
}
// checkInPackageBlock performs safety checks for renames of
// func/var/const/type objects in the package block.
func (r *renamer) checkInPackageBlock(from types.Object) {
// Check that there are no references to the name from another
// package if the renaming would make it unexported.
if ast.IsExported(from.Name()) && !ast.IsExported(r.to) {
for typ, pkg := range r.packages {
if typ == from.Pkg() {
continue
}
if id := someUse(pkg.GetTypesInfo(), from); id != nil &&
!r.checkExport(id, typ, from) {
break
}
}
}
pkg := r.packages[from.Pkg()]
if pkg == nil {
return
}
// Check that in the package block, "init" is a function, and never referenced.
if r.to == "init" {
kind := objectKind(from)
if kind == "func" {
// Reject if intra-package references to it exist.
for id, obj := range pkg.GetTypesInfo().Uses {
if obj == from {
r.errorf(from.Pos(),
"renaming this func %q to %q would make it a package initializer",
from.Name(), r.to)
r.errorf(id.Pos(), "\tbut references to it exist")
break
}
}
} else {
r.errorf(from.Pos(), "you cannot have a %s at package level named %q",
kind, r.to)
}
}
// Check for conflicts between package block and all file blocks.
for _, f := range pkg.GetSyntax() {
fileScope := pkg.GetTypesInfo().Scopes[f]
b, prev := fileScope.LookupParent(r.to, token.NoPos)
if b == fileScope {
r.errorf(from.Pos(), "renaming this %s %q to %q would conflict",
objectKind(from), from.Name(), r.to)
r.errorf(prev.Pos(), "\twith this %s",
objectKind(prev))
return // since checkInPackageBlock would report redundant errors
}
}
// Check for conflicts in lexical scope.
if from.Exported() {
for _, pkg := range r.packages {
r.checkInLexicalScope(from, pkg)
}
} else {
r.checkInLexicalScope(from, pkg)
}
}
func (r *renamer) checkInLocalScope(from types.Object) {
pkg := r.packages[from.Pkg()]
r.checkInLexicalScope(from, pkg)
}
// checkInLexicalScope performs safety checks that a renaming does not
// change the lexical reference structure of the specified package.
//
// For objects in lexical scope, there are three kinds of conflicts:
// same-, sub-, and super-block conflicts. We will illustrate all three
// using this example:
//
// var x int
// var z int
//
// func f(y int) {
// print(x)
// print(y)
// }
//
// Renaming x to z encounters a SAME-BLOCK CONFLICT, because an object
// with the new name already exists, defined in the same lexical block
// as the old object.
//
// Renaming x to y encounters a SUB-BLOCK CONFLICT, because there exists
// a reference to x from within (what would become) a hole in its scope.
// The definition of y in an (inner) sub-block would cast a shadow in
// the scope of the renamed variable.
//
// Renaming y to x encounters a SUPER-BLOCK CONFLICT. This is the
// converse situation: there is an existing definition of the new name
// (x) in an (enclosing) super-block, and the renaming would create a
// hole in its scope, within which there exist references to it. The
// new name casts a shadow in scope of the existing definition of x in
// the super-block.
//
// Removing the old name (and all references to it) is always safe, and
// requires no checks.
//
func (r *renamer) checkInLexicalScope(from types.Object, pkg Package) {
b := from.Parent() // the block defining the 'from' object
if b != nil {
toBlock, to := b.LookupParent(r.to, from.Parent().End())
if toBlock == b {
// same-block conflict
r.errorf(from.Pos(), "renaming this %s %q to %q",
objectKind(from), from.Name(), r.to)
r.errorf(to.Pos(), "\tconflicts with %s in same block",
objectKind(to))
return
} else if toBlock != nil {
// Check for super-block conflict.
// The name r.to is defined in a superblock.
// Is that name referenced from within this block?
forEachLexicalRef(pkg, to, func(id *ast.Ident, block *types.Scope) bool {
_, obj := lexicalLookup(block, from.Name(), id.Pos())
if obj == from {
// super-block conflict
r.errorf(from.Pos(), "renaming this %s %q to %q",
objectKind(from), from.Name(), r.to)
r.errorf(id.Pos(), "\twould shadow this reference")
r.errorf(to.Pos(), "\tto the %s declared here",
objectKind(to))
return false // stop
}
return true
})
}
}
// Check for sub-block conflict.
// Is there an intervening definition of r.to between
// the block defining 'from' and some reference to it?
forEachLexicalRef(pkg, from, func(id *ast.Ident, block *types.Scope) bool {
// Find the block that defines the found reference.
// It may be an ancestor.
fromBlock, _ := lexicalLookup(block, from.Name(), id.Pos())
// See what r.to would resolve to in the same scope.
toBlock, to := lexicalLookup(block, r.to, id.Pos())
if to != nil {
// sub-block conflict
if deeper(toBlock, fromBlock) {
r.errorf(from.Pos(), "renaming this %s %q to %q",
objectKind(from), from.Name(), r.to)
r.errorf(id.Pos(), "\twould cause this reference to become shadowed")
r.errorf(to.Pos(), "\tby this intervening %s definition",
objectKind(to))
return false // stop
}
}
return true
})
// Renaming a type that is used as an embedded field
// requires renaming the field too. e.g.
// type T int // if we rename this to U..
// var s struct {T}
// print(s.T) // ...this must change too
if _, ok := from.(*types.TypeName); ok {
for id, obj := range pkg.GetTypesInfo().Uses {
if obj == from {
if field := pkg.GetTypesInfo().Defs[id]; field != nil {
r.check(field)
}
}
}
}
}
// lexicalLookup is like (*types.Scope).LookupParent but respects the
// environment visible at pos. It assumes the relative position
// information is correct with each file.
func lexicalLookup(block *types.Scope, name string, pos token.Pos) (*types.Scope, types.Object) {
for b := block; b != nil; b = b.Parent() {
obj := b.Lookup(name)
// The scope of a package-level object is the entire package,
// so ignore pos in that case.
// No analogous clause is needed for file-level objects
// since no reference can appear before an import decl.
if obj == nil || obj.Pkg() == nil {
continue
}
if b == obj.Pkg().Scope() || obj.Pos() < pos {
return b, obj
}
}
return nil, nil
}
// deeper reports whether block x is lexically deeper than y.
func deeper(x, y *types.Scope) bool {
if x == y || x == nil {
return false
} else if y == nil {
return true
} else {
return deeper(x.Parent(), y.Parent())
}
}
// forEachLexicalRef calls fn(id, block) for each identifier id in package
// pkg that is a reference to obj in lexical scope. block is the
// lexical block enclosing the reference. If fn returns false the
// iteration is terminated and findLexicalRefs returns false.
func forEachLexicalRef(pkg Package, obj types.Object, fn func(id *ast.Ident, block *types.Scope) bool) bool {
ok := true
var stack []ast.Node
var visit func(n ast.Node) bool
visit = func(n ast.Node) bool {
if n == nil {
stack = stack[:len(stack)-1] // pop
return false
}
if !ok {
return false // bail out
}
stack = append(stack, n) // push
switch n := n.(type) {
case *ast.Ident:
if pkg.GetTypesInfo().Uses[n] == obj {
block := enclosingBlock(pkg.GetTypesInfo(), stack)
if !fn(n, block) {
ok = false
}
}
return visit(nil) // pop stack
case *ast.SelectorExpr:
// don't visit n.Sel
ast.Inspect(n.X, visit)
return visit(nil) // pop stack, don't descend
case *ast.CompositeLit:
// Handle recursion ourselves for struct literals
// so we don't visit field identifiers.
tv, ok := pkg.GetTypesInfo().Types[n]
if !ok {
return visit(nil) // pop stack, don't descend
}
if _, ok := deref(tv.Type).Underlying().(*types.Struct); ok {
if n.Type != nil {
ast.Inspect(n.Type, visit)
}
for _, elt := range n.Elts {
if kv, ok := elt.(*ast.KeyValueExpr); ok {
ast.Inspect(kv.Value, visit)
} else {
ast.Inspect(elt, visit)
}
}
return visit(nil) // pop stack, don't descend
}
}
return true
}
for _, f := range pkg.GetSyntax() {
ast.Inspect(f, visit)
if len(stack) != 0 {
panic(stack)
}
if !ok {
break
}
}
return ok
}
// enclosingBlock returns the innermost block enclosing the specified
// AST node, specified in the form of a path from the root of the file,
// [file...n].
func enclosingBlock(info *types.Info, stack []ast.Node) *types.Scope {
for i := range stack {
n := stack[len(stack)-1-i]
// For some reason, go/types always associates a
// function's scope with its FuncType.
// TODO(adonovan): feature or a bug?
switch f := n.(type) {
case *ast.FuncDecl:
n = f.Type
case *ast.FuncLit:
n = f.Type
}
if b := info.Scopes[n]; b != nil {
return b
}
}
panic("no Scope for *ast.File")
}
func (r *renamer) checkLabel(label *types.Label) {
// Check there are no identical labels in the function's label block.
// (Label blocks don't nest, so this is easy.)
if prev := label.Parent().Lookup(r.to); prev != nil {
r.errorf(label.Pos(), "renaming this label %q to %q", label.Name(), prev.Name())
r.errorf(prev.Pos(), "\twould conflict with this one")
}
}
// checkStructField checks that the field renaming will not cause
// conflicts at its declaration, or ambiguity or changes to any selection.
func (r *renamer) checkStructField(from *types.Var) {
// Check that the struct declaration is free of field conflicts,
// and field/method conflicts.
// go/types offers no easy way to get from a field (or interface
// method) to its declaring struct (or interface), so we must
// ascend the AST.
pkg, path, _ := pathEnclosingInterval(r.fset, r.packages[from.Pkg()], from.Pos(), from.Pos())
if pkg == nil || path == nil {
return
}
// path matches this pattern:
// [Ident SelectorExpr? StarExpr? Field FieldList StructType ParenExpr* ... File]
// Ascend to FieldList.
var i int
for {
if _, ok := path[i].(*ast.FieldList); ok {
break
}
i++
}
i++
tStruct := path[i].(*ast.StructType)
i++
// Ascend past parens (unlikely).
for {
_, ok := path[i].(*ast.ParenExpr)
if !ok {
break
}
i++
}
if spec, ok := path[i].(*ast.TypeSpec); ok {
// This struct is also a named type.
// We must check for direct (non-promoted) field/field
// and method/field conflicts.
named := pkg.GetTypesInfo().Defs[spec.Name].Type()
prev, indices, _ := types.LookupFieldOrMethod(named, true, pkg.GetTypes(), r.to)
if len(indices) == 1 {
r.errorf(from.Pos(), "renaming this field %q to %q",
from.Name(), r.to)
r.errorf(prev.Pos(), "\twould conflict with this %s",
objectKind(prev))
return // skip checkSelections to avoid redundant errors
}
} else {
// This struct is not a named type.
// We need only check for direct (non-promoted) field/field conflicts.
T := pkg.GetTypesInfo().Types[tStruct].Type.Underlying().(*types.Struct)
for i := 0; i < T.NumFields(); i++ {
if prev := T.Field(i); prev.Name() == r.to {
r.errorf(from.Pos(), "renaming this field %q to %q",
from.Name(), r.to)
r.errorf(prev.Pos(), "\twould conflict with this field")
return // skip checkSelections to avoid redundant errors
}
}
}
// Renaming an anonymous field requires renaming the type too. e.g.
// print(s.T) // if we rename T to U,
// type T int // this and
// var s struct {T} // this must change too.
if from.Anonymous() {
if named, ok := from.Type().(*types.Named); ok {
r.check(named.Obj())
} else if named, ok := deref(from.Type()).(*types.Named); ok {
r.check(named.Obj())
}
}
// Check integrity of existing (field and method) selections.
r.checkSelections(from)
}
// checkSelection checks that all uses and selections that resolve to
// the specified object would continue to do so after the renaming.
func (r *renamer) checkSelections(from types.Object) {
for typ, pkg := range r.packages {
if id := someUse(pkg.GetTypesInfo(), from); id != nil {
if !r.checkExport(id, typ, from) {
return
}
}
for syntax, sel := range pkg.GetTypesInfo().Selections {
// There may be extant selections of only the old
// name or only the new name, so we must check both.
// (If neither, the renaming is sound.)
//
// In both cases, we wish to compare the lengths
// of the implicit field path (Selection.Index)
// to see if the renaming would change it.
//
// If a selection that resolves to 'from', when renamed,
// would yield a path of the same or shorter length,
// this indicates ambiguity or a changed referent,
// analogous to same- or sub-block lexical conflict.
//
// If a selection using the name 'to' would
// yield a path of the same or shorter length,
// this indicates ambiguity or shadowing,
// analogous to same- or super-block lexical conflict.
// TODO(adonovan): fix: derive from Types[syntax.X].Mode
// TODO(adonovan): test with pointer, value, addressable value.
isAddressable := true
if sel.Obj() == from {
if obj, indices, _ := types.LookupFieldOrMethod(sel.Recv(), isAddressable, from.Pkg(), r.to); obj != nil {
// Renaming this existing selection of
// 'from' may block access to an existing
// type member named 'to'.
delta := len(indices) - len(sel.Index())
if delta > 0 {
continue // no ambiguity
}
r.selectionConflict(from, delta, syntax, obj)
return
}
} else if sel.Obj().Name() == r.to {
if obj, indices, _ := types.LookupFieldOrMethod(sel.Recv(), isAddressable, from.Pkg(), from.Name()); obj == from {
// Renaming 'from' may cause this existing
// selection of the name 'to' to change
// its meaning.
delta := len(indices) - len(sel.Index())
if delta > 0 {
continue // no ambiguity
}
r.selectionConflict(from, -delta, syntax, sel.Obj())
return
}
}
}
}
}
func (r *renamer) selectionConflict(from types.Object, delta int, syntax *ast.SelectorExpr, obj types.Object) {
r.errorf(from.Pos(), "renaming this %s %q to %q",
objectKind(from), from.Name(), r.to)
switch {
case delta < 0:
// analogous to sub-block conflict
r.errorf(syntax.Sel.Pos(),
"\twould change the referent of this selection")
r.errorf(obj.Pos(), "\tof this %s", objectKind(obj))
case delta == 0:
// analogous to same-block conflict
r.errorf(syntax.Sel.Pos(),
"\twould make this reference ambiguous")
r.errorf(obj.Pos(), "\twith this %s", objectKind(obj))
case delta > 0:
// analogous to super-block conflict
r.errorf(syntax.Sel.Pos(),
"\twould shadow this selection")
r.errorf(obj.Pos(), "\tof the %s declared here",
objectKind(obj))
}
}
// checkMethod performs safety checks for renaming a method.
// There are three hazards:
// - declaration conflicts
// - selection ambiguity/changes
// - entailed renamings of assignable concrete/interface types.
// We reject renamings initiated at concrete methods if it would
// change the assignability relation. For renamings of abstract
// methods, we rename all methods transitively coupled to it via
// assignability.
func (r *renamer) checkMethod(from *types.Func) {
// e.g. error.Error
if from.Pkg() == nil {
r.errorf(from.Pos(), "you cannot rename built-in method %s", from)
return
}
// ASSIGNABILITY: We reject renamings of concrete methods that
// would break a 'satisfy' constraint; but renamings of abstract
// methods are allowed to proceed, and we rename affected
// concrete and abstract methods as necessary. It is the
// initial method that determines the policy.
// Check for conflict at point of declaration.
// Check to ensure preservation of assignability requirements.
R := recv(from).Type()
if isInterface(R) {
// Abstract method
// declaration
prev, _, _ := types.LookupFieldOrMethod(R, false, from.Pkg(), r.to)
if prev != nil {
r.errorf(from.Pos(), "renaming this interface method %q to %q",
from.Name(), r.to)
r.errorf(prev.Pos(), "\twould conflict with this method")
return
}
// Check all interfaces that embed this one for
// declaration conflicts too.
for _, pkg := range r.packages {
// Start with named interface types (better errors)
for _, obj := range pkg.GetTypesInfo().Defs {
if obj, ok := obj.(*types.TypeName); ok && isInterface(obj.Type()) {
f, _, _ := types.LookupFieldOrMethod(
obj.Type(), false, from.Pkg(), from.Name())
if f == nil {
continue
}
t, _, _ := types.LookupFieldOrMethod(
obj.Type(), false, from.Pkg(), r.to)
if t == nil {
continue
}
r.errorf(from.Pos(), "renaming this interface method %q to %q",
from.Name(), r.to)
r.errorf(t.Pos(), "\twould conflict with this method")
r.errorf(obj.Pos(), "\tin named interface type %q", obj.Name())
}
}
// Now look at all literal interface types (includes named ones again).
for e, tv := range pkg.GetTypesInfo().Types {
if e, ok := e.(*ast.InterfaceType); ok {
_ = e
_ = tv.Type.(*types.Interface)
// TODO(adonovan): implement same check as above.
}
}
}
// assignability
//
// Find the set of concrete or abstract methods directly
// coupled to abstract method 'from' by some
// satisfy.Constraint, and rename them too.
for key := range r.satisfy() {
// key = (lhs, rhs) where lhs is always an interface.
lsel := r.msets.MethodSet(key.LHS).Lookup(from.Pkg(), from.Name())
if lsel == nil {
continue
}
rmethods := r.msets.MethodSet(key.RHS)
rsel := rmethods.Lookup(from.Pkg(), from.Name())
if rsel == nil {
continue
}
// If both sides have a method of this name,
// and one of them is m, the other must be coupled.
var coupled *types.Func
switch from {
case lsel.Obj():
coupled = rsel.Obj().(*types.Func)
case rsel.Obj():
coupled = lsel.Obj().(*types.Func)
default:
continue
}
// We must treat concrete-to-interface
// constraints like an implicit selection C.f of
// each interface method I.f, and check that the
// renaming leaves the selection unchanged and
// unambiguous.
//
// Fun fact: the implicit selection of C.f
// type I interface{f()}
// type C struct{I}
// func (C) g()
// var _ I = C{} // here
// yields abstract method I.f. This can make error
// messages less than obvious.
//
if !isInterface(key.RHS) {
// The logic below was derived from checkSelections.
rtosel := rmethods.Lookup(from.Pkg(), r.to)
if rtosel != nil {
rto := rtosel.Obj().(*types.Func)
delta := len(rsel.Index()) - len(rtosel.Index())
if delta < 0 {
continue // no ambiguity
}
// TODO(adonovan): record the constraint's position.
keyPos := token.NoPos
r.errorf(from.Pos(), "renaming this method %q to %q",
from.Name(), r.to)
if delta == 0 {
// analogous to same-block conflict
r.errorf(keyPos, "\twould make the %s method of %s invoked via interface %s ambiguous",
r.to, key.RHS, key.LHS)
r.errorf(rto.Pos(), "\twith (%s).%s",
recv(rto).Type(), r.to)
} else {
// analogous to super-block conflict
r.errorf(keyPos, "\twould change the %s method of %s invoked via interface %s",
r.to, key.RHS, key.LHS)
r.errorf(coupled.Pos(), "\tfrom (%s).%s",
recv(coupled).Type(), r.to)
r.errorf(rto.Pos(), "\tto (%s).%s",
recv(rto).Type(), r.to)
}
return // one error is enough
}
}
if !r.changeMethods {
// This should be unreachable.
r.errorf(from.Pos(), "internal error: during renaming of abstract method %s", from)
r.errorf(coupled.Pos(), "\tchangedMethods=false, coupled method=%s", coupled)
r.errorf(from.Pos(), "\tPlease file a bug report")
return
}
// Rename the coupled method to preserve assignability.
r.check(coupled)
}
} else {
// Concrete method
// declaration
prev, indices, _ := types.LookupFieldOrMethod(R, true, from.Pkg(), r.to)
if prev != nil && len(indices) == 1 {
r.errorf(from.Pos(), "renaming this method %q to %q",
from.Name(), r.to)
r.errorf(prev.Pos(), "\twould conflict with this %s",
objectKind(prev))
return
}
// assignability
//
// Find the set of abstract methods coupled to concrete
// method 'from' by some satisfy.Constraint, and rename
// them too.
//
// Coupling may be indirect, e.g. I.f <-> C.f via type D.
//
// type I interface {f()}
// type C int
// type (C) f()
// type D struct{C}
// var _ I = D{}
//
for key := range r.satisfy() {
// key = (lhs, rhs) where lhs is always an interface.
if isInterface(key.RHS) {
continue
}
rsel := r.msets.MethodSet(key.RHS).Lookup(from.Pkg(), from.Name())
if rsel == nil || rsel.Obj() != from {
continue // rhs does not have the method
}
lsel := r.msets.MethodSet(key.LHS).Lookup(from.Pkg(), from.Name())
if lsel == nil {
continue
}
imeth := lsel.Obj().(*types.Func)
// imeth is the abstract method (e.g. I.f)
// and key.RHS is the concrete coupling type (e.g. D).
if !r.changeMethods {
r.errorf(from.Pos(), "renaming this method %q to %q",
from.Name(), r.to)
var pos token.Pos
var iface string
I := recv(imeth).Type()
if named, ok := I.(*types.Named); ok {
pos = named.Obj().Pos()
iface = "interface " + named.Obj().Name()
} else {
pos = from.Pos()
iface = I.String()
}
r.errorf(pos, "\twould make %s no longer assignable to %s",
key.RHS, iface)
r.errorf(imeth.Pos(), "\t(rename %s.%s if you intend to change both types)",
I, from.Name())
return // one error is enough
}
// Rename the coupled interface method to preserve assignability.
r.check(imeth)
}
}
// Check integrity of existing (field and method) selections.
// We skip this if there were errors above, to avoid redundant errors.
r.checkSelections(from)
}
func (r *renamer) checkExport(id *ast.Ident, pkg *types.Package, from types.Object) bool {
// Reject cross-package references if r.to is unexported.
// (Such references may be qualified identifiers or field/method
// selections.)
if !ast.IsExported(r.to) && pkg != from.Pkg() {
r.errorf(from.Pos(),
"renaming %q to %q would make it unexported",
from.Name(), r.to)
r.errorf(id.Pos(), "\tbreaking references from packages such as %q",
pkg.Path())
return false
}
return true
}
// satisfy returns the set of interface satisfaction constraints.
func (r *renamer) satisfy() map[satisfy.Constraint]bool {
if r.satisfyConstraints == nil {
// Compute on demand: it's expensive.
var f satisfy.Finder
for _, pkg := range r.packages {
// From satisfy.Finder documentation:
//
// The package must be free of type errors, and
// info.{Defs,Uses,Selections,Types} must have been populated by the
// type-checker.
//
// Only proceed if all packages have no errors.
if errs := pkg.GetErrors(); len(errs) > 0 {
r.errorf(token.NoPos, // we don't have a position for this error.
"renaming %q to %q not possible because %q has errors",
r.from, r.to, pkg.PkgPath())
return nil
}
f.Find(pkg.GetTypesInfo(), pkg.GetSyntax())
}
r.satisfyConstraints = f.Result
}
return r.satisfyConstraints
}
// -- helpers ----------------------------------------------------------
// recv returns the method's receiver.
func recv(meth *types.Func) *types.Var {
return meth.Type().(*types.Signature).Recv()
}
// someUse returns an arbitrary use of obj within info.
func someUse(info *types.Info, obj types.Object) *ast.Ident {
for id, o := range info.Uses {
if o == obj {
return id
}
}
return nil
}
// pathEnclosingInterval returns the Package and ast.Node that
// contain source interval [start, end), and all the node's ancestors
// up to the AST root. It searches all ast.Files of all packages.
// exact is defined as for astutil.PathEnclosingInterval.
//
// The zero value is returned if not found.
//
func pathEnclosingInterval(fset *token.FileSet, pkg Package, start, end token.Pos) (resPkg Package, path []ast.Node, exact bool) {
var pkgs = []Package{pkg}
for _, f := range pkg.GetSyntax() {
for _, imp := range f.Imports {
if imp == nil {
continue
}
importPath, err := strconv.Unquote(imp.Path.Value)
if err != nil {
continue
}
importPkg, err := pkg.GetImport(importPath)
if err != nil {
return nil, nil, false
}
pkgs = append(pkgs, importPkg)
}
}
for _, p := range pkgs {
for _, f := range p.GetSyntax() {
if f.Pos() == token.NoPos {
// This can happen if the parser saw
// too many errors and bailed out.
// (Use parser.AllErrors to prevent that.)
continue
}
if !tokenFileContainsPos(fset.File(f.Pos()), start) {
continue
}
if path, exact := astutil.PathEnclosingInterval(f, start, end); path != nil {
return pkg, path, exact
}
}
}
return nil, nil, false
}
// TODO(adonovan): make this a method: func (*token.File) Contains(token.Pos)
func tokenFileContainsPos(f *token.File, pos token.Pos) bool {
p := int(pos)
base := f.Base()
return base <= p && p < base+f.Size()
}
func objectKind(obj types.Object) string {
switch obj := obj.(type) {
case *types.PkgName:
return "imported package name"
case *types.TypeName:
return "type"
case *types.Var:
if obj.IsField() {
return "field"
}
case *types.Func:
if obj.Type().(*types.Signature).Recv() != nil {
return "method"
}
}
// label, func, var, const
return strings.ToLower(strings.TrimPrefix(reflect.TypeOf(obj).String(), "*types."))
}
// NB: for renamings, blank is not considered valid.
func isValidIdentifier(id string) bool {
if id == "" || id == "_" {
return false
}
for i, r := range id {
if !isLetter(r) && (i == 0 || !isDigit(r)) {
return false
}
}
return token.Lookup(id) == token.IDENT
}
// isLocal reports whether obj is local to some function.
// Precondition: not a struct field or interface method.
func isLocal(obj types.Object) bool {
// [... 5=stmt 4=func 3=file 2=pkg 1=universe]
var depth int
for scope := obj.Parent(); scope != nil; scope = scope.Parent() {
depth++
}
return depth >= 4
}
func isPackageLevel(obj types.Object) bool {
return obj.Pkg().Scope().Lookup(obj.Name()) == obj
}
func isInterface(T types.Type) bool {
return T != nil && types.IsInterface(T)
}
// -- Plundered from go/scanner: ---------------------------------------
func isLetter(ch rune) bool {
return 'a' <= ch && ch <= 'z' || 'A' <= ch && ch <= 'Z' || ch == '_' || ch >= 0x80 && unicode.IsLetter(ch)
}
func isDigit(ch rune) bool {
return '0' <= ch && ch <= '9' || ch >= 0x80 && unicode.IsDigit(ch)
}