go/analysis/passes/shadow/shadow.go - tools - Git at Google

 // 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 shadow

 import (
 	"go/ast"
 	"go/token"
 	"go/types"

 	"golang.org/x/tools/go/analysis"
 	"golang.org/x/tools/go/analysis/passes/inspect"
 	"golang.org/x/tools/go/ast/inspector"
 )

 // NOTE: Experimental. Not part of the vet suite.

 const Doc = `check for possible unintended shadowing of variables

 This analyzer check for shadowed variables.
 A shadowed variable is a variable declared in an inner scope
 with the same name and type as a variable in an outer scope,
 and where the outer variable is mentioned after the inner one
 is declared.

 (This definition can be refined; the module generates too many
 false positives and is not yet enabled by default.)

 For example:

 	func BadRead(f *os.File, buf []byte) error {
 		var err error
 		for {
 			n, err := f.Read(buf) // shadows the function variable 'err'
 			if err != nil {
 				break // causes return of wrong value
 			}
 			foo(buf)
 		}
 		return err
 	}
 `

 var Analyzer = &analysis.Analyzer{
 	Name:     "shadow",
 	Doc:      Doc,
 	Requires: []*analysis.Analyzer{inspect.Analyzer},
 	Run:      run,
 }

 // flags
 var strict = false

 func init() {
 	Analyzer.Flags.BoolVar(&strict, "strict", strict, "whether to be strict about shadowing; can be noisy")
 }

 func run(pass *analysis.Pass) (interface{}, error) {
 	inspect := pass.ResultOf[inspect.Analyzer].(*inspector.Inspector)

 	spans := make(map[types.Object]span)
 	for id, obj := range pass.TypesInfo.Defs {
 		// Ignore identifiers that don't denote objects
 		// (package names, symbolic variables such as t
 		// in t := x.(type) of type switch headers).
 		if obj != nil {
 			growSpan(spans, obj, id.Pos(), id.End())
 		}
 	}
 	for id, obj := range pass.TypesInfo.Uses {
 		growSpan(spans, obj, id.Pos(), id.End())
 	}
 	for node, obj := range pass.TypesInfo.Implicits {
 		// A type switch with a short variable declaration
 		// such as t := x.(type) doesn't declare the symbolic
 		// variable (t in the example) at the switch header;
 		// instead a new variable t (with specific type) is
 		// declared implicitly for each case. Such variables
 		// are found in the types.Info.Implicits (not Defs)
 		// map. Add them here, assuming they are declared at
 		// the type cases' colon ":".
 		if cc, ok := node.(*ast.CaseClause); ok {
 			growSpan(spans, obj, cc.Colon, cc.Colon)
 		}
 	}

 	nodeFilter := []ast.Node{
 		(*ast.AssignStmt)(nil),
 		(*ast.GenDecl)(nil),
 	}
 	inspect.Preorder(nodeFilter, func(n ast.Node) {
 		switch n := n.(type) {
 		case *ast.AssignStmt:
 			checkShadowAssignment(pass, spans, n)
 		case *ast.GenDecl:
 			checkShadowDecl(pass, spans, n)
 		}
 	})
 	return nil, nil
 }

 // A span stores the minimum range of byte positions in the file in which a
 // given variable (types.Object) is mentioned. It is lexically defined: it spans
 // from the beginning of its first mention to the end of its last mention.
 // A variable is considered shadowed (if strict is off) only if the
 // shadowing variable is declared within the span of the shadowed variable.
 // In other words, if a variable is shadowed but not used after the shadowed
 // variable is declared, it is inconsequential and not worth complaining about.
 // This simple check dramatically reduces the nuisance rate for the shadowing
 // check, at least until something cleverer comes along.
 //
 // One wrinkle: A "naked return" is a silent use of a variable that the Span
 // will not capture, but the compilers catch naked returns of shadowed
 // variables so we don't need to.
 //
 // Cases this gets wrong (TODO):
 // - If a for loop's continuation statement mentions a variable redeclared in
 // the block, we should complain about it but don't.
 // - A variable declared inside a function literal can falsely be identified
 // as shadowing a variable in the outer function.
 //
 type span struct {
 	min token.Pos
 	max token.Pos
 }

 // contains reports whether the position is inside the span.
 func (s span) contains(pos token.Pos) bool {
 	return s.min <= pos && pos < s.max
 }

 // growSpan expands the span for the object to contain the source range [pos, end).
 func growSpan(spans map[types.Object]span, obj types.Object, pos, end token.Pos) {
 	if strict {
 		return // No need
 	}
 	s, ok := spans[obj]
 	if ok {
 		if s.min > pos {
 			s.min = pos
 		}
 		if s.max < end {
 			s.max = end
 		}
 	} else {
 		s = span{pos, end}
 	}
 	spans[obj] = s
 }

 // checkShadowAssignment checks for shadowing in a short variable declaration.
 func checkShadowAssignment(pass *analysis.Pass, spans map[types.Object]span, a *ast.AssignStmt) {
 	if a.Tok != token.DEFINE {
 		return
 	}
 	if idiomaticShortRedecl(pass, a) {
 		return
 	}
 	for _, expr := range a.Lhs {
 		ident, ok := expr.(*ast.Ident)
 		if !ok {
 			pass.Reportf(expr.Pos(), "invalid AST: short variable declaration of non-identifier")
 			return
 		}
 		checkShadowing(pass, spans, ident)
 	}
 }

 // idiomaticShortRedecl reports whether this short declaration can be ignored for
 // the purposes of shadowing, that is, that any redeclarations it contains are deliberate.
 func idiomaticShortRedecl(pass *analysis.Pass, a *ast.AssignStmt) bool {
 	// Don't complain about deliberate redeclarations of the form
 	//	i := i
 	// Such constructs are idiomatic in range loops to create a new variable
 	// for each iteration. Another example is
 	//	switch n := n.(type)
 	if len(a.Rhs) != len(a.Lhs) {
 		return false
 	}
 	// We know it's an assignment, so the LHS must be all identifiers. (We check anyway.)
 	for i, expr := range a.Lhs {
 		lhs, ok := expr.(*ast.Ident)
 		if !ok {
 			pass.Reportf(expr.Pos(), "invalid AST: short variable declaration of non-identifier")
 			return true // Don't do any more processing.
 		}
 		switch rhs := a.Rhs[i].(type) {
 		case *ast.Ident:
 			if lhs.Name != rhs.Name {
 				return false
 			}
 		case *ast.TypeAssertExpr:
 			if id, ok := rhs.X.(*ast.Ident); ok {
 				if lhs.Name != id.Name {
 					return false
 				}
 			}
 		default:
 			return false
 		}
 	}
 	return true
 }

 // idiomaticRedecl reports whether this declaration spec can be ignored for
 // the purposes of shadowing, that is, that any redeclarations it contains are deliberate.
 func idiomaticRedecl(d *ast.ValueSpec) bool {
 	// Don't complain about deliberate redeclarations of the form
 	//	var i, j = i, j
 	if len(d.Names) != len(d.Values) {
 		return false
 	}
 	for i, lhs := range d.Names {
 		if rhs, ok := d.Values[i].(*ast.Ident); ok {
 			if lhs.Name != rhs.Name {
 				return false
 			}
 		}
 	}
 	return true
 }

 // checkShadowDecl checks for shadowing in a general variable declaration.
 func checkShadowDecl(pass *analysis.Pass, spans map[types.Object]span, d *ast.GenDecl) {
 	if d.Tok != token.VAR {
 		return
 	}
 	for _, spec := range d.Specs {
 		valueSpec, ok := spec.(*ast.ValueSpec)
 		if !ok {
 			pass.Reportf(spec.Pos(), "invalid AST: var GenDecl not ValueSpec")
 			return
 		}
 		// Don't complain about deliberate redeclarations of the form
 		//	var i = i
 		if idiomaticRedecl(valueSpec) {
 			return
 		}
 		for _, ident := range valueSpec.Names {
 			checkShadowing(pass, spans, ident)
 		}
 	}
 }

 // checkShadowing checks whether the identifier shadows an identifier in an outer scope.
 func checkShadowing(pass *analysis.Pass, spans map[types.Object]span, ident *ast.Ident) {
 	if ident.Name == "_" {
 		// Can't shadow the blank identifier.
 		return
 	}
 	obj := pass.TypesInfo.Defs[ident]
 	if obj == nil {
 		return
 	}
 	// obj.Parent.Parent is the surrounding scope. If we can find another declaration
 	// starting from there, we have a shadowed identifier.
 	_, shadowed := obj.Parent().Parent().LookupParent(obj.Name(), obj.Pos())
 	if shadowed == nil {
 		return
 	}
 	// Don't complain if it's shadowing a universe-declared identifier; that's fine.
 	if shadowed.Parent() == types.Universe {
 		return
 	}
 	if strict {
 		// The shadowed identifier must appear before this one to be an instance of shadowing.
 		if shadowed.Pos() > ident.Pos() {
 			return
 		}
 	} else {
 		// Don't complain if the span of validity of the shadowed identifier doesn't include
 		// the shadowing identifier.
 		span, ok := spans[shadowed]
 		if !ok {
 			pass.Reportf(ident.Pos(), "internal error: no range for %q", ident.Name)
 			return
 		}
 		if !span.contains(ident.Pos()) {
 			return
 		}
 	}
 	// Don't complain if the types differ: that implies the programmer really wants two different things.
 	if types.Identical(obj.Type(), shadowed.Type()) {
 		line := pass.Fset.Position(shadowed.Pos()).Line
 		pass.Reportf(ident.Pos(), "declaration of %q shadows declaration at line %d", obj.Name(), line)
 	}
 }
	// 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 shadow

	import (
	"go/ast"
	"go/token"
	"go/types"

	"golang.org/x/tools/go/analysis"
	"golang.org/x/tools/go/analysis/passes/inspect"
	"golang.org/x/tools/go/ast/inspector"
	)

	// NOTE: Experimental. Not part of the vet suite.

	const Doc = `check for possible unintended shadowing of variables

	This analyzer check for shadowed variables.
	A shadowed variable is a variable declared in an inner scope
	with the same name and type as a variable in an outer scope,
	and where the outer variable is mentioned after the inner one
	is declared.

	(This definition can be refined; the module generates too many
	false positives and is not yet enabled by default.)

	For example:

	func BadRead(f *os.File, buf []byte) error {
	var err error
	for {
	n, err := f.Read(buf) // shadows the function variable 'err'
	if err != nil {
	break // causes return of wrong value
	}
	foo(buf)
	}
	return err
	}
	`

	var Analyzer = &analysis.Analyzer{
	Name: "shadow",
	Doc: Doc,
	Requires: []*analysis.Analyzer{inspect.Analyzer},
	Run: run,
	}

	// flags
	var strict = false

	func init() {
	Analyzer.Flags.BoolVar(&strict, "strict", strict, "whether to be strict about shadowing; can be noisy")
	}

	func run(pass *analysis.Pass) (interface{}, error) {
	inspect := pass.ResultOf[inspect.Analyzer].(*inspector.Inspector)

	spans := make(map[types.Object]span)
	for id, obj := range pass.TypesInfo.Defs {
	// Ignore identifiers that don't denote objects
	// (package names, symbolic variables such as t
	// in t := x.(type) of type switch headers).
	if obj != nil {
	growSpan(spans, obj, id.Pos(), id.End())
	}
	}
	for id, obj := range pass.TypesInfo.Uses {
	growSpan(spans, obj, id.Pos(), id.End())
	}
	for node, obj := range pass.TypesInfo.Implicits {
	// A type switch with a short variable declaration
	// such as t := x.(type) doesn't declare the symbolic
	// variable (t in the example) at the switch header;
	// instead a new variable t (with specific type) is
	// declared implicitly for each case. Such variables
	// are found in the types.Info.Implicits (not Defs)
	// map. Add them here, assuming they are declared at
	// the type cases' colon ":".
	if cc, ok := node.(*ast.CaseClause); ok {
	growSpan(spans, obj, cc.Colon, cc.Colon)
	}
	}

	nodeFilter := []ast.Node{
	(*ast.AssignStmt)(nil),
	(*ast.GenDecl)(nil),
	}
	inspect.Preorder(nodeFilter, func(n ast.Node) {
	switch n := n.(type) {
	case *ast.AssignStmt:
	checkShadowAssignment(pass, spans, n)
	case *ast.GenDecl:
	checkShadowDecl(pass, spans, n)
	}
	})
	return nil, nil
	}

	// A span stores the minimum range of byte positions in the file in which a
	// given variable (types.Object) is mentioned. It is lexically defined: it spans
	// from the beginning of its first mention to the end of its last mention.
	// A variable is considered shadowed (if strict is off) only if the
	// shadowing variable is declared within the span of the shadowed variable.
	// In other words, if a variable is shadowed but not used after the shadowed
	// variable is declared, it is inconsequential and not worth complaining about.
	// This simple check dramatically reduces the nuisance rate for the shadowing
	// check, at least until something cleverer comes along.
	//
	// One wrinkle: A "naked return" is a silent use of a variable that the Span
	// will not capture, but the compilers catch naked returns of shadowed
	// variables so we don't need to.
	//
	// Cases this gets wrong (TODO):
	// - If a for loop's continuation statement mentions a variable redeclared in
	// the block, we should complain about it but don't.
	// - A variable declared inside a function literal can falsely be identified
	// as shadowing a variable in the outer function.
	//
	type span struct {
	min token.Pos
	max token.Pos
	}

	// contains reports whether the position is inside the span.
	func (s span) contains(pos token.Pos) bool {
	return s.min <= pos && pos < s.max
	}

	// growSpan expands the span for the object to contain the source range [pos, end).
	func growSpan(spans map[types.Object]span, obj types.Object, pos, end token.Pos) {
	if strict {
	return // No need
	}
	s, ok := spans[obj]
	if ok {
	if s.min > pos {
	s.min = pos
	}
	if s.max < end {
	s.max = end
	}
	} else {
	s = span{pos, end}
	}
	spans[obj] = s
	}

	// checkShadowAssignment checks for shadowing in a short variable declaration.
	func checkShadowAssignment(pass analysis.Pass, spans map[types.Object]span, a ast.AssignStmt) {
	if a.Tok != token.DEFINE {
	return
	}
	if idiomaticShortRedecl(pass, a) {
	return
	}
	for _, expr := range a.Lhs {
	ident, ok := expr.(*ast.Ident)
	if !ok {
	pass.Reportf(expr.Pos(), "invalid AST: short variable declaration of non-identifier")
	return
	}
	checkShadowing(pass, spans, ident)
	}
	}

	// idiomaticShortRedecl reports whether this short declaration can be ignored for
	// the purposes of shadowing, that is, that any redeclarations it contains are deliberate.
	func idiomaticShortRedecl(pass analysis.Pass, a ast.AssignStmt) bool {
	// Don't complain about deliberate redeclarations of the form
	// i := i
	// Such constructs are idiomatic in range loops to create a new variable
	// for each iteration. Another example is
	// switch n := n.(type)
	if len(a.Rhs) != len(a.Lhs) {
	return false
	}
	// We know it's an assignment, so the LHS must be all identifiers. (We check anyway.)
	for i, expr := range a.Lhs {
	lhs, ok := expr.(*ast.Ident)
	if !ok {
	pass.Reportf(expr.Pos(), "invalid AST: short variable declaration of non-identifier")
	return true // Don't do any more processing.
	}
	switch rhs := a.Rhs[i].(type) {
	case *ast.Ident:
	if lhs.Name != rhs.Name {
	return false
	}
	case *ast.TypeAssertExpr:
	if id, ok := rhs.X.(*ast.Ident); ok {
	if lhs.Name != id.Name {
	return false
	}
	}
	default:
	return false
	}
	}
	return true
	}

	// idiomaticRedecl reports whether this declaration spec can be ignored for
	// the purposes of shadowing, that is, that any redeclarations it contains are deliberate.
	func idiomaticRedecl(d *ast.ValueSpec) bool {
	// Don't complain about deliberate redeclarations of the form
	// var i, j = i, j
	if len(d.Names) != len(d.Values) {
	return false
	}
	for i, lhs := range d.Names {
	if rhs, ok := d.Values[i].(*ast.Ident); ok {
	if lhs.Name != rhs.Name {
	return false
	}
	}
	}
	return true
	}

	// checkShadowDecl checks for shadowing in a general variable declaration.
	func checkShadowDecl(pass analysis.Pass, spans map[types.Object]span, d ast.GenDecl) {
	if d.Tok != token.VAR {
	return
	}
	for _, spec := range d.Specs {
	valueSpec, ok := spec.(*ast.ValueSpec)
	if !ok {
	pass.Reportf(spec.Pos(), "invalid AST: var GenDecl not ValueSpec")
	return
	}
	// Don't complain about deliberate redeclarations of the form
	// var i = i
	if idiomaticRedecl(valueSpec) {
	return
	}
	for _, ident := range valueSpec.Names {
	checkShadowing(pass, spans, ident)
	}
	}
	}

	// checkShadowing checks whether the identifier shadows an identifier in an outer scope.
	func checkShadowing(pass analysis.Pass, spans map[types.Object]span, ident ast.Ident) {
	if ident.Name == "_" {
	// Can't shadow the blank identifier.
	return
	}
	obj := pass.TypesInfo.Defs[ident]
	if obj == nil {
	return
	}
	// obj.Parent.Parent is the surrounding scope. If we can find another declaration
	// starting from there, we have a shadowed identifier.
	_, shadowed := obj.Parent().Parent().LookupParent(obj.Name(), obj.Pos())
	if shadowed == nil {
	return
	}
	// Don't complain if it's shadowing a universe-declared identifier; that's fine.
	if shadowed.Parent() == types.Universe {
	return
	}
	if strict {
	// The shadowed identifier must appear before this one to be an instance of shadowing.
	if shadowed.Pos() > ident.Pos() {
	return
	}
	} else {
	// Don't complain if the span of validity of the shadowed identifier doesn't include
	// the shadowing identifier.
	span, ok := spans[shadowed]
	if !ok {
	pass.Reportf(ident.Pos(), "internal error: no range for %q", ident.Name)
	return
	}
	if !span.contains(ident.Pos()) {
	return
	}
	}
	// Don't complain if the types differ: that implies the programmer really wants two different things.
	if types.Identical(obj.Type(), shadowed.Type()) {
	line := pass.Fset.Position(shadowed.Pos()).Line
	pass.Reportf(ident.Pos(), "declaration of %q shadows declaration at line %d", obj.Name(), line)
	}
	}