libgo/go/go/parser/resolver.go - gcc - Git at Google

 // Copyright 2021 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 parser

 import (
 	"fmt"
 	"go/ast"
 	"go/internal/typeparams"
 	"go/token"
 )

 const debugResolve = false

 // resolveFile walks the given file to resolve identifiers within the file
 // scope, updating ast.Ident.Obj fields with declaration information.
 //
 // If declErr is non-nil, it is used to report declaration errors during
 // resolution. tok is used to format position in error messages.
 func resolveFile(file *ast.File, handle *token.File, declErr func(token.Pos, string)) {
 	pkgScope := ast.NewScope(nil)
 	r := &resolver{
 		handle:   handle,
 		declErr:  declErr,
 		topScope: pkgScope,
 		pkgScope: pkgScope,
 	}

 	for _, decl := range file.Decls {
 		ast.Walk(r, decl)
 	}

 	r.closeScope()
 	assert(r.topScope == nil, "unbalanced scopes")
 	assert(r.labelScope == nil, "unbalanced label scopes")

 	// resolve global identifiers within the same file
 	i := 0
 	for _, ident := range r.unresolved {
 		// i <= index for current ident
 		assert(ident.Obj == unresolved, "object already resolved")
 		ident.Obj = r.pkgScope.Lookup(ident.Name) // also removes unresolved sentinel
 		if ident.Obj == nil {
 			r.unresolved[i] = ident
 			i++
 		} else if debugResolve {
 			pos := ident.Obj.Decl.(interface{ Pos() token.Pos }).Pos()
 			r.dump("resolved %s@%v to package object %v", ident.Name, ident.Pos(), pos)
 		}
 	}
 	file.Scope = r.pkgScope
 	file.Unresolved = r.unresolved[0:i]
 }

 type resolver struct {
 	handle  *token.File
 	declErr func(token.Pos, string)

 	// Ordinary identifier scopes
 	pkgScope   *ast.Scope   // pkgScope.Outer == nil
 	topScope   *ast.Scope   // top-most scope; may be pkgScope
 	unresolved []*ast.Ident // unresolved identifiers

 	// Label scopes
 	// (maintained by open/close LabelScope)
 	labelScope  *ast.Scope     // label scope for current function
 	targetStack [][]*ast.Ident // stack of unresolved labels
 }

 func (r *resolver) dump(format string, args ...interface{}) {
 	fmt.Println(">>> " + r.sprintf(format, args...))
 }

 func (r *resolver) sprintf(format string, args ...interface{}) string {
 	for i, arg := range args {
 		switch arg := arg.(type) {
 		case token.Pos:
 			args[i] = r.handle.Position(arg)
 		}
 	}
 	return fmt.Sprintf(format, args...)
 }

 func (r *resolver) openScope(pos token.Pos) {
 	if debugResolve {
 		r.dump("opening scope @%v", pos)
 	}
 	r.topScope = ast.NewScope(r.topScope)
 }

 func (r *resolver) closeScope() {
 	if debugResolve {
 		r.dump("closing scope")
 	}
 	r.topScope = r.topScope.Outer
 }

 func (r *resolver) openLabelScope() {
 	r.labelScope = ast.NewScope(r.labelScope)
 	r.targetStack = append(r.targetStack, nil)
 }

 func (r *resolver) closeLabelScope() {
 	// resolve labels
 	n := len(r.targetStack) - 1
 	scope := r.labelScope
 	for _, ident := range r.targetStack[n] {
 		ident.Obj = scope.Lookup(ident.Name)
 		if ident.Obj == nil && r.declErr != nil {
 			r.declErr(ident.Pos(), fmt.Sprintf("label %s undefined", ident.Name))
 		}
 	}
 	// pop label scope
 	r.targetStack = r.targetStack[0:n]
 	r.labelScope = r.labelScope.Outer
 }

 func (r *resolver) declare(decl, data interface{}, scope *ast.Scope, kind ast.ObjKind, idents ...*ast.Ident) {
 	for _, ident := range idents {
 		// "type" is used for type lists in interfaces, and is otherwise an invalid
 		// identifier. The 'type' identifier is also artificially duplicated in the
 		// type list, so could cause panics below if we were to proceed.
 		if ident.Name == "type" {
 			continue
 		}
 		assert(ident.Obj == nil, "identifier already declared or resolved")
 		obj := ast.NewObj(kind, ident.Name)
 		// remember the corresponding declaration for redeclaration
 		// errors and global variable resolution/typechecking phase
 		obj.Decl = decl
 		obj.Data = data
 		ident.Obj = obj
 		if ident.Name != "_" {
 			if debugResolve {
 				r.dump("declaring %s@%v", ident.Name, ident.Pos())
 			}
 			if alt := scope.Insert(obj); alt != nil && r.declErr != nil {
 				prevDecl := ""
 				if pos := alt.Pos(); pos.IsValid() {
 					prevDecl = fmt.Sprintf("\n\tprevious declaration at %s", r.handle.Position(pos))
 				}
 				r.declErr(ident.Pos(), fmt.Sprintf("%s redeclared in this block%s", ident.Name, prevDecl))
 			}
 		}
 	}
 }

 func (r *resolver) shortVarDecl(decl *ast.AssignStmt) {
 	// Go spec: A short variable declaration may redeclare variables
 	// provided they were originally declared in the same block with
 	// the same type, and at least one of the non-blank variables is new.
 	n := 0 // number of new variables
 	for _, x := range decl.Lhs {
 		if ident, isIdent := x.(*ast.Ident); isIdent {
 			assert(ident.Obj == nil, "identifier already declared or resolved")
 			obj := ast.NewObj(ast.Var, ident.Name)
 			// remember corresponding assignment for other tools
 			obj.Decl = decl
 			ident.Obj = obj
 			if ident.Name != "_" {
 				if debugResolve {
 					r.dump("declaring %s@%v", ident.Name, ident.Pos())
 				}
 				if alt := r.topScope.Insert(obj); alt != nil {
 					ident.Obj = alt // redeclaration
 				} else {
 					n++ // new declaration
 				}
 			}
 		}
 	}
 	if n == 0 && r.declErr != nil {
 		r.declErr(decl.Lhs[0].Pos(), "no new variables on left side of :=")
 	}
 }

 // The unresolved object is a sentinel to mark identifiers that have been added
 // to the list of unresolved identifiers. The sentinel is only used for verifying
 // internal consistency.
 var unresolved = new(ast.Object)

 // If x is an identifier, resolve attempts to resolve x by looking up
 // the object it denotes. If no object is found and collectUnresolved is
 // set, x is marked as unresolved and collected in the list of unresolved
 // identifiers.
 //
 func (r *resolver) resolve(ident *ast.Ident, collectUnresolved bool) {
 	if ident.Obj != nil {
 		panic(fmt.Sprintf("%s: identifier %s already declared or resolved", r.handle.Position(ident.Pos()), ident.Name))
 	}
 	// '_' and 'type' should never refer to existing declarations: '_' because it
 	// has special handling in the spec, and 'type' because it is a keyword, and
 	// only valid in an interface type list.
 	if ident.Name == "_" || ident.Name == "type" {
 		return
 	}
 	for s := r.topScope; s != nil; s = s.Outer {
 		if obj := s.Lookup(ident.Name); obj != nil {
 			assert(obj.Name != "", "obj with no name")
 			ident.Obj = obj
 			return
 		}
 	}
 	// all local scopes are known, so any unresolved identifier
 	// must be found either in the file scope, package scope
 	// (perhaps in another file), or universe scope --- collect
 	// them so that they can be resolved later
 	if collectUnresolved {
 		ident.Obj = unresolved
 		r.unresolved = append(r.unresolved, ident)
 	}
 }

 func (r *resolver) walkExprs(list []ast.Expr) {
 	for _, node := range list {
 		ast.Walk(r, node)
 	}
 }

 func (r *resolver) walkLHS(list []ast.Expr) {
 	for _, expr := range list {
 		expr := unparen(expr)
 		if _, ok := expr.(*ast.Ident); !ok && expr != nil {
 			ast.Walk(r, expr)
 		}
 	}
 }

 func (r *resolver) walkStmts(list []ast.Stmt) {
 	for _, stmt := range list {
 		ast.Walk(r, stmt)
 	}
 }

 func (r *resolver) Visit(node ast.Node) ast.Visitor {
 	if debugResolve && node != nil {
 		r.dump("node %T@%v", node, node.Pos())
 	}

 	switch n := node.(type) {

 	// Expressions.
 	case *ast.Ident:
 		r.resolve(n, true)

 	case *ast.FuncLit:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkFuncType(n.Type)
 		r.walkBody(n.Body)

 	case *ast.SelectorExpr:
 		ast.Walk(r, n.X)
 		// Note: don't try to resolve n.Sel, as we don't support qualified
 		// resolution.

 	case *ast.StructType:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkFieldList(n.Fields, ast.Var)

 	case *ast.FuncType:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkFuncType(n)

 	case *ast.CompositeLit:
 		if n.Type != nil {
 			ast.Walk(r, n.Type)
 		}
 		for _, e := range n.Elts {
 			if kv, _ := e.(*ast.KeyValueExpr); kv != nil {
 				// See issue #45160: try to resolve composite lit keys, but don't
 				// collect them as unresolved if resolution failed. This replicates
 				// existing behavior when resolving during parsing.
 				if ident, _ := kv.Key.(*ast.Ident); ident != nil {
 					r.resolve(ident, false)
 				} else {
 					ast.Walk(r, kv.Key)
 				}
 				ast.Walk(r, kv.Value)
 			} else {
 				ast.Walk(r, e)
 			}
 		}

 	case *ast.InterfaceType:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkFieldList(n.Methods, ast.Fun)

 	// Statements
 	case *ast.LabeledStmt:
 		r.declare(n, nil, r.labelScope, ast.Lbl, n.Label)
 		ast.Walk(r, n.Stmt)

 	case *ast.AssignStmt:
 		r.walkExprs(n.Rhs)
 		if n.Tok == token.DEFINE {
 			r.shortVarDecl(n)
 		} else {
 			r.walkExprs(n.Lhs)
 		}

 	case *ast.BranchStmt:
 		// add to list of unresolved targets
 		if n.Tok != token.FALLTHROUGH && n.Label != nil {
 			depth := len(r.targetStack) - 1
 			r.targetStack[depth] = append(r.targetStack[depth], n.Label)
 		}

 	case *ast.BlockStmt:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkStmts(n.List)

 	case *ast.IfStmt:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		if n.Init != nil {
 			ast.Walk(r, n.Init)
 		}
 		ast.Walk(r, n.Cond)
 		ast.Walk(r, n.Body)
 		if n.Else != nil {
 			ast.Walk(r, n.Else)
 		}

 	case *ast.CaseClause:
 		r.walkExprs(n.List)
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		r.walkStmts(n.Body)

 	case *ast.SwitchStmt:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		if n.Init != nil {
 			ast.Walk(r, n.Init)
 		}
 		if n.Tag != nil {
 			// The scope below reproduces some unnecessary behavior of the parser,
 			// opening an extra scope in case this is a type switch. It's not needed
 			// for expression switches.
 			// TODO: remove this once we've matched the parser resolution exactly.
 			if n.Init != nil {
 				r.openScope(n.Tag.Pos())
 				defer r.closeScope()
 			}
 			ast.Walk(r, n.Tag)
 		}
 		if n.Body != nil {
 			r.walkStmts(n.Body.List)
 		}

 	case *ast.TypeSwitchStmt:
 		if n.Init != nil {
 			r.openScope(n.Pos())
 			defer r.closeScope()
 			ast.Walk(r, n.Init)
 		}
 		r.openScope(n.Assign.Pos())
 		defer r.closeScope()
 		ast.Walk(r, n.Assign)
 		// s.Body consists only of case clauses, so does not get its own
 		// scope.
 		if n.Body != nil {
 			r.walkStmts(n.Body.List)
 		}

 	case *ast.CommClause:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		if n.Comm != nil {
 			ast.Walk(r, n.Comm)
 		}
 		r.walkStmts(n.Body)

 	case *ast.SelectStmt:
 		// as for switch statements, select statement bodies don't get their own
 		// scope.
 		if n.Body != nil {
 			r.walkStmts(n.Body.List)
 		}

 	case *ast.ForStmt:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		if n.Init != nil {
 			ast.Walk(r, n.Init)
 		}
 		if n.Cond != nil {
 			ast.Walk(r, n.Cond)
 		}
 		if n.Post != nil {
 			ast.Walk(r, n.Post)
 		}
 		ast.Walk(r, n.Body)

 	case *ast.RangeStmt:
 		r.openScope(n.Pos())
 		defer r.closeScope()
 		ast.Walk(r, n.X)
 		var lhs []ast.Expr
 		if n.Key != nil {
 			lhs = append(lhs, n.Key)
 		}
 		if n.Value != nil {
 			lhs = append(lhs, n.Value)
 		}
 		if len(lhs) > 0 {
 			if n.Tok == token.DEFINE {
 				// Note: we can't exactly match the behavior of object resolution
 				// during the parsing pass here, as it uses the position of the RANGE
 				// token for the RHS OpPos. That information is not contained within
 				// the AST.
 				as := &ast.AssignStmt{
 					Lhs:    lhs,
 					Tok:    token.DEFINE,
 					TokPos: n.TokPos,
 					Rhs:    []ast.Expr{&ast.UnaryExpr{Op: token.RANGE, X: n.X}},
 				}
 				// TODO(rFindley): this walkLHS reproduced the parser resolution, but
 				// is it necessary? By comparison, for a normal AssignStmt we don't
 				// walk the LHS in case there is an invalid identifier list.
 				r.walkLHS(lhs)
 				r.shortVarDecl(as)
 			} else {
 				r.walkExprs(lhs)
 			}
 		}
 		ast.Walk(r, n.Body)

 	// Declarations
 	case *ast.GenDecl:
 		switch n.Tok {
 		case token.CONST, token.VAR:
 			for i, spec := range n.Specs {
 				spec := spec.(*ast.ValueSpec)
 				kind := ast.Con
 				if n.Tok == token.VAR {
 					kind = ast.Var
 				}
 				r.walkExprs(spec.Values)
 				if spec.Type != nil {
 					ast.Walk(r, spec.Type)
 				}
 				r.declare(spec, i, r.topScope, kind, spec.Names...)
 			}
 		case token.TYPE:
 			for _, spec := range n.Specs {
 				spec := spec.(*ast.TypeSpec)
 				// Go spec: The scope of a type identifier declared inside a function begins
 				// at the identifier in the TypeSpec and ends at the end of the innermost
 				// containing block.
 				r.declare(spec, nil, r.topScope, ast.Typ, spec.Name)
 				if tparams := typeparams.Get(spec); tparams != nil {
 					r.openScope(spec.Pos())
 					defer r.closeScope()
 					r.walkTParams(tparams)
 				}
 				ast.Walk(r, spec.Type)
 			}
 		}

 	case *ast.FuncDecl:
 		// Open the function scope.
 		r.openScope(n.Pos())
 		defer r.closeScope()

 		// Resolve the receiver first, without declaring.
 		r.resolveList(n.Recv)

 		// Type parameters are walked normally: they can reference each other, and
 		// can be referenced by normal parameters.
 		if tparams := typeparams.Get(n.Type); tparams != nil {
 			r.walkTParams(tparams)
 			// TODO(rFindley): need to address receiver type parameters.
 		}

 		// Resolve and declare parameters in a specific order to get duplicate
 		// declaration errors in the correct location.
 		r.resolveList(n.Type.Params)
 		r.resolveList(n.Type.Results)
 		r.declareList(n.Recv, ast.Var)
 		r.declareList(n.Type.Params, ast.Var)
 		r.declareList(n.Type.Results, ast.Var)

 		r.walkBody(n.Body)
 		if n.Recv == nil && n.Name.Name != "init" {
 			r.declare(n, nil, r.pkgScope, ast.Fun, n.Name)
 		}

 	default:
 		return r
 	}

 	return nil
 }

 func (r *resolver) walkFuncType(typ *ast.FuncType) {
 	// typ.TParams must be walked separately for FuncDecls.
 	r.resolveList(typ.Params)
 	r.resolveList(typ.Results)
 	r.declareList(typ.Params, ast.Var)
 	r.declareList(typ.Results, ast.Var)
 }

 func (r *resolver) resolveList(list *ast.FieldList) {
 	if list == nil {
 		return
 	}
 	for _, f := range list.List {
 		if f.Type != nil {
 			ast.Walk(r, f.Type)
 		}
 	}
 }

 func (r *resolver) declareList(list *ast.FieldList, kind ast.ObjKind) {
 	if list == nil {
 		return
 	}
 	for _, f := range list.List {
 		r.declare(f, nil, r.topScope, kind, f.Names...)
 	}
 }

 func (r *resolver) walkFieldList(list *ast.FieldList, kind ast.ObjKind) {
 	if list == nil {
 		return
 	}
 	r.resolveList(list)
 	r.declareList(list, kind)
 }

 // walkTParams is like walkFieldList, but declares type parameters eagerly so
 // that they may be resolved in the constraint expressions held in the field
 // Type.
 func (r *resolver) walkTParams(list *ast.FieldList) {
 	if list == nil {
 		return
 	}
 	r.declareList(list, ast.Typ)
 	r.resolveList(list)
 }

 func (r *resolver) walkBody(body *ast.BlockStmt) {
 	if body == nil {
 		return
 	}
 	r.openLabelScope()
 	defer r.closeLabelScope()
 	r.walkStmts(body.List)
 }
	// Copyright 2021 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 parser

	import (
	"fmt"
	"go/ast"
	"go/internal/typeparams"
	"go/token"
	)

	const debugResolve = false

	// resolveFile walks the given file to resolve identifiers within the file
	// scope, updating ast.Ident.Obj fields with declaration information.
	//
	// If declErr is non-nil, it is used to report declaration errors during
	// resolution. tok is used to format position in error messages.
	func resolveFile(file ast.File, handle token.File, declErr func(token.Pos, string)) {
	pkgScope := ast.NewScope(nil)
	r := &resolver{
	handle: handle,
	declErr: declErr,
	topScope: pkgScope,
	pkgScope: pkgScope,
	}

	for _, decl := range file.Decls {
	ast.Walk(r, decl)
	}

	r.closeScope()
	assert(r.topScope == nil, "unbalanced scopes")
	assert(r.labelScope == nil, "unbalanced label scopes")

	// resolve global identifiers within the same file
	i := 0
	for _, ident := range r.unresolved {
	// i <= index for current ident
	assert(ident.Obj == unresolved, "object already resolved")
	ident.Obj = r.pkgScope.Lookup(ident.Name) // also removes unresolved sentinel
	if ident.Obj == nil {
	r.unresolved[i] = ident
	i++
	} else if debugResolve {
	pos := ident.Obj.Decl.(interface{ Pos() token.Pos }).Pos()
	r.dump("resolved %s@%v to package object %v", ident.Name, ident.Pos(), pos)
	}
	}
	file.Scope = r.pkgScope
	file.Unresolved = r.unresolved[0:i]
	}

	type resolver struct {
	handle *token.File
	declErr func(token.Pos, string)

	// Ordinary identifier scopes
	pkgScope *ast.Scope // pkgScope.Outer == nil
	topScope *ast.Scope // top-most scope; may be pkgScope
	unresolved []*ast.Ident // unresolved identifiers

	// Label scopes
	// (maintained by open/close LabelScope)
	labelScope *ast.Scope // label scope for current function
	targetStack [][]*ast.Ident // stack of unresolved labels
	}

	func (r *resolver) dump(format string, args ...interface{}) {
	fmt.Println(">>> " + r.sprintf(format, args...))
	}

	func (r *resolver) sprintf(format string, args ...interface{}) string {
	for i, arg := range args {
	switch arg := arg.(type) {
	case token.Pos:
	args[i] = r.handle.Position(arg)
	}
	}
	return fmt.Sprintf(format, args...)
	}

	func (r *resolver) openScope(pos token.Pos) {
	if debugResolve {
	r.dump("opening scope @%v", pos)
	}
	r.topScope = ast.NewScope(r.topScope)
	}

	func (r *resolver) closeScope() {
	if debugResolve {
	r.dump("closing scope")
	}
	r.topScope = r.topScope.Outer
	}

	func (r *resolver) openLabelScope() {
	r.labelScope = ast.NewScope(r.labelScope)
	r.targetStack = append(r.targetStack, nil)
	}

	func (r *resolver) closeLabelScope() {
	// resolve labels
	n := len(r.targetStack) - 1
	scope := r.labelScope
	for _, ident := range r.targetStack[n] {
	ident.Obj = scope.Lookup(ident.Name)
	if ident.Obj == nil && r.declErr != nil {
	r.declErr(ident.Pos(), fmt.Sprintf("label %s undefined", ident.Name))
	}
	}
	// pop label scope
	r.targetStack = r.targetStack[0:n]
	r.labelScope = r.labelScope.Outer
	}

	func (r resolver) declare(decl, data interface{}, scope ast.Scope, kind ast.ObjKind, idents ...*ast.Ident) {
	for _, ident := range idents {
	// "type" is used for type lists in interfaces, and is otherwise an invalid
	// identifier. The 'type' identifier is also artificially duplicated in the
	// type list, so could cause panics below if we were to proceed.
	if ident.Name == "type" {
	continue
	}
	assert(ident.Obj == nil, "identifier already declared or resolved")
	obj := ast.NewObj(kind, ident.Name)
	// remember the corresponding declaration for redeclaration
	// errors and global variable resolution/typechecking phase
	obj.Decl = decl
	obj.Data = data
	ident.Obj = obj
	if ident.Name != "_" {
	if debugResolve {
	r.dump("declaring %s@%v", ident.Name, ident.Pos())
	}
	if alt := scope.Insert(obj); alt != nil && r.declErr != nil {
	prevDecl := ""
	if pos := alt.Pos(); pos.IsValid() {
	prevDecl = fmt.Sprintf("\n\tprevious declaration at %s", r.handle.Position(pos))
	}
	r.declErr(ident.Pos(), fmt.Sprintf("%s redeclared in this block%s", ident.Name, prevDecl))
	}
	}
	}
	}

	func (r resolver) shortVarDecl(decl ast.AssignStmt) {
	// Go spec: A short variable declaration may redeclare variables
	// provided they were originally declared in the same block with
	// the same type, and at least one of the non-blank variables is new.
	n := 0 // number of new variables
	for _, x := range decl.Lhs {
	if ident, isIdent := x.(*ast.Ident); isIdent {
	assert(ident.Obj == nil, "identifier already declared or resolved")
	obj := ast.NewObj(ast.Var, ident.Name)
	// remember corresponding assignment for other tools
	obj.Decl = decl
	ident.Obj = obj
	if ident.Name != "_" {
	if debugResolve {
	r.dump("declaring %s@%v", ident.Name, ident.Pos())
	}
	if alt := r.topScope.Insert(obj); alt != nil {
	ident.Obj = alt // redeclaration
	} else {
	n++ // new declaration
	}
	}
	}
	}
	if n == 0 && r.declErr != nil {
	r.declErr(decl.Lhs[0].Pos(), "no new variables on left side of :=")
	}
	}

	// The unresolved object is a sentinel to mark identifiers that have been added
	// to the list of unresolved identifiers. The sentinel is only used for verifying
	// internal consistency.
	var unresolved = new(ast.Object)

	// If x is an identifier, resolve attempts to resolve x by looking up
	// the object it denotes. If no object is found and collectUnresolved is
	// set, x is marked as unresolved and collected in the list of unresolved
	// identifiers.
	//
	func (r resolver) resolve(ident ast.Ident, collectUnresolved bool) {
	if ident.Obj != nil {
	panic(fmt.Sprintf("%s: identifier %s already declared or resolved", r.handle.Position(ident.Pos()), ident.Name))
	}
	// '_' and 'type' should never refer to existing declarations: '_' because it
	// has special handling in the spec, and 'type' because it is a keyword, and
	// only valid in an interface type list.
	if ident.Name == "_" \|\| ident.Name == "type" {
	return
	}
	for s := r.topScope; s != nil; s = s.Outer {
	if obj := s.Lookup(ident.Name); obj != nil {
	assert(obj.Name != "", "obj with no name")
	ident.Obj = obj
	return
	}
	}
	// all local scopes are known, so any unresolved identifier
	// must be found either in the file scope, package scope
	// (perhaps in another file), or universe scope --- collect
	// them so that they can be resolved later
	if collectUnresolved {
	ident.Obj = unresolved
	r.unresolved = append(r.unresolved, ident)
	}
	}

	func (r *resolver) walkExprs(list []ast.Expr) {
	for _, node := range list {
	ast.Walk(r, node)
	}
	}

	func (r *resolver) walkLHS(list []ast.Expr) {
	for _, expr := range list {
	expr := unparen(expr)
	if _, ok := expr.(*ast.Ident); !ok && expr != nil {
	ast.Walk(r, expr)
	}
	}
	}

	func (r *resolver) walkStmts(list []ast.Stmt) {
	for _, stmt := range list {
	ast.Walk(r, stmt)
	}
	}

	func (r *resolver) Visit(node ast.Node) ast.Visitor {
	if debugResolve && node != nil {
	r.dump("node %T@%v", node, node.Pos())
	}

	switch n := node.(type) {

	// Expressions.
	case *ast.Ident:
	r.resolve(n, true)

	case *ast.FuncLit:
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkFuncType(n.Type)
	r.walkBody(n.Body)

	case *ast.SelectorExpr:
	ast.Walk(r, n.X)
	// Note: don't try to resolve n.Sel, as we don't support qualified
	// resolution.

	case *ast.StructType:
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkFieldList(n.Fields, ast.Var)

	case *ast.FuncType:
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkFuncType(n)

	case *ast.CompositeLit:
	if n.Type != nil {
	ast.Walk(r, n.Type)
	}
	for _, e := range n.Elts {
	if kv, _ := e.(*ast.KeyValueExpr); kv != nil {
	// See issue #45160: try to resolve composite lit keys, but don't
	// collect them as unresolved if resolution failed. This replicates
	// existing behavior when resolving during parsing.
	if ident, _ := kv.Key.(*ast.Ident); ident != nil {
	r.resolve(ident, false)
	} else {
	ast.Walk(r, kv.Key)
	}
	ast.Walk(r, kv.Value)
	} else {
	ast.Walk(r, e)
	}
	}

	case *ast.InterfaceType:
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkFieldList(n.Methods, ast.Fun)

	// Statements
	case *ast.LabeledStmt:
	r.declare(n, nil, r.labelScope, ast.Lbl, n.Label)
	ast.Walk(r, n.Stmt)

	case *ast.AssignStmt:
	r.walkExprs(n.Rhs)
	if n.Tok == token.DEFINE {
	r.shortVarDecl(n)
	} else {
	r.walkExprs(n.Lhs)
	}

	case *ast.BranchStmt:
	// add to list of unresolved targets
	if n.Tok != token.FALLTHROUGH && n.Label != nil {
	depth := len(r.targetStack) - 1
	r.targetStack[depth] = append(r.targetStack[depth], n.Label)
	}

	case *ast.BlockStmt:
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkStmts(n.List)

	case *ast.IfStmt:
	r.openScope(n.Pos())
	defer r.closeScope()
	if n.Init != nil {
	ast.Walk(r, n.Init)
	}
	ast.Walk(r, n.Cond)
	ast.Walk(r, n.Body)
	if n.Else != nil {
	ast.Walk(r, n.Else)
	}

	case *ast.CaseClause:
	r.walkExprs(n.List)
	r.openScope(n.Pos())
	defer r.closeScope()
	r.walkStmts(n.Body)

	case *ast.SwitchStmt:
	r.openScope(n.Pos())
	defer r.closeScope()
	if n.Init != nil {
	ast.Walk(r, n.Init)
	}
	if n.Tag != nil {
	// The scope below reproduces some unnecessary behavior of the parser,
	// opening an extra scope in case this is a type switch. It's not needed
	// for expression switches.
	// TODO: remove this once we've matched the parser resolution exactly.
	if n.Init != nil {
	r.openScope(n.Tag.Pos())
	defer r.closeScope()
	}
	ast.Walk(r, n.Tag)
	}
	if n.Body != nil {
	r.walkStmts(n.Body.List)
	}

	case *ast.TypeSwitchStmt:
	if n.Init != nil {
	r.openScope(n.Pos())
	defer r.closeScope()
	ast.Walk(r, n.Init)
	}
	r.openScope(n.Assign.Pos())
	defer r.closeScope()
	ast.Walk(r, n.Assign)
	// s.Body consists only of case clauses, so does not get its own
	// scope.
	if n.Body != nil {
	r.walkStmts(n.Body.List)
	}

	case *ast.CommClause:
	r.openScope(n.Pos())
	defer r.closeScope()
	if n.Comm != nil {
	ast.Walk(r, n.Comm)
	}
	r.walkStmts(n.Body)

	case *ast.SelectStmt:
	// as for switch statements, select statement bodies don't get their own
	// scope.
	if n.Body != nil {
	r.walkStmts(n.Body.List)
	}

	case *ast.ForStmt:
	r.openScope(n.Pos())
	defer r.closeScope()
	if n.Init != nil {
	ast.Walk(r, n.Init)
	}
	if n.Cond != nil {
	ast.Walk(r, n.Cond)
	}
	if n.Post != nil {
	ast.Walk(r, n.Post)
	}
	ast.Walk(r, n.Body)

	case *ast.RangeStmt:
	r.openScope(n.Pos())
	defer r.closeScope()
	ast.Walk(r, n.X)
	var lhs []ast.Expr
	if n.Key != nil {
	lhs = append(lhs, n.Key)
	}
	if n.Value != nil {
	lhs = append(lhs, n.Value)
	}
	if len(lhs) > 0 {
	if n.Tok == token.DEFINE {
	// Note: we can't exactly match the behavior of object resolution
	// during the parsing pass here, as it uses the position of the RANGE
	// token for the RHS OpPos. That information is not contained within
	// the AST.
	as := &ast.AssignStmt{
	Lhs: lhs,
	Tok: token.DEFINE,
	TokPos: n.TokPos,
	Rhs: []ast.Expr{&ast.UnaryExpr{Op: token.RANGE, X: n.X}},
	}
	// TODO(rFindley): this walkLHS reproduced the parser resolution, but
	// is it necessary? By comparison, for a normal AssignStmt we don't
	// walk the LHS in case there is an invalid identifier list.
	r.walkLHS(lhs)
	r.shortVarDecl(as)
	} else {
	r.walkExprs(lhs)
	}
	}
	ast.Walk(r, n.Body)

	// Declarations
	case *ast.GenDecl:
	switch n.Tok {
	case token.CONST, token.VAR:
	for i, spec := range n.Specs {
	spec := spec.(*ast.ValueSpec)
	kind := ast.Con
	if n.Tok == token.VAR {
	kind = ast.Var
	}
	r.walkExprs(spec.Values)
	if spec.Type != nil {
	ast.Walk(r, spec.Type)
	}
	r.declare(spec, i, r.topScope, kind, spec.Names...)
	}
	case token.TYPE:
	for _, spec := range n.Specs {
	spec := spec.(*ast.TypeSpec)
	// Go spec: The scope of a type identifier declared inside a function begins
	// at the identifier in the TypeSpec and ends at the end of the innermost
	// containing block.
	r.declare(spec, nil, r.topScope, ast.Typ, spec.Name)
	if tparams := typeparams.Get(spec); tparams != nil {
	r.openScope(spec.Pos())
	defer r.closeScope()
	r.walkTParams(tparams)
	}
	ast.Walk(r, spec.Type)
	}
	}

	case *ast.FuncDecl:
	// Open the function scope.
	r.openScope(n.Pos())
	defer r.closeScope()

	// Resolve the receiver first, without declaring.
	r.resolveList(n.Recv)

	// Type parameters are walked normally: they can reference each other, and
	// can be referenced by normal parameters.
	if tparams := typeparams.Get(n.Type); tparams != nil {
	r.walkTParams(tparams)
	// TODO(rFindley): need to address receiver type parameters.
	}

	// Resolve and declare parameters in a specific order to get duplicate
	// declaration errors in the correct location.
	r.resolveList(n.Type.Params)
	r.resolveList(n.Type.Results)
	r.declareList(n.Recv, ast.Var)
	r.declareList(n.Type.Params, ast.Var)
	r.declareList(n.Type.Results, ast.Var)

	r.walkBody(n.Body)
	if n.Recv == nil && n.Name.Name != "init" {
	r.declare(n, nil, r.pkgScope, ast.Fun, n.Name)
	}

	default:
	return r
	}

	return nil
	}

	func (r resolver) walkFuncType(typ ast.FuncType) {
	// typ.TParams must be walked separately for FuncDecls.
	r.resolveList(typ.Params)
	r.resolveList(typ.Results)
	r.declareList(typ.Params, ast.Var)
	r.declareList(typ.Results, ast.Var)
	}

	func (r resolver) resolveList(list ast.FieldList) {
	if list == nil {
	return
	}
	for _, f := range list.List {
	if f.Type != nil {
	ast.Walk(r, f.Type)
	}
	}
	}

	func (r resolver) declareList(list ast.FieldList, kind ast.ObjKind) {
	if list == nil {
	return
	}
	for _, f := range list.List {
	r.declare(f, nil, r.topScope, kind, f.Names...)
	}
	}

	func (r resolver) walkFieldList(list ast.FieldList, kind ast.ObjKind) {
	if list == nil {
	return
	}
	r.resolveList(list)
	r.declareList(list, kind)
	}

	// walkTParams is like walkFieldList, but declares type parameters eagerly so
	// that they may be resolved in the constraint expressions held in the field
	// Type.
	func (r resolver) walkTParams(list ast.FieldList) {
	if list == nil {
	return
	}
	r.declareList(list, ast.Typ)
	r.resolveList(list)
	}

	func (r resolver) walkBody(body ast.BlockStmt) {
	if body == nil {
	return
	}
	r.openLabelScope()
	defer r.closeLabelScope()
	r.walkStmts(body.List)
	}