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go/parser: switch to resolving objects as a post-processing pass

Coupling object resolution to parsing complicates the parsing code, and
is a barrier to improvement. It requires passing around context such as
'lhs' or 'keyOk', and even then sometimes requires guess-work, such as
whether to resolve the key in a composite literal.

In this CL we delay object resolution to a separate pass after the file
parse completes. This makes it easier to see logic of scoping, and
removes state from the parsing code. This can enable subsequent
improvements such as optionally skipping object resolution, aligning the
parser with cmd/compile/internal/syntax, and allowing alternative
parsers to reuse object resolution.

The additional AST traversal appears to slow down parsing by around 4%.
That seems small enough not to worry about, especially since performance
sensitive users may eventually be able to disable object resolution
entirely, saving around 18% off the previous baseline. I'll also mail a
speculative CL showing how we can significantly mitigate the cost of
object resolution by transposing scopes.

For #45104

Change-Id: I98d9143fd77ae29e84ec7c3ae2fdb1139510da37
Reviewed-on: https://go-review.googlesource.com/c/go/+/304455
Trust: Robert Findley <rfindley@google.com>
Trust: Robert Griesemer <gri@golang.org>
Run-TryBot: Robert Findley <rfindley@google.com>
TryBot-Result: Go Bot <gobot@golang.org>
Reviewed-by: Robert Griesemer <gri@golang.org>
This commit is contained in:
Rob Findley 2021-03-24 09:36:04 -04:00 committed by Robert Findley
parent 44dd06670f
commit 4acefa07b1
3 changed files with 595 additions and 395 deletions

View File

@ -215,15 +215,7 @@ func ParseExprFrom(fset *token.FileSet, filename string, src interface{}, mode M
// parse expr
p.init(fset, filename, text, mode)
// Set up pkg-level scopes to avoid nil-pointer errors.
// This is not needed for a correct expression x as the
// parser will be ok with a nil topScope, but be cautious
// in case of an erroneous x.
p.openScope()
p.pkgScope = p.topScope
expr = p.parseRhsOrType()
p.closeScope()
assert(p.topScope == nil, "unbalanced scopes")
// If a semicolon was inserted, consume it;
// report an error if there's more tokens.

File diff suppressed because it is too large Load Diff

505
src/go/parser/resolver.go Normal file
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@ -0,0 +1,505 @@
// 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/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)) {
topScope := ast.NewScope(nil)
r := &resolver{
handle: handle,
declErr: declErr,
topScope: topScope,
pkgScope: topScope,
}
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:
functionScope := ast.NewScope(r.topScope)
r.walkFuncType(functionScope, n.Type)
r.walkBody(functionScope, 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:
scope := ast.NewScope(nil)
r.walkFieldList(scope, n.Fields, ast.Var)
case *ast.FuncType:
scope := ast.NewScope(r.topScope)
r.walkFuncType(scope, 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:
scope := ast.NewScope(nil)
r.walkFieldList(scope, 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 spec.TParams != nil {
r.openScope(spec.Pos())
defer r.closeScope()
r.walkFieldList(r.topScope, spec.TParams, ast.Typ)
}
ast.Walk(r, spec.Type)
}
}
case *ast.FuncDecl:
scope := ast.NewScope(r.topScope)
r.walkFieldList(scope, n.Recv, ast.Var)
r.walkFuncType(scope, n.Type)
r.walkBody(scope, 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(scope *ast.Scope, typ *ast.FuncType) {
r.walkFieldList(scope, typ.TParams, ast.Typ)
r.walkFieldList(scope, typ.Params, ast.Var)
r.walkFieldList(scope, typ.Results, ast.Var)
}
func (r *resolver) walkFieldList(scope *ast.Scope, list *ast.FieldList, kind ast.ObjKind) {
if list == nil {
return
}
for _, f := range list.List {
if f.Type != nil {
ast.Walk(r, f.Type)
}
r.declare(f, nil, scope, kind, f.Names...)
}
}
func (r *resolver) walkBody(scope *ast.Scope, body *ast.BlockStmt) {
if body == nil {
return
}
r.topScope = scope // open function scope
defer r.closeScope()
r.openLabelScope()
defer r.closeLabelScope()
r.walkStmts(body.List)
}