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|
// UNREVIEWED
// 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 noder
import (
"fmt"
"cmd/compile/internal/base"
"cmd/compile/internal/ir"
"cmd/compile/internal/syntax"
"cmd/compile/internal/types2"
"cmd/internal/src"
)
// This file defines helper functions useful for satisfying toolstash
// -cmp when compared against the legacy frontend behavior, but can be
// removed after that's no longer a concern.
// quirksMode controls whether behavior specific to satisfying
// toolstash -cmp is used.
func quirksMode() bool {
return base.Debug.UnifiedQuirks != 0
}
// posBasesOf returns all of the position bases in the source files,
// as seen in a straightforward traversal.
//
// This is necessary to ensure position bases (and thus file names)
// get registered in the same order as noder would visit them.
func posBasesOf(noders []*noder) []*syntax.PosBase {
seen := make(map[*syntax.PosBase]bool)
var bases []*syntax.PosBase
for _, p := range noders {
syntax.Crawl(p.file, func(n syntax.Node) bool {
if b := n.Pos().Base(); !seen[b] {
bases = append(bases, b)
seen[b] = true
}
return false
})
}
return bases
}
// importedObjsOf returns the imported objects (i.e., referenced
// objects not declared by curpkg) from the parsed source files, in
// the order that typecheck used to load their definitions.
//
// This is needed because loading the definitions for imported objects
// can also add file names.
func importedObjsOf(curpkg *types2.Package, info *types2.Info, noders []*noder) []types2.Object {
// This code is complex because it matches the precise order that
// typecheck recursively and repeatedly traverses the IR. It's meant
// to be thrown away eventually anyway.
seen := make(map[types2.Object]bool)
var objs []types2.Object
var phase int
decls := make(map[types2.Object]syntax.Decl)
assoc := func(decl syntax.Decl, names ...*syntax.Name) {
for _, name := range names {
obj, ok := info.Defs[name]
assert(ok)
decls[obj] = decl
}
}
for _, p := range noders {
syntax.Crawl(p.file, func(n syntax.Node) bool {
switch n := n.(type) {
case *syntax.ConstDecl:
assoc(n, n.NameList...)
case *syntax.FuncDecl:
assoc(n, n.Name)
case *syntax.TypeDecl:
assoc(n, n.Name)
case *syntax.VarDecl:
assoc(n, n.NameList...)
case *syntax.BlockStmt:
return true
}
return false
})
}
var visited map[syntax.Decl]bool
var resolveDecl func(n syntax.Decl)
var resolveNode func(n syntax.Node, top bool)
resolveDecl = func(n syntax.Decl) {
if visited[n] {
return
}
visited[n] = true
switch n := n.(type) {
case *syntax.ConstDecl:
resolveNode(n.Type, true)
resolveNode(n.Values, true)
case *syntax.FuncDecl:
if n.Recv != nil {
resolveNode(n.Recv, true)
}
resolveNode(n.Type, true)
case *syntax.TypeDecl:
resolveNode(n.Type, true)
case *syntax.VarDecl:
if n.Type != nil {
resolveNode(n.Type, true)
} else {
resolveNode(n.Values, true)
}
}
}
resolveObj := func(pos syntax.Pos, obj types2.Object) {
switch obj.Pkg() {
case nil:
// builtin; nothing to do
case curpkg:
if decl, ok := decls[obj]; ok {
resolveDecl(decl)
}
default:
if obj.Parent() == obj.Pkg().Scope() && !seen[obj] {
seen[obj] = true
objs = append(objs, obj)
}
}
}
checkdefat := func(pos syntax.Pos, n *syntax.Name) {
if n.Value == "_" {
return
}
obj, ok := info.Uses[n]
if !ok {
obj, ok = info.Defs[n]
if !ok {
return
}
}
if obj == nil {
return
}
resolveObj(pos, obj)
}
checkdef := func(n *syntax.Name) { checkdefat(n.Pos(), n) }
var later []syntax.Node
resolveNode = func(n syntax.Node, top bool) {
if n == nil {
return
}
syntax.Crawl(n, func(n syntax.Node) bool {
switch n := n.(type) {
case *syntax.Name:
checkdef(n)
case *syntax.SelectorExpr:
if name, ok := n.X.(*syntax.Name); ok {
if _, isPkg := info.Uses[name].(*types2.PkgName); isPkg {
checkdefat(n.X.Pos(), n.Sel)
return true
}
}
case *syntax.AssignStmt:
resolveNode(n.Rhs, top)
resolveNode(n.Lhs, top)
return true
case *syntax.VarDecl:
resolveNode(n.Values, top)
case *syntax.FuncLit:
if top {
resolveNode(n.Type, top)
later = append(later, n.Body)
return true
}
case *syntax.BlockStmt:
if phase >= 3 {
for _, stmt := range n.List {
resolveNode(stmt, false)
}
}
return true
}
return false
})
}
for phase = 1; phase <= 5; phase++ {
visited = map[syntax.Decl]bool{}
for _, p := range noders {
for _, decl := range p.file.DeclList {
switch decl := decl.(type) {
case *syntax.ConstDecl:
resolveDecl(decl)
case *syntax.FuncDecl:
resolveDecl(decl)
if phase >= 3 && decl.Body != nil {
resolveNode(decl.Body, true)
}
case *syntax.TypeDecl:
if !decl.Alias || phase >= 2 {
resolveDecl(decl)
}
case *syntax.VarDecl:
if phase >= 2 {
resolveNode(decl.Values, true)
resolveDecl(decl)
}
}
}
if phase >= 5 {
syntax.Crawl(p.file, func(n syntax.Node) bool {
if name, ok := n.(*syntax.Name); ok {
if obj, ok := info.Uses[name]; ok {
resolveObj(name.Pos(), obj)
}
}
return false
})
}
}
for i := 0; i < len(later); i++ {
resolveNode(later[i], true)
}
later = nil
}
return objs
}
// typeExprEndPos returns the position that noder would leave base.Pos
// after parsing the given type expression.
func typeExprEndPos(expr0 syntax.Expr) syntax.Pos {
for {
switch expr := expr0.(type) {
case *syntax.Name:
return expr.Pos()
case *syntax.SelectorExpr:
return expr.X.Pos()
case *syntax.ParenExpr:
expr0 = expr.X
case *syntax.Operation:
assert(expr.Op == syntax.Mul)
assert(expr.Y == nil)
expr0 = expr.X
case *syntax.ArrayType:
expr0 = expr.Elem
case *syntax.ChanType:
expr0 = expr.Elem
case *syntax.DotsType:
expr0 = expr.Elem
case *syntax.MapType:
expr0 = expr.Value
case *syntax.SliceType:
expr0 = expr.Elem
case *syntax.StructType:
return expr.Pos()
case *syntax.InterfaceType:
expr0 = lastFieldType(expr.MethodList)
if expr0 == nil {
return expr.Pos()
}
case *syntax.FuncType:
expr0 = lastFieldType(expr.ResultList)
if expr0 == nil {
expr0 = lastFieldType(expr.ParamList)
if expr0 == nil {
return expr.Pos()
}
}
case *syntax.IndexExpr: // explicit type instantiation
targs := unpackListExpr(expr.Index)
expr0 = targs[len(targs)-1]
default:
panic(fmt.Sprintf("%s: unexpected type expression %v", expr.Pos(), syntax.String(expr)))
}
}
}
func lastFieldType(fields []*syntax.Field) syntax.Expr {
if len(fields) == 0 {
return nil
}
return fields[len(fields)-1].Type
}
// sumPos returns the position that noder.sum would produce for
// constant expression x.
func sumPos(x syntax.Expr) syntax.Pos {
orig := x
for {
switch x1 := x.(type) {
case *syntax.BasicLit:
assert(x1.Kind == syntax.StringLit)
return x1.Pos()
case *syntax.Operation:
assert(x1.Op == syntax.Add && x1.Y != nil)
if r, ok := x1.Y.(*syntax.BasicLit); ok {
assert(r.Kind == syntax.StringLit)
x = x1.X
continue
}
}
return orig.Pos()
}
}
// funcParamsEndPos returns the value of base.Pos left by noder after
// processing a function signature.
func funcParamsEndPos(fn *ir.Func) src.XPos {
sig := fn.Nname.Type()
fields := sig.Results().FieldSlice()
if len(fields) == 0 {
fields = sig.Params().FieldSlice()
if len(fields) == 0 {
fields = sig.Recvs().FieldSlice()
if len(fields) == 0 {
if fn.OClosure != nil {
return fn.Nname.Ntype.Pos()
}
return fn.Pos()
}
}
}
return fields[len(fields)-1].Pos
}
type dupTypes struct {
origs map[types2.Type]types2.Type
}
func (d *dupTypes) orig(t types2.Type) types2.Type {
if orig, ok := d.origs[t]; ok {
return orig
}
return t
}
func (d *dupTypes) add(t, orig types2.Type) {
if t == orig {
return
}
if d.origs == nil {
d.origs = make(map[types2.Type]types2.Type)
}
assert(d.origs[t] == nil)
d.origs[t] = orig
switch t := t.(type) {
case *types2.Pointer:
orig := orig.(*types2.Pointer)
d.add(t.Elem(), orig.Elem())
case *types2.Slice:
orig := orig.(*types2.Slice)
d.add(t.Elem(), orig.Elem())
case *types2.Map:
orig := orig.(*types2.Map)
d.add(t.Key(), orig.Key())
d.add(t.Elem(), orig.Elem())
case *types2.Array:
orig := orig.(*types2.Array)
assert(t.Len() == orig.Len())
d.add(t.Elem(), orig.Elem())
case *types2.Chan:
orig := orig.(*types2.Chan)
assert(t.Dir() == orig.Dir())
d.add(t.Elem(), orig.Elem())
case *types2.Struct:
orig := orig.(*types2.Struct)
assert(t.NumFields() == orig.NumFields())
for i := 0; i < t.NumFields(); i++ {
d.add(t.Field(i).Type(), orig.Field(i).Type())
}
case *types2.Interface:
orig := orig.(*types2.Interface)
assert(t.NumExplicitMethods() == orig.NumExplicitMethods())
assert(t.NumEmbeddeds() == orig.NumEmbeddeds())
for i := 0; i < t.NumExplicitMethods(); i++ {
d.add(t.ExplicitMethod(i).Type(), orig.ExplicitMethod(i).Type())
}
for i := 0; i < t.NumEmbeddeds(); i++ {
d.add(t.EmbeddedType(i), orig.EmbeddedType(i))
}
case *types2.Signature:
orig := orig.(*types2.Signature)
assert((t.Recv() == nil) == (orig.Recv() == nil))
if t.Recv() != nil {
d.add(t.Recv().Type(), orig.Recv().Type())
}
d.add(t.Params(), orig.Params())
d.add(t.Results(), orig.Results())
case *types2.Tuple:
orig := orig.(*types2.Tuple)
assert(t.Len() == orig.Len())
for i := 0; i < t.Len(); i++ {
d.add(t.At(i).Type(), orig.At(i).Type())
}
default:
assert(types2.Identical(t, orig))
}
}
|
