src/cmd/compile/internal/noder/reader2.go - go - Git at Google

 // 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 (
 	"cmd/compile/internal/base"
 	"cmd/compile/internal/syntax"
 	"cmd/compile/internal/types2"
 	"cmd/internal/src"
 )

 type pkgReader2 struct {
 	pkgDecoder

 	ctxt    *types2.Context
 	imports map[string]*types2.Package

 	posBases []*syntax.PosBase
 	pkgs     []*types2.Package
 	typs     []types2.Type
 }

 func readPackage2(ctxt *types2.Context, imports map[string]*types2.Package, input pkgDecoder) *types2.Package {
 	pr := pkgReader2{
 		pkgDecoder: input,

 		ctxt:    ctxt,
 		imports: imports,

 		posBases: make([]*syntax.PosBase, input.numElems(relocPosBase)),
 		pkgs:     make([]*types2.Package, input.numElems(relocPkg)),
 		typs:     make([]types2.Type, input.numElems(relocType)),
 	}

 	r := pr.newReader(relocMeta, publicRootIdx, syncPublic)
 	pkg := r.pkg()
 	r.bool() // has init

 	for i, n := 0, r.len(); i < n; i++ {
 		// As if r.obj(), but avoiding the Scope.Lookup call,
 		// to avoid eager loading of imports.
 		r.sync(syncObject)
 		assert(!r.bool())
 		r.p.objIdx(r.reloc(relocObj))
 		assert(r.len() == 0)
 	}

 	r.sync(syncEOF)

 	pkg.MarkComplete()
 	return pkg
 }

 type reader2 struct {
 	decoder

 	p *pkgReader2

 	dict *reader2Dict
 }

 type reader2Dict struct {
 	bounds []typeInfo

 	tparams []*types2.TypeParam

 	derived      []derivedInfo
 	derivedTypes []types2.Type
 }

 type reader2TypeBound struct {
 	derived  bool
 	boundIdx int
 }

 func (pr *pkgReader2) newReader(k reloc, idx int, marker syncMarker) *reader2 {
 	return &reader2{
 		decoder: pr.newDecoder(k, idx, marker),
 		p:       pr,
 	}
 }

 // @@@ Positions

 func (r *reader2) pos() syntax.Pos {
 	r.sync(syncPos)
 	if !r.bool() {
 		return syntax.Pos{}
 	}

 	// TODO(mdempsky): Delta encoding.
 	posBase := r.posBase()
 	line := r.uint()
 	col := r.uint()
 	return syntax.MakePos(posBase, line, col)
 }

 func (r *reader2) posBase() *syntax.PosBase {
 	return r.p.posBaseIdx(r.reloc(relocPosBase))
 }

 func (pr *pkgReader2) posBaseIdx(idx int) *syntax.PosBase {
 	if b := pr.posBases[idx]; b != nil {
 		return b
 	}

 	r := pr.newReader(relocPosBase, idx, syncPosBase)
 	var b *syntax.PosBase

 	filename := r.string()

 	if r.bool() {
 		b = syntax.NewTrimmedFileBase(filename, true)
 	} else {
 		pos := r.pos()
 		line := r.uint()
 		col := r.uint()
 		b = syntax.NewLineBase(pos, filename, true, line, col)
 	}

 	pr.posBases[idx] = b
 	return b
 }

 // @@@ Packages

 func (r *reader2) pkg() *types2.Package {
 	r.sync(syncPkg)
 	return r.p.pkgIdx(r.reloc(relocPkg))
 }

 func (pr *pkgReader2) pkgIdx(idx int) *types2.Package {
 	// TODO(mdempsky): Consider using some non-nil pointer to indicate
 	// the universe scope, so we don't need to keep re-reading it.
 	if pkg := pr.pkgs[idx]; pkg != nil {
 		return pkg
 	}

 	pkg := pr.newReader(relocPkg, idx, syncPkgDef).doPkg()
 	pr.pkgs[idx] = pkg
 	return pkg
 }

 func (r *reader2) doPkg() *types2.Package {
 	path := r.string()
 	if path == "builtin" {
 		return nil // universe
 	}
 	if path == "" {
 		path = r.p.pkgPath
 	}

 	if pkg := r.p.imports[path]; pkg != nil {
 		return pkg
 	}

 	name := r.string()
 	height := r.len()

 	pkg := types2.NewPackageHeight(path, name, height)
 	r.p.imports[path] = pkg

 	// TODO(mdempsky): The list of imported packages is important for
 	// go/types, but we could probably skip populating it for types2.
 	imports := make([]*types2.Package, r.len())
 	for i := range imports {
 		imports[i] = r.pkg()
 	}
 	pkg.SetImports(imports)

 	return pkg
 }

 // @@@ Types

 func (r *reader2) typ() types2.Type {
 	return r.p.typIdx(r.typInfo(), r.dict)
 }

 func (r *reader2) typInfo() typeInfo {
 	r.sync(syncType)
 	if r.bool() {
 		return typeInfo{idx: r.len(), derived: true}
 	}
 	return typeInfo{idx: r.reloc(relocType), derived: false}
 }

 func (pr *pkgReader2) typIdx(info typeInfo, dict *reader2Dict) types2.Type {
 	idx := info.idx
 	var where *types2.Type
 	if info.derived {
 		where = &dict.derivedTypes[idx]
 		idx = dict.derived[idx].idx
 	} else {
 		where = &pr.typs[idx]
 	}

 	if typ := *where; typ != nil {
 		return typ
 	}

 	r := pr.newReader(relocType, idx, syncTypeIdx)
 	r.dict = dict

 	typ := r.doTyp()
 	assert(typ != nil)

 	// See comment in pkgReader.typIdx explaining how this happens.
 	if prev := *where; prev != nil {
 		return prev
 	}

 	*where = typ
 	return typ
 }

 func (r *reader2) doTyp() (res types2.Type) {
 	switch tag := codeType(r.code(syncType)); tag {
 	default:
 		base.FatalfAt(src.NoXPos, "unhandled type tag: %v", tag)
 		panic("unreachable")

 	case typeBasic:
 		return types2.Typ[r.len()]

 	case typeNamed:
 		obj, targs := r.obj()
 		name := obj.(*types2.TypeName)
 		if len(targs) != 0 {
 			t, _ := types2.Instantiate(r.p.ctxt, name.Type(), targs, false)
 			return t
 		}
 		return name.Type()

 	case typeTypeParam:
 		return r.dict.tparams[r.len()]

 	case typeArray:
 		len := int64(r.uint64())
 		return types2.NewArray(r.typ(), len)
 	case typeChan:
 		dir := types2.ChanDir(r.len())
 		return types2.NewChan(dir, r.typ())
 	case typeMap:
 		return types2.NewMap(r.typ(), r.typ())
 	case typePointer:
 		return types2.NewPointer(r.typ())
 	case typeSignature:
 		return r.signature(nil)
 	case typeSlice:
 		return types2.NewSlice(r.typ())
 	case typeStruct:
 		return r.structType()
 	case typeInterface:
 		return r.interfaceType()
 	case typeUnion:
 		return r.unionType()
 	}
 }

 func (r *reader2) structType() *types2.Struct {
 	fields := make([]*types2.Var, r.len())
 	var tags []string
 	for i := range fields {
 		pos := r.pos()
 		pkg, name := r.selector()
 		ftyp := r.typ()
 		tag := r.string()
 		embedded := r.bool()

 		fields[i] = types2.NewField(pos, pkg, name, ftyp, embedded)
 		if tag != "" {
 			for len(tags) < i {
 				tags = append(tags, "")
 			}
 			tags = append(tags, tag)
 		}
 	}
 	return types2.NewStruct(fields, tags)
 }

 func (r *reader2) unionType() *types2.Union {
 	terms := make([]*types2.Term, r.len())
 	for i := range terms {
 		terms[i] = types2.NewTerm(r.bool(), r.typ())
 	}
 	return types2.NewUnion(terms)
 }

 func (r *reader2) interfaceType() *types2.Interface {
 	methods := make([]*types2.Func, r.len())
 	embeddeds := make([]types2.Type, r.len())

 	for i := range methods {
 		pos := r.pos()
 		pkg, name := r.selector()
 		mtyp := r.signature(nil)
 		methods[i] = types2.NewFunc(pos, pkg, name, mtyp)
 	}

 	for i := range embeddeds {
 		embeddeds[i] = r.typ()
 	}

 	return types2.NewInterfaceType(methods, embeddeds)
 }

 func (r *reader2) signature(recv *types2.Var) *types2.Signature {
 	r.sync(syncSignature)

 	params := r.params()
 	results := r.params()
 	variadic := r.bool()

 	return types2.NewSignatureType(recv, nil, nil, params, results, variadic)
 }

 func (r *reader2) params() *types2.Tuple {
 	r.sync(syncParams)
 	params := make([]*types2.Var, r.len())
 	for i := range params {
 		params[i] = r.param()
 	}
 	return types2.NewTuple(params...)
 }

 func (r *reader2) param() *types2.Var {
 	r.sync(syncParam)

 	pos := r.pos()
 	pkg, name := r.localIdent()
 	typ := r.typ()

 	return types2.NewParam(pos, pkg, name, typ)
 }

 // @@@ Objects

 func (r *reader2) obj() (types2.Object, []types2.Type) {
 	r.sync(syncObject)

 	assert(!r.bool())

 	pkg, name := r.p.objIdx(r.reloc(relocObj))
 	obj := pkg.Scope().Lookup(name)

 	targs := make([]types2.Type, r.len())
 	for i := range targs {
 		targs[i] = r.typ()
 	}

 	return obj, targs
 }

 func (pr *pkgReader2) objIdx(idx int) (*types2.Package, string) {
 	rname := pr.newReader(relocName, idx, syncObject1)

 	objPkg, objName := rname.qualifiedIdent()
 	assert(objName != "")

 	tag := codeObj(rname.code(syncCodeObj))

 	if tag == objStub {
 		assert(objPkg == nil || objPkg == types2.Unsafe)
 		return objPkg, objName
 	}

 	dict := pr.objDictIdx(idx)

 	r := pr.newReader(relocObj, idx, syncObject1)
 	r.dict = dict

 	objPkg.Scope().InsertLazy(objName, func() types2.Object {
 		switch tag {
 		default:
 			panic("weird")

 		case objAlias:
 			pos := r.pos()
 			typ := r.typ()
 			return types2.NewTypeName(pos, objPkg, objName, typ)

 		case objConst:
 			pos := r.pos()
 			typ := r.typ()
 			val := r.value()
 			return types2.NewConst(pos, objPkg, objName, typ, val)

 		case objFunc:
 			pos := r.pos()
 			tparams := r.typeParamNames()
 			sig := r.signature(nil)
 			sig.SetTypeParams(tparams)
 			return types2.NewFunc(pos, objPkg, objName, sig)

 		case objType:
 			pos := r.pos()

 			return types2.NewTypeNameLazy(pos, objPkg, objName, func(named *types2.Named) (tparams []*types2.TypeParam, underlying types2.Type, methods []*types2.Func) {
 				tparams = r.typeParamNames()

 				// TODO(mdempsky): Rewrite receiver types to underlying is an
 				// Interface? The go/types importer does this (I think because
 				// unit tests expected that), but cmd/compile doesn't care
 				// about it, so maybe we can avoid worrying about that here.
 				underlying = r.typ().Underlying()

 				methods = make([]*types2.Func, r.len())
 				for i := range methods {
 					methods[i] = r.method()
 				}

 				return
 			})

 		case objVar:
 			pos := r.pos()
 			typ := r.typ()
 			return types2.NewVar(pos, objPkg, objName, typ)
 		}
 	})

 	return objPkg, objName
 }

 func (pr *pkgReader2) objDictIdx(idx int) *reader2Dict {
 	r := pr.newReader(relocObjDict, idx, syncObject1)

 	var dict reader2Dict

 	if implicits := r.len(); implicits != 0 {
 		base.Fatalf("unexpected object with %v implicit type parameter(s)", implicits)
 	}

 	dict.bounds = make([]typeInfo, r.len())
 	for i := range dict.bounds {
 		dict.bounds[i] = r.typInfo()
 	}

 	dict.derived = make([]derivedInfo, r.len())
 	dict.derivedTypes = make([]types2.Type, len(dict.derived))
 	for i := range dict.derived {
 		dict.derived[i] = derivedInfo{r.reloc(relocType), r.bool()}
 	}

 	// function references follow, but reader2 doesn't need those

 	return &dict
 }

 func (r *reader2) typeParamNames() []*types2.TypeParam {
 	r.sync(syncTypeParamNames)

 	// Note: This code assumes it only processes objects without
 	// implement type parameters. This is currently fine, because
 	// reader2 is only used to read in exported declarations, which are
 	// always package scoped.

 	if len(r.dict.bounds) == 0 {
 		return nil
 	}

 	// Careful: Type parameter lists may have cycles. To allow for this,
 	// we construct the type parameter list in two passes: first we
 	// create all the TypeNames and TypeParams, then we construct and
 	// set the bound type.

 	r.dict.tparams = make([]*types2.TypeParam, len(r.dict.bounds))
 	for i := range r.dict.bounds {
 		pos := r.pos()
 		pkg, name := r.localIdent()

 		tname := types2.NewTypeName(pos, pkg, name, nil)
 		r.dict.tparams[i] = types2.NewTypeParam(tname, nil)
 	}

 	for i, bound := range r.dict.bounds {
 		r.dict.tparams[i].SetConstraint(r.p.typIdx(bound, r.dict))
 	}

 	return r.dict.tparams
 }

 func (r *reader2) method() *types2.Func {
 	r.sync(syncMethod)
 	pos := r.pos()
 	pkg, name := r.selector()

 	rparams := r.typeParamNames()
 	sig := r.signature(r.param())
 	sig.SetRecvTypeParams(rparams)

 	_ = r.pos() // TODO(mdempsky): Remove; this is a hacker for linker.go.
 	return types2.NewFunc(pos, pkg, name, sig)
 }

 func (r *reader2) qualifiedIdent() (*types2.Package, string) { return r.ident(syncSym) }
 func (r *reader2) localIdent() (*types2.Package, string)     { return r.ident(syncLocalIdent) }
 func (r *reader2) selector() (*types2.Package, string)       { return r.ident(syncSelector) }

 func (r *reader2) ident(marker syncMarker) (*types2.Package, string) {
 	r.sync(marker)
 	return r.pkg(), r.string()
 }
	// 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 (
	"cmd/compile/internal/base"
	"cmd/compile/internal/syntax"
	"cmd/compile/internal/types2"
	"cmd/internal/src"
	)

	type pkgReader2 struct {
	pkgDecoder

	ctxt *types2.Context
	imports map[string]*types2.Package

	posBases []*syntax.PosBase
	pkgs []*types2.Package
	typs []types2.Type
	}

	func readPackage2(ctxt types2.Context, imports map[string]types2.Package, input pkgDecoder) *types2.Package {
	pr := pkgReader2{
	pkgDecoder: input,

	ctxt: ctxt,
	imports: imports,

	posBases: make([]*syntax.PosBase, input.numElems(relocPosBase)),
	pkgs: make([]*types2.Package, input.numElems(relocPkg)),
	typs: make([]types2.Type, input.numElems(relocType)),
	}

	r := pr.newReader(relocMeta, publicRootIdx, syncPublic)
	pkg := r.pkg()
	r.bool() // has init

	for i, n := 0, r.len(); i < n; i++ {
	// As if r.obj(), but avoiding the Scope.Lookup call,
	// to avoid eager loading of imports.
	r.sync(syncObject)
	assert(!r.bool())
	r.p.objIdx(r.reloc(relocObj))
	assert(r.len() == 0)
	}

	r.sync(syncEOF)

	pkg.MarkComplete()
	return pkg
	}

	type reader2 struct {
	decoder

	p *pkgReader2

	dict *reader2Dict
	}

	type reader2Dict struct {
	bounds []typeInfo

	tparams []*types2.TypeParam

	derived []derivedInfo
	derivedTypes []types2.Type
	}

	type reader2TypeBound struct {
	derived bool
	boundIdx int
	}

	func (pr pkgReader2) newReader(k reloc, idx int, marker syncMarker) reader2 {
	return &reader2{
	decoder: pr.newDecoder(k, idx, marker),
	p: pr,
	}
	}

	// @@@ Positions

	func (r *reader2) pos() syntax.Pos {
	r.sync(syncPos)
	if !r.bool() {
	return syntax.Pos{}
	}

	// TODO(mdempsky): Delta encoding.
	posBase := r.posBase()
	line := r.uint()
	col := r.uint()
	return syntax.MakePos(posBase, line, col)
	}

	func (r reader2) posBase() syntax.PosBase {
	return r.p.posBaseIdx(r.reloc(relocPosBase))
	}

	func (pr pkgReader2) posBaseIdx(idx int) syntax.PosBase {
	if b := pr.posBases[idx]; b != nil {
	return b
	}

	r := pr.newReader(relocPosBase, idx, syncPosBase)
	var b *syntax.PosBase

	filename := r.string()

	if r.bool() {
	b = syntax.NewTrimmedFileBase(filename, true)
	} else {
	pos := r.pos()
	line := r.uint()
	col := r.uint()
	b = syntax.NewLineBase(pos, filename, true, line, col)
	}

	pr.posBases[idx] = b
	return b
	}

	// @@@ Packages

	func (r reader2) pkg() types2.Package {
	r.sync(syncPkg)
	return r.p.pkgIdx(r.reloc(relocPkg))
	}

	func (pr pkgReader2) pkgIdx(idx int) types2.Package {
	// TODO(mdempsky): Consider using some non-nil pointer to indicate
	// the universe scope, so we don't need to keep re-reading it.
	if pkg := pr.pkgs[idx]; pkg != nil {
	return pkg
	}

	pkg := pr.newReader(relocPkg, idx, syncPkgDef).doPkg()
	pr.pkgs[idx] = pkg
	return pkg
	}

	func (r reader2) doPkg() types2.Package {
	path := r.string()
	if path == "builtin" {
	return nil // universe
	}
	if path == "" {
	path = r.p.pkgPath
	}

	if pkg := r.p.imports[path]; pkg != nil {
	return pkg
	}

	name := r.string()
	height := r.len()

	pkg := types2.NewPackageHeight(path, name, height)
	r.p.imports[path] = pkg

	// TODO(mdempsky): The list of imported packages is important for
	// go/types, but we could probably skip populating it for types2.
	imports := make([]*types2.Package, r.len())
	for i := range imports {
	imports[i] = r.pkg()
	}
	pkg.SetImports(imports)

	return pkg
	}

	// @@@ Types

	func (r *reader2) typ() types2.Type {
	return r.p.typIdx(r.typInfo(), r.dict)
	}

	func (r *reader2) typInfo() typeInfo {
	r.sync(syncType)
	if r.bool() {
	return typeInfo{idx: r.len(), derived: true}
	}
	return typeInfo{idx: r.reloc(relocType), derived: false}
	}

	func (pr pkgReader2) typIdx(info typeInfo, dict reader2Dict) types2.Type {
	idx := info.idx
	var where *types2.Type
	if info.derived {
	where = &dict.derivedTypes[idx]
	idx = dict.derived[idx].idx
	} else {
	where = &pr.typs[idx]
	}

	if typ := *where; typ != nil {
	return typ
	}

	r := pr.newReader(relocType, idx, syncTypeIdx)
	r.dict = dict

	typ := r.doTyp()
	assert(typ != nil)

	// See comment in pkgReader.typIdx explaining how this happens.
	if prev := *where; prev != nil {
	return prev
	}

	*where = typ
	return typ
	}

	func (r *reader2) doTyp() (res types2.Type) {
	switch tag := codeType(r.code(syncType)); tag {
	default:
	base.FatalfAt(src.NoXPos, "unhandled type tag: %v", tag)
	panic("unreachable")

	case typeBasic:
	return types2.Typ[r.len()]

	case typeNamed:
	obj, targs := r.obj()
	name := obj.(*types2.TypeName)
	if len(targs) != 0 {
	t, _ := types2.Instantiate(r.p.ctxt, name.Type(), targs, false)
	return t
	}
	return name.Type()

	case typeTypeParam:
	return r.dict.tparams[r.len()]

	case typeArray:
	len := int64(r.uint64())
	return types2.NewArray(r.typ(), len)
	case typeChan:
	dir := types2.ChanDir(r.len())
	return types2.NewChan(dir, r.typ())
	case typeMap:
	return types2.NewMap(r.typ(), r.typ())
	case typePointer:
	return types2.NewPointer(r.typ())
	case typeSignature:
	return r.signature(nil)
	case typeSlice:
	return types2.NewSlice(r.typ())
	case typeStruct:
	return r.structType()
	case typeInterface:
	return r.interfaceType()
	case typeUnion:
	return r.unionType()
	}
	}

	func (r reader2) structType() types2.Struct {
	fields := make([]*types2.Var, r.len())
	var tags []string
	for i := range fields {
	pos := r.pos()
	pkg, name := r.selector()
	ftyp := r.typ()
	tag := r.string()
	embedded := r.bool()

	fields[i] = types2.NewField(pos, pkg, name, ftyp, embedded)
	if tag != "" {
	for len(tags) < i {
	tags = append(tags, "")
	}
	tags = append(tags, tag)
	}
	}
	return types2.NewStruct(fields, tags)
	}

	func (r reader2) unionType() types2.Union {
	terms := make([]*types2.Term, r.len())
	for i := range terms {
	terms[i] = types2.NewTerm(r.bool(), r.typ())
	}
	return types2.NewUnion(terms)
	}

	func (r reader2) interfaceType() types2.Interface {
	methods := make([]*types2.Func, r.len())
	embeddeds := make([]types2.Type, r.len())

	for i := range methods {
	pos := r.pos()
	pkg, name := r.selector()
	mtyp := r.signature(nil)
	methods[i] = types2.NewFunc(pos, pkg, name, mtyp)
	}

	for i := range embeddeds {
	embeddeds[i] = r.typ()
	}

	return types2.NewInterfaceType(methods, embeddeds)
	}

	func (r reader2) signature(recv types2.Var) *types2.Signature {
	r.sync(syncSignature)

	params := r.params()
	results := r.params()
	variadic := r.bool()

	return types2.NewSignatureType(recv, nil, nil, params, results, variadic)
	}

	func (r reader2) params() types2.Tuple {
	r.sync(syncParams)
	params := make([]*types2.Var, r.len())
	for i := range params {
	params[i] = r.param()
	}
	return types2.NewTuple(params...)
	}

	func (r reader2) param() types2.Var {
	r.sync(syncParam)

	pos := r.pos()
	pkg, name := r.localIdent()
	typ := r.typ()

	return types2.NewParam(pos, pkg, name, typ)
	}

	// @@@ Objects

	func (r *reader2) obj() (types2.Object, []types2.Type) {
	r.sync(syncObject)

	assert(!r.bool())

	pkg, name := r.p.objIdx(r.reloc(relocObj))
	obj := pkg.Scope().Lookup(name)

	targs := make([]types2.Type, r.len())
	for i := range targs {
	targs[i] = r.typ()
	}

	return obj, targs
	}

	func (pr pkgReader2) objIdx(idx int) (types2.Package, string) {
	rname := pr.newReader(relocName, idx, syncObject1)

	objPkg, objName := rname.qualifiedIdent()
	assert(objName != "")

	tag := codeObj(rname.code(syncCodeObj))

	if tag == objStub {
	assert(objPkg == nil \|\| objPkg == types2.Unsafe)
	return objPkg, objName
	}

	dict := pr.objDictIdx(idx)

	r := pr.newReader(relocObj, idx, syncObject1)
	r.dict = dict

	objPkg.Scope().InsertLazy(objName, func() types2.Object {
	switch tag {
	default:
	panic("weird")

	case objAlias:
	pos := r.pos()
	typ := r.typ()
	return types2.NewTypeName(pos, objPkg, objName, typ)

	case objConst:
	pos := r.pos()
	typ := r.typ()
	val := r.value()
	return types2.NewConst(pos, objPkg, objName, typ, val)

	case objFunc:
	pos := r.pos()
	tparams := r.typeParamNames()
	sig := r.signature(nil)
	sig.SetTypeParams(tparams)
	return types2.NewFunc(pos, objPkg, objName, sig)

	case objType:
	pos := r.pos()

	return types2.NewTypeNameLazy(pos, objPkg, objName, func(named types2.Named) (tparams []types2.TypeParam, underlying types2.Type, methods []*types2.Func) {
	tparams = r.typeParamNames()

	// TODO(mdempsky): Rewrite receiver types to underlying is an
	// Interface? The go/types importer does this (I think because
	// unit tests expected that), but cmd/compile doesn't care
	// about it, so maybe we can avoid worrying about that here.
	underlying = r.typ().Underlying()

	methods = make([]*types2.Func, r.len())
	for i := range methods {
	methods[i] = r.method()
	}

	return
	})

	case objVar:
	pos := r.pos()
	typ := r.typ()
	return types2.NewVar(pos, objPkg, objName, typ)
	}
	})

	return objPkg, objName
	}

	func (pr pkgReader2) objDictIdx(idx int) reader2Dict {
	r := pr.newReader(relocObjDict, idx, syncObject1)

	var dict reader2Dict

	if implicits := r.len(); implicits != 0 {
	base.Fatalf("unexpected object with %v implicit type parameter(s)", implicits)
	}

	dict.bounds = make([]typeInfo, r.len())
	for i := range dict.bounds {
	dict.bounds[i] = r.typInfo()
	}

	dict.derived = make([]derivedInfo, r.len())
	dict.derivedTypes = make([]types2.Type, len(dict.derived))
	for i := range dict.derived {
	dict.derived[i] = derivedInfo{r.reloc(relocType), r.bool()}
	}

	// function references follow, but reader2 doesn't need those

	return &dict
	}

	func (r reader2) typeParamNames() []types2.TypeParam {
	r.sync(syncTypeParamNames)

	// Note: This code assumes it only processes objects without
	// implement type parameters. This is currently fine, because
	// reader2 is only used to read in exported declarations, which are
	// always package scoped.

	if len(r.dict.bounds) == 0 {
	return nil
	}

	// Careful: Type parameter lists may have cycles. To allow for this,
	// we construct the type parameter list in two passes: first we
	// create all the TypeNames and TypeParams, then we construct and
	// set the bound type.

	r.dict.tparams = make([]*types2.TypeParam, len(r.dict.bounds))
	for i := range r.dict.bounds {
	pos := r.pos()
	pkg, name := r.localIdent()

	tname := types2.NewTypeName(pos, pkg, name, nil)
	r.dict.tparams[i] = types2.NewTypeParam(tname, nil)
	}

	for i, bound := range r.dict.bounds {
	r.dict.tparams[i].SetConstraint(r.p.typIdx(bound, r.dict))
	}

	return r.dict.tparams
	}

	func (r reader2) method() types2.Func {
	r.sync(syncMethod)
	pos := r.pos()
	pkg, name := r.selector()

	rparams := r.typeParamNames()
	sig := r.signature(r.param())
	sig.SetRecvTypeParams(rparams)

	_ = r.pos() // TODO(mdempsky): Remove; this is a hacker for linker.go.
	return types2.NewFunc(pos, pkg, name, sig)
	}

	func (r reader2) qualifiedIdent() (types2.Package, string) { return r.ident(syncSym) }
	func (r reader2) localIdent() (types2.Package, string) { return r.ident(syncLocalIdent) }
	func (r reader2) selector() (types2.Package, string) { return r.ident(syncSelector) }

	func (r reader2) ident(marker syncMarker) (types2.Package, string) {
	r.sync(marker)
	return r.pkg(), r.string()
	}