internal/gcimporter/ureader_yes.go - tools - 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.

 // Derived from go/internal/gcimporter/ureader.go

 //go:build go1.18
 // +build go1.18

 package gcimporter

 import (
 	"go/token"
 	"go/types"
 	"strings"

 	"golang.org/x/tools/internal/pkgbits"
 )

 // A pkgReader holds the shared state for reading a unified IR package
 // description.
 type pkgReader struct {
 	pkgbits.PkgDecoder

 	fake fakeFileSet

 	ctxt    *types.Context
 	imports map[string]*types.Package // previously imported packages, indexed by path

 	// lazily initialized arrays corresponding to the unified IR
 	// PosBase, Pkg, and Type sections, respectively.
 	posBases []string // position bases (i.e., file names)
 	pkgs     []*types.Package
 	typs     []types.Type

 	// laterFns holds functions that need to be invoked at the end of
 	// import reading.
 	laterFns []func()
 	// laterFors is used in case of 'type A B' to ensure that B is processed before A.
 	laterFors map[types.Type]int

 	// ifaces holds a list of constructed Interfaces, which need to have
 	// Complete called after importing is done.
 	ifaces []*types.Interface
 }

 // later adds a function to be invoked at the end of import reading.
 func (pr *pkgReader) later(fn func()) {
 	pr.laterFns = append(pr.laterFns, fn)
 }

 // See cmd/compile/internal/noder.derivedInfo.
 type derivedInfo struct {
 	idx    pkgbits.Index
 	needed bool
 }

 // See cmd/compile/internal/noder.typeInfo.
 type typeInfo struct {
 	idx     pkgbits.Index
 	derived bool
 }

 func UImportData(fset *token.FileSet, imports map[string]*types.Package, data []byte, path string) (_ int, pkg *types.Package, err error) {
 	s := string(data)
 	s = s[:strings.LastIndex(s, "\n$$\n")]
 	input := pkgbits.NewPkgDecoder(path, s)
 	pkg = readUnifiedPackage(fset, nil, imports, input)
 	return
 }

 // laterFor adds a function to be invoked at the end of import reading, and records the type that function is finishing.
 func (pr *pkgReader) laterFor(t types.Type, fn func()) {
 	if pr.laterFors == nil {
 		pr.laterFors = make(map[types.Type]int)
 	}
 	pr.laterFors[t] = len(pr.laterFns)
 	pr.laterFns = append(pr.laterFns, fn)
 }

 // readUnifiedPackage reads a package description from the given
 // unified IR export data decoder.
 func readUnifiedPackage(fset *token.FileSet, ctxt *types.Context, imports map[string]*types.Package, input pkgbits.PkgDecoder) *types.Package {
 	pr := pkgReader{
 		PkgDecoder: input,

 		fake: fakeFileSet{
 			fset:  fset,
 			files: make(map[string]*fileInfo),
 		},

 		ctxt:    ctxt,
 		imports: imports,

 		posBases: make([]string, input.NumElems(pkgbits.RelocPosBase)),
 		pkgs:     make([]*types.Package, input.NumElems(pkgbits.RelocPkg)),
 		typs:     make([]types.Type, input.NumElems(pkgbits.RelocType)),
 	}
 	defer pr.fake.setLines()

 	r := pr.newReader(pkgbits.RelocMeta, pkgbits.PublicRootIdx, pkgbits.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(pkgbits.SyncObject)
 		assert(!r.Bool())
 		r.p.objIdx(r.Reloc(pkgbits.RelocObj))
 		assert(r.Len() == 0)
 	}

 	r.Sync(pkgbits.SyncEOF)

 	for _, fn := range pr.laterFns {
 		fn()
 	}

 	for _, iface := range pr.ifaces {
 		iface.Complete()
 	}

 	pkg.MarkComplete()
 	return pkg
 }

 // A reader holds the state for reading a single unified IR element
 // within a package.
 type reader struct {
 	pkgbits.Decoder

 	p *pkgReader

 	dict *readerDict
 }

 // A readerDict holds the state for type parameters that parameterize
 // the current unified IR element.
 type readerDict struct {
 	// bounds is a slice of typeInfos corresponding to the underlying
 	// bounds of the element's type parameters.
 	bounds []typeInfo

 	// tparams is a slice of the constructed TypeParams for the element.
 	tparams []*types.TypeParam

 	// devived is a slice of types derived from tparams, which may be
 	// instantiated while reading the current element.
 	derived      []derivedInfo
 	derivedTypes []types.Type // lazily instantiated from derived
 }

 func (pr *pkgReader) newReader(k pkgbits.RelocKind, idx pkgbits.Index, marker pkgbits.SyncMarker) *reader {
 	return &reader{
 		Decoder: pr.NewDecoder(k, idx, marker),
 		p:       pr,
 	}
 }

 func (pr *pkgReader) tempReader(k pkgbits.RelocKind, idx pkgbits.Index, marker pkgbits.SyncMarker) *reader {
 	return &reader{
 		Decoder: pr.TempDecoder(k, idx, marker),
 		p:       pr,
 	}
 }

 func (pr *pkgReader) retireReader(r *reader) {
 	pr.RetireDecoder(&r.Decoder)
 }

 // @@@ Positions

 func (r *reader) pos() token.Pos {
 	r.Sync(pkgbits.SyncPos)
 	if !r.Bool() {
 		return token.NoPos
 	}

 	// TODO(mdempsky): Delta encoding.
 	posBase := r.posBase()
 	line := r.Uint()
 	col := r.Uint()
 	return r.p.fake.pos(posBase, int(line), int(col))
 }

 func (r *reader) posBase() string {
 	return r.p.posBaseIdx(r.Reloc(pkgbits.RelocPosBase))
 }

 func (pr *pkgReader) posBaseIdx(idx pkgbits.Index) string {
 	if b := pr.posBases[idx]; b != "" {
 		return b
 	}

 	var filename string
 	{
 		r := pr.tempReader(pkgbits.RelocPosBase, idx, pkgbits.SyncPosBase)

 		// Within types2, position bases have a lot more details (e.g.,
 		// keeping track of where //line directives appeared exactly).
 		//
 		// For go/types, we just track the file name.

 		filename = r.String()

 		if r.Bool() { // file base
 			// Was: "b = token.NewTrimmedFileBase(filename, true)"
 		} else { // line base
 			pos := r.pos()
 			line := r.Uint()
 			col := r.Uint()

 			// Was: "b = token.NewLineBase(pos, filename, true, line, col)"
 			_, _, _ = pos, line, col
 		}
 		pr.retireReader(r)
 	}
 	b := filename
 	pr.posBases[idx] = b
 	return b
 }

 // @@@ Packages

 func (r *reader) pkg() *types.Package {
 	r.Sync(pkgbits.SyncPkg)
 	return r.p.pkgIdx(r.Reloc(pkgbits.RelocPkg))
 }

 func (pr *pkgReader) pkgIdx(idx pkgbits.Index) *types.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(pkgbits.RelocPkg, idx, pkgbits.SyncPkgDef).doPkg()
 	pr.pkgs[idx] = pkg
 	return pkg
 }

 func (r *reader) doPkg() *types.Package {
 	path := r.String()
 	switch path {
 	case "":
 		path = r.p.PkgPath()
 	case "builtin":
 		return nil // universe
 	case "unsafe":
 		return types.Unsafe
 	}

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

 	name := r.String()

 	pkg := types.NewPackage(path, name)
 	r.p.imports[path] = pkg

 	imports := make([]*types.Package, r.Len())
 	for i := range imports {
 		imports[i] = r.pkg()
 	}
 	pkg.SetImports(flattenImports(imports))

 	return pkg
 }

 // flattenImports returns the transitive closure of all imported
 // packages rooted from pkgs.
 func flattenImports(pkgs []*types.Package) []*types.Package {
 	var res []*types.Package
 	seen := make(map[*types.Package]struct{})
 	for _, pkg := range pkgs {
 		if _, ok := seen[pkg]; ok {
 			continue
 		}
 		seen[pkg] = struct{}{}
 		res = append(res, pkg)

 		// pkg.Imports() is already flattened.
 		for _, pkg := range pkg.Imports() {
 			if _, ok := seen[pkg]; ok {
 				continue
 			}
 			seen[pkg] = struct{}{}
 			res = append(res, pkg)
 		}
 	}
 	return res
 }

 // @@@ Types

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

 func (r *reader) typInfo() typeInfo {
 	r.Sync(pkgbits.SyncType)
 	if r.Bool() {
 		return typeInfo{idx: pkgbits.Index(r.Len()), derived: true}
 	}
 	return typeInfo{idx: r.Reloc(pkgbits.RelocType), derived: false}
 }

 func (pr *pkgReader) typIdx(info typeInfo, dict *readerDict) types.Type {
 	idx := info.idx
 	var where *types.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
 	}

 	var typ types.Type
 	{
 		r := pr.tempReader(pkgbits.RelocType, idx, pkgbits.SyncTypeIdx)
 		r.dict = dict

 		typ = r.doTyp()
 		assert(typ != nil)
 		pr.retireReader(r)
 	}
 	// See comment in pkgReader.typIdx explaining how this happens.
 	if prev := *where; prev != nil {
 		return prev
 	}

 	*where = typ
 	return typ
 }

 func (r *reader) doTyp() (res types.Type) {
 	switch tag := pkgbits.CodeType(r.Code(pkgbits.SyncType)); tag {
 	default:
 		errorf("unhandled type tag: %v", tag)
 		panic("unreachable")

 	case pkgbits.TypeBasic:
 		return types.Typ[r.Len()]

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

 	case pkgbits.TypeTypeParam:
 		return r.dict.tparams[r.Len()]

 	case pkgbits.TypeArray:
 		len := int64(r.Uint64())
 		return types.NewArray(r.typ(), len)
 	case pkgbits.TypeChan:
 		dir := types.ChanDir(r.Len())
 		return types.NewChan(dir, r.typ())
 	case pkgbits.TypeMap:
 		return types.NewMap(r.typ(), r.typ())
 	case pkgbits.TypePointer:
 		return types.NewPointer(r.typ())
 	case pkgbits.TypeSignature:
 		return r.signature(nil, nil, nil)
 	case pkgbits.TypeSlice:
 		return types.NewSlice(r.typ())
 	case pkgbits.TypeStruct:
 		return r.structType()
 	case pkgbits.TypeInterface:
 		return r.interfaceType()
 	case pkgbits.TypeUnion:
 		return r.unionType()
 	}
 }

 func (r *reader) structType() *types.Struct {
 	fields := make([]*types.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] = types.NewField(pos, pkg, name, ftyp, embedded)
 		if tag != "" {
 			for len(tags) < i {
 				tags = append(tags, "")
 			}
 			tags = append(tags, tag)
 		}
 	}
 	return types.NewStruct(fields, tags)
 }

 func (r *reader) unionType() *types.Union {
 	terms := make([]*types.Term, r.Len())
 	for i := range terms {
 		terms[i] = types.NewTerm(r.Bool(), r.typ())
 	}
 	return types.NewUnion(terms)
 }

 func (r *reader) interfaceType() *types.Interface {
 	methods := make([]*types.Func, r.Len())
 	embeddeds := make([]types.Type, r.Len())
 	implicit := len(methods) == 0 && len(embeddeds) == 1 && r.Bool()

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

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

 	iface := types.NewInterfaceType(methods, embeddeds)
 	if implicit {
 		iface.MarkImplicit()
 	}

 	// We need to call iface.Complete(), but if there are any embedded
 	// defined types, then we may not have set their underlying
 	// interface type yet. So we need to defer calling Complete until
 	// after we've called SetUnderlying everywhere.
 	//
 	// TODO(mdempsky): After CL 424876 lands, it should be safe to call
 	// iface.Complete() immediately.
 	r.p.ifaces = append(r.p.ifaces, iface)

 	return iface
 }

 func (r *reader) signature(recv *types.Var, rtparams, tparams []*types.TypeParam) *types.Signature {
 	r.Sync(pkgbits.SyncSignature)

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

 	return types.NewSignatureType(recv, rtparams, tparams, params, results, variadic)
 }

 func (r *reader) params() *types.Tuple {
 	r.Sync(pkgbits.SyncParams)

 	params := make([]*types.Var, r.Len())
 	for i := range params {
 		params[i] = r.param()
 	}

 	return types.NewTuple(params...)
 }

 func (r *reader) param() *types.Var {
 	r.Sync(pkgbits.SyncParam)

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

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

 // @@@ Objects

 func (r *reader) obj() (types.Object, []types.Type) {
 	r.Sync(pkgbits.SyncObject)

 	assert(!r.Bool())

 	pkg, name := r.p.objIdx(r.Reloc(pkgbits.RelocObj))
 	obj := pkgScope(pkg).Lookup(name)

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

 	return obj, targs
 }

 func (pr *pkgReader) objIdx(idx pkgbits.Index) (*types.Package, string) {

 	var objPkg *types.Package
 	var objName string
 	var tag pkgbits.CodeObj
 	{
 		rname := pr.tempReader(pkgbits.RelocName, idx, pkgbits.SyncObject1)

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

 		tag = pkgbits.CodeObj(rname.Code(pkgbits.SyncCodeObj))
 		pr.retireReader(rname)
 	}

 	if tag == pkgbits.ObjStub {
 		assert(objPkg == nil || objPkg == types.Unsafe)
 		return objPkg, objName
 	}

 	// Ignore local types promoted to global scope (#55110).
 	if _, suffix := splitVargenSuffix(objName); suffix != "" {
 		return objPkg, objName
 	}

 	if objPkg.Scope().Lookup(objName) == nil {
 		dict := pr.objDictIdx(idx)

 		r := pr.newReader(pkgbits.RelocObj, idx, pkgbits.SyncObject1)
 		r.dict = dict

 		declare := func(obj types.Object) {
 			objPkg.Scope().Insert(obj)
 		}

 		switch tag {
 		default:
 			panic("weird")

 		case pkgbits.ObjAlias:
 			pos := r.pos()
 			typ := r.typ()
 			declare(types.NewTypeName(pos, objPkg, objName, typ))

 		case pkgbits.ObjConst:
 			pos := r.pos()
 			typ := r.typ()
 			val := r.Value()
 			declare(types.NewConst(pos, objPkg, objName, typ, val))

 		case pkgbits.ObjFunc:
 			pos := r.pos()
 			tparams := r.typeParamNames()
 			sig := r.signature(nil, nil, tparams)
 			declare(types.NewFunc(pos, objPkg, objName, sig))

 		case pkgbits.ObjType:
 			pos := r.pos()

 			obj := types.NewTypeName(pos, objPkg, objName, nil)
 			named := types.NewNamed(obj, nil, nil)
 			declare(obj)

 			named.SetTypeParams(r.typeParamNames())

 			rhs := r.typ()
 			pk := r.p
 			pk.laterFor(named, func() {
 				// First be sure that the rhs is initialized, if it needs to be initialized.
 				delete(pk.laterFors, named) // prevent cycles
 				if i, ok := pk.laterFors[rhs]; ok {
 					f := pk.laterFns[i]
 					pk.laterFns[i] = func() {} // function is running now, so replace it with a no-op
 					f()                        // initialize RHS
 				}
 				underlying := rhs.Underlying()

 				// If the underlying type is an interface, we need to
 				// duplicate its methods so we can replace the receiver
 				// parameter's type (#49906).
 				if iface, ok := underlying.(*types.Interface); ok && iface.NumExplicitMethods() != 0 {
 					methods := make([]*types.Func, iface.NumExplicitMethods())
 					for i := range methods {
 						fn := iface.ExplicitMethod(i)
 						sig := fn.Type().(*types.Signature)

 						recv := types.NewVar(fn.Pos(), fn.Pkg(), "", named)
 						methods[i] = types.NewFunc(fn.Pos(), fn.Pkg(), fn.Name(), types.NewSignature(recv, sig.Params(), sig.Results(), sig.Variadic()))
 					}

 					embeds := make([]types.Type, iface.NumEmbeddeds())
 					for i := range embeds {
 						embeds[i] = iface.EmbeddedType(i)
 					}

 					newIface := types.NewInterfaceType(methods, embeds)
 					r.p.ifaces = append(r.p.ifaces, newIface)
 					underlying = newIface
 				}

 				named.SetUnderlying(underlying)
 			})

 			for i, n := 0, r.Len(); i < n; i++ {
 				named.AddMethod(r.method())
 			}

 		case pkgbits.ObjVar:
 			pos := r.pos()
 			typ := r.typ()
 			declare(types.NewVar(pos, objPkg, objName, typ))
 		}
 	}

 	return objPkg, objName
 }

 func (pr *pkgReader) objDictIdx(idx pkgbits.Index) *readerDict {

 	var dict readerDict

 	{
 		r := pr.tempReader(pkgbits.RelocObjDict, idx, pkgbits.SyncObject1)
 		if implicits := r.Len(); implicits != 0 {
 			errorf("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([]types.Type, len(dict.derived))
 		for i := range dict.derived {
 			dict.derived[i] = derivedInfo{r.Reloc(pkgbits.RelocType), r.Bool()}
 		}

 		pr.retireReader(r)
 	}
 	// function references follow, but reader doesn't need those

 	return &dict
 }

 func (r *reader) typeParamNames() []*types.TypeParam {
 	r.Sync(pkgbits.SyncTypeParamNames)

 	// Note: This code assumes it only processes objects without
 	// implement type parameters. This is currently fine, because
 	// reader 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([]*types.TypeParam, len(r.dict.bounds))
 	for i := range r.dict.bounds {
 		pos := r.pos()
 		pkg, name := r.localIdent()

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

 	typs := make([]types.Type, len(r.dict.bounds))
 	for i, bound := range r.dict.bounds {
 		typs[i] = r.p.typIdx(bound, r.dict)
 	}

 	// TODO(mdempsky): This is subtle, elaborate further.
 	//
 	// We have to save tparams outside of the closure, because
 	// typeParamNames() can be called multiple times with the same
 	// dictionary instance.
 	//
 	// Also, this needs to happen later to make sure SetUnderlying has
 	// been called.
 	//
 	// TODO(mdempsky): Is it safe to have a single "later" slice or do
 	// we need to have multiple passes? See comments on CL 386002 and
 	// go.dev/issue/52104.
 	tparams := r.dict.tparams
 	r.p.later(func() {
 		for i, typ := range typs {
 			tparams[i].SetConstraint(typ)
 		}
 	})

 	return r.dict.tparams
 }

 func (r *reader) method() *types.Func {
 	r.Sync(pkgbits.SyncMethod)
 	pos := r.pos()
 	pkg, name := r.selector()

 	rparams := r.typeParamNames()
 	sig := r.signature(r.param(), rparams, nil)

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

 func (r *reader) qualifiedIdent() (*types.Package, string) { return r.ident(pkgbits.SyncSym) }
 func (r *reader) localIdent() (*types.Package, string)     { return r.ident(pkgbits.SyncLocalIdent) }
 func (r *reader) selector() (*types.Package, string)       { return r.ident(pkgbits.SyncSelector) }

 func (r *reader) ident(marker pkgbits.SyncMarker) (*types.Package, string) {
 	r.Sync(marker)
 	return r.pkg(), r.String()
 }

 // pkgScope returns pkg.Scope().
 // If pkg is nil, it returns types.Universe instead.
 //
 // TODO(mdempsky): Remove after x/tools can depend on Go 1.19.
 func pkgScope(pkg *types.Package) *types.Scope {
 	if pkg != nil {
 		return pkg.Scope()
 	}
 	return types.Universe
 }
	// 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.

	// Derived from go/internal/gcimporter/ureader.go

	//go:build go1.18
	// +build go1.18

	package gcimporter

	import (
	"go/token"
	"go/types"
	"strings"

	"golang.org/x/tools/internal/pkgbits"
	)

	// A pkgReader holds the shared state for reading a unified IR package
	// description.
	type pkgReader struct {
	pkgbits.PkgDecoder

	fake fakeFileSet

	ctxt *types.Context
	imports map[string]*types.Package // previously imported packages, indexed by path

	// lazily initialized arrays corresponding to the unified IR
	// PosBase, Pkg, and Type sections, respectively.
	posBases []string // position bases (i.e., file names)
	pkgs []*types.Package
	typs []types.Type

	// laterFns holds functions that need to be invoked at the end of
	// import reading.
	laterFns []func()
	// laterFors is used in case of 'type A B' to ensure that B is processed before A.
	laterFors map[types.Type]int

	// ifaces holds a list of constructed Interfaces, which need to have
	// Complete called after importing is done.
	ifaces []*types.Interface
	}

	// later adds a function to be invoked at the end of import reading.
	func (pr *pkgReader) later(fn func()) {
	pr.laterFns = append(pr.laterFns, fn)
	}

	// See cmd/compile/internal/noder.derivedInfo.
	type derivedInfo struct {
	idx pkgbits.Index
	needed bool
	}

	// See cmd/compile/internal/noder.typeInfo.
	type typeInfo struct {
	idx pkgbits.Index
	derived bool
	}

	func UImportData(fset token.FileSet, imports map[string]types.Package, data []byte, path string) (_ int, pkg *types.Package, err error) {
	s := string(data)
	s = s[:strings.LastIndex(s, "\n$$\n")]
	input := pkgbits.NewPkgDecoder(path, s)
	pkg = readUnifiedPackage(fset, nil, imports, input)
	return
	}

	// laterFor adds a function to be invoked at the end of import reading, and records the type that function is finishing.
	func (pr *pkgReader) laterFor(t types.Type, fn func()) {
	if pr.laterFors == nil {
	pr.laterFors = make(map[types.Type]int)
	}
	pr.laterFors[t] = len(pr.laterFns)
	pr.laterFns = append(pr.laterFns, fn)
	}

	// readUnifiedPackage reads a package description from the given
	// unified IR export data decoder.
	func readUnifiedPackage(fset token.FileSet, ctxt types.Context, imports map[string]types.Package, input pkgbits.PkgDecoder) types.Package {
	pr := pkgReader{
	PkgDecoder: input,

	fake: fakeFileSet{
	fset: fset,
	files: make(map[string]*fileInfo),
	},

	ctxt: ctxt,
	imports: imports,

	posBases: make([]string, input.NumElems(pkgbits.RelocPosBase)),
	pkgs: make([]*types.Package, input.NumElems(pkgbits.RelocPkg)),
	typs: make([]types.Type, input.NumElems(pkgbits.RelocType)),
	}
	defer pr.fake.setLines()

	r := pr.newReader(pkgbits.RelocMeta, pkgbits.PublicRootIdx, pkgbits.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(pkgbits.SyncObject)
	assert(!r.Bool())
	r.p.objIdx(r.Reloc(pkgbits.RelocObj))
	assert(r.Len() == 0)
	}

	r.Sync(pkgbits.SyncEOF)

	for _, fn := range pr.laterFns {
	fn()
	}

	for _, iface := range pr.ifaces {
	iface.Complete()
	}

	pkg.MarkComplete()
	return pkg
	}

	// A reader holds the state for reading a single unified IR element
	// within a package.
	type reader struct {
	pkgbits.Decoder

	p *pkgReader

	dict *readerDict
	}

	// A readerDict holds the state for type parameters that parameterize
	// the current unified IR element.
	type readerDict struct {
	// bounds is a slice of typeInfos corresponding to the underlying
	// bounds of the element's type parameters.
	bounds []typeInfo

	// tparams is a slice of the constructed TypeParams for the element.
	tparams []*types.TypeParam

	// devived is a slice of types derived from tparams, which may be
	// instantiated while reading the current element.
	derived []derivedInfo
	derivedTypes []types.Type // lazily instantiated from derived
	}

	func (pr pkgReader) newReader(k pkgbits.RelocKind, idx pkgbits.Index, marker pkgbits.SyncMarker) reader {
	return &reader{
	Decoder: pr.NewDecoder(k, idx, marker),
	p: pr,
	}
	}

	func (pr pkgReader) tempReader(k pkgbits.RelocKind, idx pkgbits.Index, marker pkgbits.SyncMarker) reader {
	return &reader{
	Decoder: pr.TempDecoder(k, idx, marker),
	p: pr,
	}
	}

	func (pr pkgReader) retireReader(r reader) {
	pr.RetireDecoder(&r.Decoder)
	}

	// @@@ Positions

	func (r *reader) pos() token.Pos {
	r.Sync(pkgbits.SyncPos)
	if !r.Bool() {
	return token.NoPos
	}

	// TODO(mdempsky): Delta encoding.
	posBase := r.posBase()
	line := r.Uint()
	col := r.Uint()
	return r.p.fake.pos(posBase, int(line), int(col))
	}

	func (r *reader) posBase() string {
	return r.p.posBaseIdx(r.Reloc(pkgbits.RelocPosBase))
	}

	func (pr *pkgReader) posBaseIdx(idx pkgbits.Index) string {
	if b := pr.posBases[idx]; b != "" {
	return b
	}

	var filename string
	{
	r := pr.tempReader(pkgbits.RelocPosBase, idx, pkgbits.SyncPosBase)

	// Within types2, position bases have a lot more details (e.g.,
	// keeping track of where //line directives appeared exactly).
	//
	// For go/types, we just track the file name.

	filename = r.String()

	if r.Bool() { // file base
	// Was: "b = token.NewTrimmedFileBase(filename, true)"
	} else { // line base
	pos := r.pos()
	line := r.Uint()
	col := r.Uint()

	// Was: "b = token.NewLineBase(pos, filename, true, line, col)"
	_, _, _ = pos, line, col
	}
	pr.retireReader(r)
	}
	b := filename
	pr.posBases[idx] = b
	return b
	}

	// @@@ Packages

	func (r reader) pkg() types.Package {
	r.Sync(pkgbits.SyncPkg)
	return r.p.pkgIdx(r.Reloc(pkgbits.RelocPkg))
	}

	func (pr pkgReader) pkgIdx(idx pkgbits.Index) types.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(pkgbits.RelocPkg, idx, pkgbits.SyncPkgDef).doPkg()
	pr.pkgs[idx] = pkg
	return pkg
	}

	func (r reader) doPkg() types.Package {
	path := r.String()
	switch path {
	case "":
	path = r.p.PkgPath()
	case "builtin":
	return nil // universe
	case "unsafe":
	return types.Unsafe
	}

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

	name := r.String()

	pkg := types.NewPackage(path, name)
	r.p.imports[path] = pkg

	imports := make([]*types.Package, r.Len())
	for i := range imports {
	imports[i] = r.pkg()
	}
	pkg.SetImports(flattenImports(imports))

	return pkg
	}

	// flattenImports returns the transitive closure of all imported
	// packages rooted from pkgs.
	func flattenImports(pkgs []types.Package) []types.Package {
	var res []*types.Package
	seen := make(map[*types.Package]struct{})
	for _, pkg := range pkgs {
	if _, ok := seen[pkg]; ok {
	continue
	}
	seen[pkg] = struct{}{}
	res = append(res, pkg)

	// pkg.Imports() is already flattened.
	for _, pkg := range pkg.Imports() {
	if _, ok := seen[pkg]; ok {
	continue
	}
	seen[pkg] = struct{}{}
	res = append(res, pkg)
	}
	}
	return res
	}

	// @@@ Types

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

	func (r *reader) typInfo() typeInfo {
	r.Sync(pkgbits.SyncType)
	if r.Bool() {
	return typeInfo{idx: pkgbits.Index(r.Len()), derived: true}
	}
	return typeInfo{idx: r.Reloc(pkgbits.RelocType), derived: false}
	}

	func (pr pkgReader) typIdx(info typeInfo, dict readerDict) types.Type {
	idx := info.idx
	var where *types.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
	}

	var typ types.Type
	{
	r := pr.tempReader(pkgbits.RelocType, idx, pkgbits.SyncTypeIdx)
	r.dict = dict

	typ = r.doTyp()
	assert(typ != nil)
	pr.retireReader(r)
	}
	// See comment in pkgReader.typIdx explaining how this happens.
	if prev := *where; prev != nil {
	return prev
	}

	*where = typ
	return typ
	}

	func (r *reader) doTyp() (res types.Type) {
	switch tag := pkgbits.CodeType(r.Code(pkgbits.SyncType)); tag {
	default:
	errorf("unhandled type tag: %v", tag)
	panic("unreachable")

	case pkgbits.TypeBasic:
	return types.Typ[r.Len()]

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

	case pkgbits.TypeTypeParam:
	return r.dict.tparams[r.Len()]

	case pkgbits.TypeArray:
	len := int64(r.Uint64())
	return types.NewArray(r.typ(), len)
	case pkgbits.TypeChan:
	dir := types.ChanDir(r.Len())
	return types.NewChan(dir, r.typ())
	case pkgbits.TypeMap:
	return types.NewMap(r.typ(), r.typ())
	case pkgbits.TypePointer:
	return types.NewPointer(r.typ())
	case pkgbits.TypeSignature:
	return r.signature(nil, nil, nil)
	case pkgbits.TypeSlice:
	return types.NewSlice(r.typ())
	case pkgbits.TypeStruct:
	return r.structType()
	case pkgbits.TypeInterface:
	return r.interfaceType()
	case pkgbits.TypeUnion:
	return r.unionType()
	}
	}

	func (r reader) structType() types.Struct {
	fields := make([]*types.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] = types.NewField(pos, pkg, name, ftyp, embedded)
	if tag != "" {
	for len(tags) < i {
	tags = append(tags, "")
	}
	tags = append(tags, tag)
	}
	}
	return types.NewStruct(fields, tags)
	}

	func (r reader) unionType() types.Union {
	terms := make([]*types.Term, r.Len())
	for i := range terms {
	terms[i] = types.NewTerm(r.Bool(), r.typ())
	}
	return types.NewUnion(terms)
	}

	func (r reader) interfaceType() types.Interface {
	methods := make([]*types.Func, r.Len())
	embeddeds := make([]types.Type, r.Len())
	implicit := len(methods) == 0 && len(embeddeds) == 1 && r.Bool()

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

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

	iface := types.NewInterfaceType(methods, embeddeds)
	if implicit {
	iface.MarkImplicit()
	}

	// We need to call iface.Complete(), but if there are any embedded
	// defined types, then we may not have set their underlying
	// interface type yet. So we need to defer calling Complete until
	// after we've called SetUnderlying everywhere.
	//
	// TODO(mdempsky): After CL 424876 lands, it should be safe to call
	// iface.Complete() immediately.
	r.p.ifaces = append(r.p.ifaces, iface)

	return iface
	}

	func (r reader) signature(recv types.Var, rtparams, tparams []types.TypeParam) types.Signature {
	r.Sync(pkgbits.SyncSignature)

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

	return types.NewSignatureType(recv, rtparams, tparams, params, results, variadic)
	}

	func (r reader) params() types.Tuple {
	r.Sync(pkgbits.SyncParams)

	params := make([]*types.Var, r.Len())
	for i := range params {
	params[i] = r.param()
	}

	return types.NewTuple(params...)
	}

	func (r reader) param() types.Var {
	r.Sync(pkgbits.SyncParam)

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

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

	// @@@ Objects

	func (r *reader) obj() (types.Object, []types.Type) {
	r.Sync(pkgbits.SyncObject)

	assert(!r.Bool())

	pkg, name := r.p.objIdx(r.Reloc(pkgbits.RelocObj))
	obj := pkgScope(pkg).Lookup(name)

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

	return obj, targs
	}

	func (pr pkgReader) objIdx(idx pkgbits.Index) (types.Package, string) {

	var objPkg *types.Package
	var objName string
	var tag pkgbits.CodeObj
	{
	rname := pr.tempReader(pkgbits.RelocName, idx, pkgbits.SyncObject1)

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

	tag = pkgbits.CodeObj(rname.Code(pkgbits.SyncCodeObj))
	pr.retireReader(rname)
	}

	if tag == pkgbits.ObjStub {
	assert(objPkg == nil \|\| objPkg == types.Unsafe)
	return objPkg, objName
	}

	// Ignore local types promoted to global scope (#55110).
	if _, suffix := splitVargenSuffix(objName); suffix != "" {
	return objPkg, objName
	}

	if objPkg.Scope().Lookup(objName) == nil {
	dict := pr.objDictIdx(idx)

	r := pr.newReader(pkgbits.RelocObj, idx, pkgbits.SyncObject1)
	r.dict = dict

	declare := func(obj types.Object) {
	objPkg.Scope().Insert(obj)
	}

	switch tag {
	default:
	panic("weird")

	case pkgbits.ObjAlias:
	pos := r.pos()
	typ := r.typ()
	declare(types.NewTypeName(pos, objPkg, objName, typ))

	case pkgbits.ObjConst:
	pos := r.pos()
	typ := r.typ()
	val := r.Value()
	declare(types.NewConst(pos, objPkg, objName, typ, val))

	case pkgbits.ObjFunc:
	pos := r.pos()
	tparams := r.typeParamNames()
	sig := r.signature(nil, nil, tparams)
	declare(types.NewFunc(pos, objPkg, objName, sig))

	case pkgbits.ObjType:
	pos := r.pos()

	obj := types.NewTypeName(pos, objPkg, objName, nil)
	named := types.NewNamed(obj, nil, nil)
	declare(obj)

	named.SetTypeParams(r.typeParamNames())

	rhs := r.typ()
	pk := r.p
	pk.laterFor(named, func() {
	// First be sure that the rhs is initialized, if it needs to be initialized.
	delete(pk.laterFors, named) // prevent cycles
	if i, ok := pk.laterFors[rhs]; ok {
	f := pk.laterFns[i]
	pk.laterFns[i] = func() {} // function is running now, so replace it with a no-op
	f() // initialize RHS
	}
	underlying := rhs.Underlying()

	// If the underlying type is an interface, we need to
	// duplicate its methods so we can replace the receiver
	// parameter's type (#49906).
	if iface, ok := underlying.(*types.Interface); ok && iface.NumExplicitMethods() != 0 {
	methods := make([]*types.Func, iface.NumExplicitMethods())
	for i := range methods {
	fn := iface.ExplicitMethod(i)
	sig := fn.Type().(*types.Signature)

	recv := types.NewVar(fn.Pos(), fn.Pkg(), "", named)
	methods[i] = types.NewFunc(fn.Pos(), fn.Pkg(), fn.Name(), types.NewSignature(recv, sig.Params(), sig.Results(), sig.Variadic()))
	}

	embeds := make([]types.Type, iface.NumEmbeddeds())
	for i := range embeds {
	embeds[i] = iface.EmbeddedType(i)
	}

	newIface := types.NewInterfaceType(methods, embeds)
	r.p.ifaces = append(r.p.ifaces, newIface)
	underlying = newIface
	}

	named.SetUnderlying(underlying)
	})

	for i, n := 0, r.Len(); i < n; i++ {
	named.AddMethod(r.method())
	}

	case pkgbits.ObjVar:
	pos := r.pos()
	typ := r.typ()
	declare(types.NewVar(pos, objPkg, objName, typ))
	}
	}

	return objPkg, objName
	}

	func (pr pkgReader) objDictIdx(idx pkgbits.Index) readerDict {

	var dict readerDict

	{
	r := pr.tempReader(pkgbits.RelocObjDict, idx, pkgbits.SyncObject1)
	if implicits := r.Len(); implicits != 0 {
	errorf("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([]types.Type, len(dict.derived))
	for i := range dict.derived {
	dict.derived[i] = derivedInfo{r.Reloc(pkgbits.RelocType), r.Bool()}
	}

	pr.retireReader(r)
	}
	// function references follow, but reader doesn't need those

	return &dict
	}

	func (r reader) typeParamNames() []types.TypeParam {
	r.Sync(pkgbits.SyncTypeParamNames)

	// Note: This code assumes it only processes objects without
	// implement type parameters. This is currently fine, because
	// reader 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([]*types.TypeParam, len(r.dict.bounds))
	for i := range r.dict.bounds {
	pos := r.pos()
	pkg, name := r.localIdent()

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

	typs := make([]types.Type, len(r.dict.bounds))
	for i, bound := range r.dict.bounds {
	typs[i] = r.p.typIdx(bound, r.dict)
	}

	// TODO(mdempsky): This is subtle, elaborate further.
	//
	// We have to save tparams outside of the closure, because
	// typeParamNames() can be called multiple times with the same
	// dictionary instance.
	//
	// Also, this needs to happen later to make sure SetUnderlying has
	// been called.
	//
	// TODO(mdempsky): Is it safe to have a single "later" slice or do
	// we need to have multiple passes? See comments on CL 386002 and
	// go.dev/issue/52104.
	tparams := r.dict.tparams
	r.p.later(func() {
	for i, typ := range typs {
	tparams[i].SetConstraint(typ)
	}
	})

	return r.dict.tparams
	}

	func (r reader) method() types.Func {
	r.Sync(pkgbits.SyncMethod)
	pos := r.pos()
	pkg, name := r.selector()

	rparams := r.typeParamNames()
	sig := r.signature(r.param(), rparams, nil)

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

	func (r reader) qualifiedIdent() (types.Package, string) { return r.ident(pkgbits.SyncSym) }
	func (r reader) localIdent() (types.Package, string) { return r.ident(pkgbits.SyncLocalIdent) }
	func (r reader) selector() (types.Package, string) { return r.ident(pkgbits.SyncSelector) }

	func (r reader) ident(marker pkgbits.SyncMarker) (types.Package, string) {
	r.Sync(marker)
	return r.pkg(), r.String()
	}

	// pkgScope returns pkg.Scope().
	// If pkg is nil, it returns types.Universe instead.
	//
	// TODO(mdempsky): Remove after x/tools can depend on Go 1.19.
	func pkgScope(pkg types.Package) types.Scope {
	if pkg != nil {
	return pkg.Scope()
	}
	return types.Universe
	}