src/cmd/compile/internal/importer/iimport.go - go - Git at Google

 // Copyright 2018 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.

 // Indexed package import.
 // See cmd/compile/internal/typecheck/iexport.go for the export data format.

 package importer

 import (
 	"cmd/compile/internal/syntax"
 	"cmd/compile/internal/typecheck"
 	"cmd/compile/internal/types2"
 	"encoding/binary"
 	"fmt"
 	"go/constant"
 	"go/token"
 	"io"
 	"math/big"
 	"sort"
 	"strings"
 )

 type intReader struct {
 	*strings.Reader
 	path string
 }

 func (r *intReader) int64() int64 {
 	i, err := binary.ReadVarint(r.Reader)
 	if err != nil {
 		errorf("import %q: read varint error: %v", r.path, err)
 	}
 	return i
 }

 func (r *intReader) uint64() uint64 {
 	i, err := binary.ReadUvarint(r.Reader)
 	if err != nil {
 		errorf("import %q: read varint error: %v", r.path, err)
 	}
 	return i
 }

 // Keep this in sync with constants in iexport.go.
 const (
 	iexportVersionGo1_11   = 0
 	iexportVersionPosCol   = 1
 	iexportVersionGenerics = 2
 	iexportVersionGo1_18   = 2

 	iexportVersionCurrent = 2
 )

 type ident struct {
 	pkg  *types2.Package
 	name string
 }

 const predeclReserved = 32

 type itag uint64

 const (
 	// Types
 	definedType itag = iota
 	pointerType
 	sliceType
 	arrayType
 	chanType
 	mapType
 	signatureType
 	structType
 	interfaceType
 	typeParamType
 	instanceType
 	unionType
 )

 const io_SeekCurrent = 1 // io.SeekCurrent (not defined in Go 1.4)

 // ImportData imports a package from the serialized package data
 // and returns the number of bytes consumed and a reference to the package.
 // If the export data version is not recognized or the format is otherwise
 // compromised, an error is returned.
 func ImportData(imports map[string]*types2.Package, data, path string) (pkg *types2.Package, err error) {
 	const currentVersion = iexportVersionCurrent
 	version := int64(-1)
 	defer func() {
 		if e := recover(); e != nil {
 			if version > currentVersion {
 				err = fmt.Errorf("cannot import %q (%v), export data is newer version - update tool", path, e)
 			} else {
 				err = fmt.Errorf("cannot import %q (%v), possibly version skew - reinstall package", path, e)
 			}
 		}
 	}()

 	r := &intReader{strings.NewReader(data), path}

 	version = int64(r.uint64())
 	switch version {
 	case iexportVersionGo1_18, iexportVersionPosCol, iexportVersionGo1_11:
 	default:
 		errorf("unknown iexport format version %d", version)
 	}

 	sLen := int64(r.uint64())
 	dLen := int64(r.uint64())

 	whence, _ := r.Seek(0, io_SeekCurrent)
 	stringData := data[whence : whence+sLen]
 	declData := data[whence+sLen : whence+sLen+dLen]
 	r.Seek(sLen+dLen, io_SeekCurrent)

 	p := iimporter{
 		exportVersion: version,
 		ipath:         path,
 		version:       int(version),

 		stringData:   stringData,
 		pkgCache:     make(map[uint64]*types2.Package),
 		posBaseCache: make(map[uint64]*syntax.PosBase),

 		declData: declData,
 		pkgIndex: make(map[*types2.Package]map[string]uint64),
 		typCache: make(map[uint64]types2.Type),
 		// Separate map for typeparams, keyed by their package and unique
 		// name (name with subscript).
 		tparamIndex: make(map[ident]*types2.TypeParam),
 	}

 	for i, pt := range predeclared {
 		p.typCache[uint64(i)] = pt
 	}

 	pkgList := make([]*types2.Package, r.uint64())
 	for i := range pkgList {
 		pkgPathOff := r.uint64()
 		pkgPath := p.stringAt(pkgPathOff)
 		pkgName := p.stringAt(r.uint64())
 		_ = int(r.uint64()) // was package height, but not necessary anymore.

 		if pkgPath == "" {
 			pkgPath = path
 		}
 		pkg := imports[pkgPath]
 		if pkg == nil {
 			pkg = types2.NewPackage(pkgPath, pkgName)
 			imports[pkgPath] = pkg
 		} else {
 			if pkg.Name() != pkgName {
 				errorf("conflicting names %s and %s for package %q", pkg.Name(), pkgName, path)
 			}
 		}

 		p.pkgCache[pkgPathOff] = pkg

 		nameIndex := make(map[string]uint64)
 		for nSyms := r.uint64(); nSyms > 0; nSyms-- {
 			name := p.stringAt(r.uint64())
 			nameIndex[name] = r.uint64()
 		}

 		p.pkgIndex[pkg] = nameIndex
 		pkgList[i] = pkg
 	}

 	localpkg := pkgList[0]

 	names := make([]string, 0, len(p.pkgIndex[localpkg]))
 	for name := range p.pkgIndex[localpkg] {
 		names = append(names, name)
 	}
 	sort.Strings(names)
 	for _, name := range names {
 		p.doDecl(localpkg, name)
 	}

 	// SetConstraint can't be called if the constraint type is not yet complete.
 	// When type params are created in the 'P' case of (*importReader).obj(),
 	// the associated constraint type may not be complete due to recursion.
 	// Therefore, we defer calling SetConstraint there, and call it here instead
 	// after all types are complete.
 	for _, d := range p.later {
 		d.t.SetConstraint(d.constraint)
 	}
 	// record all referenced packages as imports
 	list := append(([]*types2.Package)(nil), pkgList[1:]...)
 	sort.Sort(byPath(list))
 	localpkg.SetImports(list)

 	// package was imported completely and without errors
 	localpkg.MarkComplete()

 	return localpkg, nil
 }

 type setConstraintArgs struct {
 	t          *types2.TypeParam
 	constraint types2.Type
 }

 type iimporter struct {
 	exportVersion int64
 	ipath         string
 	version       int

 	stringData   string
 	pkgCache     map[uint64]*types2.Package
 	posBaseCache map[uint64]*syntax.PosBase

 	declData    string
 	pkgIndex    map[*types2.Package]map[string]uint64
 	typCache    map[uint64]types2.Type
 	tparamIndex map[ident]*types2.TypeParam

 	interfaceList []*types2.Interface

 	// Arguments for calls to SetConstraint that are deferred due to recursive types
 	later []setConstraintArgs
 }

 func (p *iimporter) doDecl(pkg *types2.Package, name string) {
 	// See if we've already imported this declaration.
 	if obj := pkg.Scope().Lookup(name); obj != nil {
 		return
 	}

 	off, ok := p.pkgIndex[pkg][name]
 	if !ok {
 		errorf("%v.%v not in index", pkg, name)
 	}

 	r := &importReader{p: p, currPkg: pkg}
 	r.declReader.Reset(p.declData[off:])

 	r.obj(name)
 }

 func (p *iimporter) stringAt(off uint64) string {
 	var x [binary.MaxVarintLen64]byte
 	n := copy(x[:], p.stringData[off:])

 	slen, n := binary.Uvarint(x[:n])
 	if n <= 0 {
 		errorf("varint failed")
 	}
 	spos := off + uint64(n)
 	return p.stringData[spos : spos+slen]
 }

 func (p *iimporter) pkgAt(off uint64) *types2.Package {
 	if pkg, ok := p.pkgCache[off]; ok {
 		return pkg
 	}
 	path := p.stringAt(off)
 	errorf("missing package %q in %q", path, p.ipath)
 	return nil
 }

 func (p *iimporter) posBaseAt(off uint64) *syntax.PosBase {
 	if posBase, ok := p.posBaseCache[off]; ok {
 		return posBase
 	}
 	filename := p.stringAt(off)
 	posBase := syntax.NewTrimmedFileBase(filename, true)
 	p.posBaseCache[off] = posBase
 	return posBase
 }

 func (p *iimporter) typAt(off uint64, base *types2.Named) types2.Type {
 	if t, ok := p.typCache[off]; ok && canReuse(base, t) {
 		return t
 	}

 	if off < predeclReserved {
 		errorf("predeclared type missing from cache: %v", off)
 	}

 	r := &importReader{p: p}
 	r.declReader.Reset(p.declData[off-predeclReserved:])
 	t := r.doType(base)

 	if canReuse(base, t) {
 		p.typCache[off] = t
 	}
 	return t
 }

 // canReuse reports whether the type rhs on the RHS of the declaration for def
 // may be re-used.
 //
 // Specifically, if def is non-nil and rhs is an interface type with methods, it
 // may not be re-used because we have a convention of setting the receiver type
 // for interface methods to def.
 func canReuse(def *types2.Named, rhs types2.Type) bool {
 	if def == nil {
 		return true
 	}
 	iface, _ := rhs.(*types2.Interface)
 	if iface == nil {
 		return true
 	}
 	// Don't use iface.Empty() here as iface may not be complete.
 	return iface.NumEmbeddeds() == 0 && iface.NumExplicitMethods() == 0
 }

 type importReader struct {
 	p           *iimporter
 	declReader  strings.Reader
 	currPkg     *types2.Package
 	prevPosBase *syntax.PosBase
 	prevLine    int64
 	prevColumn  int64
 }

 func (r *importReader) obj(name string) {
 	tag := r.byte()
 	pos := r.pos()

 	switch tag {
 	case 'A':
 		typ := r.typ()

 		r.declare(types2.NewTypeName(pos, r.currPkg, name, typ))

 	case 'C':
 		typ, val := r.value()

 		r.declare(types2.NewConst(pos, r.currPkg, name, typ, val))

 	case 'F', 'G':
 		var tparams []*types2.TypeParam
 		if tag == 'G' {
 			tparams = r.tparamList()
 		}
 		sig := r.signature(nil, nil, tparams)
 		r.declare(types2.NewFunc(pos, r.currPkg, name, sig))

 	case 'T', 'U':
 		// Types can be recursive. We need to setup a stub
 		// declaration before recursing.
 		obj := types2.NewTypeName(pos, r.currPkg, name, nil)
 		named := types2.NewNamed(obj, nil, nil)
 		// Declare obj before calling r.tparamList, so the new type name is recognized
 		// if used in the constraint of one of its own typeparams (see #48280).
 		r.declare(obj)
 		if tag == 'U' {
 			tparams := r.tparamList()
 			named.SetTypeParams(tparams)
 		}

 		underlying := r.p.typAt(r.uint64(), named).Underlying()
 		named.SetUnderlying(underlying)

 		if !isInterface(underlying) {
 			for n := r.uint64(); n > 0; n-- {
 				mpos := r.pos()
 				mname := r.ident()
 				recv := r.param()

 				// If the receiver has any targs, set those as the
 				// rparams of the method (since those are the
 				// typeparams being used in the method sig/body).
 				targs := baseType(recv.Type()).TypeArgs()
 				var rparams []*types2.TypeParam
 				if targs.Len() > 0 {
 					rparams = make([]*types2.TypeParam, targs.Len())
 					for i := range rparams {
 						rparams[i], _ = targs.At(i).(*types2.TypeParam)
 					}
 				}
 				msig := r.signature(recv, rparams, nil)

 				named.AddMethod(types2.NewFunc(mpos, r.currPkg, mname, msig))
 			}
 		}

 	case 'P':
 		// We need to "declare" a typeparam in order to have a name that
 		// can be referenced recursively (if needed) in the type param's
 		// bound.
 		if r.p.exportVersion < iexportVersionGenerics {
 			errorf("unexpected type param type")
 		}
 		name0 := typecheck.TparamName(name)
 		if name0 == "" {
 			errorf("malformed type parameter export name %s: missing prefix", name)
 		}

 		tn := types2.NewTypeName(pos, r.currPkg, name0, nil)
 		t := types2.NewTypeParam(tn, nil)
 		// To handle recursive references to the typeparam within its
 		// bound, save the partial type in tparamIndex before reading the bounds.
 		id := ident{r.currPkg, name}
 		r.p.tparamIndex[id] = t

 		var implicit bool
 		if r.p.exportVersion >= iexportVersionGo1_18 {
 			implicit = r.bool()
 		}
 		constraint := r.typ()
 		if implicit {
 			iface, _ := constraint.(*types2.Interface)
 			if iface == nil {
 				errorf("non-interface constraint marked implicit")
 			}
 			iface.MarkImplicit()
 		}
 		// The constraint type may not be complete, if we
 		// are in the middle of a type recursion involving type
 		// constraints. So, we defer SetConstraint until we have
 		// completely set up all types in ImportData.
 		r.p.later = append(r.p.later, setConstraintArgs{t: t, constraint: constraint})

 	case 'V':
 		typ := r.typ()

 		r.declare(types2.NewVar(pos, r.currPkg, name, typ))

 	default:
 		errorf("unexpected tag: %v", tag)
 	}
 }

 func (r *importReader) declare(obj types2.Object) {
 	obj.Pkg().Scope().Insert(obj)
 }

 func (r *importReader) value() (typ types2.Type, val constant.Value) {
 	typ = r.typ()
 	if r.p.exportVersion >= iexportVersionGo1_18 {
 		// TODO: add support for using the kind
 		_ = constant.Kind(r.int64())
 	}

 	switch b := typ.Underlying().(*types2.Basic); b.Info() & types2.IsConstType {
 	case types2.IsBoolean:
 		val = constant.MakeBool(r.bool())

 	case types2.IsString:
 		val = constant.MakeString(r.string())

 	case types2.IsInteger:
 		var x big.Int
 		r.mpint(&x, b)
 		val = constant.Make(&x)

 	case types2.IsFloat:
 		val = r.mpfloat(b)

 	case types2.IsComplex:
 		re := r.mpfloat(b)
 		im := r.mpfloat(b)
 		val = constant.BinaryOp(re, token.ADD, constant.MakeImag(im))

 	default:
 		errorf("unexpected type %v", typ) // panics
 		panic("unreachable")
 	}

 	return
 }

 func intSize(b *types2.Basic) (signed bool, maxBytes uint) {
 	if (b.Info() & types2.IsUntyped) != 0 {
 		return true, 64
 	}

 	switch b.Kind() {
 	case types2.Float32, types2.Complex64:
 		return true, 3
 	case types2.Float64, types2.Complex128:
 		return true, 7
 	}

 	signed = (b.Info() & types2.IsUnsigned) == 0
 	switch b.Kind() {
 	case types2.Int8, types2.Uint8:
 		maxBytes = 1
 	case types2.Int16, types2.Uint16:
 		maxBytes = 2
 	case types2.Int32, types2.Uint32:
 		maxBytes = 4
 	default:
 		maxBytes = 8
 	}

 	return
 }

 func (r *importReader) mpint(x *big.Int, typ *types2.Basic) {
 	signed, maxBytes := intSize(typ)

 	maxSmall := 256 - maxBytes
 	if signed {
 		maxSmall = 256 - 2*maxBytes
 	}
 	if maxBytes == 1 {
 		maxSmall = 256
 	}

 	n, _ := r.declReader.ReadByte()
 	if uint(n) < maxSmall {
 		v := int64(n)
 		if signed {
 			v >>= 1
 			if n&1 != 0 {
 				v = ^v
 			}
 		}
 		x.SetInt64(v)
 		return
 	}

 	v := -n
 	if signed {
 		v = -(n &^ 1) >> 1
 	}
 	if v < 1 || uint(v) > maxBytes {
 		errorf("weird decoding: %v, %v => %v", n, signed, v)
 	}
 	b := make([]byte, v)
 	io.ReadFull(&r.declReader, b)
 	x.SetBytes(b)
 	if signed && n&1 != 0 {
 		x.Neg(x)
 	}
 }

 func (r *importReader) mpfloat(typ *types2.Basic) constant.Value {
 	var mant big.Int
 	r.mpint(&mant, typ)
 	var f big.Float
 	f.SetInt(&mant)
 	if f.Sign() != 0 {
 		f.SetMantExp(&f, int(r.int64()))
 	}
 	return constant.Make(&f)
 }

 func (r *importReader) ident() string {
 	return r.string()
 }

 func (r *importReader) qualifiedIdent() (*types2.Package, string) {
 	name := r.string()
 	pkg := r.pkg()
 	return pkg, name
 }

 func (r *importReader) pos() syntax.Pos {
 	if r.p.version >= 1 {
 		r.posv1()
 	} else {
 		r.posv0()
 	}

 	if (r.prevPosBase == nil || r.prevPosBase.Filename() == "") && r.prevLine == 0 && r.prevColumn == 0 {
 		return syntax.Pos{}
 	}

 	return syntax.MakePos(r.prevPosBase, uint(r.prevLine), uint(r.prevColumn))
 }

 func (r *importReader) posv0() {
 	delta := r.int64()
 	if delta != deltaNewFile {
 		r.prevLine += delta
 	} else if l := r.int64(); l == -1 {
 		r.prevLine += deltaNewFile
 	} else {
 		r.prevPosBase = r.posBase()
 		r.prevLine = l
 	}
 }

 func (r *importReader) posv1() {
 	delta := r.int64()
 	r.prevColumn += delta >> 1
 	if delta&1 != 0 {
 		delta = r.int64()
 		r.prevLine += delta >> 1
 		if delta&1 != 0 {
 			r.prevPosBase = r.posBase()
 		}
 	}
 }

 func (r *importReader) typ() types2.Type {
 	return r.p.typAt(r.uint64(), nil)
 }

 func isInterface(t types2.Type) bool {
 	_, ok := t.(*types2.Interface)
 	return ok
 }

 func (r *importReader) pkg() *types2.Package     { return r.p.pkgAt(r.uint64()) }
 func (r *importReader) string() string           { return r.p.stringAt(r.uint64()) }
 func (r *importReader) posBase() *syntax.PosBase { return r.p.posBaseAt(r.uint64()) }

 func (r *importReader) doType(base *types2.Named) types2.Type {
 	switch k := r.kind(); k {
 	default:
 		errorf("unexpected kind tag in %q: %v", r.p.ipath, k)
 		return nil

 	case definedType:
 		pkg, name := r.qualifiedIdent()
 		r.p.doDecl(pkg, name)
 		return pkg.Scope().Lookup(name).(*types2.TypeName).Type()
 	case pointerType:
 		return types2.NewPointer(r.typ())
 	case sliceType:
 		return types2.NewSlice(r.typ())
 	case arrayType:
 		n := r.uint64()
 		return types2.NewArray(r.typ(), int64(n))
 	case chanType:
 		dir := chanDir(int(r.uint64()))
 		return types2.NewChan(dir, r.typ())
 	case mapType:
 		return types2.NewMap(r.typ(), r.typ())
 	case signatureType:
 		r.currPkg = r.pkg()
 		return r.signature(nil, nil, nil)

 	case structType:
 		r.currPkg = r.pkg()

 		fields := make([]*types2.Var, r.uint64())
 		tags := make([]string, len(fields))
 		for i := range fields {
 			fpos := r.pos()
 			fname := r.ident()
 			ftyp := r.typ()
 			emb := r.bool()
 			tag := r.string()

 			fields[i] = types2.NewField(fpos, r.currPkg, fname, ftyp, emb)
 			tags[i] = tag
 		}
 		return types2.NewStruct(fields, tags)

 	case interfaceType:
 		r.currPkg = r.pkg()

 		embeddeds := make([]types2.Type, r.uint64())
 		for i := range embeddeds {
 			_ = r.pos()
 			embeddeds[i] = r.typ()
 		}

 		methods := make([]*types2.Func, r.uint64())
 		for i := range methods {
 			mpos := r.pos()
 			mname := r.ident()

 			// TODO(mdempsky): Matches bimport.go, but I
 			// don't agree with this.
 			var recv *types2.Var
 			if base != nil {
 				recv = types2.NewVar(syntax.Pos{}, r.currPkg, "", base)
 			}

 			msig := r.signature(recv, nil, nil)
 			methods[i] = types2.NewFunc(mpos, r.currPkg, mname, msig)
 		}

 		typ := types2.NewInterfaceType(methods, embeddeds)
 		r.p.interfaceList = append(r.p.interfaceList, typ)
 		return typ

 	case typeParamType:
 		if r.p.exportVersion < iexportVersionGenerics {
 			errorf("unexpected type param type")
 		}
 		pkg, name := r.qualifiedIdent()
 		id := ident{pkg, name}
 		if t, ok := r.p.tparamIndex[id]; ok {
 			// We're already in the process of importing this typeparam.
 			return t
 		}
 		// Otherwise, import the definition of the typeparam now.
 		r.p.doDecl(pkg, name)
 		return r.p.tparamIndex[id]

 	case instanceType:
 		if r.p.exportVersion < iexportVersionGenerics {
 			errorf("unexpected instantiation type")
 		}
 		// pos does not matter for instances: they are positioned on the original
 		// type.
 		_ = r.pos()
 		len := r.uint64()
 		targs := make([]types2.Type, len)
 		for i := range targs {
 			targs[i] = r.typ()
 		}
 		baseType := r.typ()
 		// The imported instantiated type doesn't include any methods, so
 		// we must always use the methods of the base (orig) type.
 		// TODO provide a non-nil *Context
 		t, _ := types2.Instantiate(nil, baseType, targs, false)
 		return t

 	case unionType:
 		if r.p.exportVersion < iexportVersionGenerics {
 			errorf("unexpected instantiation type")
 		}
 		terms := make([]*types2.Term, r.uint64())
 		for i := range terms {
 			terms[i] = types2.NewTerm(r.bool(), r.typ())
 		}
 		return types2.NewUnion(terms)
 	}
 }

 func (r *importReader) kind() itag {
 	return itag(r.uint64())
 }

 func (r *importReader) signature(recv *types2.Var, rparams, tparams []*types2.TypeParam) *types2.Signature {
 	params := r.paramList()
 	results := r.paramList()
 	variadic := params.Len() > 0 && r.bool()
 	return types2.NewSignatureType(recv, rparams, tparams, params, results, variadic)
 }

 func (r *importReader) tparamList() []*types2.TypeParam {
 	n := r.uint64()
 	if n == 0 {
 		return nil
 	}
 	xs := make([]*types2.TypeParam, n)
 	for i := range xs {
 		xs[i] = r.typ().(*types2.TypeParam)
 	}
 	return xs
 }

 func (r *importReader) paramList() *types2.Tuple {
 	xs := make([]*types2.Var, r.uint64())
 	for i := range xs {
 		xs[i] = r.param()
 	}
 	return types2.NewTuple(xs...)
 }

 func (r *importReader) param() *types2.Var {
 	pos := r.pos()
 	name := r.ident()
 	typ := r.typ()
 	return types2.NewParam(pos, r.currPkg, name, typ)
 }

 func (r *importReader) bool() bool {
 	return r.uint64() != 0
 }

 func (r *importReader) int64() int64 {
 	n, err := binary.ReadVarint(&r.declReader)
 	if err != nil {
 		errorf("readVarint: %v", err)
 	}
 	return n
 }

 func (r *importReader) uint64() uint64 {
 	n, err := binary.ReadUvarint(&r.declReader)
 	if err != nil {
 		errorf("readUvarint: %v", err)
 	}
 	return n
 }

 func (r *importReader) byte() byte {
 	x, err := r.declReader.ReadByte()
 	if err != nil {
 		errorf("declReader.ReadByte: %v", err)
 	}
 	return x
 }

 func baseType(typ types2.Type) *types2.Named {
 	// pointer receivers are never types2.Named types
 	if p, _ := typ.(*types2.Pointer); p != nil {
 		typ = p.Elem()
 	}
 	// receiver base types are always (possibly generic) types2.Named types
 	n, _ := typ.(*types2.Named)
 	return n
 }
	// Copyright 2018 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.

	// Indexed package import.
	// See cmd/compile/internal/typecheck/iexport.go for the export data format.

	package importer

	import (
	"cmd/compile/internal/syntax"
	"cmd/compile/internal/typecheck"
	"cmd/compile/internal/types2"
	"encoding/binary"
	"fmt"
	"go/constant"
	"go/token"
	"io"
	"math/big"
	"sort"
	"strings"
	)

	type intReader struct {
	*strings.Reader
	path string
	}

	func (r *intReader) int64() int64 {
	i, err := binary.ReadVarint(r.Reader)
	if err != nil {
	errorf("import %q: read varint error: %v", r.path, err)
	}
	return i
	}

	func (r *intReader) uint64() uint64 {
	i, err := binary.ReadUvarint(r.Reader)
	if err != nil {
	errorf("import %q: read varint error: %v", r.path, err)
	}
	return i
	}

	// Keep this in sync with constants in iexport.go.
	const (
	iexportVersionGo1_11 = 0
	iexportVersionPosCol = 1
	iexportVersionGenerics = 2
	iexportVersionGo1_18 = 2

	iexportVersionCurrent = 2
	)

	type ident struct {
	pkg *types2.Package
	name string
	}

	const predeclReserved = 32

	type itag uint64

	const (
	// Types
	definedType itag = iota
	pointerType
	sliceType
	arrayType
	chanType
	mapType
	signatureType
	structType
	interfaceType
	typeParamType
	instanceType
	unionType
	)

	const io_SeekCurrent = 1 // io.SeekCurrent (not defined in Go 1.4)

	// ImportData imports a package from the serialized package data
	// and returns the number of bytes consumed and a reference to the package.
	// If the export data version is not recognized or the format is otherwise
	// compromised, an error is returned.
	func ImportData(imports map[string]types2.Package, data, path string) (pkg types2.Package, err error) {
	const currentVersion = iexportVersionCurrent
	version := int64(-1)
	defer func() {
	if e := recover(); e != nil {
	if version > currentVersion {
	err = fmt.Errorf("cannot import %q (%v), export data is newer version - update tool", path, e)
	} else {
	err = fmt.Errorf("cannot import %q (%v), possibly version skew - reinstall package", path, e)
	}
	}
	}()

	r := &intReader{strings.NewReader(data), path}

	version = int64(r.uint64())
	switch version {
	case iexportVersionGo1_18, iexportVersionPosCol, iexportVersionGo1_11:
	default:
	errorf("unknown iexport format version %d", version)
	}

	sLen := int64(r.uint64())
	dLen := int64(r.uint64())

	whence, _ := r.Seek(0, io_SeekCurrent)
	stringData := data[whence : whence+sLen]
	declData := data[whence+sLen : whence+sLen+dLen]
	r.Seek(sLen+dLen, io_SeekCurrent)

	p := iimporter{
	exportVersion: version,
	ipath: path,
	version: int(version),

	stringData: stringData,
	pkgCache: make(map[uint64]*types2.Package),
	posBaseCache: make(map[uint64]*syntax.PosBase),

	declData: declData,
	pkgIndex: make(map[*types2.Package]map[string]uint64),
	typCache: make(map[uint64]types2.Type),
	// Separate map for typeparams, keyed by their package and unique
	// name (name with subscript).
	tparamIndex: make(map[ident]*types2.TypeParam),
	}

	for i, pt := range predeclared {
	p.typCache[uint64(i)] = pt
	}

	pkgList := make([]*types2.Package, r.uint64())
	for i := range pkgList {
	pkgPathOff := r.uint64()
	pkgPath := p.stringAt(pkgPathOff)
	pkgName := p.stringAt(r.uint64())
	_ = int(r.uint64()) // was package height, but not necessary anymore.

	if pkgPath == "" {
	pkgPath = path
	}
	pkg := imports[pkgPath]
	if pkg == nil {
	pkg = types2.NewPackage(pkgPath, pkgName)
	imports[pkgPath] = pkg
	} else {
	if pkg.Name() != pkgName {
	errorf("conflicting names %s and %s for package %q", pkg.Name(), pkgName, path)
	}
	}

	p.pkgCache[pkgPathOff] = pkg

	nameIndex := make(map[string]uint64)
	for nSyms := r.uint64(); nSyms > 0; nSyms-- {
	name := p.stringAt(r.uint64())
	nameIndex[name] = r.uint64()
	}

	p.pkgIndex[pkg] = nameIndex
	pkgList[i] = pkg
	}

	localpkg := pkgList[0]

	names := make([]string, 0, len(p.pkgIndex[localpkg]))
	for name := range p.pkgIndex[localpkg] {
	names = append(names, name)
	}
	sort.Strings(names)
	for _, name := range names {
	p.doDecl(localpkg, name)
	}

	// SetConstraint can't be called if the constraint type is not yet complete.
	// When type params are created in the 'P' case of (*importReader).obj(),
	// the associated constraint type may not be complete due to recursion.
	// Therefore, we defer calling SetConstraint there, and call it here instead
	// after all types are complete.
	for _, d := range p.later {
	d.t.SetConstraint(d.constraint)
	}
	// record all referenced packages as imports
	list := append(([]*types2.Package)(nil), pkgList[1:]...)
	sort.Sort(byPath(list))
	localpkg.SetImports(list)

	// package was imported completely and without errors
	localpkg.MarkComplete()

	return localpkg, nil
	}

	type setConstraintArgs struct {
	t *types2.TypeParam
	constraint types2.Type
	}

	type iimporter struct {
	exportVersion int64
	ipath string
	version int

	stringData string
	pkgCache map[uint64]*types2.Package
	posBaseCache map[uint64]*syntax.PosBase

	declData string
	pkgIndex map[*types2.Package]map[string]uint64
	typCache map[uint64]types2.Type
	tparamIndex map[ident]*types2.TypeParam

	interfaceList []*types2.Interface

	// Arguments for calls to SetConstraint that are deferred due to recursive types
	later []setConstraintArgs
	}

	func (p iimporter) doDecl(pkg types2.Package, name string) {
	// See if we've already imported this declaration.
	if obj := pkg.Scope().Lookup(name); obj != nil {
	return
	}

	off, ok := p.pkgIndex[pkg][name]
	if !ok {
	errorf("%v.%v not in index", pkg, name)
	}

	r := &importReader{p: p, currPkg: pkg}
	r.declReader.Reset(p.declData[off:])

	r.obj(name)
	}

	func (p *iimporter) stringAt(off uint64) string {
	var x [binary.MaxVarintLen64]byte
	n := copy(x[:], p.stringData[off:])

	slen, n := binary.Uvarint(x[:n])
	if n <= 0 {
	errorf("varint failed")
	}
	spos := off + uint64(n)
	return p.stringData[spos : spos+slen]
	}

	func (p iimporter) pkgAt(off uint64) types2.Package {
	if pkg, ok := p.pkgCache[off]; ok {
	return pkg
	}
	path := p.stringAt(off)
	errorf("missing package %q in %q", path, p.ipath)
	return nil
	}

	func (p iimporter) posBaseAt(off uint64) syntax.PosBase {
	if posBase, ok := p.posBaseCache[off]; ok {
	return posBase
	}
	filename := p.stringAt(off)
	posBase := syntax.NewTrimmedFileBase(filename, true)
	p.posBaseCache[off] = posBase
	return posBase
	}

	func (p iimporter) typAt(off uint64, base types2.Named) types2.Type {
	if t, ok := p.typCache[off]; ok && canReuse(base, t) {
	return t
	}

	if off < predeclReserved {
	errorf("predeclared type missing from cache: %v", off)
	}

	r := &importReader{p: p}
	r.declReader.Reset(p.declData[off-predeclReserved:])
	t := r.doType(base)

	if canReuse(base, t) {
	p.typCache[off] = t
	}
	return t
	}

	// canReuse reports whether the type rhs on the RHS of the declaration for def
	// may be re-used.
	//
	// Specifically, if def is non-nil and rhs is an interface type with methods, it
	// may not be re-used because we have a convention of setting the receiver type
	// for interface methods to def.
	func canReuse(def *types2.Named, rhs types2.Type) bool {
	if def == nil {
	return true
	}
	iface, _ := rhs.(*types2.Interface)
	if iface == nil {
	return true
	}
	// Don't use iface.Empty() here as iface may not be complete.
	return iface.NumEmbeddeds() == 0 && iface.NumExplicitMethods() == 0
	}

	type importReader struct {
	p *iimporter
	declReader strings.Reader
	currPkg *types2.Package
	prevPosBase *syntax.PosBase
	prevLine int64
	prevColumn int64
	}

	func (r *importReader) obj(name string) {
	tag := r.byte()
	pos := r.pos()

	switch tag {
	case 'A':
	typ := r.typ()

	r.declare(types2.NewTypeName(pos, r.currPkg, name, typ))

	case 'C':
	typ, val := r.value()

	r.declare(types2.NewConst(pos, r.currPkg, name, typ, val))

	case 'F', 'G':
	var tparams []*types2.TypeParam
	if tag == 'G' {
	tparams = r.tparamList()
	}
	sig := r.signature(nil, nil, tparams)
	r.declare(types2.NewFunc(pos, r.currPkg, name, sig))

	case 'T', 'U':
	// Types can be recursive. We need to setup a stub
	// declaration before recursing.
	obj := types2.NewTypeName(pos, r.currPkg, name, nil)
	named := types2.NewNamed(obj, nil, nil)
	// Declare obj before calling r.tparamList, so the new type name is recognized
	// if used in the constraint of one of its own typeparams (see #48280).
	r.declare(obj)
	if tag == 'U' {
	tparams := r.tparamList()
	named.SetTypeParams(tparams)
	}

	underlying := r.p.typAt(r.uint64(), named).Underlying()
	named.SetUnderlying(underlying)

	if !isInterface(underlying) {
	for n := r.uint64(); n > 0; n-- {
	mpos := r.pos()
	mname := r.ident()
	recv := r.param()

	// If the receiver has any targs, set those as the
	// rparams of the method (since those are the
	// typeparams being used in the method sig/body).
	targs := baseType(recv.Type()).TypeArgs()
	var rparams []*types2.TypeParam
	if targs.Len() > 0 {
	rparams = make([]*types2.TypeParam, targs.Len())
	for i := range rparams {
	rparams[i], _ = targs.At(i).(*types2.TypeParam)
	}
	}
	msig := r.signature(recv, rparams, nil)

	named.AddMethod(types2.NewFunc(mpos, r.currPkg, mname, msig))
	}
	}

	case 'P':
	// We need to "declare" a typeparam in order to have a name that
	// can be referenced recursively (if needed) in the type param's
	// bound.
	if r.p.exportVersion < iexportVersionGenerics {
	errorf("unexpected type param type")
	}
	name0 := typecheck.TparamName(name)
	if name0 == "" {
	errorf("malformed type parameter export name %s: missing prefix", name)
	}

	tn := types2.NewTypeName(pos, r.currPkg, name0, nil)
	t := types2.NewTypeParam(tn, nil)
	// To handle recursive references to the typeparam within its
	// bound, save the partial type in tparamIndex before reading the bounds.
	id := ident{r.currPkg, name}
	r.p.tparamIndex[id] = t

	var implicit bool
	if r.p.exportVersion >= iexportVersionGo1_18 {
	implicit = r.bool()
	}
	constraint := r.typ()
	if implicit {
	iface, _ := constraint.(*types2.Interface)
	if iface == nil {
	errorf("non-interface constraint marked implicit")
	}
	iface.MarkImplicit()
	}
	// The constraint type may not be complete, if we
	// are in the middle of a type recursion involving type
	// constraints. So, we defer SetConstraint until we have
	// completely set up all types in ImportData.
	r.p.later = append(r.p.later, setConstraintArgs{t: t, constraint: constraint})

	case 'V':
	typ := r.typ()

	r.declare(types2.NewVar(pos, r.currPkg, name, typ))

	default:
	errorf("unexpected tag: %v", tag)
	}
	}

	func (r *importReader) declare(obj types2.Object) {
	obj.Pkg().Scope().Insert(obj)
	}

	func (r *importReader) value() (typ types2.Type, val constant.Value) {
	typ = r.typ()
	if r.p.exportVersion >= iexportVersionGo1_18 {
	// TODO: add support for using the kind
	_ = constant.Kind(r.int64())
	}

	switch b := typ.Underlying().(*types2.Basic); b.Info() & types2.IsConstType {
	case types2.IsBoolean:
	val = constant.MakeBool(r.bool())

	case types2.IsString:
	val = constant.MakeString(r.string())

	case types2.IsInteger:
	var x big.Int
	r.mpint(&x, b)
	val = constant.Make(&x)

	case types2.IsFloat:
	val = r.mpfloat(b)

	case types2.IsComplex:
	re := r.mpfloat(b)
	im := r.mpfloat(b)
	val = constant.BinaryOp(re, token.ADD, constant.MakeImag(im))

	default:
	errorf("unexpected type %v", typ) // panics
	panic("unreachable")
	}

	return
	}

	func intSize(b *types2.Basic) (signed bool, maxBytes uint) {
	if (b.Info() & types2.IsUntyped) != 0 {
	return true, 64
	}

	switch b.Kind() {
	case types2.Float32, types2.Complex64:
	return true, 3
	case types2.Float64, types2.Complex128:
	return true, 7
	}

	signed = (b.Info() & types2.IsUnsigned) == 0
	switch b.Kind() {
	case types2.Int8, types2.Uint8:
	maxBytes = 1
	case types2.Int16, types2.Uint16:
	maxBytes = 2
	case types2.Int32, types2.Uint32:
	maxBytes = 4
	default:
	maxBytes = 8
	}

	return
	}

	func (r importReader) mpint(x big.Int, typ *types2.Basic) {
	signed, maxBytes := intSize(typ)

	maxSmall := 256 - maxBytes
	if signed {
	maxSmall = 256 - 2*maxBytes
	}
	if maxBytes == 1 {
	maxSmall = 256
	}

	n, _ := r.declReader.ReadByte()
	if uint(n) < maxSmall {
	v := int64(n)
	if signed {
	v >>= 1
	if n&1 != 0 {
	v = ^v
	}
	}
	x.SetInt64(v)
	return
	}

	v := -n
	if signed {
	v = -(n &^ 1) >> 1
	}
	if v < 1 \|\| uint(v) > maxBytes {
	errorf("weird decoding: %v, %v => %v", n, signed, v)
	}
	b := make([]byte, v)
	io.ReadFull(&r.declReader, b)
	x.SetBytes(b)
	if signed && n&1 != 0 {
	x.Neg(x)
	}
	}

	func (r importReader) mpfloat(typ types2.Basic) constant.Value {
	var mant big.Int
	r.mpint(&mant, typ)
	var f big.Float
	f.SetInt(&mant)
	if f.Sign() != 0 {
	f.SetMantExp(&f, int(r.int64()))
	}
	return constant.Make(&f)
	}

	func (r *importReader) ident() string {
	return r.string()
	}

	func (r importReader) qualifiedIdent() (types2.Package, string) {
	name := r.string()
	pkg := r.pkg()
	return pkg, name
	}

	func (r *importReader) pos() syntax.Pos {
	if r.p.version >= 1 {
	r.posv1()
	} else {
	r.posv0()
	}

	if (r.prevPosBase == nil \|\| r.prevPosBase.Filename() == "") && r.prevLine == 0 && r.prevColumn == 0 {
	return syntax.Pos{}
	}

	return syntax.MakePos(r.prevPosBase, uint(r.prevLine), uint(r.prevColumn))
	}

	func (r *importReader) posv0() {
	delta := r.int64()
	if delta != deltaNewFile {
	r.prevLine += delta
	} else if l := r.int64(); l == -1 {
	r.prevLine += deltaNewFile
	} else {
	r.prevPosBase = r.posBase()
	r.prevLine = l
	}
	}

	func (r *importReader) posv1() {
	delta := r.int64()
	r.prevColumn += delta >> 1
	if delta&1 != 0 {
	delta = r.int64()
	r.prevLine += delta >> 1
	if delta&1 != 0 {
	r.prevPosBase = r.posBase()
	}
	}
	}

	func (r *importReader) typ() types2.Type {
	return r.p.typAt(r.uint64(), nil)
	}

	func isInterface(t types2.Type) bool {
	_, ok := t.(*types2.Interface)
	return ok
	}

	func (r importReader) pkg() types2.Package { return r.p.pkgAt(r.uint64()) }
	func (r *importReader) string() string { return r.p.stringAt(r.uint64()) }
	func (r importReader) posBase() syntax.PosBase { return r.p.posBaseAt(r.uint64()) }

	func (r importReader) doType(base types2.Named) types2.Type {
	switch k := r.kind(); k {
	default:
	errorf("unexpected kind tag in %q: %v", r.p.ipath, k)
	return nil

	case definedType:
	pkg, name := r.qualifiedIdent()
	r.p.doDecl(pkg, name)
	return pkg.Scope().Lookup(name).(*types2.TypeName).Type()
	case pointerType:
	return types2.NewPointer(r.typ())
	case sliceType:
	return types2.NewSlice(r.typ())
	case arrayType:
	n := r.uint64()
	return types2.NewArray(r.typ(), int64(n))
	case chanType:
	dir := chanDir(int(r.uint64()))
	return types2.NewChan(dir, r.typ())
	case mapType:
	return types2.NewMap(r.typ(), r.typ())
	case signatureType:
	r.currPkg = r.pkg()
	return r.signature(nil, nil, nil)

	case structType:
	r.currPkg = r.pkg()

	fields := make([]*types2.Var, r.uint64())
	tags := make([]string, len(fields))
	for i := range fields {
	fpos := r.pos()
	fname := r.ident()
	ftyp := r.typ()
	emb := r.bool()
	tag := r.string()

	fields[i] = types2.NewField(fpos, r.currPkg, fname, ftyp, emb)
	tags[i] = tag
	}
	return types2.NewStruct(fields, tags)

	case interfaceType:
	r.currPkg = r.pkg()

	embeddeds := make([]types2.Type, r.uint64())
	for i := range embeddeds {
	_ = r.pos()
	embeddeds[i] = r.typ()
	}

	methods := make([]*types2.Func, r.uint64())
	for i := range methods {
	mpos := r.pos()
	mname := r.ident()

	// TODO(mdempsky): Matches bimport.go, but I
	// don't agree with this.
	var recv *types2.Var
	if base != nil {
	recv = types2.NewVar(syntax.Pos{}, r.currPkg, "", base)
	}

	msig := r.signature(recv, nil, nil)
	methods[i] = types2.NewFunc(mpos, r.currPkg, mname, msig)
	}

	typ := types2.NewInterfaceType(methods, embeddeds)
	r.p.interfaceList = append(r.p.interfaceList, typ)
	return typ

	case typeParamType:
	if r.p.exportVersion < iexportVersionGenerics {
	errorf("unexpected type param type")
	}
	pkg, name := r.qualifiedIdent()
	id := ident{pkg, name}
	if t, ok := r.p.tparamIndex[id]; ok {
	// We're already in the process of importing this typeparam.
	return t
	}
	// Otherwise, import the definition of the typeparam now.
	r.p.doDecl(pkg, name)
	return r.p.tparamIndex[id]

	case instanceType:
	if r.p.exportVersion < iexportVersionGenerics {
	errorf("unexpected instantiation type")
	}
	// pos does not matter for instances: they are positioned on the original
	// type.
	_ = r.pos()
	len := r.uint64()
	targs := make([]types2.Type, len)
	for i := range targs {
	targs[i] = r.typ()
	}
	baseType := r.typ()
	// The imported instantiated type doesn't include any methods, so
	// we must always use the methods of the base (orig) type.
	// TODO provide a non-nil *Context
	t, _ := types2.Instantiate(nil, baseType, targs, false)
	return t

	case unionType:
	if r.p.exportVersion < iexportVersionGenerics {
	errorf("unexpected instantiation type")
	}
	terms := make([]*types2.Term, r.uint64())
	for i := range terms {
	terms[i] = types2.NewTerm(r.bool(), r.typ())
	}
	return types2.NewUnion(terms)
	}
	}

	func (r *importReader) kind() itag {
	return itag(r.uint64())
	}

	func (r importReader) signature(recv types2.Var, rparams, tparams []types2.TypeParam) types2.Signature {
	params := r.paramList()
	results := r.paramList()
	variadic := params.Len() > 0 && r.bool()
	return types2.NewSignatureType(recv, rparams, tparams, params, results, variadic)
	}

	func (r importReader) tparamList() []types2.TypeParam {
	n := r.uint64()
	if n == 0 {
	return nil
	}
	xs := make([]*types2.TypeParam, n)
	for i := range xs {
	xs[i] = r.typ().(*types2.TypeParam)
	}
	return xs
	}

	func (r importReader) paramList() types2.Tuple {
	xs := make([]*types2.Var, r.uint64())
	for i := range xs {
	xs[i] = r.param()
	}
	return types2.NewTuple(xs...)
	}

	func (r importReader) param() types2.Var {
	pos := r.pos()
	name := r.ident()
	typ := r.typ()
	return types2.NewParam(pos, r.currPkg, name, typ)
	}

	func (r *importReader) bool() bool {
	return r.uint64() != 0
	}

	func (r *importReader) int64() int64 {
	n, err := binary.ReadVarint(&r.declReader)
	if err != nil {
	errorf("readVarint: %v", err)
	}
	return n
	}

	func (r *importReader) uint64() uint64 {
	n, err := binary.ReadUvarint(&r.declReader)
	if err != nil {
	errorf("readUvarint: %v", err)
	}
	return n
	}

	func (r *importReader) byte() byte {
	x, err := r.declReader.ReadByte()
	if err != nil {
	errorf("declReader.ReadByte: %v", err)
	}
	return x
	}

	func baseType(typ types2.Type) *types2.Named {
	// pointer receivers are never types2.Named types
	if p, _ := typ.(*types2.Pointer); p != nil {
	typ = p.Elem()
	}
	// receiver base types are always (possibly generic) types2.Named types
	n, _ := typ.(*types2.Named)
	return n
	}