internal/lsp/analysis/stubmethods/stubmethods.go - tools - Git at Google

 // Copyright 2022 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 stubmethods

 import (
 	"bytes"
 	"fmt"
 	"go/ast"
 	"go/format"
 	"go/token"
 	"go/types"
 	"strconv"
 	"strings"

 	"golang.org/x/tools/go/analysis"
 	"golang.org/x/tools/go/analysis/passes/inspect"
 	"golang.org/x/tools/go/ast/astutil"
 	"golang.org/x/tools/internal/analysisinternal"
 	"golang.org/x/tools/internal/typesinternal"
 )

 const Doc = `stub methods analyzer

 This analyzer generates method stubs for concrete types
 in order to implement a target interface`

 var Analyzer = &analysis.Analyzer{
 	Name:             "stubmethods",
 	Doc:              Doc,
 	Requires:         []*analysis.Analyzer{inspect.Analyzer},
 	Run:              run,
 	RunDespiteErrors: true,
 }

 func run(pass *analysis.Pass) (interface{}, error) {
 	for _, err := range analysisinternal.GetTypeErrors(pass) {
 		ifaceErr := strings.Contains(err.Msg, "missing method") || strings.HasPrefix(err.Msg, "cannot convert")
 		if !ifaceErr {
 			continue
 		}
 		var file *ast.File
 		for _, f := range pass.Files {
 			if f.Pos() <= err.Pos && err.Pos < f.End() {
 				file = f
 				break
 			}
 		}
 		if file == nil {
 			continue
 		}
 		// Get the end position of the error.
 		_, _, endPos, ok := typesinternal.ReadGo116ErrorData(err)
 		if !ok {
 			var buf bytes.Buffer
 			if err := format.Node(&buf, pass.Fset, file); err != nil {
 				continue
 			}
 			endPos = analysisinternal.TypeErrorEndPos(pass.Fset, buf.Bytes(), err.Pos)
 		}
 		path, _ := astutil.PathEnclosingInterval(file, err.Pos, endPos)
 		si := GetStubInfo(pass.TypesInfo, path, err.Pos)
 		if si == nil {
 			continue
 		}
 		qf := RelativeToFiles(si.Concrete.Obj().Pkg(), file, nil, nil)
 		pass.Report(analysis.Diagnostic{
 			Pos:     err.Pos,
 			End:     endPos,
 			Message: fmt.Sprintf("Implement %s", types.TypeString(si.Interface.Type(), qf)),
 		})
 	}
 	return nil, nil
 }

 // StubInfo represents a concrete type
 // that wants to stub out an interface type
 type StubInfo struct {
 	// Interface is the interface that the client wants to implement.
 	// When the interface is defined, the underlying object will be a TypeName.
 	// Note that we keep track of types.Object instead of types.Type in order
 	// to keep a reference to the declaring object's package and the ast file
 	// in the case where the concrete type file requires a new import that happens to be renamed
 	// in the interface file.
 	// TODO(marwan-at-work): implement interface literals.
 	Interface types.Object
 	Concrete  *types.Named
 	Pointer   bool
 }

 // GetStubInfo determines whether the "missing method error"
 // can be used to deduced what the concrete and interface types are.
 func GetStubInfo(ti *types.Info, path []ast.Node, pos token.Pos) *StubInfo {
 	for _, n := range path {
 		switch n := n.(type) {
 		case *ast.ValueSpec:
 			return fromValueSpec(ti, n, pos)
 		case *ast.ReturnStmt:
 			// An error here may not indicate a real error the user should know about, but it may.
 			// Therefore, it would be best to log it out for debugging/reporting purposes instead of ignoring
 			// it. However, event.Log takes a context which is not passed via the analysis package.
 			// TODO(marwan-at-work): properly log this error.
 			si, _ := fromReturnStmt(ti, pos, path, n)
 			return si
 		case *ast.AssignStmt:
 			return fromAssignStmt(ti, n, pos)
 		case *ast.CallExpr:
 			// Note that some call expressions don't carry the interface type
 			// because they don't point to a function or method declaration elsewhere.
 			// For eaxmple, "var Interface = (*Concrete)(nil)". In that case, continue
 			// this loop to encounter other possibilities such as *ast.ValueSpec or others.
 			si := fromCallExpr(ti, pos, n)
 			if si != nil {
 				return si
 			}
 		}
 	}
 	return nil
 }

 // fromCallExpr tries to find an *ast.CallExpr's function declaration and
 // analyzes a function call's signature against the passed in parameter to deduce
 // the concrete and interface types.
 func fromCallExpr(ti *types.Info, pos token.Pos, ce *ast.CallExpr) *StubInfo {
 	paramIdx := -1
 	for i, p := range ce.Args {
 		if pos >= p.Pos() && pos <= p.End() {
 			paramIdx = i
 			break
 		}
 	}
 	if paramIdx == -1 {
 		return nil
 	}
 	p := ce.Args[paramIdx]
 	concObj, pointer := concreteType(p, ti)
 	if concObj == nil || concObj.Obj().Pkg() == nil {
 		return nil
 	}
 	tv, ok := ti.Types[ce.Fun]
 	if !ok {
 		return nil
 	}
 	sig, ok := tv.Type.(*types.Signature)
 	if !ok {
 		return nil
 	}
 	sigVar := sig.Params().At(paramIdx)
 	iface := ifaceObjFromType(sigVar.Type())
 	if iface == nil {
 		return nil
 	}
 	return &StubInfo{
 		Concrete:  concObj,
 		Pointer:   pointer,
 		Interface: iface,
 	}
 }

 // fromReturnStmt analyzes a "return" statement to extract
 // a concrete type that is trying to be returned as an interface type.
 //
 // For example, func() io.Writer { return myType{} }
 // would return StubInfo with the interface being io.Writer and the concrete type being myType{}.
 func fromReturnStmt(ti *types.Info, pos token.Pos, path []ast.Node, rs *ast.ReturnStmt) (*StubInfo, error) {
 	returnIdx := -1
 	for i, r := range rs.Results {
 		if pos >= r.Pos() && pos <= r.End() {
 			returnIdx = i
 		}
 	}
 	if returnIdx == -1 {
 		return nil, fmt.Errorf("pos %d not within return statement bounds: [%d-%d]", pos, rs.Pos(), rs.End())
 	}
 	concObj, pointer := concreteType(rs.Results[returnIdx], ti)
 	if concObj == nil || concObj.Obj().Pkg() == nil {
 		return nil, nil
 	}
 	ef := enclosingFunction(path, ti)
 	if ef == nil {
 		return nil, fmt.Errorf("could not find the enclosing function of the return statement")
 	}
 	iface := ifaceType(ef.Results.List[returnIdx].Type, ti)
 	if iface == nil {
 		return nil, nil
 	}
 	return &StubInfo{
 		Concrete:  concObj,
 		Pointer:   pointer,
 		Interface: iface,
 	}, nil
 }

 // fromValueSpec returns *StubInfo from a variable declaration such as
 // var x io.Writer = &T{}
 func fromValueSpec(ti *types.Info, vs *ast.ValueSpec, pos token.Pos) *StubInfo {
 	var idx int
 	for i, vs := range vs.Values {
 		if pos >= vs.Pos() && pos <= vs.End() {
 			idx = i
 			break
 		}
 	}

 	valueNode := vs.Values[idx]
 	ifaceNode := vs.Type
 	callExp, ok := valueNode.(*ast.CallExpr)
 	// if the ValueSpec is `var _ = myInterface(...)`
 	// as opposed to `var _ myInterface = ...`
 	if ifaceNode == nil && ok && len(callExp.Args) == 1 {
 		ifaceNode = callExp.Fun
 		valueNode = callExp.Args[0]
 	}
 	concObj, pointer := concreteType(valueNode, ti)
 	if concObj == nil || concObj.Obj().Pkg() == nil {
 		return nil
 	}
 	ifaceObj := ifaceType(ifaceNode, ti)
 	if ifaceObj == nil {
 		return nil
 	}
 	return &StubInfo{
 		Concrete:  concObj,
 		Interface: ifaceObj,
 		Pointer:   pointer,
 	}
 }

 // fromAssignStmt returns *StubInfo from a variable re-assignment such as
 // var x io.Writer
 // x = &T{}
 func fromAssignStmt(ti *types.Info, as *ast.AssignStmt, pos token.Pos) *StubInfo {
 	idx := -1
 	var lhs, rhs ast.Expr
 	// Given a re-assignment interface conversion error,
 	// the compiler error shows up on the right hand side of the expression.
 	// For example, x = &T{} where x is io.Writer highlights the error
 	// under "&T{}" and not "x".
 	for i, hs := range as.Rhs {
 		if pos >= hs.Pos() && pos <= hs.End() {
 			idx = i
 			break
 		}
 	}
 	if idx == -1 {
 		return nil
 	}
 	// Technically, this should never happen as
 	// we would get a "cannot assign N values to M variables"
 	// before we get an interface conversion error. Nonetheless,
 	// guard against out of range index errors.
 	if idx >= len(as.Lhs) {
 		return nil
 	}
 	lhs, rhs = as.Lhs[idx], as.Rhs[idx]
 	ifaceObj := ifaceType(lhs, ti)
 	if ifaceObj == nil {
 		return nil
 	}
 	concType, pointer := concreteType(rhs, ti)
 	if concType == nil || concType.Obj().Pkg() == nil {
 		return nil
 	}
 	return &StubInfo{
 		Concrete:  concType,
 		Interface: ifaceObj,
 		Pointer:   pointer,
 	}
 }

 // RelativeToFiles returns a types.Qualifier that formats package names
 // according to the files where the concrete and interface types are defined.
 //
 // This is similar to types.RelativeTo except if a file imports the package with a different name,
 // then it will use it. And if the file does import the package but it is ignored,
 // then it will return the original name. It also prefers package names in ifaceFile in case
 // an import is missing from concFile but is present in ifaceFile.
 //
 // Additionally, if missingImport is not nil, the function will be called whenever the concFile
 // is presented with a package that is not imported. This is useful so that as types.TypeString is
 // formatting a function signature, it is identifying packages that will need to be imported when
 // stubbing an interface.
 func RelativeToFiles(concPkg *types.Package, concFile, ifaceFile *ast.File, missingImport func(name, path string)) types.Qualifier {
 	return func(other *types.Package) string {
 		if other == concPkg {
 			return ""
 		}

 		// Check if the concrete file already has the given import,
 		// if so return the default package name or the renamed import statement.
 		for _, imp := range concFile.Imports {
 			impPath, _ := strconv.Unquote(imp.Path.Value)
 			isIgnored := imp.Name != nil && (imp.Name.Name == "." || imp.Name.Name == "_")
 			if impPath == other.Path() && !isIgnored {
 				importName := other.Name()
 				if imp.Name != nil {
 					importName = imp.Name.Name
 				}
 				return importName
 			}
 		}

 		// If the concrete file does not have the import, check if the package
 		// is renamed in the interface file and prefer that.
 		var importName string
 		if ifaceFile != nil {
 			for _, imp := range ifaceFile.Imports {
 				impPath, _ := strconv.Unquote(imp.Path.Value)
 				isIgnored := imp.Name != nil && (imp.Name.Name == "." || imp.Name.Name == "_")
 				if impPath == other.Path() && !isIgnored {
 					if imp.Name != nil && imp.Name.Name != concPkg.Name() {
 						importName = imp.Name.Name
 					}
 					break
 				}
 			}
 		}

 		if missingImport != nil {
 			missingImport(importName, other.Path())
 		}

 		// Up until this point, importName must stay empty when calling missingImport,
 		// otherwise we'd end up with `import time "time"` which doesn't look idiomatic.
 		if importName == "" {
 			importName = other.Name()
 		}
 		return importName
 	}
 }

 // ifaceType will try to extract the types.Object that defines
 // the interface given the ast.Expr where the "missing method"
 // or "conversion" errors happen.
 func ifaceType(n ast.Expr, ti *types.Info) types.Object {
 	tv, ok := ti.Types[n]
 	if !ok {
 		return nil
 	}
 	return ifaceObjFromType(tv.Type)
 }

 func ifaceObjFromType(t types.Type) types.Object {
 	named, ok := t.(*types.Named)
 	if !ok {
 		return nil
 	}
 	_, ok = named.Underlying().(*types.Interface)
 	if !ok {
 		return nil
 	}
 	// Interfaces defined in the "builtin" package return nil a Pkg().
 	// But they are still real interfaces that we need to make a special case for.
 	// Therefore, protect gopls from panicking if a new interface type was added in the future.
 	if named.Obj().Pkg() == nil && named.Obj().Name() != "error" {
 		return nil
 	}
 	return named.Obj()
 }

 // concreteType tries to extract the *types.Named that defines
 // the concrete type given the ast.Expr where the "missing method"
 // or "conversion" errors happened. If the concrete type is something
 // that cannot have methods defined on it (such as basic types), this
 // method will return a nil *types.Named. The second return parameter
 // is a boolean that indicates whether the concreteType was defined as a
 // pointer or value.
 func concreteType(n ast.Expr, ti *types.Info) (*types.Named, bool) {
 	tv, ok := ti.Types[n]
 	if !ok {
 		return nil, false
 	}
 	typ := tv.Type
 	ptr, isPtr := typ.(*types.Pointer)
 	if isPtr {
 		typ = ptr.Elem()
 	}
 	named, ok := typ.(*types.Named)
 	if !ok {
 		return nil, false
 	}
 	return named, isPtr
 }

 // enclosingFunction returns the signature and type of the function
 // enclosing the given position.
 func enclosingFunction(path []ast.Node, info *types.Info) *ast.FuncType {
 	for _, node := range path {
 		switch t := node.(type) {
 		case *ast.FuncDecl:
 			if _, ok := info.Defs[t.Name]; ok {
 				return t.Type
 			}
 		case *ast.FuncLit:
 			if _, ok := info.Types[t]; ok {
 				return t.Type
 			}
 		}
 	}
 	return nil
 }
	// Copyright 2022 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 stubmethods

	import (
	"bytes"
	"fmt"
	"go/ast"
	"go/format"
	"go/token"
	"go/types"
	"strconv"
	"strings"

	"golang.org/x/tools/go/analysis"
	"golang.org/x/tools/go/analysis/passes/inspect"
	"golang.org/x/tools/go/ast/astutil"
	"golang.org/x/tools/internal/analysisinternal"
	"golang.org/x/tools/internal/typesinternal"
	)

	const Doc = `stub methods analyzer

	This analyzer generates method stubs for concrete types
	in order to implement a target interface`

	var Analyzer = &analysis.Analyzer{
	Name: "stubmethods",
	Doc: Doc,
	Requires: []*analysis.Analyzer{inspect.Analyzer},
	Run: run,
	RunDespiteErrors: true,
	}

	func run(pass *analysis.Pass) (interface{}, error) {
	for _, err := range analysisinternal.GetTypeErrors(pass) {
	ifaceErr := strings.Contains(err.Msg, "missing method") \|\| strings.HasPrefix(err.Msg, "cannot convert")
	if !ifaceErr {
	continue
	}
	var file *ast.File
	for _, f := range pass.Files {
	if f.Pos() <= err.Pos && err.Pos < f.End() {
	file = f
	break
	}
	}
	if file == nil {
	continue
	}
	// Get the end position of the error.
	_, _, endPos, ok := typesinternal.ReadGo116ErrorData(err)
	if !ok {
	var buf bytes.Buffer
	if err := format.Node(&buf, pass.Fset, file); err != nil {
	continue
	}
	endPos = analysisinternal.TypeErrorEndPos(pass.Fset, buf.Bytes(), err.Pos)
	}
	path, _ := astutil.PathEnclosingInterval(file, err.Pos, endPos)
	si := GetStubInfo(pass.TypesInfo, path, err.Pos)
	if si == nil {
	continue
	}
	qf := RelativeToFiles(si.Concrete.Obj().Pkg(), file, nil, nil)
	pass.Report(analysis.Diagnostic{
	Pos: err.Pos,
	End: endPos,
	Message: fmt.Sprintf("Implement %s", types.TypeString(si.Interface.Type(), qf)),
	})
	}
	return nil, nil
	}

	// StubInfo represents a concrete type
	// that wants to stub out an interface type
	type StubInfo struct {
	// Interface is the interface that the client wants to implement.
	// When the interface is defined, the underlying object will be a TypeName.
	// Note that we keep track of types.Object instead of types.Type in order
	// to keep a reference to the declaring object's package and the ast file
	// in the case where the concrete type file requires a new import that happens to be renamed
	// in the interface file.
	// TODO(marwan-at-work): implement interface literals.
	Interface types.Object
	Concrete *types.Named
	Pointer bool
	}

	// GetStubInfo determines whether the "missing method error"
	// can be used to deduced what the concrete and interface types are.
	func GetStubInfo(ti types.Info, path []ast.Node, pos token.Pos) StubInfo {
	for _, n := range path {
	switch n := n.(type) {
	case *ast.ValueSpec:
	return fromValueSpec(ti, n, pos)
	case *ast.ReturnStmt:
	// An error here may not indicate a real error the user should know about, but it may.
	// Therefore, it would be best to log it out for debugging/reporting purposes instead of ignoring
	// it. However, event.Log takes a context which is not passed via the analysis package.
	// TODO(marwan-at-work): properly log this error.
	si, _ := fromReturnStmt(ti, pos, path, n)
	return si
	case *ast.AssignStmt:
	return fromAssignStmt(ti, n, pos)
	case *ast.CallExpr:
	// Note that some call expressions don't carry the interface type
	// because they don't point to a function or method declaration elsewhere.
	// For eaxmple, "var Interface = (*Concrete)(nil)". In that case, continue
	// this loop to encounter other possibilities such as *ast.ValueSpec or others.
	si := fromCallExpr(ti, pos, n)
	if si != nil {
	return si
	}
	}
	}
	return nil
	}

	// fromCallExpr tries to find an *ast.CallExpr's function declaration and
	// analyzes a function call's signature against the passed in parameter to deduce
	// the concrete and interface types.
	func fromCallExpr(ti types.Info, pos token.Pos, ce ast.CallExpr) *StubInfo {
	paramIdx := -1
	for i, p := range ce.Args {
	if pos >= p.Pos() && pos <= p.End() {
	paramIdx = i
	break
	}
	}
	if paramIdx == -1 {
	return nil
	}
	p := ce.Args[paramIdx]
	concObj, pointer := concreteType(p, ti)
	if concObj == nil \|\| concObj.Obj().Pkg() == nil {
	return nil
	}
	tv, ok := ti.Types[ce.Fun]
	if !ok {
	return nil
	}
	sig, ok := tv.Type.(*types.Signature)
	if !ok {
	return nil
	}
	sigVar := sig.Params().At(paramIdx)
	iface := ifaceObjFromType(sigVar.Type())
	if iface == nil {
	return nil
	}
	return &StubInfo{
	Concrete: concObj,
	Pointer: pointer,
	Interface: iface,
	}
	}

	// fromReturnStmt analyzes a "return" statement to extract
	// a concrete type that is trying to be returned as an interface type.
	//
	// For example, func() io.Writer { return myType{} }
	// would return StubInfo with the interface being io.Writer and the concrete type being myType{}.
	func fromReturnStmt(ti types.Info, pos token.Pos, path []ast.Node, rs ast.ReturnStmt) (*StubInfo, error) {
	returnIdx := -1
	for i, r := range rs.Results {
	if pos >= r.Pos() && pos <= r.End() {
	returnIdx = i
	}
	}
	if returnIdx == -1 {
	return nil, fmt.Errorf("pos %d not within return statement bounds: [%d-%d]", pos, rs.Pos(), rs.End())
	}
	concObj, pointer := concreteType(rs.Results[returnIdx], ti)
	if concObj == nil \|\| concObj.Obj().Pkg() == nil {
	return nil, nil
	}
	ef := enclosingFunction(path, ti)
	if ef == nil {
	return nil, fmt.Errorf("could not find the enclosing function of the return statement")
	}
	iface := ifaceType(ef.Results.List[returnIdx].Type, ti)
	if iface == nil {
	return nil, nil
	}
	return &StubInfo{
	Concrete: concObj,
	Pointer: pointer,
	Interface: iface,
	}, nil
	}

	// fromValueSpec returns *StubInfo from a variable declaration such as
	// var x io.Writer = &T{}
	func fromValueSpec(ti types.Info, vs ast.ValueSpec, pos token.Pos) *StubInfo {
	var idx int
	for i, vs := range vs.Values {
	if pos >= vs.Pos() && pos <= vs.End() {
	idx = i
	break
	}
	}

	valueNode := vs.Values[idx]
	ifaceNode := vs.Type
	callExp, ok := valueNode.(*ast.CallExpr)
	// if the ValueSpec is `var _ = myInterface(...)`
	// as opposed to `var _ myInterface = ...`
	if ifaceNode == nil && ok && len(callExp.Args) == 1 {
	ifaceNode = callExp.Fun
	valueNode = callExp.Args[0]
	}
	concObj, pointer := concreteType(valueNode, ti)
	if concObj == nil \|\| concObj.Obj().Pkg() == nil {
	return nil
	}
	ifaceObj := ifaceType(ifaceNode, ti)
	if ifaceObj == nil {
	return nil
	}
	return &StubInfo{
	Concrete: concObj,
	Interface: ifaceObj,
	Pointer: pointer,
	}
	}

	// fromAssignStmt returns *StubInfo from a variable re-assignment such as
	// var x io.Writer
	// x = &T{}
	func fromAssignStmt(ti types.Info, as ast.AssignStmt, pos token.Pos) *StubInfo {
	idx := -1
	var lhs, rhs ast.Expr
	// Given a re-assignment interface conversion error,
	// the compiler error shows up on the right hand side of the expression.
	// For example, x = &T{} where x is io.Writer highlights the error
	// under "&T{}" and not "x".
	for i, hs := range as.Rhs {
	if pos >= hs.Pos() && pos <= hs.End() {
	idx = i
	break
	}
	}
	if idx == -1 {
	return nil
	}
	// Technically, this should never happen as
	// we would get a "cannot assign N values to M variables"
	// before we get an interface conversion error. Nonetheless,
	// guard against out of range index errors.
	if idx >= len(as.Lhs) {
	return nil
	}
	lhs, rhs = as.Lhs[idx], as.Rhs[idx]
	ifaceObj := ifaceType(lhs, ti)
	if ifaceObj == nil {
	return nil
	}
	concType, pointer := concreteType(rhs, ti)
	if concType == nil \|\| concType.Obj().Pkg() == nil {
	return nil
	}
	return &StubInfo{
	Concrete: concType,
	Interface: ifaceObj,
	Pointer: pointer,
	}
	}

	// RelativeToFiles returns a types.Qualifier that formats package names
	// according to the files where the concrete and interface types are defined.
	//
	// This is similar to types.RelativeTo except if a file imports the package with a different name,
	// then it will use it. And if the file does import the package but it is ignored,
	// then it will return the original name. It also prefers package names in ifaceFile in case
	// an import is missing from concFile but is present in ifaceFile.
	//
	// Additionally, if missingImport is not nil, the function will be called whenever the concFile
	// is presented with a package that is not imported. This is useful so that as types.TypeString is
	// formatting a function signature, it is identifying packages that will need to be imported when
	// stubbing an interface.
	func RelativeToFiles(concPkg types.Package, concFile, ifaceFile ast.File, missingImport func(name, path string)) types.Qualifier {
	return func(other *types.Package) string {
	if other == concPkg {
	return ""
	}

	// Check if the concrete file already has the given import,
	// if so return the default package name or the renamed import statement.
	for _, imp := range concFile.Imports {
	impPath, _ := strconv.Unquote(imp.Path.Value)
	isIgnored := imp.Name != nil && (imp.Name.Name == "." \|\| imp.Name.Name == "_")
	if impPath == other.Path() && !isIgnored {
	importName := other.Name()
	if imp.Name != nil {
	importName = imp.Name.Name
	}
	return importName
	}
	}

	// If the concrete file does not have the import, check if the package
	// is renamed in the interface file and prefer that.
	var importName string
	if ifaceFile != nil {
	for _, imp := range ifaceFile.Imports {
	impPath, _ := strconv.Unquote(imp.Path.Value)
	isIgnored := imp.Name != nil && (imp.Name.Name == "." \|\| imp.Name.Name == "_")
	if impPath == other.Path() && !isIgnored {
	if imp.Name != nil && imp.Name.Name != concPkg.Name() {
	importName = imp.Name.Name
	}
	break
	}
	}
	}

	if missingImport != nil {
	missingImport(importName, other.Path())
	}

	// Up until this point, importName must stay empty when calling missingImport,
	// otherwise we'd end up with `import time "time"` which doesn't look idiomatic.
	if importName == "" {
	importName = other.Name()
	}
	return importName
	}
	}

	// ifaceType will try to extract the types.Object that defines
	// the interface given the ast.Expr where the "missing method"
	// or "conversion" errors happen.
	func ifaceType(n ast.Expr, ti *types.Info) types.Object {
	tv, ok := ti.Types[n]
	if !ok {
	return nil
	}
	return ifaceObjFromType(tv.Type)
	}

	func ifaceObjFromType(t types.Type) types.Object {
	named, ok := t.(*types.Named)
	if !ok {
	return nil
	}
	_, ok = named.Underlying().(*types.Interface)
	if !ok {
	return nil
	}
	// Interfaces defined in the "builtin" package return nil a Pkg().
	// But they are still real interfaces that we need to make a special case for.
	// Therefore, protect gopls from panicking if a new interface type was added in the future.
	if named.Obj().Pkg() == nil && named.Obj().Name() != "error" {
	return nil
	}
	return named.Obj()
	}

	// concreteType tries to extract the *types.Named that defines
	// the concrete type given the ast.Expr where the "missing method"
	// or "conversion" errors happened. If the concrete type is something
	// that cannot have methods defined on it (such as basic types), this
	// method will return a nil *types.Named. The second return parameter
	// is a boolean that indicates whether the concreteType was defined as a
	// pointer or value.
	func concreteType(n ast.Expr, ti types.Info) (types.Named, bool) {
	tv, ok := ti.Types[n]
	if !ok {
	return nil, false
	}
	typ := tv.Type
	ptr, isPtr := typ.(*types.Pointer)
	if isPtr {
	typ = ptr.Elem()
	}
	named, ok := typ.(*types.Named)
	if !ok {
	return nil, false
	}
	return named, isPtr
	}

	// enclosingFunction returns the signature and type of the function
	// enclosing the given position.
	func enclosingFunction(path []ast.Node, info types.Info) ast.FuncType {
	for _, node := range path {
	switch t := node.(type) {
	case *ast.FuncDecl:
	if _, ok := info.Defs[t.Name]; ok {
	return t.Type
	}
	case *ast.FuncLit:
	if _, ok := info.Types[t]; ok {
	return t.Type
	}
	}
	}
	return nil
	}