gopls/internal/lsp/source/identifier.go - tools - 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.

 package source

 import (
 	"errors"
 	"go/ast"
 	"go/types"

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

 // ErrNoIdentFound is error returned when no identifier is found at a particular position
 var ErrNoIdentFound = errors.New("no identifier found")

 // inferredSignature determines the resolved non-generic signature for an
 // identifier in an instantiation expression.
 //
 // If no such signature exists, it returns nil.
 func inferredSignature(info *types.Info, id *ast.Ident) *types.Signature {
 	inst := typeparams.GetInstances(info)[id]
 	sig, _ := inst.Type.(*types.Signature)
 	return sig
 }

 func searchForEnclosing(info *types.Info, path []ast.Node) *types.TypeName {
 	for _, n := range path {
 		switch n := n.(type) {
 		case *ast.SelectorExpr:
 			if sel, ok := info.Selections[n]; ok {
 				recv := Deref(sel.Recv())

 				// Keep track of the last exported type seen.
 				var exported *types.TypeName
 				if named, ok := recv.(*types.Named); ok && named.Obj().Exported() {
 					exported = named.Obj()
 				}
 				// We don't want the last element, as that's the field or
 				// method itself.
 				for _, index := range sel.Index()[:len(sel.Index())-1] {
 					if r, ok := recv.Underlying().(*types.Struct); ok {
 						recv = Deref(r.Field(index).Type())
 						if named, ok := recv.(*types.Named); ok && named.Obj().Exported() {
 							exported = named.Obj()
 						}
 					}
 				}
 				return exported
 			}
 		}
 	}
 	return nil
 }

 // typeToObject returns the relevant type name for the given type, after
 // unwrapping pointers, arrays, slices, channels, and function signatures with
 // a single non-error result.
 func typeToObject(typ types.Type) *types.TypeName {
 	switch typ := typ.(type) {
 	case *types.Named:
 		// TODO(rfindley): this should use typeparams.NamedTypeOrigin.
 		return typ.Obj()
 	case *types.Pointer:
 		return typeToObject(typ.Elem())
 	case *types.Array:
 		return typeToObject(typ.Elem())
 	case *types.Slice:
 		return typeToObject(typ.Elem())
 	case *types.Chan:
 		return typeToObject(typ.Elem())
 	case *types.Signature:
 		// Try to find a return value of a named type. If there's only one
 		// such value, jump to its type definition.
 		var res *types.TypeName

 		results := typ.Results()
 		for i := 0; i < results.Len(); i++ {
 			obj := typeToObject(results.At(i).Type())
 			if obj == nil || hasErrorType(obj) {
 				// Skip builtins.
 				continue
 			}
 			if res != nil {
 				// The function/method must have only one return value of a named type.
 				return nil
 			}

 			res = obj
 		}
 		return res
 	default:
 		return nil
 	}
 }

 func hasErrorType(obj types.Object) bool {
 	return types.IsInterface(obj.Type()) && obj.Pkg() == nil && obj.Name() == "error"
 }

 // typeSwitchImplicits returns all the implicit type switch objects that
 // correspond to the leaf *ast.Ident. It also returns the original type
 // associated with the identifier (outside of a case clause).
 func typeSwitchImplicits(info *types.Info, path []ast.Node) ([]types.Object, types.Type) {
 	ident, _ := path[0].(*ast.Ident)
 	if ident == nil {
 		return nil, nil
 	}

 	var (
 		ts     *ast.TypeSwitchStmt
 		assign *ast.AssignStmt
 		cc     *ast.CaseClause
 		obj    = info.ObjectOf(ident)
 	)

 	// Walk our ancestors to determine if our leaf ident refers to a
 	// type switch variable, e.g. the "a" from "switch a := b.(type)".
 Outer:
 	for i := 1; i < len(path); i++ {
 		switch n := path[i].(type) {
 		case *ast.AssignStmt:
 			// Check if ident is the "a" in "a := foo.(type)". The "a" in
 			// this case has no types.Object, so check for ident equality.
 			if len(n.Lhs) == 1 && n.Lhs[0] == ident {
 				assign = n
 			}
 		case *ast.CaseClause:
 			// Check if ident is a use of "a" within a case clause. Each
 			// case clause implicitly maps "a" to a different types.Object,
 			// so check if ident's object is the case clause's implicit
 			// object.
 			if obj != nil && info.Implicits[n] == obj {
 				cc = n
 			}
 		case *ast.TypeSwitchStmt:
 			// Look for the type switch that owns our previously found
 			// *ast.AssignStmt or *ast.CaseClause.
 			if n.Assign == assign {
 				ts = n
 				break Outer
 			}

 			for _, stmt := range n.Body.List {
 				if stmt == cc {
 					ts = n
 					break Outer
 				}
 			}
 		}
 	}
 	if ts == nil {
 		return nil, nil
 	}
 	// Our leaf ident refers to a type switch variable. Fan out to the
 	// type switch's implicit case clause objects.
 	var objs []types.Object
 	for _, cc := range ts.Body.List {
 		if ccObj := info.Implicits[cc]; ccObj != nil {
 			objs = append(objs, ccObj)
 		}
 	}
 	// The right-hand side of a type switch should only have one
 	// element, and we need to track its type in order to generate
 	// hover information for implicit type switch variables.
 	var typ types.Type
 	if assign, ok := ts.Assign.(*ast.AssignStmt); ok && len(assign.Rhs) == 1 {
 		if rhs := assign.Rhs[0].(*ast.TypeAssertExpr); ok {
 			typ = info.TypeOf(rhs.X)
 		}
 	}
 	return objs, typ
 }
	// 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.

	package source

	import (
	"errors"
	"go/ast"
	"go/types"

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

	// ErrNoIdentFound is error returned when no identifier is found at a particular position
	var ErrNoIdentFound = errors.New("no identifier found")

	// inferredSignature determines the resolved non-generic signature for an
	// identifier in an instantiation expression.
	//
	// If no such signature exists, it returns nil.
	func inferredSignature(info types.Info, id ast.Ident) *types.Signature {
	inst := typeparams.GetInstances(info)[id]
	sig, _ := inst.Type.(*types.Signature)
	return sig
	}

	func searchForEnclosing(info types.Info, path []ast.Node) types.TypeName {
	for _, n := range path {
	switch n := n.(type) {
	case *ast.SelectorExpr:
	if sel, ok := info.Selections[n]; ok {
	recv := Deref(sel.Recv())

	// Keep track of the last exported type seen.
	var exported *types.TypeName
	if named, ok := recv.(*types.Named); ok && named.Obj().Exported() {
	exported = named.Obj()
	}
	// We don't want the last element, as that's the field or
	// method itself.
	for _, index := range sel.Index()[:len(sel.Index())-1] {
	if r, ok := recv.Underlying().(*types.Struct); ok {
	recv = Deref(r.Field(index).Type())
	if named, ok := recv.(*types.Named); ok && named.Obj().Exported() {
	exported = named.Obj()
	}
	}
	}
	return exported
	}
	}
	}
	return nil
	}

	// typeToObject returns the relevant type name for the given type, after
	// unwrapping pointers, arrays, slices, channels, and function signatures with
	// a single non-error result.
	func typeToObject(typ types.Type) *types.TypeName {
	switch typ := typ.(type) {
	case *types.Named:
	// TODO(rfindley): this should use typeparams.NamedTypeOrigin.
	return typ.Obj()
	case *types.Pointer:
	return typeToObject(typ.Elem())
	case *types.Array:
	return typeToObject(typ.Elem())
	case *types.Slice:
	return typeToObject(typ.Elem())
	case *types.Chan:
	return typeToObject(typ.Elem())
	case *types.Signature:
	// Try to find a return value of a named type. If there's only one
	// such value, jump to its type definition.
	var res *types.TypeName

	results := typ.Results()
	for i := 0; i < results.Len(); i++ {
	obj := typeToObject(results.At(i).Type())
	if obj == nil \|\| hasErrorType(obj) {
	// Skip builtins.
	continue
	}
	if res != nil {
	// The function/method must have only one return value of a named type.
	return nil
	}

	res = obj
	}
	return res
	default:
	return nil
	}
	}

	func hasErrorType(obj types.Object) bool {
	return types.IsInterface(obj.Type()) && obj.Pkg() == nil && obj.Name() == "error"
	}

	// typeSwitchImplicits returns all the implicit type switch objects that
	// correspond to the leaf *ast.Ident. It also returns the original type
	// associated with the identifier (outside of a case clause).
	func typeSwitchImplicits(info *types.Info, path []ast.Node) ([]types.Object, types.Type) {
	ident, _ := path[0].(*ast.Ident)
	if ident == nil {
	return nil, nil
	}

	var (
	ts *ast.TypeSwitchStmt
	assign *ast.AssignStmt
	cc *ast.CaseClause
	obj = info.ObjectOf(ident)
	)

	// Walk our ancestors to determine if our leaf ident refers to a
	// type switch variable, e.g. the "a" from "switch a := b.(type)".
	Outer:
	for i := 1; i < len(path); i++ {
	switch n := path[i].(type) {
	case *ast.AssignStmt:
	// Check if ident is the "a" in "a := foo.(type)". The "a" in
	// this case has no types.Object, so check for ident equality.
	if len(n.Lhs) == 1 && n.Lhs[0] == ident {
	assign = n
	}
	case *ast.CaseClause:
	// Check if ident is a use of "a" within a case clause. Each
	// case clause implicitly maps "a" to a different types.Object,
	// so check if ident's object is the case clause's implicit
	// object.
	if obj != nil && info.Implicits[n] == obj {
	cc = n
	}
	case *ast.TypeSwitchStmt:
	// Look for the type switch that owns our previously found
	// ast.AssignStmt or ast.CaseClause.
	if n.Assign == assign {
	ts = n
	break Outer
	}

	for _, stmt := range n.Body.List {
	if stmt == cc {
	ts = n
	break Outer
	}
	}
	}
	}
	if ts == nil {
	return nil, nil
	}
	// Our leaf ident refers to a type switch variable. Fan out to the
	// type switch's implicit case clause objects.
	var objs []types.Object
	for _, cc := range ts.Body.List {
	if ccObj := info.Implicits[cc]; ccObj != nil {
	objs = append(objs, ccObj)
	}
	}
	// The right-hand side of a type switch should only have one
	// element, and we need to track its type in order to generate
	// hover information for implicit type switch variables.
	var typ types.Type
	if assign, ok := ts.Assign.(*ast.AssignStmt); ok && len(assign.Rhs) == 1 {
	if rhs := assign.Rhs[0].(*ast.TypeAssertExpr); ok {
	typ = info.TypeOf(rhs.X)
	}
	}
	return objs, typ
	}