// Copyright 2020 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 analysisinternal exposes internal-only fields from go/analysis. package analysisinternal import ( "bytes" "fmt" "go/ast" "go/token" "go/types" "strings" "golang.org/x/tools/go/ast/astutil" ) var ( GetTypeErrors func(p interface{}) []types.Error SetTypeErrors func(p interface{}, errors []types.Error) ) func TypeErrorEndPos(fset *token.FileSet, src []byte, start token.Pos) token.Pos { // Get the end position for the type error. offset, end := fset.PositionFor(start, false).Offset, start if offset >= len(src) { return end } if width := bytes.IndexAny(src[offset:], " \n,():;[]+-*"); width > 0 { end = start + token.Pos(width) } return end } func ZeroValue(fset *token.FileSet, f *ast.File, pkg *types.Package, typ types.Type) ast.Expr { under := typ if n, ok := typ.(*types.Named); ok { under = n.Underlying() } switch u := under.(type) { case *types.Basic: switch { case u.Info()&types.IsNumeric != 0: return &ast.BasicLit{Kind: token.INT, Value: "0"} case u.Info()&types.IsBoolean != 0: return &ast.Ident{Name: "false"} case u.Info()&types.IsString != 0: return &ast.BasicLit{Kind: token.STRING, Value: `""`} default: panic("unknown basic type") } case *types.Chan, *types.Interface, *types.Map, *types.Pointer, *types.Signature, *types.Slice: return ast.NewIdent("nil") case *types.Struct: texpr := TypeExpr(fset, f, pkg, typ) // typ because we want the name here. if texpr == nil { return nil } return &ast.CompositeLit{ Type: texpr, } case *types.Array: texpr := TypeExpr(fset, f, pkg, u.Elem()) if texpr == nil { return nil } return &ast.CompositeLit{ Type: &ast.ArrayType{ Elt: texpr, Len: &ast.BasicLit{Kind: token.INT, Value: fmt.Sprintf("%v", u.Len())}, }, } } return nil } func TypeExpr(fset *token.FileSet, f *ast.File, pkg *types.Package, typ types.Type) ast.Expr { switch t := typ.(type) { case *types.Basic: switch t.Kind() { case types.UnsafePointer: return &ast.SelectorExpr{X: ast.NewIdent("unsafe"), Sel: ast.NewIdent("Pointer")} default: return ast.NewIdent(t.Name()) } case *types.Named: if t.Obj().Pkg() == nil { return nil } if t.Obj().Pkg() == pkg { return ast.NewIdent(t.Obj().Name()) } pkgName := t.Obj().Pkg().Name() // If the file already imports the package under another name, use that. for _, group := range astutil.Imports(fset, f) { for _, cand := range group { if strings.Trim(cand.Path.Value, `"`) == t.Obj().Pkg().Path() { if cand.Name != nil && cand.Name.Name != "" { pkgName = cand.Name.Name } } } } if pkgName == "." { return ast.NewIdent(t.Obj().Name()) } return &ast.SelectorExpr{ X: ast.NewIdent(pkgName), Sel: ast.NewIdent(t.Obj().Name()), } case *types.Pointer: return &ast.UnaryExpr{ Op: token.MUL, X: TypeExpr(fset, f, pkg, t.Elem()), } default: return nil // TODO: anonymous structs, but who does that } } type TypeErrorPass string const ( NoNewVars TypeErrorPass = "nonewvars" NoResultValues TypeErrorPass = "noresultvalues" UndeclaredName TypeErrorPass = "undeclaredname" ) // StmtToInsertVarBefore returns the ast.Stmt before which we can safely insert a new variable. // Some examples: // // Basic Example: // z := 1 // y := z + x // If x is undeclared, then this function would return `y := z + x`, so that we // can insert `x := ` on the line before `y := z + x`. // // If stmt example: // if z == 1 { // } else if z == y {} // If y is undeclared, then this function would return `if z == 1 {`, because we cannot // insert a statement between an if and an else if statement. As a result, we need to find // the top of the if chain to insert `y := ` before. func StmtToInsertVarBefore(path []ast.Node) ast.Stmt { enclosingIndex := -1 for i, p := range path { if _, ok := p.(ast.Stmt); ok { enclosingIndex = i break } } if enclosingIndex == -1 { return nil } enclosingStmt := path[enclosingIndex] switch enclosingStmt.(type) { case *ast.IfStmt: // The enclosingStmt is inside of the if declaration, // We need to check if we are in an else-if stmt and // get the base if statement. return baseIfStmt(path, enclosingIndex) case *ast.CaseClause: // Get the enclosing switch stmt if the enclosingStmt is // inside of the case statement. for i := enclosingIndex + 1; i < len(path); i++ { if node, ok := path[i].(*ast.SwitchStmt); ok { return node } else if node, ok := path[i].(*ast.TypeSwitchStmt); ok { return node } } } if len(path) <= enclosingIndex+1 { return enclosingStmt.(ast.Stmt) } // Check if the enclosing statement is inside another node. switch expr := path[enclosingIndex+1].(type) { case *ast.IfStmt: // Get the base if statement. return baseIfStmt(path, enclosingIndex+1) case *ast.ForStmt: if expr.Init == enclosingStmt || expr.Post == enclosingStmt { return expr } } return enclosingStmt.(ast.Stmt) } // baseIfStmt walks up the if/else-if chain until we get to // the top of the current if chain. func baseIfStmt(path []ast.Node, index int) ast.Stmt { stmt := path[index] for i := index + 1; i < len(path); i++ { if node, ok := path[i].(*ast.IfStmt); ok && node.Else == stmt { stmt = node continue } break } return stmt.(ast.Stmt) }