// Copyright 2010 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. // This file contains the pieces of the tool that use typechecking from the go/types package. package main import ( "go/ast" "go/importer" "go/token" "go/types" ) // imports is the canonical map of imported packages we need for typechecking. // It is created during initialization. var imports = make(map[string]*types.Package) var ( defaultImporter = importer.Default() errorType *types.Interface stringerType *types.Interface // possibly nil formatterType *types.Interface // possibly nil ) func init() { errorType = types.Universe.Lookup("error").Type().Underlying().(*types.Interface) if typ := importType("fmt", "Stringer"); typ != nil { stringerType = typ.Underlying().(*types.Interface) } if typ := importType("fmt", "Formatter"); typ != nil { formatterType = typ.Underlying().(*types.Interface) } } // importType returns the type denoted by the qualified identifier // path.name, and adds the respective package to the imports map // as a side effect. In case of an error, importType returns nil. func importType(path, name string) types.Type { pkg, err := defaultImporter.Import(path) if err != nil { // This can happen if the package at path hasn't been compiled yet. warnf("import failed: %v", err) return nil } if obj, ok := pkg.Scope().Lookup(name).(*types.TypeName); ok { return obj.Type() } warnf("invalid type name %q", name) return nil } func (pkg *Package) check(fs *token.FileSet, astFiles []*ast.File) error { pkg.defs = make(map[*ast.Ident]types.Object) pkg.uses = make(map[*ast.Ident]types.Object) pkg.selectors = make(map[*ast.SelectorExpr]*types.Selection) pkg.spans = make(map[types.Object]Span) pkg.types = make(map[ast.Expr]types.TypeAndValue) config := types.Config{ Importer: defaultImporter, // By providing a Config with our own error function, it will continue // past the first error. There is no need for that function to do anything. Error: func(error) {}, } info := &types.Info{ Selections: pkg.selectors, Types: pkg.types, Defs: pkg.defs, Uses: pkg.uses, } typesPkg, err := config.Check(pkg.path, fs, astFiles, info) pkg.typesPkg = typesPkg // update spans for id, obj := range pkg.defs { pkg.growSpan(id, obj) } for id, obj := range pkg.uses { pkg.growSpan(id, obj) } return err } // isStruct reports whether the composite literal c is a struct. // If it is not (probably a struct), it returns a printable form of the type. func (pkg *Package) isStruct(c *ast.CompositeLit) (bool, string) { // Check that the CompositeLit's type is a slice or array (which needs no field keys), if possible. typ := pkg.types[c].Type // If it's a named type, pull out the underlying type. If it's not, the Underlying // method returns the type itself. actual := typ if actual != nil { actual = actual.Underlying() } if actual == nil { // No type information available. Assume true, so we do the check. return true, "" } switch actual.(type) { case *types.Struct: return true, typ.String() default: return false, "" } } // matchArgType reports an error if printf verb t is not appropriate // for operand arg. // // typ is used only for recursive calls; external callers must supply nil. // // (Recursion arises from the compound types {map,chan,slice} which // may be printed with %d etc. if that is appropriate for their element // types.) func (f *File) matchArgType(t printfArgType, typ types.Type, arg ast.Expr) bool { return f.matchArgTypeInternal(t, typ, arg, make(map[types.Type]bool)) } // matchArgTypeInternal is the internal version of matchArgType. It carries a map // remembering what types are in progress so we don't recur when faced with recursive // types or mutually recursive types. func (f *File) matchArgTypeInternal(t printfArgType, typ types.Type, arg ast.Expr, inProgress map[types.Type]bool) bool { // %v, %T accept any argument type. if t == anyType { return true } if typ == nil { // external call typ = f.pkg.types[arg].Type if typ == nil { return true // probably a type check problem } } // If the type implements fmt.Formatter, we have nothing to check. // formatterTyp may be nil - be conservative and check for Format method in that case. if formatterType != nil && types.Implements(typ, formatterType) || f.hasMethod(typ, "Format") { return true } // If we can use a string, might arg (dynamically) implement the Stringer or Error interface? if t&argString != 0 { if types.AssertableTo(errorType, typ) || stringerType != nil && types.AssertableTo(stringerType, typ) { return true } } typ = typ.Underlying() if inProgress[typ] { // We're already looking at this type. The call that started it will take care of it. return true } inProgress[typ] = true switch typ := typ.(type) { case *types.Signature: return t&argPointer != 0 case *types.Map: // Recur: map[int]int matches %d. return t&argPointer != 0 || (f.matchArgTypeInternal(t, typ.Key(), arg, inProgress) && f.matchArgTypeInternal(t, typ.Elem(), arg, inProgress)) case *types.Chan: return t&argPointer != 0 case *types.Array: // Same as slice. if types.Identical(typ.Elem().Underlying(), types.Typ[types.Byte]) && t&argString != 0 { return true // %s matches []byte } // Recur: []int matches %d. return t&argPointer != 0 || f.matchArgTypeInternal(t, typ.Elem().Underlying(), arg, inProgress) case *types.Slice: // Same as array. if types.Identical(typ.Elem().Underlying(), types.Typ[types.Byte]) && t&argString != 0 { return true // %s matches []byte } // Recur: []int matches %d. But watch out for // type T []T // If the element is a pointer type (type T[]*T), it's handled fine by the Pointer case below. return t&argPointer != 0 || f.matchArgTypeInternal(t, typ.Elem(), arg, inProgress) case *types.Pointer: // Ugly, but dealing with an edge case: a known pointer to an invalid type, // probably something from a failed import. if typ.Elem().String() == "invalid type" { if *verbose { f.Warnf(arg.Pos(), "printf argument %v is pointer to invalid or unknown type", f.gofmt(arg)) } return true // special case } // If it's actually a pointer with %p, it prints as one. if t == argPointer { return true } // If it's pointer to struct, that's equivalent in our analysis to whether we can print the struct. if str, ok := typ.Elem().Underlying().(*types.Struct); ok { return f.matchStructArgType(t, str, arg, inProgress) } // The rest can print with %p as pointers, or as integers with %x etc. return t&(argInt|argPointer) != 0 case *types.Struct: return f.matchStructArgType(t, typ, arg, inProgress) case *types.Interface: // If the static type of the argument is empty interface, there's little we can do. // Example: // func f(x interface{}) { fmt.Printf("%s", x) } // Whether x is valid for %s depends on the type of the argument to f. One day // we will be able to do better. For now, we assume that empty interface is OK // but non-empty interfaces, with Stringer and Error handled above, are errors. return typ.NumMethods() == 0 case *types.Basic: switch typ.Kind() { case types.UntypedBool, types.Bool: return t&argBool != 0 case types.UntypedInt, types.Int, types.Int8, types.Int16, types.Int32, types.Int64, types.Uint, types.Uint8, types.Uint16, types.Uint32, types.Uint64, types.Uintptr: return t&argInt != 0 case types.UntypedFloat, types.Float32, types.Float64: return t&argFloat != 0 case types.UntypedComplex, types.Complex64, types.Complex128: return t&argComplex != 0 case types.UntypedString, types.String: return t&argString != 0 case types.UnsafePointer: return t&(argPointer|argInt) != 0 case types.UntypedRune: return t&(argInt|argRune) != 0 case types.UntypedNil: return t&argPointer != 0 // TODO? case types.Invalid: if *verbose { f.Warnf(arg.Pos(), "printf argument %v has invalid or unknown type", f.gofmt(arg)) } return true // Probably a type check problem. } panic("unreachable") } return false } // hasBasicType reports whether x's type is a types.Basic with the given kind. func (f *File) hasBasicType(x ast.Expr, kind types.BasicKind) bool { t := f.pkg.types[x].Type if t != nil { t = t.Underlying() } b, ok := t.(*types.Basic) return ok && b.Kind() == kind } // matchStructArgType reports whether all the elements of the struct match the expected // type. For instance, with "%d" all the elements must be printable with the "%d" format. func (f *File) matchStructArgType(t printfArgType, typ *types.Struct, arg ast.Expr, inProgress map[types.Type]bool) bool { for i := 0; i < typ.NumFields(); i++ { if !f.matchArgTypeInternal(t, typ.Field(i).Type(), arg, inProgress) { return false } } return true } // numArgsInSignature tells how many formal arguments the function type // being called has. func (f *File) numArgsInSignature(call *ast.CallExpr) int { // Check the type of the function or method declaration typ := f.pkg.types[call.Fun].Type if typ == nil { return 0 } // The type must be a signature, but be sure for safety. sig, ok := typ.(*types.Signature) if !ok { return 0 } return sig.Params().Len() } // isErrorMethodCall reports whether the call is of a method with signature // func Error() string // where "string" is the universe's string type. We know the method is called "Error". func (f *File) isErrorMethodCall(call *ast.CallExpr) bool { typ := f.pkg.types[call].Type if typ != nil { // We know it's called "Error", so just check the function signature // (stringerType has exactly one method, String). if stringerType != nil && stringerType.NumMethods() == 1 { return types.Identical(f.pkg.types[call.Fun].Type, stringerType.Method(0).Type()) } } // Without types, we can still check by hand. // Is it a selector expression? Otherwise it's a function call, not a method call. sel, ok := call.Fun.(*ast.SelectorExpr) if !ok { return false } // The package is type-checked, so if there are no arguments, we're done. if len(call.Args) > 0 { return false } // Check the type of the method declaration typ = f.pkg.types[sel].Type if typ == nil { return false } // The type must be a signature, but be sure for safety. sig, ok := typ.(*types.Signature) if !ok { return false } // There must be a receiver for it to be a method call. Otherwise it is // a function, not something that satisfies the error interface. if sig.Recv() == nil { return false } // There must be no arguments. Already verified by type checking, but be thorough. if sig.Params().Len() > 0 { return false } // Finally the real questions. // There must be one result. if sig.Results().Len() != 1 { return false } // It must have return type "string" from the universe. return sig.Results().At(0).Type() == types.Typ[types.String] } // hasMethod reports whether the type contains a method with the given name. // It is part of the workaround for Formatters and should be deleted when // that workaround is no longer necessary. // TODO: This could be better once issue 6259 is fixed. func (f *File) hasMethod(typ types.Type, name string) bool { // assume we have an addressable variable of type typ obj, _, _ := types.LookupFieldOrMethod(typ, true, f.pkg.typesPkg, name) _, ok := obj.(*types.Func) return ok }