// zero returns a new "zero" value of the specified type. func zero(t types.Type) value { switch t := t.(type) { case *types.Basic: if t.Kind() == types.UntypedNil { panic("untyped nil has no zero value") } if t.Info()&types.IsUntyped != 0 { // TODO(adonovan): make it an invariant that // this is unreachable. Currently some // constants have 'untyped' types when they // should be defaulted by the typechecker. t = ssa.DefaultType(t).(*types.Basic) } switch t.Kind() { case types.Bool: return false case types.Int: return int(0) case types.Int8: return int8(0) case types.Int16: return int16(0) case types.Int32: return int32(0) case types.Int64: return int64(0) case types.Uint: return uint(0) case types.Uint8: return uint8(0) case types.Uint16: return uint16(0) case types.Uint32: return uint32(0) case types.Uint64: return uint64(0) case types.Uintptr: return uintptr(0) case types.Float32: return float32(0) case types.Float64: return float64(0) case types.Complex64: return complex64(0) case types.Complex128: return complex128(0) case types.String: return "" case types.UnsafePointer: return unsafe.Pointer(nil) default: panic(fmt.Sprint("zero for unexpected type:", t)) } case *types.Pointer: return (*value)(nil) case *types.Array: a := make(array, t.Len()) for i := range a { a[i] = zero(t.Elem()) } return a case *types.Named: return zero(t.Underlying()) case *types.Interface: return iface{} // nil type, methodset and value case *types.Slice: return []value(nil) case *types.Struct: s := make(structure, t.NumFields()) for i := range s { s[i] = zero(t.Field(i).Type()) } return s case *types.Tuple: if t.Len() == 1 { return zero(t.At(0).Type()) } s := make(tuple, t.Len()) for i := range s { s[i] = zero(t.At(i).Type()) } return s case *types.Chan: return chan value(nil) case *types.Map: if usesBuiltinMap(t.Key()) { return map[value]value(nil) } return (*hashmap)(nil) case *types.Signature: return (*ssa.Function)(nil) } panic(fmt.Sprint("zero: unexpected ", t)) }
// 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. // But (see issue 6259) that's not easy to verify, so instead we see // if its method set contains a Format function. We could do better, // even now, but we don't need to be 100% accurate. Wait for 6259 to // be fixed instead. TODO. if 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) || 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 }
// hashFor computes the hash of t. func (h Hasher) hashFor(t types.Type) uint32 { // See Identical for rationale. switch t := t.(type) { case *types.Basic: return uint32(t.Kind()) case *types.Array: return 9043 + 2*uint32(t.Len()) + 3*h.Hash(t.Elem()) case *types.Slice: return 9049 + 2*h.Hash(t.Elem()) case *types.Struct: var hash uint32 = 9059 for i, n := 0, t.NumFields(); i < n; i++ { f := t.Field(i) if f.Anonymous() { hash += 8861 } hash += hashString(t.Tag(i)) hash += hashString(f.Name()) // (ignore f.Pkg) hash += h.Hash(f.Type()) } return hash case *types.Pointer: return 9067 + 2*h.Hash(t.Elem()) case *types.Signature: var hash uint32 = 9091 if t.Variadic() { hash *= 8863 } return hash + 3*h.hashTuple(t.Params()) + 5*h.hashTuple(t.Results()) case *types.Interface: var hash uint32 = 9103 for i, n := 0, t.NumMethods(); i < n; i++ { // See go/types.identicalMethods for rationale. // Method order is not significant. // Ignore m.Pkg(). m := t.Method(i) hash += 3*hashString(m.Name()) + 5*h.Hash(m.Type()) } return hash case *types.Map: return 9109 + 2*h.Hash(t.Key()) + 3*h.Hash(t.Elem()) case *types.Chan: return 9127 + 2*uint32(t.Dir()) + 3*h.Hash(t.Elem()) case *types.Named: // Not safe with a copying GC; objects may move. return uint32(reflect.ValueOf(t.Obj()).Pointer()) case *types.Tuple: return h.hashTuple(t) } panic(t) }