package binary import ( "encoding/hex" "encoding/json" "errors" "io" "reflect" "sync" "time" . "github.com/tendermint/tendermint/common" ) type TypeInfo struct { Type reflect.Type // The type // If Type is kind reflect.Interface, is registered IsRegisteredInterface bool ByteToType map[byte]reflect.Type TypeToByte map[reflect.Type]byte // If Type is concrete Byte byte // If Type is kind reflect.Struct Fields []StructFieldInfo } type StructFieldInfo struct { Index int // Struct field index JSONName string // Corresponding JSON field name. (override with `json=""`) Type reflect.Type // Struct field type } func (info StructFieldInfo) unpack() (int, string, reflect.Type) { return info.Index, info.JSONName, info.Type } // e.g. If o is struct{Foo}{}, return is the Foo interface type. func GetTypeFromStructDeclaration(o interface{}) reflect.Type { rt := reflect.TypeOf(o) if rt.NumField() != 1 { panic("Unexpected number of fields in struct-wrapped declaration of type") } return rt.Field(0).Type } func SetByteForType(typeByte byte, rt reflect.Type) { typeInfo := GetTypeInfo(rt) if typeInfo.Byte != 0x00 && typeInfo.Byte != typeByte { panic(Fmt("Type %v already registered with type byte %X", rt, typeByte)) } typeInfo.Byte = typeByte // If pointer, we need to set it for the concrete type as well. if rt.Kind() == reflect.Ptr { SetByteForType(typeByte, rt.Elem()) } } // Predeclaration of common types var ( timeType = GetTypeFromStructDeclaration(struct{ time.Time }{}) ) const ( rfc2822 = "Mon Jan 02 15:04:05 -0700 2006" ) // NOTE: do not access typeInfos directly, but call GetTypeInfo() var typeInfosMtx sync.Mutex var typeInfos = map[reflect.Type]*TypeInfo{} func GetTypeInfo(rt reflect.Type) *TypeInfo { typeInfosMtx.Lock() defer typeInfosMtx.Unlock() info := typeInfos[rt] if info == nil { info = MakeTypeInfo(rt) typeInfos[rt] = info } return info } // For use with the RegisterInterface declaration type ConcreteType struct { O interface{} Byte byte } // Must use this to register an interface to properly decode the // underlying concrete type. func RegisterInterface(o interface{}, ctypes ...ConcreteType) *TypeInfo { it := GetTypeFromStructDeclaration(o) if it.Kind() != reflect.Interface { panic("RegisterInterface expects an interface") } toType := make(map[byte]reflect.Type, 0) toByte := make(map[reflect.Type]byte, 0) for _, ctype := range ctypes { crt := reflect.TypeOf(ctype.O) typeByte := ctype.Byte SetByteForType(typeByte, crt) if typeByte == 0x00 { panic(Fmt("Byte of 0x00 is reserved for nil (%v)", ctype)) } if toType[typeByte] != nil { panic(Fmt("Duplicate Byte for type %v and %v", ctype, toType[typeByte])) } toType[typeByte] = crt toByte[crt] = typeByte } typeInfo := &TypeInfo{ Type: it, IsRegisteredInterface: true, ByteToType: toType, TypeToByte: toByte, } typeInfos[it] = typeInfo return typeInfo } func MakeTypeInfo(rt reflect.Type) *TypeInfo { info := &TypeInfo{Type: rt} // If struct, register field name options if rt.Kind() == reflect.Struct { numFields := rt.NumField() structFields := []StructFieldInfo{} for i := 0; i < numFields; i++ { field := rt.Field(i) if field.PkgPath != "" { continue } jsonName := field.Tag.Get("json") if jsonName == "-" { continue } else if jsonName == "" { jsonName = field.Name } structFields = append(structFields, StructFieldInfo{ Index: i, JSONName: jsonName, Type: field.Type, }) } info.Fields = structFields } return info } func readReflect(rv reflect.Value, rt reflect.Type, r io.Reader, n *int64, err *error) { // Get typeInfo typeInfo := GetTypeInfo(rt) if rt.Kind() == reflect.Interface { if !typeInfo.IsRegisteredInterface { // There's no way we can read such a thing. *err = errors.New(Fmt("Cannot read unregistered interface type %v", rt)) return } typeByte := ReadByte(r, n, err) if *err != nil { return } if typeByte == 0x00 { return // nil } crt, ok := typeInfo.ByteToType[typeByte] if !ok { *err = errors.New(Fmt("Unexpected type byte %X for type %v", typeByte, crt)) return } crv := reflect.New(crt).Elem() r = NewPrefixedReader([]byte{typeByte}, r) readReflect(crv, crt, r, n, err) rv.Set(crv) // NOTE: orig rv is ignored. return } if rt.Kind() == reflect.Ptr { typeByte := ReadByte(r, n, err) if *err != nil { return } if typeByte == 0x00 { return // nil } // Create new if rv is nil. if rv.IsNil() { newRv := reflect.New(rt.Elem()) rv.Set(newRv) rv = newRv } // Dereference pointer rv, rt = rv.Elem(), rt.Elem() typeInfo = GetTypeInfo(rt) if typeInfo.Byte != 0x00 { r = NewPrefixedReader([]byte{typeByte}, r) } // continue... } // Read Byte prefix if typeInfo.Byte != 0x00 { typeByte := ReadByte(r, n, err) if typeByte != typeInfo.Byte { *err = errors.New(Fmt("Expected Byte of %X but got %X", typeInfo.Byte, typeByte)) return } } switch rt.Kind() { case reflect.Slice: elemRt := rt.Elem() if elemRt.Kind() == reflect.Uint8 { // Special case: Byteslices byteslice := ReadByteSlice(r, n, err) log.Debug("Read byteslice", "bytes", byteslice) rv.Set(reflect.ValueOf(byteslice)) } else { // Read length length := int(ReadUvarint(r, n, err)) log.Debug(Fmt("Read length: %v", length)) sliceRv := reflect.MakeSlice(rt, length, length) // Read elems for i := 0; i < length; i++ { elemRv := sliceRv.Index(i) readReflect(elemRv, elemRt, r, n, err) } rv.Set(sliceRv) } case reflect.Struct: if rt == timeType { // Special case: time.Time t := ReadTime(r, n, err) log.Debug(Fmt("Read time: %v", t)) rv.Set(reflect.ValueOf(t)) } else { numFields := rt.NumField() for i := 0; i < numFields; i++ { field := rt.Field(i) if field.PkgPath != "" { continue } fieldRv := rv.Field(i) readReflect(fieldRv, field.Type, r, n, err) } } case reflect.String: str := ReadString(r, n, err) log.Debug(Fmt("Read string: %v", str)) rv.SetString(str) case reflect.Int64: num := ReadUint64(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Int32: num := ReadUint32(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Int16: num := ReadUint16(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Int8: num := ReadUint8(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Int: num := ReadUvarint(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Uint64: num := ReadUint64(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Uint32: num := ReadUint32(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Uint16: num := ReadUint16(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Uint8: num := ReadUint8(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Uint: num := ReadUvarint(r, n, err) log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Bool: num := ReadUint8(r, n, err) log.Debug(Fmt("Read bool: %v", num)) rv.SetBool(num > 0) default: panic(Fmt("Unknown field type %v", rt.Kind())) } } // rv: the reflection value of the thing to write // rt: the type of rv as declared in the container, not necessarily rv.Type(). func writeReflect(rv reflect.Value, rt reflect.Type, w io.Writer, n *int64, err *error) { // Get typeInfo typeInfo := GetTypeInfo(rt) if rt.Kind() == reflect.Interface { if rv.IsNil() { // XXX ensure that typeByte 0 is reserved. WriteByte(0x00, w, n, err) return } crv := rv.Elem() // concrete reflection value crt := crv.Type() // concrete reflection type if typeInfo.IsRegisteredInterface { // See if the crt is registered. // If so, we're more restrictive. _, ok := typeInfo.TypeToByte[crt] if !ok { switch crt.Kind() { case reflect.Ptr: *err = errors.New(Fmt("Unexpected pointer type %v. Was it registered as a value receiver rather than as a pointer receiver?", crt)) case reflect.Struct: *err = errors.New(Fmt("Unexpected struct type %v. Was it registered as a pointer receiver rather than as a value receiver?", crt)) default: *err = errors.New(Fmt("Unexpected type %v.", crt)) } return } } else { // We support writing unsafely for convenience. } // We don't have to write the typeByte here, // the writeReflect() call below will write it. writeReflect(crv, crt, w, n, err) return } if rt.Kind() == reflect.Ptr { // Dereference pointer rv, rt = rv.Elem(), rt.Elem() typeInfo = GetTypeInfo(rt) if !rv.IsValid() { WriteByte(0x00, w, n, err) return } if typeInfo.Byte == 0x00 { WriteByte(0x01, w, n, err) // continue... } else { // continue... } } // Write type byte if typeInfo.Byte != 0x00 { WriteByte(typeInfo.Byte, w, n, err) } // All other types switch rt.Kind() { case reflect.Slice: elemRt := rt.Elem() if elemRt.Kind() == reflect.Uint8 { // Special case: Byteslices byteslice := rv.Bytes() WriteByteSlice(byteslice, w, n, err) } else { // Write length length := rv.Len() WriteUvarint(uint(length), w, n, err) // Write elems for i := 0; i < length; i++ { elemRv := rv.Index(i) writeReflect(elemRv, elemRt, w, n, err) } } case reflect.Struct: if rt == timeType { // Special case: time.Time WriteTime(rv.Interface().(time.Time), w, n, err) } else { numFields := rt.NumField() for i := 0; i < numFields; i++ { field := rt.Field(i) if field.PkgPath != "" { continue } fieldRv := rv.Field(i) writeReflect(fieldRv, field.Type, w, n, err) } } case reflect.String: WriteString(rv.String(), w, n, err) case reflect.Int64: WriteInt64(rv.Int(), w, n, err) case reflect.Int32: WriteInt32(int32(rv.Int()), w, n, err) case reflect.Int16: WriteInt16(int16(rv.Int()), w, n, err) case reflect.Int8: WriteInt8(int8(rv.Int()), w, n, err) case reflect.Int: WriteVarint(int(rv.Int()), w, n, err) case reflect.Uint64: WriteUint64(rv.Uint(), w, n, err) case reflect.Uint32: WriteUint32(uint32(rv.Uint()), w, n, err) case reflect.Uint16: WriteUint16(uint16(rv.Uint()), w, n, err) case reflect.Uint8: WriteUint8(uint8(rv.Uint()), w, n, err) case reflect.Uint: WriteUvarint(uint(rv.Uint()), w, n, err) case reflect.Bool: if rv.Bool() { WriteUint8(uint8(1), w, n, err) } else { WriteUint8(uint8(0), w, n, err) } default: panic(Fmt("Unknown field type %v", rt.Kind())) } } //----------------------------------------------------------------------------- func readByteJSON(o interface{}) (typeByte byte, rest interface{}, err error) { oSlice, ok := o.([]interface{}) if !ok { err = errors.New(Fmt("Expected type [Byte,?] but got type %v", reflect.TypeOf(o))) return } if len(oSlice) != 2 { err = errors.New(Fmt("Expected [Byte,?] len 2 but got len %v", len(oSlice))) return } typeByte_, ok := oSlice[0].(float64) typeByte = byte(typeByte_) rest = oSlice[1] return } func readReflectJSON(rv reflect.Value, rt reflect.Type, o interface{}, err *error) { // Get typeInfo typeInfo := GetTypeInfo(rt) if rt.Kind() == reflect.Interface { if !typeInfo.IsRegisteredInterface { // There's no way we can read such a thing. *err = errors.New(Fmt("Cannot read unregistered interface type %v", rt)) return } if o == nil { return // nil } typeByte, _, err_ := readByteJSON(o) if err_ != nil { *err = err_ return } crt, ok := typeInfo.ByteToType[typeByte] if !ok { *err = errors.New(Fmt("Byte %X not registered for interface %v", typeByte, rt)) return } crv := reflect.New(crt).Elem() readReflectJSON(crv, crt, o, err) rv.Set(crv) // NOTE: orig rv is ignored. return } if rt.Kind() == reflect.Ptr { if o == nil { return // nil } // Create new struct if rv is nil. if rv.IsNil() { newRv := reflect.New(rt.Elem()) rv.Set(newRv) rv = newRv } // Dereference pointer rv, rt = rv.Elem(), rt.Elem() typeInfo = GetTypeInfo(rt) // continue... } // Read Byte prefix if typeInfo.Byte != 0x00 { typeByte, rest, err_ := readByteJSON(o) if err_ != nil { *err = err_ return } if typeByte != typeInfo.Byte { *err = errors.New(Fmt("Expected Byte of %X but got %X", typeInfo.Byte, byte(typeByte))) return } o = rest } switch rt.Kind() { case reflect.Slice: elemRt := rt.Elem() if elemRt.Kind() == reflect.Uint8 { // Special case: Byteslices oString, ok := o.(string) if !ok { *err = errors.New(Fmt("Expected string but got type %v", reflect.TypeOf(o))) return } byteslice, err_ := hex.DecodeString(oString) if err_ != nil { *err = err_ return } log.Debug("Read byteslice", "bytes", byteslice) rv.Set(reflect.ValueOf(byteslice)) } else { // Read length oSlice, ok := o.([]interface{}) if !ok { *err = errors.New(Fmt("Expected array of %v but got type %v", rt, reflect.TypeOf(o))) return } length := len(oSlice) log.Debug(Fmt("Read length: %v", length)) sliceRv := reflect.MakeSlice(rt, length, length) // Read elems for i := 0; i < length; i++ { elemRv := sliceRv.Index(i) readReflectJSON(elemRv, elemRt, oSlice[i], err) } rv.Set(sliceRv) } case reflect.Struct: if rt == timeType { // Special case: time.Time str, ok := o.(string) if !ok { *err = errors.New(Fmt("Expected string but got type %v", reflect.TypeOf(o))) return } log.Debug(Fmt("Read time: %v", str)) t, err_ := time.Parse(rfc2822, str) if err_ != nil { *err = err_ return } rv.Set(reflect.ValueOf(t)) } else { oMap, ok := o.(map[string]interface{}) if !ok { *err = errors.New(Fmt("Expected map but got type %v", reflect.TypeOf(o))) return } // TODO: ensure that all fields are set? // TODO: disallow unknown oMap fields? for _, fieldInfo := range typeInfo.Fields { i, jsonName, fieldType := fieldInfo.unpack() value, ok := oMap[jsonName] if !ok { continue // Skip missing fields. } fieldRv := rv.Field(i) readReflectJSON(fieldRv, fieldType, value, err) } } case reflect.String: str, ok := o.(string) if !ok { *err = errors.New(Fmt("Expected string but got type %v", reflect.TypeOf(o))) return } log.Debug(Fmt("Read string: %v", str)) rv.SetString(str) case reflect.Int64, reflect.Int32, reflect.Int16, reflect.Int8, reflect.Int: num, ok := o.(float64) if !ok { *err = errors.New(Fmt("Expected numeric but got type %v", reflect.TypeOf(o))) return } log.Debug(Fmt("Read num: %v", num)) rv.SetInt(int64(num)) case reflect.Uint64, reflect.Uint32, reflect.Uint16, reflect.Uint8, reflect.Uint: num, ok := o.(float64) if !ok { *err = errors.New(Fmt("Expected numeric but got type %v", reflect.TypeOf(o))) return } if num < 0 { *err = errors.New(Fmt("Expected unsigned numeric but got %v", num)) return } log.Debug(Fmt("Read num: %v", num)) rv.SetUint(uint64(num)) case reflect.Bool: bl, ok := o.(bool) if !ok { *err = errors.New(Fmt("Expected boolean but got type %v", reflect.TypeOf(o))) return } log.Debug(Fmt("Read boolean: %v", bl)) rv.SetBool(bl) default: panic(Fmt("Unknown field type %v", rt.Kind())) } } func writeReflectJSON(rv reflect.Value, rt reflect.Type, w io.Writer, n *int64, err *error) { log.Debug(Fmt("writeReflectJSON(%v, %v, %v, %v, %v)", rv, rt, w, n, err)) // Get typeInfo typeInfo := GetTypeInfo(rt) if rt.Kind() == reflect.Interface { if rv.IsNil() { // XXX ensure that typeByte 0 is reserved. WriteTo([]byte("null"), w, n, err) return } crv := rv.Elem() // concrete reflection value crt := crv.Type() // concrete reflection type if typeInfo.IsRegisteredInterface { // See if the crt is registered. // If so, we're more restrictive. _, ok := typeInfo.TypeToByte[crt] if !ok { switch crt.Kind() { case reflect.Ptr: *err = errors.New(Fmt("Unexpected pointer type %v. Was it registered as a value receiver rather than as a pointer receiver?", crt)) case reflect.Struct: *err = errors.New(Fmt("Unexpected struct type %v. Was it registered as a pointer receiver rather than as a value receiver?", crt)) default: *err = errors.New(Fmt("Unexpected type %v.", crt)) } return } } else { // We support writing unsafely for convenience. } // We don't have to write the typeByte here, // the writeReflectJSON() call below will write it. writeReflectJSON(crv, crt, w, n, err) return } if rt.Kind() == reflect.Ptr { // Dereference pointer rv, rt = rv.Elem(), rt.Elem() typeInfo = GetTypeInfo(rt) if !rv.IsValid() { WriteTo([]byte("null"), w, n, err) return } // continue... } // Write Byte if typeInfo.Byte != 0x00 { WriteTo([]byte(Fmt("[%v,", typeInfo.Byte)), w, n, err) defer WriteTo([]byte("]"), w, n, err) } // All other types switch rt.Kind() { case reflect.Slice: elemRt := rt.Elem() if elemRt.Kind() == reflect.Uint8 { // Special case: Byteslices byteslice := rv.Bytes() WriteTo([]byte(Fmt("\"%X\"", byteslice)), w, n, err) //WriteByteSlice(byteslice, w, n, err) } else { WriteTo([]byte("["), w, n, err) // Write elems length := rv.Len() for i := 0; i < length; i++ { elemRv := rv.Index(i) writeReflectJSON(elemRv, elemRt, w, n, err) if i < length-1 { WriteTo([]byte(","), w, n, err) } } WriteTo([]byte("]"), w, n, err) } case reflect.Struct: if rt == timeType { // Special case: time.Time t := rv.Interface().(time.Time) str := t.Format(rfc2822) jsonBytes, err_ := json.Marshal(str) if err_ != nil { *err = err_ return } WriteTo(jsonBytes, w, n, err) } else { WriteTo([]byte("{"), w, n, err) wroteField := false for _, fieldInfo := range typeInfo.Fields { i, jsonName, fieldType := fieldInfo.unpack() fieldRv := rv.Field(i) if wroteField { WriteTo([]byte(","), w, n, err) } else { wroteField = true } WriteTo([]byte(Fmt("\"%v\":", jsonName)), w, n, err) writeReflectJSON(fieldRv, fieldType, w, n, err) } WriteTo([]byte("}"), w, n, err) } case reflect.String: fallthrough case reflect.Uint64, reflect.Uint32, reflect.Uint16, reflect.Uint8, reflect.Uint: fallthrough case reflect.Int64, reflect.Int32, reflect.Int16, reflect.Int8, reflect.Int: fallthrough case reflect.Bool: jsonBytes, err_ := json.Marshal(rv.Interface()) if err_ != nil { *err = err_ return } WriteTo(jsonBytes, w, n, err) default: panic(Fmt("Unknown field type %v", rt.Kind())) } }