// Copyright 2009 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. /* The gob package manages streams of gobs - binary values exchanged between an Encoder (transmitter) and a Decoder (receiver). A typical use is transporting arguments and results of remote procedure calls (RPCs) such as those provided by package "rpc". A stream of gobs is self-describing. Each data item in the stream is preceded by a specification of its type, expressed in terms of a small set of predefined types. Pointers are not transmitted, but the things they point to are transmitted; that is, the values are flattened. Recursive types work fine, but recursive values (data with cycles) are problematic. This may change. To use gobs, create an Encoder and present it with a series of data items as values or addresses that can be dereferenced to values. The Encoder makes sure all type information is sent before it is needed. At the receive side, a Decoder retrieves values from the encoded stream and unpacks them into local variables. The source and destination values/types need not correspond exactly. For structs, fields (identified by name) that are in the source but absent from the receiving variable will be ignored. Fields that are in the receiving variable but missing from the transmitted type or value will be ignored in the destination. If a field with the same name is present in both, their types must be compatible. Both the receiver and transmitter will do all necessary indirection and dereferencing to convert between gobs and actual Go values. For instance, a gob type that is schematically, struct { a, b int } can be sent from or received into any of these Go types: struct { a, b int } // the same *struct { a, b int } // extra indirection of the struct struct { *a, **b int } // extra indirection of the fields struct { a, b int64 } // different concrete value type; see below It may also be received into any of these: struct { a, b int } // the same struct { b, a int } // ordering doesn't matter; matching is by name struct { a, b, c int } // extra field (c) ignored struct { b int } // missing field (a) ignored; data will be dropped struct { b, c int } // missing field (a) ignored; extra field (c) ignored. Attempting to receive into these types will draw a decode error: struct { a int; b uint } // change of signedness for b struct { a int; b float } // change of type for b struct { } // no field names in common struct { c, d int } // no field names in common Integers are transmitted two ways: arbitrary precision signed integers or arbitrary precision unsigned integers. There is no int8, int16 etc. discrimination in the gob format; there are only signed and unsigned integers. As described below, the transmitter sends the value in a variable-length encoding; the receiver accepts the value and stores it in the destination variable. Floating-point numbers are always sent using IEEE-754 64-bit precision (see below). Signed integers may be received into any signed integer variable: int, int16, etc.; unsigned integers may be received into any unsigned integer variable; and floating point values may be received into any floating point variable. However, the destination variable must be able to represent the value or the decode operation will fail. Structs, arrays and slices are also supported. Strings and arrays of bytes are supported with a special, efficient representation (see below). Functions and channels cannot be sent in a gob. Attempting to encode a value that contains one will fail. The rest of this comment documents the encoding, details that are not important for most users. Details are presented bottom-up. An unsigned integer is sent one of two ways. If it is less than 128, it is sent as a byte with that value. Otherwise it is sent as a minimal-length big-endian (high byte first) byte stream holding the value, preceded by one byte holding the byte count, negated. Thus 0 is transmitted as (00), 7 is transmitted as (07) and 256 is transmitted as (FE 01 00). A boolean is encoded within an unsigned integer: 0 for false, 1 for true. A signed integer, i, is encoded within an unsigned integer, u. Within u, bits 1 upward contain the value; bit 0 says whether they should be complemented upon receipt. The encode algorithm looks like this: uint u; if i < 0 { u = (^i << 1) | 1 // complement i, bit 0 is 1 } else { u = (i << 1) // do not complement i, bit 0 is 0 } encodeUnsigned(u) The low bit is therefore analogous to a sign bit, but making it the complement bit instead guarantees that the largest negative integer is not a special case. For example, -129=^128=(^256>>1) encodes as (FE 01 01). Floating-point numbers are always sent as a representation of a float64 value. That value is converted to a uint64 using math.Float64bits. The uint64 is then byte-reversed and sent as a regular unsigned integer. The byte-reversal means the exponent and high-precision part of the mantissa go first. Since the low bits are often zero, this can save encoding bytes. For instance, 17.0 is encoded in only three bytes (FE 31 40). Strings and slices of bytes are sent as an unsigned count followed by that many uninterpreted bytes of the value. All other slices and arrays are sent as an unsigned count followed by that many elements using the standard gob encoding for their type, recursively. Structs are sent as a sequence of (field number, field value) pairs. The field value is sent using the standard gob encoding for its type, recursively. If a field has the zero value for its type, it is omitted from the transmission. The field number is defined by the type of the encoded struct: the first field of the encoded type is field 0, the second is field 1, etc. When encoding a value, the field numbers are delta encoded for efficiency and the fields are always sent in order of increasing field number; the deltas are therefore unsigned. The initialization for the delta encoding sets the field number to -1, so an unsigned integer field 0 with value 7 is transmitted as unsigned delta = 1, unsigned value = 7 or (01 07). Finally, after all the fields have been sent a terminating mark denotes the end of the struct. That mark is a delta=0 value, which has representation (00). Interface types are not checked for compatibility; all interface types are treated, for transmission, as members of a single "interface" type, analogous to int or []byte - in effect they're all treated as interface{}. Interface values are transmitted as a string identifying the concrete type being sent (a name that must be pre-defined by calling Register), followed by a byte count of the length of the following data (so the value can be skipped if it cannot be stored), followed by the usual encoding of concrete (dynamic) value stored in the interface value. (A nil interface value is identified by the empty string and transmits no value.) Upon receipt, the decoder verifies that the unpacked concrete item satisfies the interface of the receiving variable. The representation of types is described below. When a type is defined on a given connection between an Encoder and Decoder, it is assigned a signed integer type id. When Encoder.Encode(v) is called, it makes sure there is an id assigned for the type of v and all its elements and then it sends the pair (typeid, encoded-v) where typeid is the type id of the encoded type of v and encoded-v is the gob encoding of the value v. To define a type, the encoder chooses an unused, positive type id and sends the pair (-type id, encoded-type) where encoded-type is the gob encoding of a wireType description, constructed from these types: type wireType struct { ArrayT *ArrayType SliceT *SliceType StructT *StructType MapT *MapType } type ArrayType struct { CommonType Elem typeId Len int } type CommonType { Name string // the name of the struct type Id int // the id of the type, repeated so it's inside the type } type SliceType struct { CommonType Elem typeId } type StructType struct { CommonType Field []*fieldType // the fields of the struct. } type FieldType struct { Name string // the name of the field. Id int // the type id of the field, which must be already defined } type MapType struct { CommonType Key typeId Elem typeId } If there are nested type ids, the types for all inner type ids must be defined before the top-level type id is used to describe an encoded-v. For simplicity in setup, the connection is defined to understand these types a priori, as well as the basic gob types int, uint, etc. Their ids are: bool 1 int 2 uint 3 float 4 []byte 5 string 6 complex 7 interface 8 // gap for reserved ids. WireType 16 ArrayType 17 CommonType 18 SliceType 19 StructType 20 FieldType 21 // 22 is slice of fieldType. MapType 23 Finally, each message created by a call to Encode is preceded by an encoded unsigned integer count of the number of bytes remaining in the message. After the initial type name, interface values are wrapped the same way; in effect, the interface value acts like a recursive invocation of Encode. In summary, a gob stream looks like (byteCount (-type id, encoding of a wireType)* (type id, encoding of a value))* where * signifies zero or more repetitions and the type id of a value must be predefined or be defined before the value in the stream. */ package gob /* Grammar: Tokens starting with a lower case letter are terminals; int(n) and uint(n) represent the signed/unsigned encodings of the value n. GobStream: DelimitedMessage* DelimitedMessage: uint(lengthOfMessage) Message Message: TypeSequence TypedValue TypeSequence (TypeDefinition DelimitedTypeDefinition*)? DelimitedTypeDefinition: uint(lengthOfTypeDefinition) TypeDefinition TypedValue: int(typeId) Value TypeDefinition: int(-typeId) encodingOfWireType Value: SingletonValue | StructValue SingletonValue: uint(0) FieldValue FieldValue: builtinValue | ArrayValue | MapValue | SliceValue | StructValue | InterfaceValue InterfaceValue: NilInterfaceValue | NonNilInterfaceValue NilInterfaceValue: uint(0) NonNilInterfaceValue: ConcreteTypeName TypeSequence InterfaceContents ConcreteTypeName: uint(lengthOfName) [already read=n] name InterfaceContents: int(concreteTypeId) DelimitedValue DelimitedValue: uint(length) Value ArrayValue: uint(n) FieldValue*n [n elements] MapValue: uint(n) (FieldValue FieldValue)*n [n (key, value) pairs] SliceValue: uint(n) FieldValue*n [n elements] StructValue: (uint(fieldDelta) FieldValue)* */ /* For implementers and the curious, here is an encoded example. Given type Point struct {x, y int} and the value p := Point{22, 33} the bytes transmitted that encode p will be: 1f ff 81 03 01 01 05 50 6f 69 6e 74 01 ff 82 00 01 02 01 01 78 01 04 00 01 01 79 01 04 00 00 00 07 ff 82 01 2c 01 42 00 They are determined as follows. Since this is the first transmission of type Point, the type descriptor for Point itself must be sent before the value. This is the first type we've sent on this Encoder, so it has type id 65 (0 through 64 are reserved). 1f // This item (a type descriptor) is 31 bytes long. ff 81 // The negative of the id for the type we're defining, -65. // This is one byte (indicated by FF = -1) followed by // ^-65<<1 | 1. The low 1 bit signals to complement the // rest upon receipt. // Now we send a type descriptor, which is itself a struct (wireType). // The type of wireType itself is known (it's built in, as is the type of // all its components), so we just need to send a *value* of type wireType // that represents type "Point". // Here starts the encoding of that value. // Set the field number implicitly to -1; this is done at the beginning // of every struct, including nested structs. 03 // Add 3 to field number; now 2 (wireType.structType; this is a struct). // structType starts with an embedded commonType, which appears // as a regular structure here too. 01 // add 1 to field number (now 0); start of embedded commonType. 01 // add 1 to field number (now 0, the name of the type) 05 // string is (unsigned) 5 bytes long 50 6f 69 6e 74 // wireType.structType.commonType.name = "Point" 01 // add 1 to field number (now 1, the id of the type) ff 82 // wireType.structType.commonType._id = 65 00 // end of embedded wiretype.structType.commonType struct 01 // add 1 to field number (now 1, the field array in wireType.structType) 02 // There are two fields in the type (len(structType.field)) 01 // Start of first field structure; add 1 to get field number 0: field[0].name 01 // 1 byte 78 // structType.field[0].name = "x" 01 // Add 1 to get field number 1: field[0].id 04 // structType.field[0].typeId is 2 (signed int). 00 // End of structType.field[0]; start structType.field[1]; set field number to -1. 01 // Add 1 to get field number 0: field[1].name 01 // 1 byte 79 // structType.field[1].name = "y" 01 // Add 1 to get field number 1: field[0].id 04 // struct.Type.field[1].typeId is 2 (signed int). 00 // End of structType.field[1]; end of structType.field. 00 // end of wireType.structType structure 00 // end of wireType structure Now we can send the Point value. Again the field number resets to -1: 07 // this value is 7 bytes long ff 82 // the type number, 65 (1 byte (-FF) followed by 65<<1) 01 // add one to field number, yielding field 0 2c // encoding of signed "22" (0x22 = 44 = 22<<1); Point.x = 22 01 // add one to field number, yielding field 1 42 // encoding of signed "33" (0x42 = 66 = 33<<1); Point.y = 33 00 // end of structure The type encoding is long and fairly intricate but we send it only once. If p is transmitted a second time, the type is already known so the output will be just: 07 ff 82 01 2c 01 42 00 A single non-struct value at top level is transmitted like a field with delta tag 0. For instance, a signed integer with value 3 presented as the argument to Encode will emit: 03 04 00 06 Which represents: 03 // this value is 3 bytes long 04 // the type number, 2, represents an integer 00 // tag delta 0 06 // value 3 */