gob: break documentation into a separate doc.go file

R=adg, r2
CC=golang-dev
https://golang.org/cl/2596041

src/pkg/gob/Makefile

@@ -8,6 +8,7 @@ TARG=gob
 GOFILES=\
 	decode.go\
 	decoder.go\
+	doc.go\
 	encode.go\
 	encoder.go\
 	type.go\

src/pkg/gob/doc.go

+// 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).
+
+Interfaces, 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 0E).  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).
+
+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 {
+		s	structType;
+	}
+	type fieldType struct {
+		name	string;	// the name of the field.
+		id	int;	// the type id of the field, which must be already defined
+	}
+	type commonType {
+		name	string;	// the name of the struct type
+		id	int;	// the id of the type, repeated for so it's inside the type
+	}
+	type structType struct {
+		commonType;
+		field	[]fieldType;	// the fields of the struct.
+	}
+
+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
+	wireType	7
+	structType	8
+	commonType	9
+	fieldType	10
+
+In summary, a gob stream looks like
+
+	((-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
+
+/*
+For implementers and the curious, here is an encoded example.  Given
+	type Point {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 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 zero; this is done at the beginning
+	// of every struct, including nested structs.
+	03 	// Add 3 to field number; now 3 (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 1); start of embedded commonType.
+	01	// add one to field number (now 1, the name of the type)
+	05	// string is (unsigned) 5 bytes long
+	50 6f 69 6e 74	// wireType.structType.commonType.name = "Point"
+	01	// add one to field number (now 2, the id of the type)
+	ff 82	// wireType.structType.commonType._id = 65
+	00 	// end of embedded wiretype.structType.commonType struct
+	01	// add one to field number (now 2, 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 1: field[0].name
+	01	// 1 byte
+	78	// structType.field[0].name = "x"
+	01	// Add 1 to get field number 2: 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 0.
+	01	// Add 1 to get field number 1: field[1].name
+	01	// 1 byte
+	79	// structType.field[1].name = "y"
+	01	// Add 1 to get field number 2: 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 zero:
+
+	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 1
+	2c // encoding of signed "22" (0x22 = 44 = 22<<1); Point.x = 22
+	01 // add one to field number, yielding field 2
+	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
+
+*/

src/pkg/gob/encode.go

@@ -2,270 +2,8 @@
 // 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).
-
-	Interfaces, 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 0E).  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).
-
-	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 {
-			s	structType;
-		}
-		type fieldType struct {
-			name	string;	// the name of the field.
-			id	int;	// the type id of the field, which must be already defined
-		}
-		type commonType {
-			name	string;	// the name of the struct type
-			id	int;	// the id of the type, repeated for so it's inside the type
-		}
-		type structType struct {
-			commonType;
-			field	[]fieldType;	// the fields of the struct.
-		}
-
-	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
-		wireType	7
-		structType	8
-		commonType	9
-		fieldType	10
-
-	In summary, a gob stream looks like
-
-		((-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
 
-/*
-	For implementers and the curious, here is an encoded example.  Given
-		type Point {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 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 zero; this is done at the beginning
-		// of every struct, including nested structs.
-		03 	// Add 3 to field number; now 3 (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 1); start of embedded commonType.
-		01	// add one to field number (now 1, the name of the type)
-		05	// string is (unsigned) 5 bytes long
-		50 6f 69 6e 74	// wireType.structType.commonType.name = "Point"
-		01	// add one to field number (now 2, the id of the type)
-		ff 82	// wireType.structType.commonType._id = 65
-		00 	// end of embedded wiretype.structType.commonType struct
-		01	// add one to field number (now 2, 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 1: field[0].name
-		01	// 1 byte
-		78	// structType.field[0].name = "x"
-		01	// Add 1 to get field number 2: 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 0.
-		01	// Add 1 to get field number 1: field[1].name
-		01	// 1 byte
-		79	// structType.field[1].name = "y"
-		01	// Add 1 to get field number 2: 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 zero:
-
-		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 1
-		2c // encoding of signed "22" (0x22 = 44 = 22<<1); Point.x = 22
-		01 // add one to field number, yielding field 2
-		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
-
-*/
-
 import (
 	"bytes"
 	"io"