upstream/mercurial-mirror Commit - r29860:b42c26b0

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10

The protocol is synchronous and does not support multiplexing (concurrent

11

commands).

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13

Transport Protocols

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===================

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HTTP Transport

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--------------

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19

Commands are issued as HTTP/1.0 or HTTP/1.1 requests. Commands are

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sent to the base URL of the repository with the command name sent in

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the ``cmd`` query string parameter. e.g.

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``https://example.com/repo?cmd=capabilities``. The HTTP method is ``GET``

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or ``POST`` depending on the command and whether there is a request

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body.

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Command arguments can be sent multiple ways.

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The simplest is part of the URL query string using ``x-www-form-urlencoded``

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encoding (see Python's ``urllib.urlencode()``. However, many servers impose

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length limitations on the URL. So this mechanism is typically only used if

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the server doesn't support other mechanisms.

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If the server supports the ``httpheader`` capability, command arguments can

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be sent in HTTP request headers named ``X-HgArg-<N>`` where ``<N>`` is an

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integer starting at 1. A ``x-www-form-urlencoded`` representation of the

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arguments is obtained. This full string is then split into chunks and sent

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in numbered ``X-HgArg-<N>`` headers. The maximum length of each HTTP header

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is defined by the server in the ``httpheader`` capability value, which defaults

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to ``1024``. The server reassembles the encoded arguments string by

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concatenating the ``X-HgArg-<N>`` headers then URL decodes them into a

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dictionary.

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The list of ``X-HgArg-<N>`` headers should be added to the ``Vary`` request

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header to instruct caches to take these headers into consideration when caching

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requests.

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If the server supports the ``httppostargs`` capability, the client

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may send command arguments in the HTTP request body as part of an

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HTTP POST request. The command arguments will be URL encoded just like

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they would for sending them via HTTP headers. However, no splitting is

51

performed: the raw arguments are included in the HTTP request body.

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The client sends a ``X-HgArgs-Post`` header with the string length of the

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encoded arguments data. Additional data may be included in the HTTP

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request body immediately following the argument data. The offset of the

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non-argument data is defined by the ``X-HgArgs-Post`` header. The

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``X-HgArgs-Post`` header is not required if there is no argument data.

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Additional command data can be sent as part of the HTTP request body. The

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default ``Content-Type`` when sending data is ``application/mercurial-0.1``.

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A ``Content-Length`` header is currently always sent.

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Example HTTP requests::

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GET /repo?cmd=capabilities

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X-HgArg-1: foo=bar&baz=hello%20world

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The ``Content-Type`` HTTP response header identifies the response as coming

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from Mercurial and can also be used to signal an error has occurred.

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The ``application/mercurial-0.1`` media type indicates a generic Mercurial

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response. It matches the media type sent by the client.

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The ``application/hg-error`` media type indicates a generic error occurred.

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The content of the HTTP response body typically holds text describing the

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error.

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The ``application/hg-changegroup`` media type indicates a changegroup response

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type.

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Clients also accept the ``text/plain`` media type. All other media

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types should cause the client to error.

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Clients should issue a ``User-Agent`` request header that identifies the client.

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The server should not use the ``User-Agent`` for feature detection.

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87

A command returning a ``string`` response issues the

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``application/mercurial-0.1`` media type and the HTTP response body contains

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the raw string value. A ``Content-Length`` header is typically issued.

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A command returning a ``stream`` response issues the

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``application/mercurial-0.1`` media type and the HTTP response is typically

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using *chunked transfer* (``Transfer-Encoding: chunked``).

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95

SSH Transport

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=============

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98

The SSH transport is a custom text-based protocol suitable for use over any

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bi-directional stream transport. It is most commonly used with SSH.

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A SSH transport server can be started with ``hg serve --stdio``. The stdin,

102

stderr, and stdout file descriptors of the started process are used to exchange

103

data. When Mercurial connects to a remote server over SSH, it actually starts

104

a ``hg serve --stdio`` process on the remote server.

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106

Commands are issued by sending the command name followed by a trailing newline

107

``\n`` to the server. e.g. ``capabilities\n``.

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109

Command arguments are sent in the following format::

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111

112

113

That is, the argument string name followed by a space followed by the

114

integer length of the value (expressed as a string) followed by a newline

115

(``\n``) followed by the raw argument value.

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117

Dictionary arguments are encoded differently::

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119

<argument> <# elements>\n

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121

122

...

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Non-argument data is sent immediately after the final argument value. It is

125

encoded in chunks::

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129

Each command declares a list of supported arguments and their types. If a

130

client sends an unknown argument to the server, the server should abort

131

immediately. The special argument ``*`` in a command's definition indicates

132

that all argument names are allowed.

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134

The definition of supported arguments and types is initially made when a

135

new command is implemented. The client and server must initially independently

136

agree on the arguments and their types. This initial set of arguments can be

137

supplemented through the presence of *capabilities* advertised by the server.

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139

Each command has a defined expected response type.

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141

A ``string`` response type is a length framed value. The response consists of

142

the string encoded integer length of a value followed by a newline (``\n``)

143

followed by the value. Empty values are allowed (and are represented as

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``0\n``).

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A ``stream`` response type consists of raw bytes of data. There is no framing.

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A generic error response type is also supported. It consists of a an error

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message written to ``stderr`` followed by ``\n-\n``. In addition, ``\n`` is

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written to ``stdout``.

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If the server receives an unknown command, it will send an empty ``string``

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response.

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The server terminates if it receives an empty command (a ``\n`` character).

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		@@ -9,3 +9,147 b' return multiple response types.'
9	9
10	10	The protocol is synchronous and does not support multiplexing (concurrent
11	11	commands).
	12
	13	Transport Protocols
	14	===================
	15
	16	HTTP Transport
	17	--------------
	18
	19	Commands are issued as HTTP/1.0 or HTTP/1.1 requests. Commands are
	20	sent to the base URL of the repository with the command name sent in
	21	the ``cmd`` query string parameter. e.g.
	22	``https://example.com/repo?cmd=capabilities``. The HTTP method is ``GET``
	23	or ``POST`` depending on the command and whether there is a request
	24	body.
	25
	26	Command arguments can be sent multiple ways.
	27
	28	The simplest is part of the URL query string using ``x-www-form-urlencoded``
	29	encoding (see Python's ``urllib.urlencode()``. However, many servers impose
	30	length limitations on the URL. So this mechanism is typically only used if
	31	the server doesn't support other mechanisms.
	32
	33	If the server supports the ``httpheader`` capability, command arguments can
	34	be sent in HTTP request headers named ``X-HgArg-<N>`` where ``<N>`` is an
	35	integer starting at 1. A ``x-www-form-urlencoded`` representation of the
	36	arguments is obtained. This full string is then split into chunks and sent
	37	in numbered ``X-HgArg-<N>`` headers. The maximum length of each HTTP header
	38	is defined by the server in the ``httpheader`` capability value, which defaults
	39	to ``1024``. The server reassembles the encoded arguments string by
	40	concatenating the ``X-HgArg-<N>`` headers then URL decodes them into a
	41	dictionary.
	42
	43	The list of ``X-HgArg-<N>`` headers should be added to the ``Vary`` request
	44	header to instruct caches to take these headers into consideration when caching
	45	requests.
	46
	47	If the server supports the ``httppostargs`` capability, the client
	48	may send command arguments in the HTTP request body as part of an
	49	HTTP POST request. The command arguments will be URL encoded just like
	50	they would for sending them via HTTP headers. However, no splitting is
	51	performed: the raw arguments are included in the HTTP request body.
	52
	53	The client sends a ``X-HgArgs-Post`` header with the string length of the
	54	encoded arguments data. Additional data may be included in the HTTP
	55	request body immediately following the argument data. The offset of the
	56	non-argument data is defined by the ``X-HgArgs-Post`` header. The
	57	``X-HgArgs-Post`` header is not required if there is no argument data.
	58
	59	Additional command data can be sent as part of the HTTP request body. The
	60	default ``Content-Type`` when sending data is ``application/mercurial-0.1``.
	61	A ``Content-Length`` header is currently always sent.
	62
	63	Example HTTP requests::
	64
	65	GET /repo?cmd=capabilities
	66	X-HgArg-1: foo=bar&baz=hello%20world
	67
	68	The ``Content-Type`` HTTP response header identifies the response as coming
	69	from Mercurial and can also be used to signal an error has occurred.
	70
	71	The ``application/mercurial-0.1`` media type indicates a generic Mercurial
	72	response. It matches the media type sent by the client.
	73
	74	The ``application/hg-error`` media type indicates a generic error occurred.
	75	The content of the HTTP response body typically holds text describing the
	76	error.
	77
	78	The ``application/hg-changegroup`` media type indicates a changegroup response
	79	type.
	80
	81	Clients also accept the ``text/plain`` media type. All other media
	82	types should cause the client to error.
	83
	84	Clients should issue a ``User-Agent`` request header that identifies the client.
	85	The server should not use the ``User-Agent`` for feature detection.
	86
	87	A command returning a ``string`` response issues the
	88	``application/mercurial-0.1`` media type and the HTTP response body contains
	89	the raw string value. A ``Content-Length`` header is typically issued.
	90
	91	A command returning a ``stream`` response issues the
	92	``application/mercurial-0.1`` media type and the HTTP response is typically
	93	using chunked transfer (``Transfer-Encoding: chunked``).
	94
	95	SSH Transport
	96	=============
	97
	98	The SSH transport is a custom text-based protocol suitable for use over any
	99	bi-directional stream transport. It is most commonly used with SSH.
	100
	101	A SSH transport server can be started with ``hg serve --stdio``. The stdin,
	102	stderr, and stdout file descriptors of the started process are used to exchange
	103	data. When Mercurial connects to a remote server over SSH, it actually starts
	104	a ``hg serve --stdio`` process on the remote server.
	105
	106	Commands are issued by sending the command name followed by a trailing newline
	107	``\n`` to the server. e.g. ``capabilities\n``.
	108
	109	Command arguments are sent in the following format::
	110
	111	<argument> <length>\n<value>
	112
	113	That is, the argument string name followed by a space followed by the
	114	integer length of the value (expressed as a string) followed by a newline
	115	(``\n``) followed by the raw argument value.
	116
	117	Dictionary arguments are encoded differently::
	118
	119	<argument> <# elements>\n
	120	<key1> <length1>\n<value1>
	121	<key2> <length2>\n<value2>
	122	...
	123
	124	Non-argument data is sent immediately after the final argument value. It is
	125	encoded in chunks::
	126
	127	<length>\n<data>
	128
	129	Each command declares a list of supported arguments and their types. If a
	130	client sends an unknown argument to the server, the server should abort
	131	immediately. The special argument ``*`` in a command's definition indicates
	132	that all argument names are allowed.
	133
	134	The definition of supported arguments and types is initially made when a
	135	new command is implemented. The client and server must initially independently
	136	agree on the arguments and their types. This initial set of arguments can be
	137	supplemented through the presence of capabilities advertised by the server.
	138
	139	Each command has a defined expected response type.
	140
	141	A ``string`` response type is a length framed value. The response consists of
	142	the string encoded integer length of a value followed by a newline (``\n``)
	143	followed by the value. Empty values are allowed (and are represented as
	144	``0\n``).
	145
	146	A ``stream`` response type consists of raw bytes of data. There is no framing.
	147
	148	A generic error response type is also supported. It consists of a an error
	149	message written to ``stderr`` followed by ``\n-\n``. In addition, ``\n`` is
	150	written to ``stdout``.
	151
	152	If the server receives an unknown command, it will send an empty ``string``
	153	response.
	154
	155	The server terminates if it receives an empty command (a ``\n`` character).