QMP/qmp-spec.txt - third_party/qemu - Git at Google

            QEMU Monitor Protocol Draft Specification - Version 0.1

 1. Introduction
 ===============

 This document specifies the QEMU Monitor Protocol (QMP), a JSON-based protocol
 which is available for applications to control QEMU at the machine-level.

 To enable QMP support, QEMU has to be run in "control mode". This is done by
 starting QEMU with the appropriate command-line options. Please, refer to the
 QEMU manual page for more information.

 2. Protocol Specification
 =========================

 This section details the protocol format. For the purpose of this document
 "Client" is any application which is communicating with QEMU in control mode,
 and "Server" is QEMU itself.

 JSON data structures, when mentioned in this document, are always in the
 following format:

     json-DATA-STRUCTURE-NAME

 Where DATA-STRUCTURE-NAME is any valid JSON data structure, as defined by
 the JSON standard:

 http://www.ietf.org/rfc/rfc4627.txt

 For convenience, json-objects mentioned in this document will have its members
 in a certain order. However, in real protocol usage json-objects members can
 be in ANY order, thus no particular order should be assumed.

 2.1 General Definitions
 -----------------------

 2.1.1 All interactions transmitted by the Server are json-objects, always
       terminating with CRLF

 2.1.2 All json-objects members are mandatory when not specified otherwise

 2.2 Server Greeting
 -------------------

 Right when connected the Server will issue a greeting message, which signals
 that the connection has been successfully established and that the Server is
 waiting for commands.

 The format is:

 { "QMP": { "capabilities": json-array } }

  Where,

 - The "capabilities" member specify the availability of features beyond the
   baseline specification

 2.3 Issuing Commands
 --------------------

 The format for command execution is:

 { "execute": json-string, "arguments": json-object, "id": json-value }

  Where,

 - The "execute" member identifies the command to be executed by the Server
 - The "arguments" member is used to pass any arguments required for the
   execution of the command, it is optional when no arguments are required
 - The "id" member is a transaction identification associated with the
   command execution, it is optional and will be part of the response if
   provided

 2.4 Commands Responses
 ----------------------

 There are two possible responses which the Server will issue as the result
 of a command execution: success or error.

 2.4.1 success
 -------------

 The success response is issued when the command execution has finished
 without errors.

 The format is:

 { "return": json-value, "id": json-value }

  Where,

 - The "return" member contains the command returned data, which is defined
   in a per-command basis or "OK" if the command does not return data
 - The "id" member contains the transaction identification associated
   with the command execution (if issued by the Client)

 2.4.2 error
 -----------

 The error response is issued when the command execution could not be
 completed because of an error condition.

 The format is:

 { "error": { "class": json-string, "data": json-value }, "id": json-value }

  Where,

 - The "class" member contains the error class name (eg. "ServiceUnavailable")
 - The "data" member contains specific error data and is defined in a
   per-command basis, it will be an empty json-object if the error has no data
 - The "id" member contains the transaction identification associated with
   the command execution (if issued by the Client)

 NOTE: Some errors can occur before the Server is able to read the "id" member,
 in these cases the "id" member will not be part of the error response, even
 if provided by the client.

 2.5 Asynchronous events
 -----------------------

 As a result of state changes, the Server may send messages unilaterally
 to the Client at any time. They are called 'asynchronous events'.

 The format is:

 { "event": json-string, "data": json-value,
   "timestamp": { "seconds": json-number, "microseconds": json-number } }

  Where,

 - The "event" member contains the event's name
 - The "data" member contains event specific data, which is defined in a
   per-event basis, it is optional
 - The "timestamp" member contains the exact time of when the event ocurred
   in the Server. It is a fixed json-object with time in seconds and
   microseconds

 For a listing of supported asynchronous events, please, refer to the
 qmp-events.txt file.

 3. QMP Examples
 ===============

 This section provides some examples of real QMP usage, in all of them
 'C' stands for 'Client' and 'S' stands for 'Server'.

 3.1 Server greeting
 -------------------

 S: {"QMP": {"capabilities": []}}

 3.2 Simple 'stop' execution
 ---------------------------

 C: { "execute": "stop" }
 S: {"return": "OK"}

 3.3 KVM information
 -------------------

 C: {"execute": "query-kvm", "id": "example"}
 S: {"return": "enabled", "id": "example"}

 3.4 Parsing error
 ------------------

 C: { "execute": }
 S: {"error": {"class": "JSONParsing", "data": {}}}

 3.5 Powerdown event
 -------------------

 S: {"timestamp": {"seconds": 1258551470, "microseconds": 802384}, "event":
 "POWERDOWN"}

 4. Notes to Client implementors
 -------------------------------

 4.1 It is recommended to always start the Server in pause mode, thus the
     Client is able to perform any setup procedure without the risk of
     race conditions and related problems

 4.2 It is recommended to always check the capabilities json-array, issued
     with the greeting message, at connection time

 4.3 Json-objects or json-arrays mentioned in this document are not fixed
     and no particular size or number of members/elements should be assumed.
     New members/elements can be added at any time.

 4.4 No particular order of json-objects members should be assumed, they
     can change at any time
	QEMU Monitor Protocol Draft Specification - Version 0.1

	1. Introduction
	===============

	This document specifies the QEMU Monitor Protocol (QMP), a JSON-based protocol
	which is available for applications to control QEMU at the machine-level.

	To enable QMP support, QEMU has to be run in "control mode". This is done by
	starting QEMU with the appropriate command-line options. Please, refer to the
	QEMU manual page for more information.

	2. Protocol Specification
	=========================

	This section details the protocol format. For the purpose of this document
	"Client" is any application which is communicating with QEMU in control mode,
	and "Server" is QEMU itself.

	JSON data structures, when mentioned in this document, are always in the
	following format:

	json-DATA-STRUCTURE-NAME

	Where DATA-STRUCTURE-NAME is any valid JSON data structure, as defined by
	the JSON standard:

	http://www.ietf.org/rfc/rfc4627.txt

	For convenience, json-objects mentioned in this document will have its members
	in a certain order. However, in real protocol usage json-objects members can
	be in ANY order, thus no particular order should be assumed.

	2.1 General Definitions
	-----------------------

	2.1.1 All interactions transmitted by the Server are json-objects, always
	terminating with CRLF

	2.1.2 All json-objects members are mandatory when not specified otherwise

	2.2 Server Greeting
	-------------------

	Right when connected the Server will issue a greeting message, which signals
	that the connection has been successfully established and that the Server is
	waiting for commands.

	The format is:

	{ "QMP": { "capabilities": json-array } }

	Where,

	- The "capabilities" member specify the availability of features beyond the
	baseline specification

	2.3 Issuing Commands
	--------------------

	The format for command execution is:

	{ "execute": json-string, "arguments": json-object, "id": json-value }

	Where,

	- The "execute" member identifies the command to be executed by the Server
	- The "arguments" member is used to pass any arguments required for the
	execution of the command, it is optional when no arguments are required
	- The "id" member is a transaction identification associated with the
	command execution, it is optional and will be part of the response if
	provided

	2.4 Commands Responses
	----------------------

	There are two possible responses which the Server will issue as the result
	of a command execution: success or error.

	2.4.1 success
	-------------

	The success response is issued when the command execution has finished
	without errors.

	The format is:

	{ "return": json-value, "id": json-value }

	Where,

	- The "return" member contains the command returned data, which is defined
	in a per-command basis or "OK" if the command does not return data
	- The "id" member contains the transaction identification associated
	with the command execution (if issued by the Client)

	2.4.2 error
	-----------

	The error response is issued when the command execution could not be
	completed because of an error condition.

	The format is:

	{ "error": { "class": json-string, "data": json-value }, "id": json-value }

	Where,

	- The "class" member contains the error class name (eg. "ServiceUnavailable")
	- The "data" member contains specific error data and is defined in a
	per-command basis, it will be an empty json-object if the error has no data
	- The "id" member contains the transaction identification associated with
	the command execution (if issued by the Client)

	NOTE: Some errors can occur before the Server is able to read the "id" member,
	in these cases the "id" member will not be part of the error response, even
	if provided by the client.

	2.5 Asynchronous events
	-----------------------

	As a result of state changes, the Server may send messages unilaterally
	to the Client at any time. They are called 'asynchronous events'.

	The format is:

	{ "event": json-string, "data": json-value,
	"timestamp": { "seconds": json-number, "microseconds": json-number } }

	Where,

	- The "event" member contains the event's name
	- The "data" member contains event specific data, which is defined in a
	per-event basis, it is optional
	- The "timestamp" member contains the exact time of when the event ocurred
	in the Server. It is a fixed json-object with time in seconds and
	microseconds

	For a listing of supported asynchronous events, please, refer to the
	qmp-events.txt file.

	3. QMP Examples
	===============

	This section provides some examples of real QMP usage, in all of them
	'C' stands for 'Client' and 'S' stands for 'Server'.

	3.1 Server greeting
	-------------------

	S: {"QMP": {"capabilities": []}}

	3.2 Simple 'stop' execution
	---------------------------

	C: { "execute": "stop" }
	S: {"return": "OK"}

	3.3 KVM information
	-------------------

	C: {"execute": "query-kvm", "id": "example"}
	S: {"return": "enabled", "id": "example"}

	3.4 Parsing error
	------------------

	C: { "execute": }
	S: {"error": {"class": "JSONParsing", "data": {}}}

	3.5 Powerdown event
	-------------------

	S: {"timestamp": {"seconds": 1258551470, "microseconds": 802384}, "event":
	"POWERDOWN"}

	4. Notes to Client implementors
	-------------------------------

	4.1 It is recommended to always start the Server in pause mode, thus the
	Client is able to perform any setup procedure without the risk of
	race conditions and related problems

	4.2 It is recommended to always check the capabilities json-array, issued
	with the greeting message, at connection time

	4.3 Json-objects or json-arrays mentioned in this document are not fixed
	and no particular size or number of members/elements should be assumed.
	New members/elements can be added at any time.

	4.4 No particular order of json-objects members should be assumed, they
	can change at any time