xref: /openbmc/qemu/qapi/misc.json (revision 31cf4b97)
1# -*- Mode: Python -*-
2#
3
4##
5# = Miscellanea
6##
7
8{ 'include': 'common.json' }
9
10##
11# @qmp_capabilities:
12#
13# Enable QMP capabilities.
14#
15# Arguments:
16#
17# @enable:   An optional list of QMPCapability values to enable.  The
18#            client must not enable any capability that is not
19#            mentioned in the QMP greeting message.  If the field is not
20#            provided, it means no QMP capabilities will be enabled.
21#            (since 2.12)
22#
23# Example:
24#
25# -> { "execute": "qmp_capabilities",
26#      "arguments": { "enable": [ "oob" ] } }
27# <- { "return": {} }
28#
29# Notes: This command is valid exactly when first connecting: it must be
30# issued before any other command will be accepted, and will fail once the
31# monitor is accepting other commands. (see qemu docs/interop/qmp-spec.txt)
32#
33# The QMP client needs to explicitly enable QMP capabilities, otherwise
34# all the QMP capabilities will be turned off by default.
35#
36# Since: 0.13
37#
38##
39{ 'command': 'qmp_capabilities',
40  'data': { '*enable': [ 'QMPCapability' ] },
41  'allow-preconfig': true }
42
43##
44# @QMPCapability:
45#
46# Enumeration of capabilities to be advertised during initial client
47# connection, used for agreeing on particular QMP extension behaviors.
48#
49# @oob:   QMP ability to support out-of-band requests.
50#         (Please refer to qmp-spec.txt for more information on OOB)
51#
52# Since: 2.12
53#
54##
55{ 'enum': 'QMPCapability',
56  'data': [ 'oob' ] }
57
58##
59# @VersionTriple:
60#
61# A three-part version number.
62#
63# @major:  The major version number.
64#
65# @minor:  The minor version number.
66#
67# @micro:  The micro version number.
68#
69# Since: 2.4
70##
71{ 'struct': 'VersionTriple',
72  'data': {'major': 'int', 'minor': 'int', 'micro': 'int'} }
73
74
75##
76# @VersionInfo:
77#
78# A description of QEMU's version.
79#
80# @qemu:        The version of QEMU.  By current convention, a micro
81#               version of 50 signifies a development branch.  A micro version
82#               greater than or equal to 90 signifies a release candidate for
83#               the next minor version.  A micro version of less than 50
84#               signifies a stable release.
85#
86# @package:     QEMU will always set this field to an empty string.  Downstream
87#               versions of QEMU should set this to a non-empty string.  The
88#               exact format depends on the downstream however it highly
89#               recommended that a unique name is used.
90#
91# Since: 0.14.0
92##
93{ 'struct': 'VersionInfo',
94  'data': {'qemu': 'VersionTriple', 'package': 'str'} }
95
96##
97# @query-version:
98#
99# Returns the current version of QEMU.
100#
101# Returns:  A @VersionInfo object describing the current version of QEMU.
102#
103# Since: 0.14.0
104#
105# Example:
106#
107# -> { "execute": "query-version" }
108# <- {
109#       "return":{
110#          "qemu":{
111#             "major":0,
112#             "minor":11,
113#             "micro":5
114#          },
115#          "package":""
116#       }
117#    }
118#
119##
120{ 'command': 'query-version', 'returns': 'VersionInfo',
121  'allow-preconfig': true }
122
123##
124# @CommandInfo:
125#
126# Information about a QMP command
127#
128# @name: The command name
129#
130# Since: 0.14.0
131##
132{ 'struct': 'CommandInfo', 'data': {'name': 'str'} }
133
134##
135# @query-commands:
136#
137# Return a list of supported QMP commands by this server
138#
139# Returns: A list of @CommandInfo for all supported commands
140#
141# Since: 0.14.0
142#
143# Example:
144#
145# -> { "execute": "query-commands" }
146# <- {
147#      "return":[
148#         {
149#            "name":"query-balloon"
150#         },
151#         {
152#            "name":"system_powerdown"
153#         }
154#      ]
155#    }
156#
157# Note: This example has been shortened as the real response is too long.
158#
159##
160{ 'command': 'query-commands', 'returns': ['CommandInfo'],
161  'allow-preconfig': true }
162
163##
164# @LostTickPolicy:
165#
166# Policy for handling lost ticks in timer devices.
167#
168# @discard: throw away the missed tick(s) and continue with future injection
169#           normally.  Guest time may be delayed, unless the OS has explicit
170#           handling of lost ticks
171#
172# @delay: continue to deliver ticks at the normal rate.  Guest time will be
173#         delayed due to the late tick
174#
175# @merge: merge the missed tick(s) into one tick and inject.  Guest time
176#         may be delayed, depending on how the OS reacts to the merging
177#         of ticks
178#
179# @slew: deliver ticks at a higher rate to catch up with the missed tick. The
180#        guest time should not be delayed once catchup is complete.
181#
182# Since: 2.0
183##
184{ 'enum': 'LostTickPolicy',
185  'data': ['discard', 'delay', 'merge', 'slew' ] }
186
187##
188# @add_client:
189#
190# Allow client connections for VNC, Spice and socket based
191# character devices to be passed in to QEMU via SCM_RIGHTS.
192#
193# @protocol: protocol name. Valid names are "vnc", "spice" or the
194#            name of a character device (eg. from -chardev id=XXXX)
195#
196# @fdname: file descriptor name previously passed via 'getfd' command
197#
198# @skipauth: whether to skip authentication. Only applies
199#            to "vnc" and "spice" protocols
200#
201# @tls: whether to perform TLS. Only applies to the "spice"
202#       protocol
203#
204# Returns: nothing on success.
205#
206# Since: 0.14.0
207#
208# Example:
209#
210# -> { "execute": "add_client", "arguments": { "protocol": "vnc",
211#                                              "fdname": "myclient" } }
212# <- { "return": {} }
213#
214##
215{ 'command': 'add_client',
216  'data': { 'protocol': 'str', 'fdname': 'str', '*skipauth': 'bool',
217            '*tls': 'bool' } }
218
219##
220# @NameInfo:
221#
222# Guest name information.
223#
224# @name: The name of the guest
225#
226# Since: 0.14.0
227##
228{ 'struct': 'NameInfo', 'data': {'*name': 'str'} }
229
230##
231# @query-name:
232#
233# Return the name information of a guest.
234#
235# Returns: @NameInfo of the guest
236#
237# Since: 0.14.0
238#
239# Example:
240#
241# -> { "execute": "query-name" }
242# <- { "return": { "name": "qemu-name" } }
243#
244##
245{ 'command': 'query-name', 'returns': 'NameInfo', 'allow-preconfig': true }
246
247##
248# @KvmInfo:
249#
250# Information about support for KVM acceleration
251#
252# @enabled: true if KVM acceleration is active
253#
254# @present: true if KVM acceleration is built into this executable
255#
256# Since: 0.14.0
257##
258{ 'struct': 'KvmInfo', 'data': {'enabled': 'bool', 'present': 'bool'} }
259
260##
261# @query-kvm:
262#
263# Returns information about KVM acceleration
264#
265# Returns: @KvmInfo
266#
267# Since: 0.14.0
268#
269# Example:
270#
271# -> { "execute": "query-kvm" }
272# <- { "return": { "enabled": true, "present": true } }
273#
274##
275{ 'command': 'query-kvm', 'returns': 'KvmInfo' }
276
277##
278# @UuidInfo:
279#
280# Guest UUID information (Universally Unique Identifier).
281#
282# @UUID: the UUID of the guest
283#
284# Since: 0.14.0
285#
286# Notes: If no UUID was specified for the guest, a null UUID is returned.
287##
288{ 'struct': 'UuidInfo', 'data': {'UUID': 'str'} }
289
290##
291# @query-uuid:
292#
293# Query the guest UUID information.
294#
295# Returns: The @UuidInfo for the guest
296#
297# Since: 0.14.0
298#
299# Example:
300#
301# -> { "execute": "query-uuid" }
302# <- { "return": { "UUID": "550e8400-e29b-41d4-a716-446655440000" } }
303#
304##
305{ 'command': 'query-uuid', 'returns': 'UuidInfo', 'allow-preconfig': true }
306
307##
308# @EventInfo:
309#
310# Information about a QMP event
311#
312# @name: The event name
313#
314# Since: 1.2.0
315##
316{ 'struct': 'EventInfo', 'data': {'name': 'str'} }
317
318##
319# @query-events:
320#
321# Return a list of supported QMP events by this server
322#
323# Returns: A list of @EventInfo for all supported events
324#
325# Since: 1.2.0
326#
327# Example:
328#
329# -> { "execute": "query-events" }
330# <- {
331#      "return": [
332#          {
333#             "name":"SHUTDOWN"
334#          },
335#          {
336#             "name":"RESET"
337#          }
338#       ]
339#    }
340#
341# Note: This example has been shortened as the real response is too long.
342#
343##
344{ 'command': 'query-events', 'returns': ['EventInfo'] }
345
346##
347# @CpuInfoArch:
348#
349# An enumeration of cpu types that enable additional information during
350# @query-cpus and @query-cpus-fast.
351#
352# @s390: since 2.12
353#
354# @riscv: since 2.12
355#
356# Since: 2.6
357##
358{ 'enum': 'CpuInfoArch',
359  'data': ['x86', 'sparc', 'ppc', 'mips', 'tricore', 's390', 'riscv', 'other' ] }
360
361##
362# @CpuInfo:
363#
364# Information about a virtual CPU
365#
366# @CPU: the index of the virtual CPU
367#
368# @current: this only exists for backwards compatibility and should be ignored
369#
370# @halted: true if the virtual CPU is in the halt state.  Halt usually refers
371#          to a processor specific low power mode.
372#
373# @qom_path: path to the CPU object in the QOM tree (since 2.4)
374#
375# @thread_id: ID of the underlying host thread
376#
377# @props: properties describing to which node/socket/core/thread
378#         virtual CPU belongs to, provided if supported by board (since 2.10)
379#
380# @arch: architecture of the cpu, which determines which additional fields
381#        will be listed (since 2.6)
382#
383# Since: 0.14.0
384#
385# Notes: @halted is a transient state that changes frequently.  By the time the
386#        data is sent to the client, the guest may no longer be halted.
387##
388{ 'union': 'CpuInfo',
389  'base': {'CPU': 'int', 'current': 'bool', 'halted': 'bool',
390           'qom_path': 'str', 'thread_id': 'int',
391           '*props': 'CpuInstanceProperties', 'arch': 'CpuInfoArch' },
392  'discriminator': 'arch',
393  'data': { 'x86': 'CpuInfoX86',
394            'sparc': 'CpuInfoSPARC',
395            'ppc': 'CpuInfoPPC',
396            'mips': 'CpuInfoMIPS',
397            'tricore': 'CpuInfoTricore',
398            's390': 'CpuInfoS390',
399            'riscv': 'CpuInfoRISCV' } }
400
401##
402# @CpuInfoX86:
403#
404# Additional information about a virtual i386 or x86_64 CPU
405#
406# @pc: the 64-bit instruction pointer
407#
408# Since: 2.6
409##
410{ 'struct': 'CpuInfoX86', 'data': { 'pc': 'int' } }
411
412##
413# @CpuInfoSPARC:
414#
415# Additional information about a virtual SPARC CPU
416#
417# @pc: the PC component of the instruction pointer
418#
419# @npc: the NPC component of the instruction pointer
420#
421# Since: 2.6
422##
423{ 'struct': 'CpuInfoSPARC', 'data': { 'pc': 'int', 'npc': 'int' } }
424
425##
426# @CpuInfoPPC:
427#
428# Additional information about a virtual PPC CPU
429#
430# @nip: the instruction pointer
431#
432# Since: 2.6
433##
434{ 'struct': 'CpuInfoPPC', 'data': { 'nip': 'int' } }
435
436##
437# @CpuInfoMIPS:
438#
439# Additional information about a virtual MIPS CPU
440#
441# @PC: the instruction pointer
442#
443# Since: 2.6
444##
445{ 'struct': 'CpuInfoMIPS', 'data': { 'PC': 'int' } }
446
447##
448# @CpuInfoTricore:
449#
450# Additional information about a virtual Tricore CPU
451#
452# @PC: the instruction pointer
453#
454# Since: 2.6
455##
456{ 'struct': 'CpuInfoTricore', 'data': { 'PC': 'int' } }
457
458##
459# @CpuInfoRISCV:
460#
461# Additional information about a virtual RISCV CPU
462#
463# @pc: the instruction pointer
464#
465# Since 2.12
466##
467{ 'struct': 'CpuInfoRISCV', 'data': { 'pc': 'int' } }
468
469##
470# @CpuS390State:
471#
472# An enumeration of cpu states that can be assumed by a virtual
473# S390 CPU
474#
475# Since: 2.12
476##
477{ 'enum': 'CpuS390State',
478  'prefix': 'S390_CPU_STATE',
479  'data': [ 'uninitialized', 'stopped', 'check-stop', 'operating', 'load' ] }
480
481##
482# @CpuInfoS390:
483#
484# Additional information about a virtual S390 CPU
485#
486# @cpu-state: the virtual CPU's state
487#
488# Since: 2.12
489##
490{ 'struct': 'CpuInfoS390', 'data': { 'cpu-state': 'CpuS390State' } }
491
492##
493# @query-cpus:
494#
495# Returns a list of information about each virtual CPU.
496#
497# This command causes vCPU threads to exit to userspace, which causes
498# a small interruption to guest CPU execution. This will have a negative
499# impact on realtime guests and other latency sensitive guest workloads.
500# It is recommended to use @query-cpus-fast instead of this command to
501# avoid the vCPU interruption.
502#
503# Returns: a list of @CpuInfo for each virtual CPU
504#
505# Since: 0.14.0
506#
507# Example:
508#
509# -> { "execute": "query-cpus" }
510# <- { "return": [
511#          {
512#             "CPU":0,
513#             "current":true,
514#             "halted":false,
515#             "qom_path":"/machine/unattached/device[0]",
516#             "arch":"x86",
517#             "pc":3227107138,
518#             "thread_id":3134
519#          },
520#          {
521#             "CPU":1,
522#             "current":false,
523#             "halted":true,
524#             "qom_path":"/machine/unattached/device[2]",
525#             "arch":"x86",
526#             "pc":7108165,
527#             "thread_id":3135
528#          }
529#       ]
530#    }
531#
532# Notes: This interface is deprecated (since 2.12.0), and it is strongly
533#        recommended that you avoid using it. Use @query-cpus-fast to
534#        obtain information about virtual CPUs.
535#
536##
537{ 'command': 'query-cpus', 'returns': ['CpuInfo'] }
538
539##
540# @CpuInfoFast:
541#
542# Information about a virtual CPU
543#
544# @cpu-index: index of the virtual CPU
545#
546# @qom-path: path to the CPU object in the QOM tree
547#
548# @thread-id: ID of the underlying host thread
549#
550# @props: properties describing to which node/socket/core/thread
551#         virtual CPU belongs to, provided if supported by board
552#
553# @arch: base architecture of the cpu; deprecated since 3.0.0 in favor
554#        of @target
555#
556# @target: the QEMU system emulation target, which determines which
557#          additional fields will be listed (since 3.0)
558#
559# Since: 2.12
560#
561##
562{ 'union'         : 'CpuInfoFast',
563  'base'          : { 'cpu-index'    : 'int',
564                      'qom-path'     : 'str',
565                      'thread-id'    : 'int',
566                      '*props'       : 'CpuInstanceProperties',
567                      'arch'         : 'CpuInfoArch',
568                      'target'       : 'SysEmuTarget' },
569  'discriminator' : 'target',
570  'data'          : { 's390x'        : 'CpuInfoS390' } }
571
572##
573# @query-cpus-fast:
574#
575# Returns information about all virtual CPUs. This command does not
576# incur a performance penalty and should be used in production
577# instead of query-cpus.
578#
579# Returns: list of @CpuInfoFast
580#
581# Since: 2.12
582#
583# Example:
584#
585# -> { "execute": "query-cpus-fast" }
586# <- { "return": [
587#         {
588#             "thread-id": 25627,
589#             "props": {
590#                 "core-id": 0,
591#                 "thread-id": 0,
592#                 "socket-id": 0
593#             },
594#             "qom-path": "/machine/unattached/device[0]",
595#             "arch":"x86",
596#             "target":"x86_64",
597#             "cpu-index": 0
598#         },
599#         {
600#             "thread-id": 25628,
601#             "props": {
602#                 "core-id": 0,
603#                 "thread-id": 0,
604#                 "socket-id": 1
605#             },
606#             "qom-path": "/machine/unattached/device[2]",
607#             "arch":"x86",
608#             "target":"x86_64",
609#             "cpu-index": 1
610#         }
611#     ]
612# }
613##
614{ 'command': 'query-cpus-fast', 'returns': [ 'CpuInfoFast' ] }
615
616##
617# @IOThreadInfo:
618#
619# Information about an iothread
620#
621# @id: the identifier of the iothread
622#
623# @thread-id: ID of the underlying host thread
624#
625# @poll-max-ns: maximum polling time in ns, 0 means polling is disabled
626#               (since 2.9)
627#
628# @poll-grow: how many ns will be added to polling time, 0 means that it's not
629#             configured (since 2.9)
630#
631# @poll-shrink: how many ns will be removed from polling time, 0 means that
632#               it's not configured (since 2.9)
633#
634# Since: 2.0
635##
636{ 'struct': 'IOThreadInfo',
637  'data': {'id': 'str',
638           'thread-id': 'int',
639           'poll-max-ns': 'int',
640           'poll-grow': 'int',
641           'poll-shrink': 'int' } }
642
643##
644# @query-iothreads:
645#
646# Returns a list of information about each iothread.
647#
648# Note: this list excludes the QEMU main loop thread, which is not declared
649# using the -object iothread command-line option.  It is always the main thread
650# of the process.
651#
652# Returns: a list of @IOThreadInfo for each iothread
653#
654# Since: 2.0
655#
656# Example:
657#
658# -> { "execute": "query-iothreads" }
659# <- { "return": [
660#          {
661#             "id":"iothread0",
662#             "thread-id":3134
663#          },
664#          {
665#             "id":"iothread1",
666#             "thread-id":3135
667#          }
668#       ]
669#    }
670#
671##
672{ 'command': 'query-iothreads', 'returns': ['IOThreadInfo'],
673  'allow-preconfig': true }
674
675##
676# @BalloonInfo:
677#
678# Information about the guest balloon device.
679#
680# @actual: the number of bytes the balloon currently contains
681#
682# Since: 0.14.0
683#
684##
685{ 'struct': 'BalloonInfo', 'data': {'actual': 'int' } }
686
687##
688# @query-balloon:
689#
690# Return information about the balloon device.
691#
692# Returns: @BalloonInfo on success
693#
694#          If the balloon driver is enabled but not functional because the KVM
695#          kernel module cannot support it, KvmMissingCap
696#
697#          If no balloon device is present, DeviceNotActive
698#
699# Since: 0.14.0
700#
701# Example:
702#
703# -> { "execute": "query-balloon" }
704# <- { "return": {
705#          "actual": 1073741824,
706#       }
707#    }
708#
709##
710{ 'command': 'query-balloon', 'returns': 'BalloonInfo' }
711
712##
713# @BALLOON_CHANGE:
714#
715# Emitted when the guest changes the actual BALLOON level. This value is
716# equivalent to the @actual field return by the 'query-balloon' command
717#
718# @actual: actual level of the guest memory balloon in bytes
719#
720# Note: this event is rate-limited.
721#
722# Since: 1.2
723#
724# Example:
725#
726# <- { "event": "BALLOON_CHANGE",
727#      "data": { "actual": 944766976 },
728#      "timestamp": { "seconds": 1267020223, "microseconds": 435656 } }
729#
730##
731{ 'event': 'BALLOON_CHANGE',
732  'data': { 'actual': 'int' } }
733
734##
735# @PciMemoryRange:
736#
737# A PCI device memory region
738#
739# @base: the starting address (guest physical)
740#
741# @limit: the ending address (guest physical)
742#
743# Since: 0.14.0
744##
745{ 'struct': 'PciMemoryRange', 'data': {'base': 'int', 'limit': 'int'} }
746
747##
748# @PciMemoryRegion:
749#
750# Information about a PCI device I/O region.
751#
752# @bar: the index of the Base Address Register for this region
753#
754# @type: 'io' if the region is a PIO region
755#        'memory' if the region is a MMIO region
756#
757# @size: memory size
758#
759# @prefetch: if @type is 'memory', true if the memory is prefetchable
760#
761# @mem_type_64: if @type is 'memory', true if the BAR is 64-bit
762#
763# Since: 0.14.0
764##
765{ 'struct': 'PciMemoryRegion',
766  'data': {'bar': 'int', 'type': 'str', 'address': 'int', 'size': 'int',
767           '*prefetch': 'bool', '*mem_type_64': 'bool' } }
768
769##
770# @PciBusInfo:
771#
772# Information about a bus of a PCI Bridge device
773#
774# @number: primary bus interface number.  This should be the number of the
775#          bus the device resides on.
776#
777# @secondary: secondary bus interface number.  This is the number of the
778#             main bus for the bridge
779#
780# @subordinate: This is the highest number bus that resides below the
781#               bridge.
782#
783# @io_range: The PIO range for all devices on this bridge
784#
785# @memory_range: The MMIO range for all devices on this bridge
786#
787# @prefetchable_range: The range of prefetchable MMIO for all devices on
788#                      this bridge
789#
790# Since: 2.4
791##
792{ 'struct': 'PciBusInfo',
793  'data': {'number': 'int', 'secondary': 'int', 'subordinate': 'int',
794           'io_range': 'PciMemoryRange',
795           'memory_range': 'PciMemoryRange',
796           'prefetchable_range': 'PciMemoryRange' } }
797
798##
799# @PciBridgeInfo:
800#
801# Information about a PCI Bridge device
802#
803# @bus: information about the bus the device resides on
804#
805# @devices: a list of @PciDeviceInfo for each device on this bridge
806#
807# Since: 0.14.0
808##
809{ 'struct': 'PciBridgeInfo',
810  'data': {'bus': 'PciBusInfo', '*devices': ['PciDeviceInfo']} }
811
812##
813# @PciDeviceClass:
814#
815# Information about the Class of a PCI device
816#
817# @desc: a string description of the device's class
818#
819# @class: the class code of the device
820#
821# Since: 2.4
822##
823{ 'struct': 'PciDeviceClass',
824  'data': {'*desc': 'str', 'class': 'int'} }
825
826##
827# @PciDeviceId:
828#
829# Information about the Id of a PCI device
830#
831# @device: the PCI device id
832#
833# @vendor: the PCI vendor id
834#
835# @subsystem: the PCI subsystem id (since 3.1)
836#
837# @subsystem-vendor: the PCI subsystem vendor id (since 3.1)
838#
839# Since: 2.4
840##
841{ 'struct': 'PciDeviceId',
842  'data': {'device': 'int', 'vendor': 'int', '*subsystem': 'int',
843            '*subsystem-vendor': 'int'} }
844
845##
846# @PciDeviceInfo:
847#
848# Information about a PCI device
849#
850# @bus: the bus number of the device
851#
852# @slot: the slot the device is located in
853#
854# @function: the function of the slot used by the device
855#
856# @class_info: the class of the device
857#
858# @id: the PCI device id
859#
860# @irq: if an IRQ is assigned to the device, the IRQ number
861#
862# @qdev_id: the device name of the PCI device
863#
864# @pci_bridge: if the device is a PCI bridge, the bridge information
865#
866# @regions: a list of the PCI I/O regions associated with the device
867#
868# Notes: the contents of @class_info.desc are not stable and should only be
869#        treated as informational.
870#
871# Since: 0.14.0
872##
873{ 'struct': 'PciDeviceInfo',
874  'data': {'bus': 'int', 'slot': 'int', 'function': 'int',
875           'class_info': 'PciDeviceClass', 'id': 'PciDeviceId',
876           '*irq': 'int', 'qdev_id': 'str', '*pci_bridge': 'PciBridgeInfo',
877           'regions': ['PciMemoryRegion']} }
878
879##
880# @PciInfo:
881#
882# Information about a PCI bus
883#
884# @bus: the bus index
885#
886# @devices: a list of devices on this bus
887#
888# Since: 0.14.0
889##
890{ 'struct': 'PciInfo', 'data': {'bus': 'int', 'devices': ['PciDeviceInfo']} }
891
892##
893# @query-pci:
894#
895# Return information about the PCI bus topology of the guest.
896#
897# Returns: a list of @PciInfo for each PCI bus. Each bus is
898# represented by a json-object, which has a key with a json-array of
899# all PCI devices attached to it. Each device is represented by a
900# json-object.
901#
902# Since: 0.14.0
903#
904# Example:
905#
906# -> { "execute": "query-pci" }
907# <- { "return": [
908#          {
909#             "bus": 0,
910#             "devices": [
911#                {
912#                   "bus": 0,
913#                   "qdev_id": "",
914#                   "slot": 0,
915#                   "class_info": {
916#                      "class": 1536,
917#                      "desc": "Host bridge"
918#                   },
919#                   "id": {
920#                      "device": 32902,
921#                      "vendor": 4663
922#                   },
923#                   "function": 0,
924#                   "regions": [
925#                   ]
926#                },
927#                {
928#                   "bus": 0,
929#                   "qdev_id": "",
930#                   "slot": 1,
931#                   "class_info": {
932#                      "class": 1537,
933#                      "desc": "ISA bridge"
934#                   },
935#                   "id": {
936#                      "device": 32902,
937#                      "vendor": 28672
938#                   },
939#                   "function": 0,
940#                   "regions": [
941#                   ]
942#                },
943#                {
944#                   "bus": 0,
945#                   "qdev_id": "",
946#                   "slot": 1,
947#                   "class_info": {
948#                      "class": 257,
949#                      "desc": "IDE controller"
950#                   },
951#                   "id": {
952#                      "device": 32902,
953#                      "vendor": 28688
954#                   },
955#                   "function": 1,
956#                   "regions": [
957#                      {
958#                         "bar": 4,
959#                         "size": 16,
960#                         "address": 49152,
961#                         "type": "io"
962#                      }
963#                   ]
964#                },
965#                {
966#                   "bus": 0,
967#                   "qdev_id": "",
968#                   "slot": 2,
969#                   "class_info": {
970#                      "class": 768,
971#                      "desc": "VGA controller"
972#                   },
973#                   "id": {
974#                      "device": 4115,
975#                      "vendor": 184
976#                   },
977#                   "function": 0,
978#                   "regions": [
979#                      {
980#                         "prefetch": true,
981#                         "mem_type_64": false,
982#                         "bar": 0,
983#                         "size": 33554432,
984#                         "address": 4026531840,
985#                         "type": "memory"
986#                      },
987#                      {
988#                         "prefetch": false,
989#                         "mem_type_64": false,
990#                         "bar": 1,
991#                         "size": 4096,
992#                         "address": 4060086272,
993#                         "type": "memory"
994#                      },
995#                      {
996#                         "prefetch": false,
997#                         "mem_type_64": false,
998#                         "bar": 6,
999#                         "size": 65536,
1000#                         "address": -1,
1001#                         "type": "memory"
1002#                      }
1003#                   ]
1004#                },
1005#                {
1006#                   "bus": 0,
1007#                   "qdev_id": "",
1008#                   "irq": 11,
1009#                   "slot": 4,
1010#                   "class_info": {
1011#                      "class": 1280,
1012#                      "desc": "RAM controller"
1013#                   },
1014#                   "id": {
1015#                      "device": 6900,
1016#                      "vendor": 4098
1017#                   },
1018#                   "function": 0,
1019#                   "regions": [
1020#                      {
1021#                         "bar": 0,
1022#                         "size": 32,
1023#                         "address": 49280,
1024#                         "type": "io"
1025#                      }
1026#                   ]
1027#                }
1028#             ]
1029#          }
1030#       ]
1031#    }
1032#
1033# Note: This example has been shortened as the real response is too long.
1034#
1035##
1036{ 'command': 'query-pci', 'returns': ['PciInfo'] }
1037
1038##
1039# @quit:
1040#
1041# This command will cause the QEMU process to exit gracefully.  While every
1042# attempt is made to send the QMP response before terminating, this is not
1043# guaranteed.  When using this interface, a premature EOF would not be
1044# unexpected.
1045#
1046# Since: 0.14.0
1047#
1048# Example:
1049#
1050# -> { "execute": "quit" }
1051# <- { "return": {} }
1052##
1053{ 'command': 'quit' }
1054
1055##
1056# @stop:
1057#
1058# Stop all guest VCPU execution.
1059#
1060# Since:  0.14.0
1061#
1062# Notes:  This function will succeed even if the guest is already in the stopped
1063#         state.  In "inmigrate" state, it will ensure that the guest
1064#         remains paused once migration finishes, as if the -S option was
1065#         passed on the command line.
1066#
1067# Example:
1068#
1069# -> { "execute": "stop" }
1070# <- { "return": {} }
1071#
1072##
1073{ 'command': 'stop' }
1074
1075##
1076# @system_reset:
1077#
1078# Performs a hard reset of a guest.
1079#
1080# Since: 0.14.0
1081#
1082# Example:
1083#
1084# -> { "execute": "system_reset" }
1085# <- { "return": {} }
1086#
1087##
1088{ 'command': 'system_reset' }
1089
1090##
1091# @system_powerdown:
1092#
1093# Requests that a guest perform a powerdown operation.
1094#
1095# Since: 0.14.0
1096#
1097# Notes: A guest may or may not respond to this command.  This command
1098#        returning does not indicate that a guest has accepted the request or
1099#        that it has shut down.  Many guests will respond to this command by
1100#        prompting the user in some way.
1101# Example:
1102#
1103# -> { "execute": "system_powerdown" }
1104# <- { "return": {} }
1105#
1106##
1107{ 'command': 'system_powerdown' }
1108
1109##
1110# @cpu-add:
1111#
1112# Adds CPU with specified ID.
1113#
1114# @id: ID of CPU to be created, valid values [0..max_cpus)
1115#
1116# Returns: Nothing on success
1117#
1118# Since: 1.5
1119#
1120# Note: This command is deprecated.  The `device_add` command should be
1121#       used instead.  See the `query-hotpluggable-cpus` command for
1122#       details.
1123#
1124# Example:
1125#
1126# -> { "execute": "cpu-add", "arguments": { "id": 2 } }
1127# <- { "return": {} }
1128#
1129##
1130{ 'command': 'cpu-add', 'data': {'id': 'int'} }
1131
1132##
1133# @memsave:
1134#
1135# Save a portion of guest memory to a file.
1136#
1137# @val: the virtual address of the guest to start from
1138#
1139# @size: the size of memory region to save
1140#
1141# @filename: the file to save the memory to as binary data
1142#
1143# @cpu-index: the index of the virtual CPU to use for translating the
1144#                       virtual address (defaults to CPU 0)
1145#
1146# Returns: Nothing on success
1147#
1148# Since: 0.14.0
1149#
1150# Notes: Errors were not reliably returned until 1.1
1151#
1152# Example:
1153#
1154# -> { "execute": "memsave",
1155#      "arguments": { "val": 10,
1156#                     "size": 100,
1157#                     "filename": "/tmp/virtual-mem-dump" } }
1158# <- { "return": {} }
1159#
1160##
1161{ 'command': 'memsave',
1162  'data': {'val': 'int', 'size': 'int', 'filename': 'str', '*cpu-index': 'int'} }
1163
1164##
1165# @pmemsave:
1166#
1167# Save a portion of guest physical memory to a file.
1168#
1169# @val: the physical address of the guest to start from
1170#
1171# @size: the size of memory region to save
1172#
1173# @filename: the file to save the memory to as binary data
1174#
1175# Returns: Nothing on success
1176#
1177# Since: 0.14.0
1178#
1179# Notes: Errors were not reliably returned until 1.1
1180#
1181# Example:
1182#
1183# -> { "execute": "pmemsave",
1184#      "arguments": { "val": 10,
1185#                     "size": 100,
1186#                     "filename": "/tmp/physical-mem-dump" } }
1187# <- { "return": {} }
1188#
1189##
1190{ 'command': 'pmemsave',
1191  'data': {'val': 'int', 'size': 'int', 'filename': 'str'} }
1192
1193##
1194# @cont:
1195#
1196# Resume guest VCPU execution.
1197#
1198# Since:  0.14.0
1199#
1200# Returns:  If successful, nothing
1201#
1202# Notes:  This command will succeed if the guest is currently running.  It
1203#         will also succeed if the guest is in the "inmigrate" state; in
1204#         this case, the effect of the command is to make sure the guest
1205#         starts once migration finishes, removing the effect of the -S
1206#         command line option if it was passed.
1207#
1208# Example:
1209#
1210# -> { "execute": "cont" }
1211# <- { "return": {} }
1212#
1213##
1214{ 'command': 'cont' }
1215
1216##
1217# @x-exit-preconfig:
1218#
1219# Exit from "preconfig" state
1220#
1221# This command makes QEMU exit the preconfig state and proceed with
1222# VM initialization using configuration data provided on the command line
1223# and via the QMP monitor during the preconfig state. The command is only
1224# available during the preconfig state (i.e. when the --preconfig command
1225# line option was in use).
1226#
1227# Since 3.0
1228#
1229# Returns: nothing
1230#
1231# Example:
1232#
1233# -> { "execute": "x-exit-preconfig" }
1234# <- { "return": {} }
1235#
1236##
1237{ 'command': 'x-exit-preconfig', 'allow-preconfig': true }
1238
1239##
1240# @system_wakeup:
1241#
1242# Wake up guest from suspend. If the guest has wake-up from suspend
1243# support enabled (wakeup-suspend-support flag from
1244# query-current-machine), wake-up guest from suspend if the guest is
1245# in SUSPENDED state. Return an error otherwise.
1246#
1247# Since:  1.1
1248#
1249# Returns:  nothing.
1250#
1251# Note: prior to 4.0, this command does nothing in case the guest
1252# isn't suspended.
1253#
1254# Example:
1255#
1256# -> { "execute": "system_wakeup" }
1257# <- { "return": {} }
1258#
1259##
1260{ 'command': 'system_wakeup' }
1261
1262##
1263# @inject-nmi:
1264#
1265# Injects a Non-Maskable Interrupt into the default CPU (x86/s390) or all CPUs (ppc64).
1266# The command fails when the guest doesn't support injecting.
1267#
1268# Returns:  If successful, nothing
1269#
1270# Since:  0.14.0
1271#
1272# Note: prior to 2.1, this command was only supported for x86 and s390 VMs
1273#
1274# Example:
1275#
1276# -> { "execute": "inject-nmi" }
1277# <- { "return": {} }
1278#
1279##
1280{ 'command': 'inject-nmi' }
1281
1282##
1283# @balloon:
1284#
1285# Request the balloon driver to change its balloon size.
1286#
1287# @value: the target size of the balloon in bytes
1288#
1289# Returns: Nothing on success
1290#          If the balloon driver is enabled but not functional because the KVM
1291#            kernel module cannot support it, KvmMissingCap
1292#          If no balloon device is present, DeviceNotActive
1293#
1294# Notes: This command just issues a request to the guest.  When it returns,
1295#        the balloon size may not have changed.  A guest can change the balloon
1296#        size independent of this command.
1297#
1298# Since: 0.14.0
1299#
1300# Example:
1301#
1302# -> { "execute": "balloon", "arguments": { "value": 536870912 } }
1303# <- { "return": {} }
1304#
1305##
1306{ 'command': 'balloon', 'data': {'value': 'int'} }
1307
1308##
1309# @human-monitor-command:
1310#
1311# Execute a command on the human monitor and return the output.
1312#
1313# @command-line: the command to execute in the human monitor
1314#
1315# @cpu-index: The CPU to use for commands that require an implicit CPU
1316#
1317# Returns: the output of the command as a string
1318#
1319# Since: 0.14.0
1320#
1321# Notes: This command only exists as a stop-gap.  Its use is highly
1322#        discouraged.  The semantics of this command are not
1323#        guaranteed: this means that command names, arguments and
1324#        responses can change or be removed at ANY time.  Applications
1325#        that rely on long term stability guarantees should NOT
1326#        use this command.
1327#
1328#        Known limitations:
1329#
1330#        * This command is stateless, this means that commands that depend
1331#          on state information (such as getfd) might not work
1332#
1333#        * Commands that prompt the user for data don't currently work
1334#
1335# Example:
1336#
1337# -> { "execute": "human-monitor-command",
1338#      "arguments": { "command-line": "info kvm" } }
1339# <- { "return": "kvm support: enabled\r\n" }
1340#
1341##
1342{ 'command': 'human-monitor-command',
1343  'data': {'command-line': 'str', '*cpu-index': 'int'},
1344  'returns': 'str' }
1345
1346##
1347# @ObjectPropertyInfo:
1348#
1349# @name: the name of the property
1350#
1351# @type: the type of the property.  This will typically come in one of four
1352#        forms:
1353#
1354#        1) A primitive type such as 'u8', 'u16', 'bool', 'str', or 'double'.
1355#           These types are mapped to the appropriate JSON type.
1356#
1357#        2) A child type in the form 'child<subtype>' where subtype is a qdev
1358#           device type name.  Child properties create the composition tree.
1359#
1360#        3) A link type in the form 'link<subtype>' where subtype is a qdev
1361#           device type name.  Link properties form the device model graph.
1362#
1363# @description: if specified, the description of the property.
1364#
1365# Since: 1.2
1366##
1367{ 'struct': 'ObjectPropertyInfo',
1368  'data': { 'name': 'str', 'type': 'str', '*description': 'str' } }
1369
1370##
1371# @qom-list:
1372#
1373# This command will list any properties of a object given a path in the object
1374# model.
1375#
1376# @path: the path within the object model.  See @qom-get for a description of
1377#        this parameter.
1378#
1379# Returns: a list of @ObjectPropertyInfo that describe the properties of the
1380#          object.
1381#
1382# Since: 1.2
1383##
1384{ 'command': 'qom-list',
1385  'data': { 'path': 'str' },
1386  'returns': [ 'ObjectPropertyInfo' ],
1387  'allow-preconfig': true }
1388
1389##
1390# @qom-get:
1391#
1392# This command will get a property from a object model path and return the
1393# value.
1394#
1395# @path: The path within the object model.  There are two forms of supported
1396#        paths--absolute and partial paths.
1397#
1398#        Absolute paths are derived from the root object and can follow child<>
1399#        or link<> properties.  Since they can follow link<> properties, they
1400#        can be arbitrarily long.  Absolute paths look like absolute filenames
1401#        and are prefixed  with a leading slash.
1402#
1403#        Partial paths look like relative filenames.  They do not begin
1404#        with a prefix.  The matching rules for partial paths are subtle but
1405#        designed to make specifying objects easy.  At each level of the
1406#        composition tree, the partial path is matched as an absolute path.
1407#        The first match is not returned.  At least two matches are searched
1408#        for.  A successful result is only returned if only one match is
1409#        found.  If more than one match is found, a flag is return to
1410#        indicate that the match was ambiguous.
1411#
1412# @property: The property name to read
1413#
1414# Returns: The property value.  The type depends on the property
1415#          type. child<> and link<> properties are returned as #str
1416#          pathnames.  All integer property types (u8, u16, etc) are
1417#          returned as #int.
1418#
1419# Since: 1.2
1420##
1421{ 'command': 'qom-get',
1422  'data': { 'path': 'str', 'property': 'str' },
1423  'returns': 'any',
1424  'allow-preconfig': true }
1425
1426##
1427# @qom-set:
1428#
1429# This command will set a property from a object model path.
1430#
1431# @path: see @qom-get for a description of this parameter
1432#
1433# @property: the property name to set
1434#
1435# @value: a value who's type is appropriate for the property type.  See @qom-get
1436#         for a description of type mapping.
1437#
1438# Since: 1.2
1439##
1440{ 'command': 'qom-set',
1441  'data': { 'path': 'str', 'property': 'str', 'value': 'any' },
1442  'allow-preconfig': true }
1443
1444##
1445# @change:
1446#
1447# This command is multiple commands multiplexed together.
1448#
1449# @device: This is normally the name of a block device but it may also be 'vnc'.
1450#          when it's 'vnc', then sub command depends on @target
1451#
1452# @target: If @device is a block device, then this is the new filename.
1453#          If @device is 'vnc', then if the value 'password' selects the vnc
1454#          change password command.   Otherwise, this specifies a new server URI
1455#          address to listen to for VNC connections.
1456#
1457# @arg:    If @device is a block device, then this is an optional format to open
1458#          the device with.
1459#          If @device is 'vnc' and @target is 'password', this is the new VNC
1460#          password to set.  See change-vnc-password for additional notes.
1461#
1462# Returns: Nothing on success.
1463#          If @device is not a valid block device, DeviceNotFound
1464#
1465# Notes:  This interface is deprecated, and it is strongly recommended that you
1466#         avoid using it.  For changing block devices, use
1467#         blockdev-change-medium; for changing VNC parameters, use
1468#         change-vnc-password.
1469#
1470# Since: 0.14.0
1471#
1472# Example:
1473#
1474# 1. Change a removable medium
1475#
1476# -> { "execute": "change",
1477#      "arguments": { "device": "ide1-cd0",
1478#                     "target": "/srv/images/Fedora-12-x86_64-DVD.iso" } }
1479# <- { "return": {} }
1480#
1481# 2. Change VNC password
1482#
1483# -> { "execute": "change",
1484#      "arguments": { "device": "vnc", "target": "password",
1485#                     "arg": "foobar1" } }
1486# <- { "return": {} }
1487#
1488##
1489{ 'command': 'change',
1490  'data': {'device': 'str', 'target': 'str', '*arg': 'str'} }
1491
1492##
1493# @ObjectTypeInfo:
1494#
1495# This structure describes a search result from @qom-list-types
1496#
1497# @name: the type name found in the search
1498#
1499# @abstract: the type is abstract and can't be directly instantiated.
1500#            Omitted if false. (since 2.10)
1501#
1502# @parent: Name of parent type, if any (since 2.10)
1503#
1504# Since: 1.1
1505##
1506{ 'struct': 'ObjectTypeInfo',
1507  'data': { 'name': 'str', '*abstract': 'bool', '*parent': 'str' } }
1508
1509##
1510# @qom-list-types:
1511#
1512# This command will return a list of types given search parameters
1513#
1514# @implements: if specified, only return types that implement this type name
1515#
1516# @abstract: if true, include abstract types in the results
1517#
1518# Returns: a list of @ObjectTypeInfo or an empty list if no results are found
1519#
1520# Since: 1.1
1521##
1522{ 'command': 'qom-list-types',
1523  'data': { '*implements': 'str', '*abstract': 'bool' },
1524  'returns': [ 'ObjectTypeInfo' ],
1525  'allow-preconfig': true }
1526
1527##
1528# @device-list-properties:
1529#
1530# List properties associated with a device.
1531#
1532# @typename: the type name of a device
1533#
1534# Returns: a list of ObjectPropertyInfo describing a devices properties
1535#
1536# Note: objects can create properties at runtime, for example to describe
1537# links between different devices and/or objects. These properties
1538# are not included in the output of this command.
1539#
1540# Since: 1.2
1541##
1542{ 'command': 'device-list-properties',
1543  'data': { 'typename': 'str'},
1544  'returns': [ 'ObjectPropertyInfo' ] }
1545
1546##
1547# @qom-list-properties:
1548#
1549# List properties associated with a QOM object.
1550#
1551# @typename: the type name of an object
1552#
1553# Note: objects can create properties at runtime, for example to describe
1554# links between different devices and/or objects. These properties
1555# are not included in the output of this command.
1556#
1557# Returns: a list of ObjectPropertyInfo describing object properties
1558#
1559# Since: 2.12
1560##
1561{ 'command': 'qom-list-properties',
1562  'data': { 'typename': 'str'},
1563  'returns': [ 'ObjectPropertyInfo' ],
1564  'allow-preconfig': true }
1565
1566##
1567# @xen-set-global-dirty-log:
1568#
1569# Enable or disable the global dirty log mode.
1570#
1571# @enable: true to enable, false to disable.
1572#
1573# Returns: nothing
1574#
1575# Since: 1.3
1576#
1577# Example:
1578#
1579# -> { "execute": "xen-set-global-dirty-log",
1580#      "arguments": { "enable": true } }
1581# <- { "return": {} }
1582#
1583##
1584{ 'command': 'xen-set-global-dirty-log', 'data': { 'enable': 'bool' } }
1585
1586##
1587# @device_add:
1588#
1589# @driver: the name of the new device's driver
1590#
1591# @bus: the device's parent bus (device tree path)
1592#
1593# @id: the device's ID, must be unique
1594#
1595# Additional arguments depend on the type.
1596#
1597# Add a device.
1598#
1599# Notes:
1600# 1. For detailed information about this command, please refer to the
1601#    'docs/qdev-device-use.txt' file.
1602#
1603# 2. It's possible to list device properties by running QEMU with the
1604#    "-device DEVICE,help" command-line argument, where DEVICE is the
1605#    device's name
1606#
1607# Example:
1608#
1609# -> { "execute": "device_add",
1610#      "arguments": { "driver": "e1000", "id": "net1",
1611#                     "bus": "pci.0",
1612#                     "mac": "52:54:00:12:34:56" } }
1613# <- { "return": {} }
1614#
1615# TODO: This command effectively bypasses QAPI completely due to its
1616# "additional arguments" business.  It shouldn't have been added to
1617# the schema in this form.  It should be qapified properly, or
1618# replaced by a properly qapified command.
1619#
1620# Since: 0.13
1621##
1622{ 'command': 'device_add',
1623  'data': {'driver': 'str', '*bus': 'str', '*id': 'str'},
1624  'gen': false } # so we can get the additional arguments
1625
1626##
1627# @device_del:
1628#
1629# Remove a device from a guest
1630#
1631# @id: the device's ID or QOM path
1632#
1633# Returns: Nothing on success
1634#          If @id is not a valid device, DeviceNotFound
1635#
1636# Notes: When this command completes, the device may not be removed from the
1637#        guest.  Hot removal is an operation that requires guest cooperation.
1638#        This command merely requests that the guest begin the hot removal
1639#        process.  Completion of the device removal process is signaled with a
1640#        DEVICE_DELETED event. Guest reset will automatically complete removal
1641#        for all devices.
1642#
1643# Since: 0.14.0
1644#
1645# Example:
1646#
1647# -> { "execute": "device_del",
1648#      "arguments": { "id": "net1" } }
1649# <- { "return": {} }
1650#
1651# -> { "execute": "device_del",
1652#      "arguments": { "id": "/machine/peripheral-anon/device[0]" } }
1653# <- { "return": {} }
1654#
1655##
1656{ 'command': 'device_del', 'data': {'id': 'str'} }
1657
1658##
1659# @DEVICE_DELETED:
1660#
1661# Emitted whenever the device removal completion is acknowledged by the guest.
1662# At this point, it's safe to reuse the specified device ID. Device removal can
1663# be initiated by the guest or by HMP/QMP commands.
1664#
1665# @device: device name
1666#
1667# @path: device path
1668#
1669# Since: 1.5
1670#
1671# Example:
1672#
1673# <- { "event": "DEVICE_DELETED",
1674#      "data": { "device": "virtio-net-pci-0",
1675#                "path": "/machine/peripheral/virtio-net-pci-0" },
1676#      "timestamp": { "seconds": 1265044230, "microseconds": 450486 } }
1677#
1678##
1679{ 'event': 'DEVICE_DELETED',
1680  'data': { '*device': 'str', 'path': 'str' } }
1681
1682##
1683# @DumpGuestMemoryFormat:
1684#
1685# An enumeration of guest-memory-dump's format.
1686#
1687# @elf: elf format
1688#
1689# @kdump-zlib: kdump-compressed format with zlib-compressed
1690#
1691# @kdump-lzo: kdump-compressed format with lzo-compressed
1692#
1693# @kdump-snappy: kdump-compressed format with snappy-compressed
1694#
1695# @win-dmp: Windows full crashdump format,
1696#           can be used instead of ELF converting (since 2.13)
1697#
1698# Since: 2.0
1699##
1700{ 'enum': 'DumpGuestMemoryFormat',
1701  'data': [ 'elf', 'kdump-zlib', 'kdump-lzo', 'kdump-snappy', 'win-dmp' ] }
1702
1703##
1704# @dump-guest-memory:
1705#
1706# Dump guest's memory to vmcore. It is a synchronous operation that can take
1707# very long depending on the amount of guest memory.
1708#
1709# @paging: if true, do paging to get guest's memory mapping. This allows
1710#          using gdb to process the core file.
1711#
1712#          IMPORTANT: this option can make QEMU allocate several gigabytes
1713#                     of RAM. This can happen for a large guest, or a
1714#                     malicious guest pretending to be large.
1715#
1716#          Also, paging=true has the following limitations:
1717#
1718#             1. The guest may be in a catastrophic state or can have corrupted
1719#                memory, which cannot be trusted
1720#             2. The guest can be in real-mode even if paging is enabled. For
1721#                example, the guest uses ACPI to sleep, and ACPI sleep state
1722#                goes in real-mode
1723#             3. Currently only supported on i386 and x86_64.
1724#
1725# @protocol: the filename or file descriptor of the vmcore. The supported
1726#            protocols are:
1727#
1728#            1. file: the protocol starts with "file:", and the following
1729#               string is the file's path.
1730#            2. fd: the protocol starts with "fd:", and the following string
1731#               is the fd's name.
1732#
1733# @detach: if true, QMP will return immediately rather than
1734#          waiting for the dump to finish. The user can track progress
1735#          using "query-dump". (since 2.6).
1736#
1737# @begin: if specified, the starting physical address.
1738#
1739# @length: if specified, the memory size, in bytes. If you don't
1740#          want to dump all guest's memory, please specify the start @begin
1741#          and @length
1742#
1743# @format: if specified, the format of guest memory dump. But non-elf
1744#          format is conflict with paging and filter, ie. @paging, @begin and
1745#          @length is not allowed to be specified with non-elf @format at the
1746#          same time (since 2.0)
1747#
1748# Note: All boolean arguments default to false
1749#
1750# Returns: nothing on success
1751#
1752# Since: 1.2
1753#
1754# Example:
1755#
1756# -> { "execute": "dump-guest-memory",
1757#      "arguments": { "protocol": "fd:dump" } }
1758# <- { "return": {} }
1759#
1760##
1761{ 'command': 'dump-guest-memory',
1762  'data': { 'paging': 'bool', 'protocol': 'str', '*detach': 'bool',
1763            '*begin': 'int', '*length': 'int',
1764            '*format': 'DumpGuestMemoryFormat'} }
1765
1766##
1767# @DumpStatus:
1768#
1769# Describe the status of a long-running background guest memory dump.
1770#
1771# @none: no dump-guest-memory has started yet.
1772#
1773# @active: there is one dump running in background.
1774#
1775# @completed: the last dump has finished successfully.
1776#
1777# @failed: the last dump has failed.
1778#
1779# Since: 2.6
1780##
1781{ 'enum': 'DumpStatus',
1782  'data': [ 'none', 'active', 'completed', 'failed' ] }
1783
1784##
1785# @DumpQueryResult:
1786#
1787# The result format for 'query-dump'.
1788#
1789# @status: enum of @DumpStatus, which shows current dump status
1790#
1791# @completed: bytes written in latest dump (uncompressed)
1792#
1793# @total: total bytes to be written in latest dump (uncompressed)
1794#
1795# Since: 2.6
1796##
1797{ 'struct': 'DumpQueryResult',
1798  'data': { 'status': 'DumpStatus',
1799            'completed': 'int',
1800            'total': 'int' } }
1801
1802##
1803# @query-dump:
1804#
1805# Query latest dump status.
1806#
1807# Returns: A @DumpStatus object showing the dump status.
1808#
1809# Since: 2.6
1810#
1811# Example:
1812#
1813# -> { "execute": "query-dump" }
1814# <- { "return": { "status": "active", "completed": 1024000,
1815#                  "total": 2048000 } }
1816#
1817##
1818{ 'command': 'query-dump', 'returns': 'DumpQueryResult' }
1819
1820##
1821# @DUMP_COMPLETED:
1822#
1823# Emitted when background dump has completed
1824#
1825# @result: final dump status
1826#
1827# @error: human-readable error string that provides
1828#         hint on why dump failed. Only presents on failure. The
1829#         user should not try to interpret the error string.
1830#
1831# Since: 2.6
1832#
1833# Example:
1834#
1835# { "event": "DUMP_COMPLETED",
1836#   "data": {"result": {"total": 1090650112, "status": "completed",
1837#                       "completed": 1090650112} } }
1838#
1839##
1840{ 'event': 'DUMP_COMPLETED' ,
1841  'data': { 'result': 'DumpQueryResult', '*error': 'str' } }
1842
1843##
1844# @DumpGuestMemoryCapability:
1845#
1846# A list of the available formats for dump-guest-memory
1847#
1848# Since: 2.0
1849##
1850{ 'struct': 'DumpGuestMemoryCapability',
1851  'data': {
1852      'formats': ['DumpGuestMemoryFormat'] } }
1853
1854##
1855# @query-dump-guest-memory-capability:
1856#
1857# Returns the available formats for dump-guest-memory
1858#
1859# Returns:  A @DumpGuestMemoryCapability object listing available formats for
1860#           dump-guest-memory
1861#
1862# Since: 2.0
1863#
1864# Example:
1865#
1866# -> { "execute": "query-dump-guest-memory-capability" }
1867# <- { "return": { "formats":
1868#                  ["elf", "kdump-zlib", "kdump-lzo", "kdump-snappy"] }
1869#
1870##
1871{ 'command': 'query-dump-guest-memory-capability',
1872  'returns': 'DumpGuestMemoryCapability' }
1873
1874##
1875# @dump-skeys:
1876#
1877# Dump guest's storage keys
1878#
1879# @filename: the path to the file to dump to
1880#
1881# This command is only supported on s390 architecture.
1882#
1883# Since: 2.5
1884#
1885# Example:
1886#
1887# -> { "execute": "dump-skeys",
1888#      "arguments": { "filename": "/tmp/skeys" } }
1889# <- { "return": {} }
1890#
1891##
1892{ 'command': 'dump-skeys',
1893  'data': { 'filename': 'str' } }
1894
1895##
1896# @object-add:
1897#
1898# Create a QOM object.
1899#
1900# @qom-type: the class name for the object to be created
1901#
1902# @id: the name of the new object
1903#
1904# @props: a dictionary of properties to be passed to the backend
1905#
1906# Returns: Nothing on success
1907#          Error if @qom-type is not a valid class name
1908#
1909# Since: 2.0
1910#
1911# Example:
1912#
1913# -> { "execute": "object-add",
1914#      "arguments": { "qom-type": "rng-random", "id": "rng1",
1915#                     "props": { "filename": "/dev/hwrng" } } }
1916# <- { "return": {} }
1917#
1918##
1919{ 'command': 'object-add',
1920  'data': {'qom-type': 'str', 'id': 'str', '*props': 'any'} }
1921
1922##
1923# @object-del:
1924#
1925# Remove a QOM object.
1926#
1927# @id: the name of the QOM object to remove
1928#
1929# Returns: Nothing on success
1930#          Error if @id is not a valid id for a QOM object
1931#
1932# Since: 2.0
1933#
1934# Example:
1935#
1936# -> { "execute": "object-del", "arguments": { "id": "rng1" } }
1937# <- { "return": {} }
1938#
1939##
1940{ 'command': 'object-del', 'data': {'id': 'str'} }
1941
1942##
1943# @getfd:
1944#
1945# Receive a file descriptor via SCM rights and assign it a name
1946#
1947# @fdname: file descriptor name
1948#
1949# Returns: Nothing on success
1950#
1951# Since: 0.14.0
1952#
1953# Notes: If @fdname already exists, the file descriptor assigned to
1954#        it will be closed and replaced by the received file
1955#        descriptor.
1956#
1957#        The 'closefd' command can be used to explicitly close the
1958#        file descriptor when it is no longer needed.
1959#
1960# Example:
1961#
1962# -> { "execute": "getfd", "arguments": { "fdname": "fd1" } }
1963# <- { "return": {} }
1964#
1965##
1966{ 'command': 'getfd', 'data': {'fdname': 'str'} }
1967
1968##
1969# @closefd:
1970#
1971# Close a file descriptor previously passed via SCM rights
1972#
1973# @fdname: file descriptor name
1974#
1975# Returns: Nothing on success
1976#
1977# Since: 0.14.0
1978#
1979# Example:
1980#
1981# -> { "execute": "closefd", "arguments": { "fdname": "fd1" } }
1982# <- { "return": {} }
1983#
1984##
1985{ 'command': 'closefd', 'data': {'fdname': 'str'} }
1986
1987##
1988# @MachineInfo:
1989#
1990# Information describing a machine.
1991#
1992# @name: the name of the machine
1993#
1994# @alias: an alias for the machine name
1995#
1996# @is-default: whether the machine is default
1997#
1998# @cpu-max: maximum number of CPUs supported by the machine type
1999#           (since 1.5.0)
2000#
2001# @hotpluggable-cpus: cpu hotplug via -device is supported (since 2.7.0)
2002#
2003# Since: 1.2.0
2004##
2005{ 'struct': 'MachineInfo',
2006  'data': { 'name': 'str', '*alias': 'str',
2007            '*is-default': 'bool', 'cpu-max': 'int',
2008            'hotpluggable-cpus': 'bool'} }
2009
2010##
2011# @query-machines:
2012#
2013# Return a list of supported machines
2014#
2015# Returns: a list of MachineInfo
2016#
2017# Since: 1.2.0
2018##
2019{ 'command': 'query-machines', 'returns': ['MachineInfo'] }
2020
2021##
2022# @CurrentMachineParams:
2023#
2024# Information describing the running machine parameters.
2025#
2026# @wakeup-suspend-support: true if the machine supports wake up from
2027#                          suspend
2028#
2029# Since: 4.0
2030##
2031{ 'struct': 'CurrentMachineParams',
2032  'data': { 'wakeup-suspend-support': 'bool'} }
2033
2034##
2035# @query-current-machine:
2036#
2037# Return information on the current virtual machine.
2038#
2039# Returns: CurrentMachineParams
2040#
2041# Since: 4.0
2042##
2043{ 'command': 'query-current-machine', 'returns': 'CurrentMachineParams' }
2044
2045##
2046# @CpuDefinitionInfo:
2047#
2048# Virtual CPU definition.
2049#
2050# @name: the name of the CPU definition
2051#
2052# @migration-safe: whether a CPU definition can be safely used for
2053#                  migration in combination with a QEMU compatibility machine
2054#                  when migrating between different QEMU versions and between
2055#                  hosts with different sets of (hardware or software)
2056#                  capabilities. If not provided, information is not available
2057#                  and callers should not assume the CPU definition to be
2058#                  migration-safe. (since 2.8)
2059#
2060# @static: whether a CPU definition is static and will not change depending on
2061#          QEMU version, machine type, machine options and accelerator options.
2062#          A static model is always migration-safe. (since 2.8)
2063#
2064# @unavailable-features: List of properties that prevent
2065#                        the CPU model from running in the current
2066#                        host. (since 2.8)
2067# @typename: Type name that can be used as argument to @device-list-properties,
2068#            to introspect properties configurable using -cpu or -global.
2069#            (since 2.9)
2070#
2071# @unavailable-features is a list of QOM property names that
2072# represent CPU model attributes that prevent the CPU from running.
2073# If the QOM property is read-only, that means there's no known
2074# way to make the CPU model run in the current host. Implementations
2075# that choose not to provide specific information return the
2076# property name "type".
2077# If the property is read-write, it means that it MAY be possible
2078# to run the CPU model in the current host if that property is
2079# changed. Management software can use it as hints to suggest or
2080# choose an alternative for the user, or just to generate meaningful
2081# error messages explaining why the CPU model can't be used.
2082# If @unavailable-features is an empty list, the CPU model is
2083# runnable using the current host and machine-type.
2084# If @unavailable-features is not present, runnability
2085# information for the CPU is not available.
2086#
2087# Since: 1.2.0
2088##
2089{ 'struct': 'CpuDefinitionInfo',
2090  'data': { 'name': 'str', '*migration-safe': 'bool', 'static': 'bool',
2091            '*unavailable-features': [ 'str' ], 'typename': 'str' } }
2092
2093##
2094# @MemoryInfo:
2095#
2096# Actual memory information in bytes.
2097#
2098# @base-memory: size of "base" memory specified with command line
2099#               option -m.
2100#
2101# @plugged-memory: size of memory that can be hot-unplugged. This field
2102#                  is omitted if target doesn't support memory hotplug
2103#                  (i.e. CONFIG_MEM_DEVICE not defined at build time).
2104#
2105# Since: 2.11.0
2106##
2107{ 'struct': 'MemoryInfo',
2108  'data'  : { 'base-memory': 'size', '*plugged-memory': 'size' } }
2109
2110##
2111# @query-memory-size-summary:
2112#
2113# Return the amount of initially allocated and present hotpluggable (if
2114# enabled) memory in bytes.
2115#
2116# Example:
2117#
2118# -> { "execute": "query-memory-size-summary" }
2119# <- { "return": { "base-memory": 4294967296, "plugged-memory": 0 } }
2120#
2121# Since: 2.11.0
2122##
2123{ 'command': 'query-memory-size-summary', 'returns': 'MemoryInfo' }
2124
2125##
2126# @query-cpu-definitions:
2127#
2128# Return a list of supported virtual CPU definitions
2129#
2130# Returns: a list of CpuDefInfo
2131#
2132# Since: 1.2.0
2133##
2134{ 'command': 'query-cpu-definitions', 'returns': ['CpuDefinitionInfo'] }
2135
2136##
2137# @CpuModelInfo:
2138#
2139# Virtual CPU model.
2140#
2141# A CPU model consists of the name of a CPU definition, to which
2142# delta changes are applied (e.g. features added/removed). Most magic values
2143# that an architecture might require should be hidden behind the name.
2144# However, if required, architectures can expose relevant properties.
2145#
2146# @name: the name of the CPU definition the model is based on
2147# @props: a dictionary of QOM properties to be applied
2148#
2149# Since: 2.8.0
2150##
2151{ 'struct': 'CpuModelInfo',
2152  'data': { 'name': 'str',
2153            '*props': 'any' } }
2154
2155##
2156# @CpuModelExpansionType:
2157#
2158# An enumeration of CPU model expansion types.
2159#
2160# @static: Expand to a static CPU model, a combination of a static base
2161#          model name and property delta changes. As the static base model will
2162#          never change, the expanded CPU model will be the same, independent of
2163#          QEMU version, machine type, machine options, and accelerator options.
2164#          Therefore, the resulting model can be used by tooling without having
2165#          to specify a compatibility machine - e.g. when displaying the "host"
2166#          model. The @static CPU models are migration-safe.
2167
2168# @full: Expand all properties. The produced model is not guaranteed to be
2169#        migration-safe, but allows tooling to get an insight and work with
2170#        model details.
2171#
2172# Note: When a non-migration-safe CPU model is expanded in static mode, some
2173# features enabled by the CPU model may be omitted, because they can't be
2174# implemented by a static CPU model definition (e.g. cache info passthrough and
2175# PMU passthrough in x86). If you need an accurate representation of the
2176# features enabled by a non-migration-safe CPU model, use @full. If you need a
2177# static representation that will keep ABI compatibility even when changing QEMU
2178# version or machine-type, use @static (but keep in mind that some features may
2179# be omitted).
2180#
2181# Since: 2.8.0
2182##
2183{ 'enum': 'CpuModelExpansionType',
2184  'data': [ 'static', 'full' ] }
2185
2186
2187##
2188# @CpuModelExpansionInfo:
2189#
2190# The result of a cpu model expansion.
2191#
2192# @model: the expanded CpuModelInfo.
2193#
2194# Since: 2.8.0
2195##
2196{ 'struct': 'CpuModelExpansionInfo',
2197  'data': { 'model': 'CpuModelInfo' } }
2198
2199
2200##
2201# @query-cpu-model-expansion:
2202#
2203# Expands a given CPU model (or a combination of CPU model + additional options)
2204# to different granularities, allowing tooling to get an understanding what a
2205# specific CPU model looks like in QEMU under a certain configuration.
2206#
2207# This interface can be used to query the "host" CPU model.
2208#
2209# The data returned by this command may be affected by:
2210#
2211# * QEMU version: CPU models may look different depending on the QEMU version.
2212#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2213# * machine-type: CPU model  may look different depending on the machine-type.
2214#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2215# * machine options (including accelerator): in some architectures, CPU models
2216#   may look different depending on machine and accelerator options. (Except for
2217#   CPU models reported as "static" in query-cpu-definitions.)
2218# * "-cpu" arguments and global properties: arguments to the -cpu option and
2219#   global properties may affect expansion of CPU models. Using
2220#   query-cpu-model-expansion while using these is not advised.
2221#
2222# Some architectures may not support all expansion types. s390x supports
2223# "full" and "static".
2224#
2225# Returns: a CpuModelExpansionInfo. Returns an error if expanding CPU models is
2226#          not supported, if the model cannot be expanded, if the model contains
2227#          an unknown CPU definition name, unknown properties or properties
2228#          with a wrong type. Also returns an error if an expansion type is
2229#          not supported.
2230#
2231# Since: 2.8.0
2232##
2233{ 'command': 'query-cpu-model-expansion',
2234  'data': { 'type': 'CpuModelExpansionType',
2235            'model': 'CpuModelInfo' },
2236  'returns': 'CpuModelExpansionInfo' }
2237
2238##
2239# @CpuModelCompareResult:
2240#
2241# An enumeration of CPU model comparison results. The result is usually
2242# calculated using e.g. CPU features or CPU generations.
2243#
2244# @incompatible: If model A is incompatible to model B, model A is not
2245#                guaranteed to run where model B runs and the other way around.
2246#
2247# @identical: If model A is identical to model B, model A is guaranteed to run
2248#             where model B runs and the other way around.
2249#
2250# @superset: If model A is a superset of model B, model B is guaranteed to run
2251#            where model A runs. There are no guarantees about the other way.
2252#
2253# @subset: If model A is a subset of model B, model A is guaranteed to run
2254#          where model B runs. There are no guarantees about the other way.
2255#
2256# Since: 2.8.0
2257##
2258{ 'enum': 'CpuModelCompareResult',
2259  'data': [ 'incompatible', 'identical', 'superset', 'subset' ] }
2260
2261##
2262# @CpuModelCompareInfo:
2263#
2264# The result of a CPU model comparison.
2265#
2266# @result: The result of the compare operation.
2267# @responsible-properties: List of properties that led to the comparison result
2268#                          not being identical.
2269#
2270# @responsible-properties is a list of QOM property names that led to
2271# both CPUs not being detected as identical. For identical models, this
2272# list is empty.
2273# If a QOM property is read-only, that means there's no known way to make the
2274# CPU models identical. If the special property name "type" is included, the
2275# models are by definition not identical and cannot be made identical.
2276#
2277# Since: 2.8.0
2278##
2279{ 'struct': 'CpuModelCompareInfo',
2280  'data': {'result': 'CpuModelCompareResult',
2281           'responsible-properties': ['str']
2282          }
2283}
2284
2285##
2286# @query-cpu-model-comparison:
2287#
2288# Compares two CPU models, returning how they compare in a specific
2289# configuration. The results indicates how both models compare regarding
2290# runnability. This result can be used by tooling to make decisions if a
2291# certain CPU model will run in a certain configuration or if a compatible
2292# CPU model has to be created by baselining.
2293#
2294# Usually, a CPU model is compared against the maximum possible CPU model
2295# of a certain configuration (e.g. the "host" model for KVM). If that CPU
2296# model is identical or a subset, it will run in that configuration.
2297#
2298# The result returned by this command may be affected by:
2299#
2300# * QEMU version: CPU models may look different depending on the QEMU version.
2301#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2302# * machine-type: CPU model may look different depending on the machine-type.
2303#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2304# * machine options (including accelerator): in some architectures, CPU models
2305#   may look different depending on machine and accelerator options. (Except for
2306#   CPU models reported as "static" in query-cpu-definitions.)
2307# * "-cpu" arguments and global properties: arguments to the -cpu option and
2308#   global properties may affect expansion of CPU models. Using
2309#   query-cpu-model-expansion while using these is not advised.
2310#
2311# Some architectures may not support comparing CPU models. s390x supports
2312# comparing CPU models.
2313#
2314# Returns: a CpuModelBaselineInfo. Returns an error if comparing CPU models is
2315#          not supported, if a model cannot be used, if a model contains
2316#          an unknown cpu definition name, unknown properties or properties
2317#          with wrong types.
2318#
2319# Since: 2.8.0
2320##
2321{ 'command': 'query-cpu-model-comparison',
2322  'data': { 'modela': 'CpuModelInfo', 'modelb': 'CpuModelInfo' },
2323  'returns': 'CpuModelCompareInfo' }
2324
2325##
2326# @CpuModelBaselineInfo:
2327#
2328# The result of a CPU model baseline.
2329#
2330# @model: the baselined CpuModelInfo.
2331#
2332# Since: 2.8.0
2333##
2334{ 'struct': 'CpuModelBaselineInfo',
2335  'data': { 'model': 'CpuModelInfo' } }
2336
2337##
2338# @query-cpu-model-baseline:
2339#
2340# Baseline two CPU models, creating a compatible third model. The created
2341# model will always be a static, migration-safe CPU model (see "static"
2342# CPU model expansion for details).
2343#
2344# This interface can be used by tooling to create a compatible CPU model out
2345# two CPU models. The created CPU model will be identical to or a subset of
2346# both CPU models when comparing them. Therefore, the created CPU model is
2347# guaranteed to run where the given CPU models run.
2348#
2349# The result returned by this command may be affected by:
2350#
2351# * QEMU version: CPU models may look different depending on the QEMU version.
2352#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2353# * machine-type: CPU model may look different depending on the machine-type.
2354#   (Except for CPU models reported as "static" in query-cpu-definitions.)
2355# * machine options (including accelerator): in some architectures, CPU models
2356#   may look different depending on machine and accelerator options. (Except for
2357#   CPU models reported as "static" in query-cpu-definitions.)
2358# * "-cpu" arguments and global properties: arguments to the -cpu option and
2359#   global properties may affect expansion of CPU models. Using
2360#   query-cpu-model-expansion while using these is not advised.
2361#
2362# Some architectures may not support baselining CPU models. s390x supports
2363# baselining CPU models.
2364#
2365# Returns: a CpuModelBaselineInfo. Returns an error if baselining CPU models is
2366#          not supported, if a model cannot be used, if a model contains
2367#          an unknown cpu definition name, unknown properties or properties
2368#          with wrong types.
2369#
2370# Since: 2.8.0
2371##
2372{ 'command': 'query-cpu-model-baseline',
2373  'data': { 'modela': 'CpuModelInfo',
2374            'modelb': 'CpuModelInfo' },
2375  'returns': 'CpuModelBaselineInfo' }
2376
2377##
2378# @AddfdInfo:
2379#
2380# Information about a file descriptor that was added to an fd set.
2381#
2382# @fdset-id: The ID of the fd set that @fd was added to.
2383#
2384# @fd: The file descriptor that was received via SCM rights and
2385#      added to the fd set.
2386#
2387# Since: 1.2.0
2388##
2389{ 'struct': 'AddfdInfo', 'data': {'fdset-id': 'int', 'fd': 'int'} }
2390
2391##
2392# @add-fd:
2393#
2394# Add a file descriptor, that was passed via SCM rights, to an fd set.
2395#
2396# @fdset-id: The ID of the fd set to add the file descriptor to.
2397#
2398# @opaque: A free-form string that can be used to describe the fd.
2399#
2400# Returns: @AddfdInfo on success
2401#
2402#          If file descriptor was not received, FdNotSupplied
2403#
2404#          If @fdset-id is a negative value, InvalidParameterValue
2405#
2406# Notes: The list of fd sets is shared by all monitor connections.
2407#
2408#        If @fdset-id is not specified, a new fd set will be created.
2409#
2410# Since: 1.2.0
2411#
2412# Example:
2413#
2414# -> { "execute": "add-fd", "arguments": { "fdset-id": 1 } }
2415# <- { "return": { "fdset-id": 1, "fd": 3 } }
2416#
2417##
2418{ 'command': 'add-fd',
2419  'data': { '*fdset-id': 'int',
2420            '*opaque': 'str' },
2421  'returns': 'AddfdInfo' }
2422
2423##
2424# @remove-fd:
2425#
2426# Remove a file descriptor from an fd set.
2427#
2428# @fdset-id: The ID of the fd set that the file descriptor belongs to.
2429#
2430# @fd: The file descriptor that is to be removed.
2431#
2432# Returns: Nothing on success
2433#          If @fdset-id or @fd is not found, FdNotFound
2434#
2435# Since: 1.2.0
2436#
2437# Notes: The list of fd sets is shared by all monitor connections.
2438#
2439#        If @fd is not specified, all file descriptors in @fdset-id
2440#        will be removed.
2441#
2442# Example:
2443#
2444# -> { "execute": "remove-fd", "arguments": { "fdset-id": 1, "fd": 3 } }
2445# <- { "return": {} }
2446#
2447##
2448{ 'command': 'remove-fd', 'data': {'fdset-id': 'int', '*fd': 'int'} }
2449
2450##
2451# @FdsetFdInfo:
2452#
2453# Information about a file descriptor that belongs to an fd set.
2454#
2455# @fd: The file descriptor value.
2456#
2457# @opaque: A free-form string that can be used to describe the fd.
2458#
2459# Since: 1.2.0
2460##
2461{ 'struct': 'FdsetFdInfo',
2462  'data': {'fd': 'int', '*opaque': 'str'} }
2463
2464##
2465# @FdsetInfo:
2466#
2467# Information about an fd set.
2468#
2469# @fdset-id: The ID of the fd set.
2470#
2471# @fds: A list of file descriptors that belong to this fd set.
2472#
2473# Since: 1.2.0
2474##
2475{ 'struct': 'FdsetInfo',
2476  'data': {'fdset-id': 'int', 'fds': ['FdsetFdInfo']} }
2477
2478##
2479# @query-fdsets:
2480#
2481# Return information describing all fd sets.
2482#
2483# Returns: A list of @FdsetInfo
2484#
2485# Since: 1.2.0
2486#
2487# Note: The list of fd sets is shared by all monitor connections.
2488#
2489# Example:
2490#
2491# -> { "execute": "query-fdsets" }
2492# <- { "return": [
2493#        {
2494#          "fds": [
2495#            {
2496#              "fd": 30,
2497#              "opaque": "rdonly:/path/to/file"
2498#            },
2499#            {
2500#              "fd": 24,
2501#              "opaque": "rdwr:/path/to/file"
2502#            }
2503#          ],
2504#          "fdset-id": 1
2505#        },
2506#        {
2507#          "fds": [
2508#            {
2509#              "fd": 28
2510#            },
2511#            {
2512#              "fd": 29
2513#            }
2514#          ],
2515#          "fdset-id": 0
2516#        }
2517#      ]
2518#    }
2519#
2520##
2521{ 'command': 'query-fdsets', 'returns': ['FdsetInfo'] }
2522
2523##
2524# @TargetInfo:
2525#
2526# Information describing the QEMU target.
2527#
2528# @arch: the target architecture
2529#
2530# Since: 1.2.0
2531##
2532{ 'struct': 'TargetInfo',
2533  'data': { 'arch': 'SysEmuTarget' } }
2534
2535##
2536# @query-target:
2537#
2538# Return information about the target for this QEMU
2539#
2540# Returns: TargetInfo
2541#
2542# Since: 1.2.0
2543##
2544{ 'command': 'query-target', 'returns': 'TargetInfo' }
2545
2546##
2547# @AcpiTableOptions:
2548#
2549# Specify an ACPI table on the command line to load.
2550#
2551# At most one of @file and @data can be specified. The list of files specified
2552# by any one of them is loaded and concatenated in order. If both are omitted,
2553# @data is implied.
2554#
2555# Other fields / optargs can be used to override fields of the generic ACPI
2556# table header; refer to the ACPI specification 5.0, section 5.2.6 System
2557# Description Table Header. If a header field is not overridden, then the
2558# corresponding value from the concatenated blob is used (in case of @file), or
2559# it is filled in with a hard-coded value (in case of @data).
2560#
2561# String fields are copied into the matching ACPI member from lowest address
2562# upwards, and silently truncated / NUL-padded to length.
2563#
2564# @sig: table signature / identifier (4 bytes)
2565#
2566# @rev: table revision number (dependent on signature, 1 byte)
2567#
2568# @oem_id: OEM identifier (6 bytes)
2569#
2570# @oem_table_id: OEM table identifier (8 bytes)
2571#
2572# @oem_rev: OEM-supplied revision number (4 bytes)
2573#
2574# @asl_compiler_id: identifier of the utility that created the table
2575#                   (4 bytes)
2576#
2577# @asl_compiler_rev: revision number of the utility that created the
2578#                    table (4 bytes)
2579#
2580# @file: colon (:) separated list of pathnames to load and
2581#        concatenate as table data. The resultant binary blob is expected to
2582#        have an ACPI table header. At least one file is required. This field
2583#        excludes @data.
2584#
2585# @data: colon (:) separated list of pathnames to load and
2586#        concatenate as table data. The resultant binary blob must not have an
2587#        ACPI table header. At least one file is required. This field excludes
2588#        @file.
2589#
2590# Since: 1.5
2591##
2592{ 'struct': 'AcpiTableOptions',
2593  'data': {
2594    '*sig':               'str',
2595    '*rev':               'uint8',
2596    '*oem_id':            'str',
2597    '*oem_table_id':      'str',
2598    '*oem_rev':           'uint32',
2599    '*asl_compiler_id':   'str',
2600    '*asl_compiler_rev':  'uint32',
2601    '*file':              'str',
2602    '*data':              'str' }}
2603
2604##
2605# @CommandLineParameterType:
2606#
2607# Possible types for an option parameter.
2608#
2609# @string: accepts a character string
2610#
2611# @boolean: accepts "on" or "off"
2612#
2613# @number: accepts a number
2614#
2615# @size: accepts a number followed by an optional suffix (K)ilo,
2616#        (M)ega, (G)iga, (T)era
2617#
2618# Since: 1.5
2619##
2620{ 'enum': 'CommandLineParameterType',
2621  'data': ['string', 'boolean', 'number', 'size'] }
2622
2623##
2624# @CommandLineParameterInfo:
2625#
2626# Details about a single parameter of a command line option.
2627#
2628# @name: parameter name
2629#
2630# @type: parameter @CommandLineParameterType
2631#
2632# @help: human readable text string, not suitable for parsing.
2633#
2634# @default: default value string (since 2.1)
2635#
2636# Since: 1.5
2637##
2638{ 'struct': 'CommandLineParameterInfo',
2639  'data': { 'name': 'str',
2640            'type': 'CommandLineParameterType',
2641            '*help': 'str',
2642            '*default': 'str' } }
2643
2644##
2645# @CommandLineOptionInfo:
2646#
2647# Details about a command line option, including its list of parameter details
2648#
2649# @option: option name
2650#
2651# @parameters: an array of @CommandLineParameterInfo
2652#
2653# Since: 1.5
2654##
2655{ 'struct': 'CommandLineOptionInfo',
2656  'data': { 'option': 'str', 'parameters': ['CommandLineParameterInfo'] } }
2657
2658##
2659# @query-command-line-options:
2660#
2661# Query command line option schema.
2662#
2663# @option: option name
2664#
2665# Returns: list of @CommandLineOptionInfo for all options (or for the given
2666#          @option).  Returns an error if the given @option doesn't exist.
2667#
2668# Since: 1.5
2669#
2670# Example:
2671#
2672# -> { "execute": "query-command-line-options",
2673#      "arguments": { "option": "option-rom" } }
2674# <- { "return": [
2675#         {
2676#             "parameters": [
2677#                 {
2678#                     "name": "romfile",
2679#                     "type": "string"
2680#                 },
2681#                 {
2682#                     "name": "bootindex",
2683#                     "type": "number"
2684#                 }
2685#             ],
2686#             "option": "option-rom"
2687#         }
2688#      ]
2689#    }
2690#
2691##
2692{'command': 'query-command-line-options',
2693 'data': { '*option': 'str' },
2694 'returns': ['CommandLineOptionInfo'],
2695 'allow-preconfig': true }
2696
2697##
2698# @X86CPURegister32:
2699#
2700# A X86 32-bit register
2701#
2702# Since: 1.5
2703##
2704{ 'enum': 'X86CPURegister32',
2705  'data': [ 'EAX', 'EBX', 'ECX', 'EDX', 'ESP', 'EBP', 'ESI', 'EDI' ] }
2706
2707##
2708# @X86CPUFeatureWordInfo:
2709#
2710# Information about a X86 CPU feature word
2711#
2712# @cpuid-input-eax: Input EAX value for CPUID instruction for that feature word
2713#
2714# @cpuid-input-ecx: Input ECX value for CPUID instruction for that
2715#                   feature word
2716#
2717# @cpuid-register: Output register containing the feature bits
2718#
2719# @features: value of output register, containing the feature bits
2720#
2721# Since: 1.5
2722##
2723{ 'struct': 'X86CPUFeatureWordInfo',
2724  'data': { 'cpuid-input-eax': 'int',
2725            '*cpuid-input-ecx': 'int',
2726            'cpuid-register': 'X86CPURegister32',
2727            'features': 'int' } }
2728
2729##
2730# @DummyForceArrays:
2731#
2732# Not used by QMP; hack to let us use X86CPUFeatureWordInfoList internally
2733#
2734# Since: 2.5
2735##
2736{ 'struct': 'DummyForceArrays',
2737  'data': { 'unused': ['X86CPUFeatureWordInfo'] } }
2738
2739
2740##
2741# @NumaOptionsType:
2742#
2743# @node: NUMA nodes configuration
2744#
2745# @dist: NUMA distance configuration (since 2.10)
2746#
2747# @cpu: property based CPU(s) to node mapping (Since: 2.10)
2748#
2749# Since: 2.1
2750##
2751{ 'enum': 'NumaOptionsType',
2752  'data': [ 'node', 'dist', 'cpu' ] }
2753
2754##
2755# @NumaOptions:
2756#
2757# A discriminated record of NUMA options. (for OptsVisitor)
2758#
2759# Since: 2.1
2760##
2761{ 'union': 'NumaOptions',
2762  'base': { 'type': 'NumaOptionsType' },
2763  'discriminator': 'type',
2764  'data': {
2765    'node': 'NumaNodeOptions',
2766    'dist': 'NumaDistOptions',
2767    'cpu': 'NumaCpuOptions' }}
2768
2769##
2770# @NumaNodeOptions:
2771#
2772# Create a guest NUMA node. (for OptsVisitor)
2773#
2774# @nodeid: NUMA node ID (increase by 1 from 0 if omitted)
2775#
2776# @cpus: VCPUs belonging to this node (assign VCPUS round-robin
2777#         if omitted)
2778#
2779# @mem: memory size of this node; mutually exclusive with @memdev.
2780#       Equally divide total memory among nodes if both @mem and @memdev are
2781#       omitted.
2782#
2783# @memdev: memory backend object.  If specified for one node,
2784#          it must be specified for all nodes.
2785#
2786# Since: 2.1
2787##
2788{ 'struct': 'NumaNodeOptions',
2789  'data': {
2790   '*nodeid': 'uint16',
2791   '*cpus':   ['uint16'],
2792   '*mem':    'size',
2793   '*memdev': 'str' }}
2794
2795##
2796# @NumaDistOptions:
2797#
2798# Set the distance between 2 NUMA nodes.
2799#
2800# @src: source NUMA node.
2801#
2802# @dst: destination NUMA node.
2803#
2804# @val: NUMA distance from source node to destination node.
2805#       When a node is unreachable from another node, set the distance
2806#       between them to 255.
2807#
2808# Since: 2.10
2809##
2810{ 'struct': 'NumaDistOptions',
2811  'data': {
2812   'src': 'uint16',
2813   'dst': 'uint16',
2814   'val': 'uint8' }}
2815
2816##
2817# @NumaCpuOptions:
2818#
2819# Option "-numa cpu" overrides default cpu to node mapping.
2820# It accepts the same set of cpu properties as returned by
2821# query-hotpluggable-cpus[].props, where node-id could be used to
2822# override default node mapping.
2823#
2824# Since: 2.10
2825##
2826{ 'struct': 'NumaCpuOptions',
2827   'base': 'CpuInstanceProperties',
2828   'data' : {} }
2829
2830##
2831# @HostMemPolicy:
2832#
2833# Host memory policy types
2834#
2835# @default: restore default policy, remove any nondefault policy
2836#
2837# @preferred: set the preferred host nodes for allocation
2838#
2839# @bind: a strict policy that restricts memory allocation to the
2840#        host nodes specified
2841#
2842# @interleave: memory allocations are interleaved across the set
2843#              of host nodes specified
2844#
2845# Since: 2.1
2846##
2847{ 'enum': 'HostMemPolicy',
2848  'data': [ 'default', 'preferred', 'bind', 'interleave' ] }
2849
2850##
2851# @Memdev:
2852#
2853# Information about memory backend
2854#
2855# @id: backend's ID if backend has 'id' property (since 2.9)
2856#
2857# @size: memory backend size
2858#
2859# @merge: enables or disables memory merge support
2860#
2861# @dump: includes memory backend's memory in a core dump or not
2862#
2863# @prealloc: enables or disables memory preallocation
2864#
2865# @host-nodes: host nodes for its memory policy
2866#
2867# @policy: memory policy of memory backend
2868#
2869# Since: 2.1
2870##
2871{ 'struct': 'Memdev',
2872  'data': {
2873    '*id':        'str',
2874    'size':       'size',
2875    'merge':      'bool',
2876    'dump':       'bool',
2877    'prealloc':   'bool',
2878    'host-nodes': ['uint16'],
2879    'policy':     'HostMemPolicy' }}
2880
2881##
2882# @query-memdev:
2883#
2884# Returns information for all memory backends.
2885#
2886# Returns: a list of @Memdev.
2887#
2888# Since: 2.1
2889#
2890# Example:
2891#
2892# -> { "execute": "query-memdev" }
2893# <- { "return": [
2894#        {
2895#          "id": "mem1",
2896#          "size": 536870912,
2897#          "merge": false,
2898#          "dump": true,
2899#          "prealloc": false,
2900#          "host-nodes": [0, 1],
2901#          "policy": "bind"
2902#        },
2903#        {
2904#          "size": 536870912,
2905#          "merge": false,
2906#          "dump": true,
2907#          "prealloc": true,
2908#          "host-nodes": [2, 3],
2909#          "policy": "preferred"
2910#        }
2911#      ]
2912#    }
2913#
2914##
2915{ 'command': 'query-memdev', 'returns': ['Memdev'], 'allow-preconfig': true }
2916
2917##
2918# @PCDIMMDeviceInfo:
2919#
2920# PCDIMMDevice state information
2921#
2922# @id: device's ID
2923#
2924# @addr: physical address, where device is mapped
2925#
2926# @size: size of memory that the device provides
2927#
2928# @slot: slot number at which device is plugged in
2929#
2930# @node: NUMA node number where device is plugged in
2931#
2932# @memdev: memory backend linked with device
2933#
2934# @hotplugged: true if device was hotplugged
2935#
2936# @hotpluggable: true if device if could be added/removed while machine is running
2937#
2938# Since: 2.1
2939##
2940{ 'struct': 'PCDIMMDeviceInfo',
2941  'data': { '*id': 'str',
2942            'addr': 'int',
2943            'size': 'int',
2944            'slot': 'int',
2945            'node': 'int',
2946            'memdev': 'str',
2947            'hotplugged': 'bool',
2948            'hotpluggable': 'bool'
2949          }
2950}
2951
2952##
2953# @MemoryDeviceInfo:
2954#
2955# Union containing information about a memory device
2956#
2957# Since: 2.1
2958##
2959{ 'union': 'MemoryDeviceInfo',
2960  'data': { 'dimm': 'PCDIMMDeviceInfo',
2961            'nvdimm': 'PCDIMMDeviceInfo'
2962          }
2963}
2964
2965##
2966# @query-memory-devices:
2967#
2968# Lists available memory devices and their state
2969#
2970# Since: 2.1
2971#
2972# Example:
2973#
2974# -> { "execute": "query-memory-devices" }
2975# <- { "return": [ { "data":
2976#                       { "addr": 5368709120,
2977#                         "hotpluggable": true,
2978#                         "hotplugged": true,
2979#                         "id": "d1",
2980#                         "memdev": "/objects/memX",
2981#                         "node": 0,
2982#                         "size": 1073741824,
2983#                         "slot": 0},
2984#                    "type": "dimm"
2985#                  } ] }
2986#
2987##
2988{ 'command': 'query-memory-devices', 'returns': ['MemoryDeviceInfo'] }
2989
2990##
2991# @MEM_UNPLUG_ERROR:
2992#
2993# Emitted when memory hot unplug error occurs.
2994#
2995# @device: device name
2996#
2997# @msg: Informative message
2998#
2999# Since: 2.4
3000#
3001# Example:
3002#
3003# <- { "event": "MEM_UNPLUG_ERROR"
3004#      "data": { "device": "dimm1",
3005#                "msg": "acpi: device unplug for unsupported device"
3006#      },
3007#      "timestamp": { "seconds": 1265044230, "microseconds": 450486 } }
3008#
3009##
3010{ 'event': 'MEM_UNPLUG_ERROR',
3011  'data': { 'device': 'str', 'msg': 'str' } }
3012
3013##
3014# @ACPISlotType:
3015#
3016# @DIMM: memory slot
3017# @CPU: logical CPU slot (since 2.7)
3018##
3019{ 'enum': 'ACPISlotType', 'data': [ 'DIMM', 'CPU' ] }
3020
3021##
3022# @ACPIOSTInfo:
3023#
3024# OSPM Status Indication for a device
3025# For description of possible values of @source and @status fields
3026# see "_OST (OSPM Status Indication)" chapter of ACPI5.0 spec.
3027#
3028# @device: device ID associated with slot
3029#
3030# @slot: slot ID, unique per slot of a given @slot-type
3031#
3032# @slot-type: type of the slot
3033#
3034# @source: an integer containing the source event
3035#
3036# @status: an integer containing the status code
3037#
3038# Since: 2.1
3039##
3040{ 'struct': 'ACPIOSTInfo',
3041  'data'  : { '*device': 'str',
3042              'slot': 'str',
3043              'slot-type': 'ACPISlotType',
3044              'source': 'int',
3045              'status': 'int' } }
3046
3047##
3048# @query-acpi-ospm-status:
3049#
3050# Return a list of ACPIOSTInfo for devices that support status
3051# reporting via ACPI _OST method.
3052#
3053# Since: 2.1
3054#
3055# Example:
3056#
3057# -> { "execute": "query-acpi-ospm-status" }
3058# <- { "return": [ { "device": "d1", "slot": "0", "slot-type": "DIMM", "source": 1, "status": 0},
3059#                  { "slot": "1", "slot-type": "DIMM", "source": 0, "status": 0},
3060#                  { "slot": "2", "slot-type": "DIMM", "source": 0, "status": 0},
3061#                  { "slot": "3", "slot-type": "DIMM", "source": 0, "status": 0}
3062#    ]}
3063#
3064##
3065{ 'command': 'query-acpi-ospm-status', 'returns': ['ACPIOSTInfo'] }
3066
3067##
3068# @ACPI_DEVICE_OST:
3069#
3070# Emitted when guest executes ACPI _OST method.
3071#
3072# @info: OSPM Status Indication
3073#
3074# Since: 2.1
3075#
3076# Example:
3077#
3078# <- { "event": "ACPI_DEVICE_OST",
3079#      "data": { "device": "d1", "slot": "0",
3080#                "slot-type": "DIMM", "source": 1, "status": 0 } }
3081#
3082##
3083{ 'event': 'ACPI_DEVICE_OST',
3084     'data': { 'info': 'ACPIOSTInfo' } }
3085
3086##
3087# @rtc-reset-reinjection:
3088#
3089# This command will reset the RTC interrupt reinjection backlog.
3090# Can be used if another mechanism to synchronize guest time
3091# is in effect, for example QEMU guest agent's guest-set-time
3092# command.
3093#
3094# Since: 2.1
3095#
3096# Example:
3097#
3098# -> { "execute": "rtc-reset-reinjection" }
3099# <- { "return": {} }
3100#
3101##
3102{ 'command': 'rtc-reset-reinjection' }
3103
3104##
3105# @RTC_CHANGE:
3106#
3107# Emitted when the guest changes the RTC time.
3108#
3109# @offset: offset between base RTC clock (as specified by -rtc base), and
3110#          new RTC clock value. Note that value will be different depending
3111#          on clock chosen to drive RTC (specified by -rtc clock).
3112#
3113# Note: This event is rate-limited.
3114#
3115# Since: 0.13.0
3116#
3117# Example:
3118#
3119# <-   { "event": "RTC_CHANGE",
3120#        "data": { "offset": 78 },
3121#        "timestamp": { "seconds": 1267020223, "microseconds": 435656 } }
3122#
3123##
3124{ 'event': 'RTC_CHANGE',
3125  'data': { 'offset': 'int' } }
3126
3127##
3128# @ReplayMode:
3129#
3130# Mode of the replay subsystem.
3131#
3132# @none: normal execution mode. Replay or record are not enabled.
3133#
3134# @record: record mode. All non-deterministic data is written into the
3135#          replay log.
3136#
3137# @play: replay mode. Non-deterministic data required for system execution
3138#        is read from the log.
3139#
3140# Since: 2.5
3141##
3142{ 'enum': 'ReplayMode',
3143  'data': [ 'none', 'record', 'play' ] }
3144
3145##
3146# @xen-load-devices-state:
3147#
3148# Load the state of all devices from file. The RAM and the block devices
3149# of the VM are not loaded by this command.
3150#
3151# @filename: the file to load the state of the devices from as binary
3152# data. See xen-save-devices-state.txt for a description of the binary
3153# format.
3154#
3155# Since: 2.7
3156#
3157# Example:
3158#
3159# -> { "execute": "xen-load-devices-state",
3160#      "arguments": { "filename": "/tmp/resume" } }
3161# <- { "return": {} }
3162#
3163##
3164{ 'command': 'xen-load-devices-state', 'data': {'filename': 'str'} }
3165
3166##
3167# @GICCapability:
3168#
3169# The struct describes capability for a specific GIC (Generic
3170# Interrupt Controller) version. These bits are not only decided by
3171# QEMU/KVM software version, but also decided by the hardware that
3172# the program is running upon.
3173#
3174# @version:  version of GIC to be described. Currently, only 2 and 3
3175#            are supported.
3176#
3177# @emulated: whether current QEMU/hardware supports emulated GIC
3178#            device in user space.
3179#
3180# @kernel:   whether current QEMU/hardware supports hardware
3181#            accelerated GIC device in kernel.
3182#
3183# Since: 2.6
3184##
3185{ 'struct': 'GICCapability',
3186  'data': { 'version': 'int',
3187            'emulated': 'bool',
3188            'kernel': 'bool' } }
3189
3190##
3191# @query-gic-capabilities:
3192#
3193# This command is ARM-only. It will return a list of GICCapability
3194# objects that describe its capability bits.
3195#
3196# Returns: a list of GICCapability objects.
3197#
3198# Since: 2.6
3199#
3200# Example:
3201#
3202# -> { "execute": "query-gic-capabilities" }
3203# <- { "return": [{ "version": 2, "emulated": true, "kernel": false },
3204#                 { "version": 3, "emulated": false, "kernel": true } ] }
3205#
3206##
3207{ 'command': 'query-gic-capabilities', 'returns': ['GICCapability'] }
3208
3209##
3210# @CpuInstanceProperties:
3211#
3212# List of properties to be used for hotplugging a CPU instance,
3213# it should be passed by management with device_add command when
3214# a CPU is being hotplugged.
3215#
3216# @node-id: NUMA node ID the CPU belongs to
3217# @socket-id: socket number within node/board the CPU belongs to
3218# @core-id: core number within socket the CPU belongs to
3219# @thread-id: thread number within core the CPU belongs to
3220#
3221# Note: currently there are 4 properties that could be present
3222# but management should be prepared to pass through other
3223# properties with device_add command to allow for future
3224# interface extension. This also requires the filed names to be kept in
3225# sync with the properties passed to -device/device_add.
3226#
3227# Since: 2.7
3228##
3229{ 'struct': 'CpuInstanceProperties',
3230  'data': { '*node-id': 'int',
3231            '*socket-id': 'int',
3232            '*core-id': 'int',
3233            '*thread-id': 'int'
3234  }
3235}
3236
3237##
3238# @HotpluggableCPU:
3239#
3240# @type: CPU object type for usage with device_add command
3241# @props: list of properties to be used for hotplugging CPU
3242# @vcpus-count: number of logical VCPU threads @HotpluggableCPU provides
3243# @qom-path: link to existing CPU object if CPU is present or
3244#            omitted if CPU is not present.
3245#
3246# Since: 2.7
3247##
3248{ 'struct': 'HotpluggableCPU',
3249  'data': { 'type': 'str',
3250            'vcpus-count': 'int',
3251            'props': 'CpuInstanceProperties',
3252            '*qom-path': 'str'
3253          }
3254}
3255
3256##
3257# @query-hotpluggable-cpus:
3258#
3259# TODO: Better documentation; currently there is none.
3260#
3261# Returns: a list of HotpluggableCPU objects.
3262#
3263# Since: 2.7
3264#
3265# Example:
3266#
3267# For pseries machine type started with -smp 2,cores=2,maxcpus=4 -cpu POWER8:
3268#
3269# -> { "execute": "query-hotpluggable-cpus" }
3270# <- {"return": [
3271#      { "props": { "core": 8 }, "type": "POWER8-spapr-cpu-core",
3272#        "vcpus-count": 1 },
3273#      { "props": { "core": 0 }, "type": "POWER8-spapr-cpu-core",
3274#        "vcpus-count": 1, "qom-path": "/machine/unattached/device[0]"}
3275#    ]}'
3276#
3277# For pc machine type started with -smp 1,maxcpus=2:
3278#
3279# -> { "execute": "query-hotpluggable-cpus" }
3280# <- {"return": [
3281#      {
3282#         "type": "qemu64-x86_64-cpu", "vcpus-count": 1,
3283#         "props": {"core-id": 0, "socket-id": 1, "thread-id": 0}
3284#      },
3285#      {
3286#         "qom-path": "/machine/unattached/device[0]",
3287#         "type": "qemu64-x86_64-cpu", "vcpus-count": 1,
3288#         "props": {"core-id": 0, "socket-id": 0, "thread-id": 0}
3289#      }
3290#    ]}
3291#
3292# For s390x-virtio-ccw machine type started with -smp 1,maxcpus=2 -cpu qemu
3293# (Since: 2.11):
3294#
3295# -> { "execute": "query-hotpluggable-cpus" }
3296# <- {"return": [
3297#      {
3298#         "type": "qemu-s390x-cpu", "vcpus-count": 1,
3299#         "props": { "core-id": 1 }
3300#      },
3301#      {
3302#         "qom-path": "/machine/unattached/device[0]",
3303#         "type": "qemu-s390x-cpu", "vcpus-count": 1,
3304#         "props": { "core-id": 0 }
3305#      }
3306#    ]}
3307#
3308##
3309{ 'command': 'query-hotpluggable-cpus', 'returns': ['HotpluggableCPU'],
3310             'allow-preconfig': true }
3311
3312##
3313# @GuidInfo:
3314#
3315# GUID information.
3316#
3317# @guid: the globally unique identifier
3318#
3319# Since: 2.9
3320##
3321{ 'struct': 'GuidInfo', 'data': {'guid': 'str'} }
3322
3323##
3324# @query-vm-generation-id:
3325#
3326# Show Virtual Machine Generation ID
3327#
3328# Since: 2.9
3329##
3330{ 'command': 'query-vm-generation-id', 'returns': 'GuidInfo' }
3331
3332
3333##
3334# @SevState:
3335#
3336# An enumeration of SEV state information used during @query-sev.
3337#
3338# @uninit: The guest is uninitialized.
3339#
3340# @launch-update: The guest is currently being launched; plaintext data and
3341#                 register state is being imported.
3342#
3343# @launch-secret: The guest is currently being launched; ciphertext data
3344#                 is being imported.
3345#
3346# @running: The guest is fully launched or migrated in.
3347#
3348# @send-update: The guest is currently being migrated out to another machine.
3349#
3350# @receive-update: The guest is currently being migrated from another machine.
3351#
3352# Since: 2.12
3353##
3354{ 'enum': 'SevState',
3355  'data': ['uninit', 'launch-update', 'launch-secret', 'running',
3356           'send-update', 'receive-update' ] }
3357
3358##
3359# @SevInfo:
3360#
3361# Information about Secure Encrypted Virtualization (SEV) support
3362#
3363# @enabled: true if SEV is active
3364#
3365# @api-major: SEV API major version
3366#
3367# @api-minor: SEV API minor version
3368#
3369# @build-id: SEV FW build id
3370#
3371# @policy: SEV policy value
3372#
3373# @state: SEV guest state
3374#
3375# @handle: SEV firmware handle
3376#
3377# Since: 2.12
3378##
3379{ 'struct': 'SevInfo',
3380    'data': { 'enabled': 'bool',
3381              'api-major': 'uint8',
3382              'api-minor' : 'uint8',
3383              'build-id' : 'uint8',
3384              'policy' : 'uint32',
3385              'state' : 'SevState',
3386              'handle' : 'uint32'
3387            }
3388}
3389
3390##
3391# @query-sev:
3392#
3393# Returns information about SEV
3394#
3395# Returns: @SevInfo
3396#
3397# Since: 2.12
3398#
3399# Example:
3400#
3401# -> { "execute": "query-sev" }
3402# <- { "return": { "enabled": true, "api-major" : 0, "api-minor" : 0,
3403#                  "build-id" : 0, "policy" : 0, "state" : "running",
3404#                  "handle" : 1 } }
3405#
3406##
3407{ 'command': 'query-sev', 'returns': 'SevInfo' }
3408
3409##
3410# @SevLaunchMeasureInfo:
3411#
3412# SEV Guest Launch measurement information
3413#
3414# @data: the measurement value encoded in base64
3415#
3416# Since: 2.12
3417#
3418##
3419{ 'struct': 'SevLaunchMeasureInfo', 'data': {'data': 'str'} }
3420
3421##
3422# @query-sev-launch-measure:
3423#
3424# Query the SEV guest launch information.
3425#
3426# Returns: The @SevLaunchMeasureInfo for the guest
3427#
3428# Since: 2.12
3429#
3430# Example:
3431#
3432# -> { "execute": "query-sev-launch-measure" }
3433# <- { "return": { "data": "4l8LXeNlSPUDlXPJG5966/8%YZ" } }
3434#
3435##
3436{ 'command': 'query-sev-launch-measure', 'returns': 'SevLaunchMeasureInfo' }
3437
3438##
3439# @SevCapability:
3440#
3441# The struct describes capability for a Secure Encrypted Virtualization
3442# feature.
3443#
3444# @pdh:  Platform Diffie-Hellman key (base64 encoded)
3445#
3446# @cert-chain:  PDH certificate chain (base64 encoded)
3447#
3448# @cbitpos: C-bit location in page table entry
3449#
3450# @reduced-phys-bits: Number of physical Address bit reduction when SEV is
3451#                     enabled
3452#
3453# Since: 2.12
3454##
3455{ 'struct': 'SevCapability',
3456  'data': { 'pdh': 'str',
3457            'cert-chain': 'str',
3458            'cbitpos': 'int',
3459            'reduced-phys-bits': 'int'} }
3460
3461##
3462# @query-sev-capabilities:
3463#
3464# This command is used to get the SEV capabilities, and is supported on AMD
3465# X86 platforms only.
3466#
3467# Returns: SevCapability objects.
3468#
3469# Since: 2.12
3470#
3471# Example:
3472#
3473# -> { "execute": "query-sev-capabilities" }
3474# <- { "return": { "pdh": "8CCDD8DDD", "cert-chain": "888CCCDDDEE",
3475#                  "cbitpos": 47, "reduced-phys-bits": 5}}
3476#
3477##
3478{ 'command': 'query-sev-capabilities', 'returns': 'SevCapability' }
3479
3480##
3481# @set-numa-node:
3482#
3483# Runtime equivalent of '-numa' CLI option, available at
3484# preconfigure stage to configure numa mapping before initializing
3485# machine.
3486#
3487# Since 3.0
3488##
3489{ 'command': 'set-numa-node', 'boxed': true,
3490  'data': 'NumaOptions',
3491  'allow-preconfig': true
3492}
3493