qemu/qmp-commands.hx

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HXCOMM QMP dispatch table and documentation
HXCOMM Text between SQMP and EQMP is copied to the QMP documentation file and
HXCOMM does not show up in the other formats.
SQMP
QMP Supported Commands
----------------------
This document describes all commands currently supported by QMP.
Most of the time their usage is exactly the same as in the user Monitor, this
means that any other document which also describe commands (the manpage,
QEMU's manual, etc) can and should be consulted.
QMP has two types of commands: regular and query commands. Regular commands
usually change the Virtual Machine's state someway, while query commands just
return information. The sections below are divided accordingly.
It's important to observe that all communication examples are formatted in
a reader-friendly way, so that they're easier to understand. However, in real
protocol usage, they're emitted as a single line.
Also, the following notation is used to denote data flow:
-> data issued by the Client
<- Server data response
Please, refer to the QMP specification (QMP/qmp-spec.txt) for detailed
information on the Server command and response formats.
NOTE: This document is temporary and will be replaced soon.
1. Stability Considerations
===========================
The current QMP command set (described in this file) may be useful for a
number of use cases, however it's limited and several commands have bad
defined semantics, specially with regard to command completion.
These problems are going to be solved incrementally in the next QEMU releases
and we're going to establish a deprecation policy for badly defined commands.
If you're planning to adopt QMP, please observe the following:
1. The deprecation policy will take effect and be documented soon, please
check the documentation of each used command as soon as a new release of
QEMU is available
2. DO NOT rely on anything which is not explicit documented
3. Errors, in special, are not documented. Applications should NOT check
for specific errors classes or data (it's strongly recommended to only
check for the "error" key)
2. Regular Commands
===================
Server's responses in the examples below are always a success response, please
refer to the QMP specification for more details on error responses.
EQMP
{
.name = "quit",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_quit,
},
SQMP
quit
----
Quit the emulator.
Arguments: None.
Example:
-> { "execute": "quit" }
<- { "return": {} }
EQMP
{
.name = "eject",
.args_type = "force:-f,device:B",
.mhandler.cmd_new = qmp_marshal_eject,
},
SQMP
eject
-----
Eject a removable medium.
Arguments:
- force: force ejection (json-bool, optional)
- device: device name (json-string)
Example:
-> { "execute": "eject", "arguments": { "device": "ide1-cd0" } }
<- { "return": {} }
Note: The "force" argument defaults to false.
EQMP
{
.name = "change",
.args_type = "device:B,target:F,arg:s?",
.mhandler.cmd_new = qmp_marshal_change,
},
SQMP
change
------
Change a removable medium or VNC configuration.
Arguments:
- "device": device name (json-string)
- "target": filename or item (json-string)
- "arg": additional argument (json-string, optional)
Examples:
1. Change a removable medium
-> { "execute": "change",
"arguments": { "device": "ide1-cd0",
"target": "/srv/images/Fedora-12-x86_64-DVD.iso" } }
<- { "return": {} }
2. Change VNC password
-> { "execute": "change",
"arguments": { "device": "vnc", "target": "password",
"arg": "foobar1" } }
<- { "return": {} }
EQMP
{
.name = "screendump",
.args_type = "filename:F",
.mhandler.cmd_new = qmp_marshal_screendump,
},
SQMP
screendump
----------
Save screen into PPM image.
Arguments:
- "filename": file path (json-string)
Example:
-> { "execute": "screendump", "arguments": { "filename": "/tmp/image" } }
<- { "return": {} }
EQMP
{
.name = "stop",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_stop,
},
SQMP
stop
----
Stop the emulator.
Arguments: None.
Example:
-> { "execute": "stop" }
<- { "return": {} }
EQMP
{
.name = "cont",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_cont,
},
SQMP
cont
----
Resume emulation.
Arguments: None.
Example:
-> { "execute": "cont" }
<- { "return": {} }
EQMP
{
.name = "system_wakeup",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_system_wakeup,
},
SQMP
system_wakeup
-------------
Wakeup guest from suspend.
Arguments: None.
Example:
-> { "execute": "system_wakeup" }
<- { "return": {} }
EQMP
{
.name = "system_reset",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_system_reset,
},
SQMP
system_reset
------------
Reset the system.
Arguments: None.
Example:
-> { "execute": "system_reset" }
<- { "return": {} }
EQMP
{
.name = "system_powerdown",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_system_powerdown,
},
SQMP
system_powerdown
----------------
Send system power down event.
Arguments: None.
Example:
-> { "execute": "system_powerdown" }
<- { "return": {} }
EQMP
{
.name = "device_add",
.args_type = "device:O",
.params = "driver[,prop=value][,...]",
.help = "add device, like -device on the command line",
qmp: Wean off qerror_report() The traditional QMP command handler interface int qmp_FOO(Monitor *mon, const QDict *params, QObject **ret_data); doesn't provide for returning an Error object. Instead, the handler is expected to stash it in the monitor with qerror_report(). When we rebased QMP on top of QAPI, we didn't change this interface. Instead, commit 776574d introduced "middle mode" as a temporary aid for converting existing QMP commands to QAPI one by one. More than three years later, we're still using it. Middle mode has two effects: * Instead of the native input marshallers static void qmp_marshal_input_FOO(QDict *, QObject **, Error **) it generates input marshallers conforming to the traditional QMP command handler interface. * It suppresses generation of code to register them with qmp_register_command() This permits giving them internal linkage. As long as we need qmp-commands.hx, we can't use the registry behind qmp_register_command(), so the latter has to stay for now. The former has to go to get rid of qerror_report(). Changing all QMP commands to fit the QAPI mold in one go was impractical back when we started, but by now there are just a few stragglers left: do_qmp_capabilities(), qmp_qom_set(), qmp_qom_get(), qmp_object_add(), qmp_netdev_add(), do_device_add(). Switch middle mode to generate native input marshallers, and adapt the stragglers. Simplifies both the monitor code and the stragglers. Rename do_qmp_capabilities() to qmp_capabilities(), and do_device_add() to qmp_device_add, because that's how QMP command handlers are named today. Signed-off-by: Markus Armbruster <armbru@redhat.com> Reviewed-by: Stefan Hajnoczi <stefanha@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Luiz Capitulino <lcapitulino@redhat.com>
2015-03-13 19:25:50 +03:00
.mhandler.cmd_new = qmp_device_add,
},
SQMP
device_add
----------
Add a device.
Arguments:
- "driver": the name of the new device's driver (json-string)
- "bus": the device's parent bus (device tree path, json-string, optional)
- "id": the device's ID, must be unique (json-string)
- device properties
Example:
-> { "execute": "device_add", "arguments": { "driver": "e1000", "id": "net1" } }
<- { "return": {} }
Notes:
(1) For detailed information about this command, please refer to the
'docs/qdev-device-use.txt' file.
(2) It's possible to list device properties by running QEMU with the
"-device DEVICE,\?" command-line argument, where DEVICE is the device's name
EQMP
{
.name = "device_del",
.args_type = "id:s",
.mhandler.cmd_new = qmp_marshal_device_del,
},
SQMP
device_del
----------
Remove a device.
Arguments:
- "id": the device's ID or QOM path (json-string)
Example:
-> { "execute": "device_del", "arguments": { "id": "net1" } }
<- { "return": {} }
Example:
-> { "execute": "device_del", "arguments": { "id": "/machine/peripheral-anon/device[0]" } }
<- { "return": {} }
EQMP
{
.name = "send-key",
.args_type = "keys:q,hold-time:i?",
.mhandler.cmd_new = qmp_marshal_send_key,
},
SQMP
send-key
----------
Send keys to VM.
Arguments:
keys array:
- "key": key sequence (a json-array of key union values,
union can be number or qcode enum)
- hold-time: time to delay key up events, milliseconds. Defaults to 100
(json-int, optional)
Example:
-> { "execute": "send-key",
"arguments": { "keys": [ { "type": "qcode", "data": "ctrl" },
{ "type": "qcode", "data": "alt" },
{ "type": "qcode", "data": "delete" } ] } }
<- { "return": {} }
EQMP
{
.name = "cpu",
.args_type = "index:i",
.mhandler.cmd_new = qmp_marshal_cpu,
},
SQMP
cpu
---
Set the default CPU.
Arguments:
- "index": the CPU's index (json-int)
Example:
-> { "execute": "cpu", "arguments": { "index": 0 } }
<- { "return": {} }
Note: CPUs' indexes are obtained with the 'query-cpus' command.
EQMP
{
.name = "cpu-add",
.args_type = "id:i",
.mhandler.cmd_new = qmp_marshal_cpu_add,
},
SQMP
cpu-add
-------
Adds virtual cpu
Arguments:
- "id": cpu id (json-int)
Example:
-> { "execute": "cpu-add", "arguments": { "id": 2 } }
<- { "return": {} }
EQMP
{
.name = "memsave",
.args_type = "val:l,size:i,filename:s,cpu:i?",
.mhandler.cmd_new = qmp_marshal_memsave,
},
SQMP
memsave
-------
Save to disk virtual memory dump starting at 'val' of size 'size'.
Arguments:
- "val": the starting address (json-int)
- "size": the memory size, in bytes (json-int)
- "filename": file path (json-string)
- "cpu": virtual CPU index (json-int, optional)
Example:
-> { "execute": "memsave",
"arguments": { "val": 10,
"size": 100,
"filename": "/tmp/virtual-mem-dump" } }
<- { "return": {} }
EQMP
{
.name = "pmemsave",
.args_type = "val:l,size:i,filename:s",
.mhandler.cmd_new = qmp_marshal_pmemsave,
},
SQMP
pmemsave
--------
Save to disk physical memory dump starting at 'val' of size 'size'.
Arguments:
- "val": the starting address (json-int)
- "size": the memory size, in bytes (json-int)
- "filename": file path (json-string)
Example:
-> { "execute": "pmemsave",
"arguments": { "val": 10,
"size": 100,
"filename": "/tmp/physical-mem-dump" } }
<- { "return": {} }
EQMP
{
.name = "inject-nmi",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_inject_nmi,
},
SQMP
inject-nmi
----------
Inject an NMI on the default CPU (x86/s390) or all CPUs (ppc64).
Arguments: None.
Example:
-> { "execute": "inject-nmi" }
<- { "return": {} }
Note: inject-nmi fails when the guest doesn't support injecting.
EQMP
{
.name = "ringbuf-write",
.args_type = "device:s,data:s,format:s?",
.mhandler.cmd_new = qmp_marshal_ringbuf_write,
},
SQMP
ringbuf-write
-------------
Write to a ring buffer character device.
Arguments:
- "device": ring buffer character device name (json-string)
- "data": data to write (json-string)
- "format": data format (json-string, optional)
- Possible values: "utf8" (default), "base64"
Bug: invalid base64 is currently not rejected.
Whitespace *is* invalid.
Example:
-> { "execute": "ringbuf-write",
"arguments": { "device": "foo",
"data": "abcdefgh",
"format": "utf8" } }
<- { "return": {} }
EQMP
{
.name = "ringbuf-read",
.args_type = "device:s,size:i,format:s?",
.mhandler.cmd_new = qmp_marshal_ringbuf_read,
},
SQMP
ringbuf-read
-------------
Read from a ring buffer character device.
Arguments:
- "device": ring buffer character device name (json-string)
- "size": how many bytes to read at most (json-int)
- Number of data bytes, not number of characters in encoded data
- "format": data format (json-string, optional)
- Possible values: "utf8" (default), "base64"
- Naturally, format "utf8" works only when the ring buffer
contains valid UTF-8 text. Invalid UTF-8 sequences get
replaced. Bug: replacement doesn't work. Bug: can screw
up on encountering NUL characters, after the ring buffer
lost data, and when reading stops because the size limit
is reached.
Example:
-> { "execute": "ringbuf-read",
"arguments": { "device": "foo",
"size": 1000,
"format": "utf8" } }
<- {"return": "abcdefgh"}
EQMP
{
.name = "xen-save-devices-state",
.args_type = "filename:F",
.mhandler.cmd_new = qmp_marshal_xen_save_devices_state,
},
SQMP
xen-save-devices-state
-------
Save the state of all devices to file. The RAM and the block devices
of the VM are not saved by this command.
Arguments:
- "filename": the file to save the state of the devices to as binary
data. See xen-save-devices-state.txt for a description of the binary
format.
Example:
-> { "execute": "xen-save-devices-state",
"arguments": { "filename": "/tmp/save" } }
<- { "return": {} }
EQMP
{
.name = "xen-set-global-dirty-log",
.args_type = "enable:b",
.mhandler.cmd_new = qmp_marshal_xen_set_global_dirty_log,
},
SQMP
xen-set-global-dirty-log
-------
Enable or disable the global dirty log mode.
Arguments:
- "enable": Enable it or disable it.
Example:
-> { "execute": "xen-set-global-dirty-log",
"arguments": { "enable": true } }
<- { "return": {} }
EQMP
{
.name = "migrate",
.args_type = "detach:-d,blk:-b,inc:-i,uri:s",
.mhandler.cmd_new = qmp_marshal_migrate,
},
SQMP
migrate
-------
Migrate to URI.
Arguments:
- "blk": block migration, full disk copy (json-bool, optional)
- "inc": incremental disk copy (json-bool, optional)
- "uri": Destination URI (json-string)
Example:
-> { "execute": "migrate", "arguments": { "uri": "tcp:0:4446" } }
<- { "return": {} }
Notes:
(1) The 'query-migrate' command should be used to check migration's progress
and final result (this information is provided by the 'status' member)
(2) All boolean arguments default to false
(3) The user Monitor's "detach" argument is invalid in QMP and should not
be used
EQMP
{
.name = "migrate_cancel",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_migrate_cancel,
},
SQMP
migrate_cancel
--------------
Cancel the current migration.
Arguments: None.
Example:
-> { "execute": "migrate_cancel" }
<- { "return": {} }
EQMP
{
.name = "migrate-incoming",
.args_type = "uri:s",
.mhandler.cmd_new = qmp_marshal_migrate_incoming,
},
SQMP
migrate-incoming
----------------
Continue an incoming migration
Arguments:
- "uri": Source/listening URI (json-string)
Example:
-> { "execute": "migrate-incoming", "arguments": { "uri": "tcp::4446" } }
<- { "return": {} }
Notes:
(1) QEMU must be started with -incoming defer to allow migrate-incoming to
be used
(2) The uri format is the same as for -incoming
EQMP
{
.name = "migrate-set-cache-size",
.args_type = "value:o",
.mhandler.cmd_new = qmp_marshal_migrate_set_cache_size,
},
SQMP
migrate-set-cache-size
----------------------
Set cache size to be used by XBZRLE migration, the cache size will be rounded
down to the nearest power of 2
Arguments:
- "value": cache size in bytes (json-int)
Example:
-> { "execute": "migrate-set-cache-size", "arguments": { "value": 536870912 } }
<- { "return": {} }
EQMP
{
.name = "query-migrate-cache-size",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_migrate_cache_size,
},
SQMP
query-migrate-cache-size
------------------------
Show cache size to be used by XBZRLE migration
returns a json-object with the following information:
- "size" : json-int
Example:
-> { "execute": "query-migrate-cache-size" }
<- { "return": 67108864 }
EQMP
{
.name = "migrate_set_speed",
.args_type = "value:o",
.mhandler.cmd_new = qmp_marshal_migrate_set_speed,
},
SQMP
migrate_set_speed
-----------------
Set maximum speed for migrations.
Arguments:
- "value": maximum speed, in bytes per second (json-int)
Example:
-> { "execute": "migrate_set_speed", "arguments": { "value": 1024 } }
<- { "return": {} }
EQMP
{
.name = "migrate_set_downtime",
.args_type = "value:T",
.mhandler.cmd_new = qmp_marshal_migrate_set_downtime,
},
SQMP
migrate_set_downtime
--------------------
Set maximum tolerated downtime (in seconds) for migrations.
Arguments:
- "value": maximum downtime (json-number)
Example:
-> { "execute": "migrate_set_downtime", "arguments": { "value": 0.1 } }
<- { "return": {} }
EQMP
{
.name = "client_migrate_info",
.args_type = "protocol:s,hostname:s,port:i?,tls-port:i?,cert-subject:s?",
.params = "protocol hostname port tls-port cert-subject",
.help = "set migration information for remote display",
.mhandler.cmd_new = qmp_marshal_client_migrate_info,
},
SQMP
client_migrate_info
-------------------
Set migration information for remote display. This makes the server
ask the client to automatically reconnect using the new parameters
once migration finished successfully. Only implemented for SPICE.
Arguments:
- "protocol": must be "spice" (json-string)
- "hostname": migration target hostname (json-string)
- "port": spice tcp port for plaintext channels (json-int, optional)
- "tls-port": spice tcp port for tls-secured channels (json-int, optional)
- "cert-subject": server certificate subject (json-string, optional)
Example:
-> { "execute": "client_migrate_info",
"arguments": { "protocol": "spice",
"hostname": "virt42.lab.kraxel.org",
"port": 1234 } }
<- { "return": {} }
EQMP
{
.name = "dump-guest-memory",
.args_type = "paging:b,protocol:s,begin:i?,end:i?,format:s?",
.params = "-p protocol [begin] [length] [format]",
.help = "dump guest memory to file",
.mhandler.cmd_new = qmp_marshal_dump_guest_memory,
},
SQMP
dump
Dump guest memory to file. The file can be processed with crash or gdb.
Arguments:
- "paging": do paging to get guest's memory mapping (json-bool)
- "protocol": destination file(started with "file:") or destination file
descriptor (started with "fd:") (json-string)
- "begin": the starting physical address. It's optional, and should be specified
with length together (json-int)
- "length": the memory size, in bytes. It's optional, and should be specified
with begin together (json-int)
- "format": the format of guest memory dump. It's optional, and can be
elf|kdump-zlib|kdump-lzo|kdump-snappy, but non-elf formats will
conflict with paging and filter, ie. begin and length (json-string)
Example:
-> { "execute": "dump-guest-memory", "arguments": { "protocol": "fd:dump" } }
<- { "return": {} }
Notes:
(1) All boolean arguments default to false
EQMP
{
.name = "query-dump-guest-memory-capability",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_dump_guest_memory_capability,
},
SQMP
query-dump-guest-memory-capability
----------
Show available formats for 'dump-guest-memory'
Example:
-> { "execute": "query-dump-guest-memory-capability" }
<- { "return": { "formats":
["elf", "kdump-zlib", "kdump-lzo", "kdump-snappy"] }
EQMP
#if defined TARGET_S390X
{
.name = "dump-skeys",
.args_type = "filename:F",
.mhandler.cmd_new = qmp_marshal_dump_skeys,
},
#endif
SQMP
dump-skeys
----------
Save guest storage keys to file.
Arguments:
- "filename": file path (json-string)
Example:
-> { "execute": "dump-skeys", "arguments": { "filename": "/tmp/skeys" } }
<- { "return": {} }
EQMP
{
.name = "netdev_add",
.args_type = "netdev:O",
.mhandler.cmd_new = qmp_netdev_add,
},
SQMP
netdev_add
----------
Add host network device.
Arguments:
- "type": the device type, "tap", "user", ... (json-string)
- "id": the device's ID, must be unique (json-string)
- device options
Example:
-> { "execute": "netdev_add",
"arguments": { "type": "user", "id": "netdev1",
"dnssearch": "example.org" } }
<- { "return": {} }
Note: The supported device options are the same ones supported by the '-netdev'
command-line argument, which are listed in the '-help' output or QEMU's
manual
EQMP
{
.name = "netdev_del",
.args_type = "id:s",
.mhandler.cmd_new = qmp_marshal_netdev_del,
},
SQMP
netdev_del
----------
Remove host network device.
Arguments:
- "id": the device's ID, must be unique (json-string)
Example:
-> { "execute": "netdev_del", "arguments": { "id": "netdev1" } }
<- { "return": {} }
EQMP
{
.name = "object-add",
.args_type = "qom-type:s,id:s,props:q?",
.mhandler.cmd_new = qmp_marshal_object_add,
},
SQMP
object-add
----------
Create QOM object.
Arguments:
- "qom-type": the object's QOM type, i.e. the class name (json-string)
- "id": the object's ID, must be unique (json-string)
- "props": a dictionary of object property values (optional, json-dict)
Example:
-> { "execute": "object-add", "arguments": { "qom-type": "rng-random", "id": "rng1",
"props": { "filename": "/dev/hwrng" } } }
<- { "return": {} }
EQMP
{
.name = "object-del",
.args_type = "id:s",
.mhandler.cmd_new = qmp_marshal_object_del,
},
SQMP
object-del
----------
Remove QOM object.
Arguments:
- "id": the object's ID (json-string)
Example:
-> { "execute": "object-del", "arguments": { "id": "rng1" } }
<- { "return": {} }
EQMP
{
.name = "block_resize",
.args_type = "device:s?,node-name:s?,size:o",
.mhandler.cmd_new = qmp_marshal_block_resize,
},
SQMP
block_resize
------------
Resize a block image while a guest is running.
Arguments:
- "device": the device's ID, must be unique (json-string)
- "node-name": the node name in the block driver state graph (json-string)
- "size": new size
Example:
-> { "execute": "block_resize", "arguments": { "device": "scratch", "size": 1073741824 } }
<- { "return": {} }
EQMP
{
.name = "block-stream",
.args_type = "device:B,base:s?,speed:o?,backing-file:s?,on-error:s?",
.mhandler.cmd_new = qmp_marshal_block_stream,
},
SQMP
block-stream
------------
Copy data from a backing file into a block device.
Arguments:
- "device": The device's ID, must be unique (json-string)
- "base": The file name of the backing image above which copying starts
(json-string, optional)
- "backing-file": The backing file string to write into the active layer. This
filename is not validated.
If a pathname string is such that it cannot be resolved by
QEMU, that means that subsequent QMP or HMP commands must use
node-names for the image in question, as filename lookup
methods will fail.
If not specified, QEMU will automatically determine the
backing file string to use, or error out if there is no
obvious choice. Care should be taken when specifying the
string, to specify a valid filename or protocol.
(json-string, optional) (Since 2.1)
- "speed": the maximum speed, in bytes per second (json-int, optional)
- "on-error": the action to take on an error (default 'report'). 'stop' and
'enospc' can only be used if the block device supports io-status.
(json-string, optional) (Since 2.1)
Example:
-> { "execute": "block-stream", "arguments": { "device": "virtio0",
"base": "/tmp/master.qcow2" } }
<- { "return": {} }
EQMP
{
.name = "block-commit",
.args_type = "device:B,base:s?,top:s?,backing-file:s?,speed:o?",
.mhandler.cmd_new = qmp_marshal_block_commit,
},
SQMP
block-commit
------------
Live commit of data from overlay image nodes into backing nodes - i.e., writes
data between 'top' and 'base' into 'base'.
Arguments:
- "device": The device's ID, must be unique (json-string)
- "base": The file name of the backing image to write data into.
If not specified, this is the deepest backing image
(json-string, optional)
- "top": The file name of the backing image within the image chain,
which contains the topmost data to be committed down. If
not specified, this is the active layer. (json-string, optional)
- backing-file: The backing file string to write into the overlay
image of 'top'. If 'top' is the active layer,
specifying a backing file string is an error. This
filename is not validated.
If a pathname string is such that it cannot be
resolved by QEMU, that means that subsequent QMP or
HMP commands must use node-names for the image in
question, as filename lookup methods will fail.
If not specified, QEMU will automatically determine
the backing file string to use, or error out if
there is no obvious choice. Care should be taken
when specifying the string, to specify a valid
filename or protocol.
(json-string, optional) (Since 2.1)
If top == base, that is an error.
If top == active, the job will not be completed by itself,
user needs to complete the job with the block-job-complete
command after getting the ready event. (Since 2.0)
If the base image is smaller than top, then the base image
will be resized to be the same size as top. If top is
smaller than the base image, the base will not be
truncated. If you want the base image size to match the
size of the smaller top, you can safely truncate it
yourself once the commit operation successfully completes.
(json-string)
- "speed": the maximum speed, in bytes per second (json-int, optional)
Example:
-> { "execute": "block-commit", "arguments": { "device": "virtio0",
"top": "/tmp/snap1.qcow2" } }
<- { "return": {} }
EQMP
block: add drive-backup QMP command @drive-backup Start a point-in-time copy of a block device to a new destination. The status of ongoing drive-backup operations can be checked with query-block-jobs where the BlockJobInfo.type field has the value 'backup'. The operation can be stopped before it has completed using the block-job-cancel command. @device: the name of the device which should be copied. @target: the target of the new image. If the file exists, or if it is a device, the existing file/device will be used as the new destination. If it does not exist, a new file will be created. @format: #optional the format of the new destination, default is to probe if @mode is 'existing', else the format of the source @mode: #optional whether and how QEMU should create a new image, default is 'absolute-paths'. @speed: #optional the maximum speed, in bytes per second @on-source-error: #optional the action to take on an error on the source, default 'report'. 'stop' and 'enospc' can only be used if the block device supports io-status (see BlockInfo). @on-target-error: #optional the action to take on an error on the target, default 'report' (no limitations, since this applies to a different block device than @device). Note that @on-source-error and @on-target-error only affect background I/O. If an error occurs during a guest write request, the device's rerror/werror actions will be used. Returns: nothing on success If @device is not a valid block device, DeviceNotFound Since 1.6 Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Kevin Wolf <kwolf@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-06-24 19:13:14 +04:00
{
.name = "drive-backup",
.args_type = "sync:s,device:B,target:s,speed:i?,mode:s?,format:s?,"
"bitmap:s?,on-source-error:s?,on-target-error:s?",
.mhandler.cmd_new = qmp_marshal_drive_backup,
block: add drive-backup QMP command @drive-backup Start a point-in-time copy of a block device to a new destination. The status of ongoing drive-backup operations can be checked with query-block-jobs where the BlockJobInfo.type field has the value 'backup'. The operation can be stopped before it has completed using the block-job-cancel command. @device: the name of the device which should be copied. @target: the target of the new image. If the file exists, or if it is a device, the existing file/device will be used as the new destination. If it does not exist, a new file will be created. @format: #optional the format of the new destination, default is to probe if @mode is 'existing', else the format of the source @mode: #optional whether and how QEMU should create a new image, default is 'absolute-paths'. @speed: #optional the maximum speed, in bytes per second @on-source-error: #optional the action to take on an error on the source, default 'report'. 'stop' and 'enospc' can only be used if the block device supports io-status (see BlockInfo). @on-target-error: #optional the action to take on an error on the target, default 'report' (no limitations, since this applies to a different block device than @device). Note that @on-source-error and @on-target-error only affect background I/O. If an error occurs during a guest write request, the device's rerror/werror actions will be used. Returns: nothing on success If @device is not a valid block device, DeviceNotFound Since 1.6 Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Kevin Wolf <kwolf@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-06-24 19:13:14 +04:00
},
SQMP
drive-backup
------------
Start a point-in-time copy of a block device to a new destination. The
status of ongoing drive-backup operations can be checked with
query-block-jobs where the BlockJobInfo.type field has the value 'backup'.
The operation can be stopped before it has completed using the
block-job-cancel command.
Arguments:
- "device": the name of the device which should be copied.
(json-string)
- "target": the target of the new image. If the file exists, or if it is a
device, the existing file/device will be used as the new
destination. If it does not exist, a new file will be created.
(json-string)
- "format": the format of the new destination, default is to probe if 'mode' is
'existing', else the format of the source
(json-string, optional)
- "sync": what parts of the disk image should be copied to the destination;
possibilities include "full" for all the disk, "top" for only the sectors
allocated in the topmost image, "incremental" for only the dirty sectors in
the bitmap, or "none" to only replicate new I/O (MirrorSyncMode).
- "bitmap": dirty bitmap name for sync==incremental. Must be present if sync
is "incremental", must NOT be present otherwise.
block: add drive-backup QMP command @drive-backup Start a point-in-time copy of a block device to a new destination. The status of ongoing drive-backup operations can be checked with query-block-jobs where the BlockJobInfo.type field has the value 'backup'. The operation can be stopped before it has completed using the block-job-cancel command. @device: the name of the device which should be copied. @target: the target of the new image. If the file exists, or if it is a device, the existing file/device will be used as the new destination. If it does not exist, a new file will be created. @format: #optional the format of the new destination, default is to probe if @mode is 'existing', else the format of the source @mode: #optional whether and how QEMU should create a new image, default is 'absolute-paths'. @speed: #optional the maximum speed, in bytes per second @on-source-error: #optional the action to take on an error on the source, default 'report'. 'stop' and 'enospc' can only be used if the block device supports io-status (see BlockInfo). @on-target-error: #optional the action to take on an error on the target, default 'report' (no limitations, since this applies to a different block device than @device). Note that @on-source-error and @on-target-error only affect background I/O. If an error occurs during a guest write request, the device's rerror/werror actions will be used. Returns: nothing on success If @device is not a valid block device, DeviceNotFound Since 1.6 Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Kevin Wolf <kwolf@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-06-24 19:13:14 +04:00
- "mode": whether and how QEMU should create a new image
(NewImageMode, optional, default 'absolute-paths')
- "speed": the maximum speed, in bytes per second (json-int, optional)
- "on-source-error": the action to take on an error on the source, default
'report'. 'stop' and 'enospc' can only be used
if the block device supports io-status.
(BlockdevOnError, optional)
- "on-target-error": the action to take on an error on the target, default
'report' (no limitations, since this applies to
a different block device than device).
(BlockdevOnError, optional)
Example:
-> { "execute": "drive-backup", "arguments": { "device": "drive0",
Implement sync modes for drive-backup. This patch adds sync-modes to the drive-backup interface and implements the FULL, NONE and TOP modes of synchronization. FULL performs as before copying the entire contents of the drive while preserving the point-in-time using CoW. NONE only copies new writes to the target drive. TOP copies changes to the topmost drive image and preserves the point-in-time using CoW. For sync mode TOP are creating a new target image using the same backing file as the original disk image. Then any new data that has been laid on top of it since creation is copied in the main backup_run() loop. There is an extra check in the 'TOP' case so that we don't bother to copy all the data of the backing file as it already exists in the target. This is where the bdrv_co_is_allocated() is used to determine if the data exists in the topmost layer or below. Also any new data being written is intercepted via the write_notifier hook which ends up calling backup_do_cow() to copy old data out before it gets overwritten. For mode 'NONE' we create the new target image and only copy in the original data from the disk image starting from the time the call was made. This preserves the point in time data by only copying the parts that are *going to change* to the target image. This way we can reconstruct the final image by checking to see if the given block exists in the new target image first, and if it does not, you can get it from the original image. This is basically an optimization allowing you to do point-in-time snapshots with low overhead vs the 'FULL' version. Since there is no old data to copy out the loop in backup_run() for the NONE case just calls qemu_coroutine_yield() which only wakes up after an event (usually cancel in this case). The rest is handled by the before_write notifier which again calls backup_do_cow() to write out the old data so it can be preserved. Signed-off-by: Ian Main <imain@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-07-26 22:39:04 +04:00
"sync": "full",
block: add drive-backup QMP command @drive-backup Start a point-in-time copy of a block device to a new destination. The status of ongoing drive-backup operations can be checked with query-block-jobs where the BlockJobInfo.type field has the value 'backup'. The operation can be stopped before it has completed using the block-job-cancel command. @device: the name of the device which should be copied. @target: the target of the new image. If the file exists, or if it is a device, the existing file/device will be used as the new destination. If it does not exist, a new file will be created. @format: #optional the format of the new destination, default is to probe if @mode is 'existing', else the format of the source @mode: #optional whether and how QEMU should create a new image, default is 'absolute-paths'. @speed: #optional the maximum speed, in bytes per second @on-source-error: #optional the action to take on an error on the source, default 'report'. 'stop' and 'enospc' can only be used if the block device supports io-status (see BlockInfo). @on-target-error: #optional the action to take on an error on the target, default 'report' (no limitations, since this applies to a different block device than @device). Note that @on-source-error and @on-target-error only affect background I/O. If an error occurs during a guest write request, the device's rerror/werror actions will be used. Returns: nothing on success If @device is not a valid block device, DeviceNotFound Since 1.6 Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Kevin Wolf <kwolf@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-06-24 19:13:14 +04:00
"target": "backup.img" } }
<- { "return": {} }
EQMP
{
.name = "blockdev-backup",
.args_type = "sync:s,device:B,target:B,speed:i?,"
"on-source-error:s?,on-target-error:s?",
.mhandler.cmd_new = qmp_marshal_blockdev_backup,
},
SQMP
blockdev-backup
---------------
The device version of drive-backup: this command takes an existing named device
as backup target.
Arguments:
- "device": the name of the device which should be copied.
(json-string)
- "target": the name of the backup target device. (json-string)
- "sync": what parts of the disk image should be copied to the destination;
possibilities include "full" for all the disk, "top" for only the
sectors allocated in the topmost image, or "none" to only replicate
new I/O (MirrorSyncMode).
- "speed": the maximum speed, in bytes per second (json-int, optional)
- "on-source-error": the action to take on an error on the source, default
'report'. 'stop' and 'enospc' can only be used
if the block device supports io-status.
(BlockdevOnError, optional)
- "on-target-error": the action to take on an error on the target, default
'report' (no limitations, since this applies to
a different block device than device).
(BlockdevOnError, optional)
Example:
-> { "execute": "blockdev-backup", "arguments": { "device": "src-id",
"sync": "full",
"target": "tgt-id" } }
<- { "return": {} }
block: add drive-backup QMP command @drive-backup Start a point-in-time copy of a block device to a new destination. The status of ongoing drive-backup operations can be checked with query-block-jobs where the BlockJobInfo.type field has the value 'backup'. The operation can be stopped before it has completed using the block-job-cancel command. @device: the name of the device which should be copied. @target: the target of the new image. If the file exists, or if it is a device, the existing file/device will be used as the new destination. If it does not exist, a new file will be created. @format: #optional the format of the new destination, default is to probe if @mode is 'existing', else the format of the source @mode: #optional whether and how QEMU should create a new image, default is 'absolute-paths'. @speed: #optional the maximum speed, in bytes per second @on-source-error: #optional the action to take on an error on the source, default 'report'. 'stop' and 'enospc' can only be used if the block device supports io-status (see BlockInfo). @on-target-error: #optional the action to take on an error on the target, default 'report' (no limitations, since this applies to a different block device than @device). Note that @on-source-error and @on-target-error only affect background I/O. If an error occurs during a guest write request, the device's rerror/werror actions will be used. Returns: nothing on success If @device is not a valid block device, DeviceNotFound Since 1.6 Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Kevin Wolf <kwolf@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2013-06-24 19:13:14 +04:00
EQMP
{
.name = "block-job-set-speed",
.args_type = "device:B,speed:o",
.mhandler.cmd_new = qmp_marshal_block_job_set_speed,
},
{
.name = "block-job-cancel",
.args_type = "device:B,force:b?",
.mhandler.cmd_new = qmp_marshal_block_job_cancel,
},
{
.name = "block-job-pause",
.args_type = "device:B",
.mhandler.cmd_new = qmp_marshal_block_job_pause,
},
{
.name = "block-job-resume",
.args_type = "device:B",
.mhandler.cmd_new = qmp_marshal_block_job_resume,
},
{
.name = "block-job-complete",
.args_type = "device:B",
.mhandler.cmd_new = qmp_marshal_block_job_complete,
},
{
.name = "transaction",
.args_type = "actions:q",
.mhandler.cmd_new = qmp_marshal_transaction,
},
SQMP
transaction
-----------
Atomically operate on one or more block devices. Operations that are
currently supported:
- drive-backup
- blockdev-backup
- blockdev-snapshot-sync
- blockdev-snapshot-internal-sync
- abort
- block-dirty-bitmap-add
- block-dirty-bitmap-clear
Refer to the qemu/qapi-schema.json file for minimum required QEMU
versions for these operations. A list of dictionaries is accepted,
that contains the actions to be performed. If there is any failure
performing any of the operations, all operations for the group are
abandoned.
For external snapshots, the dictionary contains the device, the file to use for
the new snapshot, and the format. The default format, if not specified, is
qcow2.
Each new snapshot defaults to being created by QEMU (wiping any
contents if the file already exists), but it is also possible to reuse
an externally-created file. In the latter case, you should ensure that
the new image file has the same contents as the current one; QEMU cannot
perform any meaningful check. Typically this is achieved by using the
current image file as the backing file for the new image.
On failure, the original disks pre-snapshot attempt will be used.
For internal snapshots, the dictionary contains the device and the snapshot's
name. If an internal snapshot matching name already exists, the request will
be rejected. Only some image formats support it, for example, qcow2, rbd,
and sheepdog.
On failure, qemu will try delete the newly created internal snapshot in the
transaction. When an I/O error occurs during deletion, the user needs to fix
it later with qemu-img or other command.
Arguments:
actions array:
- "type": the operation to perform (json-string). Possible
values: "drive-backup", "blockdev-backup",
"blockdev-snapshot-sync",
"blockdev-snapshot-internal-sync",
"abort", "block-dirty-bitmap-add",
"block-dirty-bitmap-clear"
- "data": a dictionary. The contents depend on the value
of "type". When "type" is "blockdev-snapshot-sync":
- "device": device name to snapshot (json-string)
- "node-name": graph node name to snapshot (json-string)
- "snapshot-file": name of new image file (json-string)
- "snapshot-node-name": graph node name of the new snapshot (json-string)
- "format": format of new image (json-string, optional)
- "mode": whether and how QEMU should create the snapshot file
(NewImageMode, optional, default "absolute-paths")
When "type" is "blockdev-snapshot-internal-sync":
- "device": device name to snapshot (json-string)
- "name": name of the new snapshot (json-string)
Example:
-> { "execute": "transaction",
"arguments": { "actions": [
{ "type": "blockdev-snapshot-sync", "data" : { "device": "ide-hd0",
"snapshot-file": "/some/place/my-image",
"format": "qcow2" } },
{ "type": "blockdev-snapshot-sync", "data" : { "node-name": "myfile",
"snapshot-file": "/some/place/my-image2",
"snapshot-node-name": "node3432",
"mode": "existing",
"format": "qcow2" } },
{ "type": "blockdev-snapshot-sync", "data" : { "device": "ide-hd1",
"snapshot-file": "/some/place/my-image2",
"mode": "existing",
"format": "qcow2" } },
{ "type": "blockdev-snapshot-internal-sync", "data" : {
"device": "ide-hd2",
"name": "snapshot0" } } ] } }
<- { "return": {} }
EQMP
{
.name = "block-dirty-bitmap-add",
.args_type = "node:B,name:s,granularity:i?",
.mhandler.cmd_new = qmp_marshal_block_dirty_bitmap_add,
},
SQMP
block-dirty-bitmap-add
----------------------
Since 2.4
Create a dirty bitmap with a name on the device, and start tracking the writes.
Arguments:
- "node": device/node on which to create dirty bitmap (json-string)
- "name": name of the new dirty bitmap (json-string)
- "granularity": granularity to track writes with (int, optional)
Example:
-> { "execute": "block-dirty-bitmap-add", "arguments": { "node": "drive0",
"name": "bitmap0" } }
<- { "return": {} }
EQMP
{
.name = "block-dirty-bitmap-remove",
.args_type = "node:B,name:s",
.mhandler.cmd_new = qmp_marshal_block_dirty_bitmap_remove,
},
SQMP
block-dirty-bitmap-remove
-------------------------
Since 2.4
Stop write tracking and remove the dirty bitmap that was created with
block-dirty-bitmap-add.
Arguments:
- "node": device/node on which to remove dirty bitmap (json-string)
- "name": name of the dirty bitmap to remove (json-string)
Example:
-> { "execute": "block-dirty-bitmap-remove", "arguments": { "node": "drive0",
"name": "bitmap0" } }
<- { "return": {} }
EQMP
{
.name = "block-dirty-bitmap-clear",
.args_type = "node:B,name:s",
.mhandler.cmd_new = qmp_marshal_block_dirty_bitmap_clear,
},
SQMP
block-dirty-bitmap-clear
------------------------
Since 2.4
Reset the dirty bitmap associated with a node so that an incremental backup
from this point in time forward will only backup clusters modified after this
clear operation.
Arguments:
- "node": device/node on which to remove dirty bitmap (json-string)
- "name": name of the dirty bitmap to remove (json-string)
Example:
-> { "execute": "block-dirty-bitmap-clear", "arguments": { "node": "drive0",
"name": "bitmap0" } }
<- { "return": {} }
EQMP
{
.name = "blockdev-snapshot-sync",
.args_type = "device:s?,node-name:s?,snapshot-file:s,snapshot-node-name:s?,format:s?,mode:s?",
.mhandler.cmd_new = qmp_marshal_blockdev_snapshot_sync,
},
SQMP
blockdev-snapshot-sync
----------------------
Synchronous snapshot of a block device. snapshot-file specifies the
target of the new image. If the file exists, or if it is a device, the
snapshot will be created in the existing file/device. If does not
exist, a new file will be created. format specifies the format of the
snapshot image, default is qcow2.
Arguments:
- "device": device name to snapshot (json-string)
- "node-name": graph node name to snapshot (json-string)
- "snapshot-file": name of new image file (json-string)
- "snapshot-node-name": graph node name of the new snapshot (json-string)
- "mode": whether and how QEMU should create the snapshot file
(NewImageMode, optional, default "absolute-paths")
- "format": format of new image (json-string, optional)
Example:
-> { "execute": "blockdev-snapshot-sync", "arguments": { "device": "ide-hd0",
"snapshot-file":
"/some/place/my-image",
"format": "qcow2" } }
<- { "return": {} }
EQMP
{
.name = "blockdev-snapshot-internal-sync",
.args_type = "device:B,name:s",
.mhandler.cmd_new = qmp_marshal_blockdev_snapshot_internal_sync,
},
SQMP
blockdev-snapshot-internal-sync
-------------------------------
Synchronously take an internal snapshot of a block device when the format of
image used supports it. If the name is an empty string, or a snapshot with
name already exists, the operation will fail.
Arguments:
- "device": device name to snapshot (json-string)
- "name": name of the new snapshot (json-string)
Example:
-> { "execute": "blockdev-snapshot-internal-sync",
"arguments": { "device": "ide-hd0",
"name": "snapshot0" }
}
<- { "return": {} }
EQMP
{
.name = "blockdev-snapshot-delete-internal-sync",
.args_type = "device:B,id:s?,name:s?",
.mhandler.cmd_new =
qmp_marshal_blockdev_snapshot_delete_internal_sync,
},
SQMP
blockdev-snapshot-delete-internal-sync
--------------------------------------
Synchronously delete an internal snapshot of a block device when the format of
image used supports it. The snapshot is identified by name or id or both. One
of name or id is required. If the snapshot is not found, the operation will
fail.
Arguments:
- "device": device name (json-string)
- "id": ID of the snapshot (json-string, optional)
- "name": name of the snapshot (json-string, optional)
Example:
-> { "execute": "blockdev-snapshot-delete-internal-sync",
"arguments": { "device": "ide-hd0",
"name": "snapshot0" }
}
<- { "return": {
"id": "1",
"name": "snapshot0",
"vm-state-size": 0,
"date-sec": 1000012,
"date-nsec": 10,
"vm-clock-sec": 100,
"vm-clock-nsec": 20
}
}
EQMP
{
.name = "drive-mirror",
.args_type = "sync:s,device:B,target:s,speed:i?,mode:s?,format:s?,"
"node-name:s?,replaces:s?,"
"on-source-error:s?,on-target-error:s?,"
"unmap:b?,"
"granularity:i?,buf-size:i?",
.mhandler.cmd_new = qmp_marshal_drive_mirror,
},
SQMP
drive-mirror
------------
Start mirroring a block device's writes to a new destination. target
specifies the target of the new image. If the file exists, or if it is
a device, it will be used as the new destination for writes. If it does not
exist, a new file will be created. format specifies the format of the
mirror image, default is to probe if mode='existing', else the format
of the source.
Arguments:
- "device": device name to operate on (json-string)
- "target": name of new image file (json-string)
- "format": format of new image (json-string, optional)
- "node-name": the name of the new block driver state in the node graph
(json-string, optional)
- "replaces": the block driver node name to replace when finished
(json-string, optional)
- "mode": how an image file should be created into the target
file/device (NewImageMode, optional, default 'absolute-paths')
- "speed": maximum speed of the streaming job, in bytes per second
(json-int)
- "granularity": granularity of the dirty bitmap, in bytes (json-int, optional)
- "buf_size": maximum amount of data in flight from source to target, in bytes
(json-int, default 10M)
- "sync": what parts of the disk image should be copied to the destination;
possibilities include "full" for all the disk, "top" for only the sectors
allocated in the topmost image, or "none" to only replicate new I/O
(MirrorSyncMode).
- "on-source-error": the action to take on an error on the source
(BlockdevOnError, default 'report')
- "on-target-error": the action to take on an error on the target
(BlockdevOnError, default 'report')
- "unmap": whether the target sectors should be discarded where source has only
zeroes. (json-bool, optional, default true)
The default value of the granularity is the image cluster size clamped
between 4096 and 65536, if the image format defines one. If the format
does not define a cluster size, the default value of the granularity
is 65536.
Example:
-> { "execute": "drive-mirror", "arguments": { "device": "ide-hd0",
"target": "/some/place/my-image",
"sync": "full",
"format": "qcow2" } }
<- { "return": {} }
EQMP
{
.name = "change-backing-file",
.args_type = "device:s,image-node-name:s,backing-file:s",
.mhandler.cmd_new = qmp_marshal_change_backing_file,
},
SQMP
change-backing-file
-------------------
Since: 2.1
Change the backing file in the image file metadata. This does not cause
QEMU to reopen the image file to reparse the backing filename (it may,
however, perform a reopen to change permissions from r/o -> r/w -> r/o,
if needed). The new backing file string is written into the image file
metadata, and the QEMU internal strings are updated.
Arguments:
- "image-node-name": The name of the block driver state node of the
image to modify. The "device" is argument is used to
verify "image-node-name" is in the chain described by
"device".
(json-string, optional)
- "device": The name of the device.
(json-string)
- "backing-file": The string to write as the backing file. This string is
not validated, so care should be taken when specifying
the string or the image chain may not be able to be
reopened again.
(json-string)
Returns: Nothing on success
If "device" does not exist or cannot be determined, DeviceNotFound
EQMP
{
.name = "balloon",
.args_type = "value:M",
.mhandler.cmd_new = qmp_marshal_balloon,
},
SQMP
balloon
-------
Request VM to change its memory allocation (in bytes).
Arguments:
- "value": New memory allocation (json-int)
Example:
-> { "execute": "balloon", "arguments": { "value": 536870912 } }
<- { "return": {} }
EQMP
{
.name = "set_link",
.args_type = "name:s,up:b",
.mhandler.cmd_new = qmp_marshal_set_link,
},
SQMP
set_link
--------
Change the link status of a network adapter.
Arguments:
- "name": network device name (json-string)
- "up": status is up (json-bool)
Example:
-> { "execute": "set_link", "arguments": { "name": "e1000.0", "up": false } }
<- { "return": {} }
EQMP
{
.name = "getfd",
.args_type = "fdname:s",
.params = "getfd name",
.help = "receive a file descriptor via SCM rights and assign it a name",
.mhandler.cmd_new = qmp_marshal_getfd,
},
SQMP
getfd
-----
Receive a file descriptor via SCM rights and assign it a name.
Arguments:
- "fdname": file descriptor name (json-string)
Example:
-> { "execute": "getfd", "arguments": { "fdname": "fd1" } }
<- { "return": {} }
Notes:
(1) If the name specified by the "fdname" argument already exists,
the file descriptor assigned to it will be closed and replaced
by the received file descriptor.
(2) The 'closefd' command can be used to explicitly close the file
descriptor when it is no longer needed.
EQMP
{
.name = "closefd",
.args_type = "fdname:s",
.params = "closefd name",
.help = "close a file descriptor previously passed via SCM rights",
.mhandler.cmd_new = qmp_marshal_closefd,
},
SQMP
closefd
-------
Close a file descriptor previously passed via SCM rights.
Arguments:
- "fdname": file descriptor name (json-string)
Example:
-> { "execute": "closefd", "arguments": { "fdname": "fd1" } }
<- { "return": {} }
EQMP
{
.name = "add-fd",
.args_type = "fdset-id:i?,opaque:s?",
.params = "add-fd fdset-id opaque",
.help = "Add a file descriptor, that was passed via SCM rights, to an fd set",
.mhandler.cmd_new = qmp_marshal_add_fd,
},
SQMP
add-fd
-------
Add a file descriptor, that was passed via SCM rights, to an fd set.
Arguments:
- "fdset-id": The ID of the fd set to add the file descriptor to.
(json-int, optional)
- "opaque": A free-form string that can be used to describe the fd.
(json-string, optional)
Return a json-object with the following information:
- "fdset-id": The ID of the fd set that the fd was added to. (json-int)
- "fd": The file descriptor that was received via SCM rights and added to the
fd set. (json-int)
Example:
-> { "execute": "add-fd", "arguments": { "fdset-id": 1 } }
<- { "return": { "fdset-id": 1, "fd": 3 } }
Notes:
(1) The list of fd sets is shared by all monitor connections.
(2) If "fdset-id" is not specified, a new fd set will be created.
EQMP
{
.name = "remove-fd",
.args_type = "fdset-id:i,fd:i?",
.params = "remove-fd fdset-id fd",
.help = "Remove a file descriptor from an fd set",
.mhandler.cmd_new = qmp_marshal_remove_fd,
},
SQMP
remove-fd
---------
Remove a file descriptor from an fd set.
Arguments:
- "fdset-id": The ID of the fd set that the file descriptor belongs to.
(json-int)
- "fd": The file descriptor that is to be removed. (json-int, optional)
Example:
-> { "execute": "remove-fd", "arguments": { "fdset-id": 1, "fd": 3 } }
<- { "return": {} }
Notes:
(1) The list of fd sets is shared by all monitor connections.
(2) If "fd" is not specified, all file descriptors in "fdset-id" will be
removed.
EQMP
{
.name = "query-fdsets",
.args_type = "",
.help = "Return information describing all fd sets",
.mhandler.cmd_new = qmp_marshal_query_fdsets,
},
SQMP
query-fdsets
-------------
Return information describing all fd sets.
Arguments: None
Example:
-> { "execute": "query-fdsets" }
<- { "return": [
{
"fds": [
{
"fd": 30,
"opaque": "rdonly:/path/to/file"
},
{
"fd": 24,
"opaque": "rdwr:/path/to/file"
}
],
"fdset-id": 1
},
{
"fds": [
{
"fd": 28
},
{
"fd": 29
}
],
"fdset-id": 0
}
]
}
Note: The list of fd sets is shared by all monitor connections.
EQMP
{
.name = "block_passwd",
qmp: Allow to change password on named block driver states. Signed-off-by: Benoit Canet <benoit@irqsave.net> Reviewed-by: Fam Zheng <famz@redhat.com> There was two candidate ways to implement named node manipulation: 1) { 'command': 'block_passwd', 'data': {'*device': 'str', '*node-name': 'str', 'password': 'str'} } 2) { 'command': 'block_passwd', 'data': {'device': 'str', '*device-is-node': 'bool', 'password': 'str'} } Luiz proposed 1 and says 2 was an abuse of the QMP interface and proposed to rewrite the QMP block interface for 2.0. Luiz does not like in 1 the fact that 2 fields are optional but one of them must be specified leading to an abuse of the QMP semantic. Kevin argumented that 2 what a clear abuse of the device field and would not be practical when reading fast some log file because the user would read "device" and think that a device is manipulated when it's in fact a node name. Documentation of 1 make it pretty clear what to do for the user. Kevin argued that all bs are node including devices ones so 2 does not make sense. Kevin also argued that rewriting the QMP block interface would not make disapear the current one. Kevin pushed the argument that making the QAPI generator compatible with the semantic of the operation would need a rewrite that no one has done yet. A vote has been done on the list to elect the version to use and 1 won. For reference the complete thread is: "[Qemu-devel] [PATCH V4 4/7] qmp: Allow to change password on names block driver states." Signed-off-by: Benoit Canet <benoit@irqsave.net> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2014-01-24 00:31:35 +04:00
.args_type = "device:s?,node-name:s?,password:s",
.mhandler.cmd_new = qmp_marshal_block_passwd,
},
SQMP
block_passwd
------------
Set the password of encrypted block devices.
Arguments:
- "device": device name (json-string)
qmp: Allow to change password on named block driver states. Signed-off-by: Benoit Canet <benoit@irqsave.net> Reviewed-by: Fam Zheng <famz@redhat.com> There was two candidate ways to implement named node manipulation: 1) { 'command': 'block_passwd', 'data': {'*device': 'str', '*node-name': 'str', 'password': 'str'} } 2) { 'command': 'block_passwd', 'data': {'device': 'str', '*device-is-node': 'bool', 'password': 'str'} } Luiz proposed 1 and says 2 was an abuse of the QMP interface and proposed to rewrite the QMP block interface for 2.0. Luiz does not like in 1 the fact that 2 fields are optional but one of them must be specified leading to an abuse of the QMP semantic. Kevin argumented that 2 what a clear abuse of the device field and would not be practical when reading fast some log file because the user would read "device" and think that a device is manipulated when it's in fact a node name. Documentation of 1 make it pretty clear what to do for the user. Kevin argued that all bs are node including devices ones so 2 does not make sense. Kevin also argued that rewriting the QMP block interface would not make disapear the current one. Kevin pushed the argument that making the QAPI generator compatible with the semantic of the operation would need a rewrite that no one has done yet. A vote has been done on the list to elect the version to use and 1 won. For reference the complete thread is: "[Qemu-devel] [PATCH V4 4/7] qmp: Allow to change password on names block driver states." Signed-off-by: Benoit Canet <benoit@irqsave.net> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2014-01-24 00:31:35 +04:00
- "node-name": name in the block driver state graph (json-string)
- "password": password (json-string)
Example:
-> { "execute": "block_passwd", "arguments": { "device": "ide0-hd0",
"password": "12345" } }
<- { "return": {} }
EQMP
{
.name = "block_set_io_throttle",
.args_type = "device:B,bps:l,bps_rd:l,bps_wr:l,iops:l,iops_rd:l,iops_wr:l,bps_max:l?,bps_rd_max:l?,bps_wr_max:l?,iops_max:l?,iops_rd_max:l?,iops_wr_max:l?,iops_size:l?,group:s?",
.mhandler.cmd_new = qmp_marshal_block_set_io_throttle,
},
SQMP
block_set_io_throttle
------------
Change I/O throttle limits for a block drive.
Arguments:
- "device": device name (json-string)
- "bps": total throughput limit in bytes per second (json-int)
- "bps_rd": read throughput limit in bytes per second (json-int)
- "bps_wr": write throughput limit in bytes per second (json-int)
- "iops": total I/O operations per second (json-int)
- "iops_rd": read I/O operations per second (json-int)
- "iops_wr": write I/O operations per second (json-int)
- "bps_max": total max in bytes (json-int)
- "bps_rd_max": read max in bytes (json-int)
- "bps_wr_max": write max in bytes (json-int)
- "iops_max": total I/O operations max (json-int)
- "iops_rd_max": read I/O operations max (json-int)
- "iops_wr_max": write I/O operations max (json-int)
- "iops_size": I/O size in bytes when limiting (json-int)
- "group": throttle group name (json-string)
Example:
-> { "execute": "block_set_io_throttle", "arguments": { "device": "virtio0",
"bps": 1000000,
"bps_rd": 0,
"bps_wr": 0,
"iops": 0,
"iops_rd": 0,
"iops_wr": 0,
"bps_max": 8000000,
"bps_rd_max": 0,
"bps_wr_max": 0,
"iops_max": 0,
"iops_rd_max": 0,
"iops_wr_max": 0,
"iops_size": 0 } }
<- { "return": {} }
EQMP
{
.name = "set_password",
.args_type = "protocol:s,password:s,connected:s?",
.mhandler.cmd_new = qmp_marshal_set_password,
},
SQMP
set_password
------------
Set the password for vnc/spice protocols.
Arguments:
- "protocol": protocol name (json-string)
- "password": password (json-string)
- "connected": [ keep | disconnect | fail ] (json-string, optional)
Example:
-> { "execute": "set_password", "arguments": { "protocol": "vnc",
"password": "secret" } }
<- { "return": {} }
EQMP
{
.name = "expire_password",
.args_type = "protocol:s,time:s",
.mhandler.cmd_new = qmp_marshal_expire_password,
},
SQMP
expire_password
---------------
Set the password expire time for vnc/spice protocols.
Arguments:
- "protocol": protocol name (json-string)
- "time": [ now | never | +secs | secs ] (json-string)
Example:
-> { "execute": "expire_password", "arguments": { "protocol": "vnc",
"time": "+60" } }
<- { "return": {} }
EQMP
{
.name = "add_client",
.args_type = "protocol:s,fdname:s,skipauth:b?,tls:b?",
.mhandler.cmd_new = qmp_marshal_add_client,
},
SQMP
add_client
----------
Add a graphics client
Arguments:
- "protocol": protocol name (json-string)
- "fdname": file descriptor name (json-string)
- "skipauth": whether to skip authentication (json-bool, optional)
- "tls": whether to perform TLS (json-bool, optional)
Example:
-> { "execute": "add_client", "arguments": { "protocol": "vnc",
"fdname": "myclient" } }
<- { "return": {} }
EQMP
{
.name = "qmp_capabilities",
.args_type = "",
.params = "",
.help = "enable QMP capabilities",
qmp: Wean off qerror_report() The traditional QMP command handler interface int qmp_FOO(Monitor *mon, const QDict *params, QObject **ret_data); doesn't provide for returning an Error object. Instead, the handler is expected to stash it in the monitor with qerror_report(). When we rebased QMP on top of QAPI, we didn't change this interface. Instead, commit 776574d introduced "middle mode" as a temporary aid for converting existing QMP commands to QAPI one by one. More than three years later, we're still using it. Middle mode has two effects: * Instead of the native input marshallers static void qmp_marshal_input_FOO(QDict *, QObject **, Error **) it generates input marshallers conforming to the traditional QMP command handler interface. * It suppresses generation of code to register them with qmp_register_command() This permits giving them internal linkage. As long as we need qmp-commands.hx, we can't use the registry behind qmp_register_command(), so the latter has to stay for now. The former has to go to get rid of qerror_report(). Changing all QMP commands to fit the QAPI mold in one go was impractical back when we started, but by now there are just a few stragglers left: do_qmp_capabilities(), qmp_qom_set(), qmp_qom_get(), qmp_object_add(), qmp_netdev_add(), do_device_add(). Switch middle mode to generate native input marshallers, and adapt the stragglers. Simplifies both the monitor code and the stragglers. Rename do_qmp_capabilities() to qmp_capabilities(), and do_device_add() to qmp_device_add, because that's how QMP command handlers are named today. Signed-off-by: Markus Armbruster <armbru@redhat.com> Reviewed-by: Stefan Hajnoczi <stefanha@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Luiz Capitulino <lcapitulino@redhat.com>
2015-03-13 19:25:50 +03:00
.mhandler.cmd_new = qmp_capabilities,
},
SQMP
qmp_capabilities
----------------
Enable QMP capabilities.
Arguments: None.
Example:
-> { "execute": "qmp_capabilities" }
<- { "return": {} }
Note: This command must be issued before issuing any other command.
EQMP
{
.name = "human-monitor-command",
.args_type = "command-line:s,cpu-index:i?",
.mhandler.cmd_new = qmp_marshal_human_monitor_command,
},
SQMP
human-monitor-command
---------------------
Execute a Human Monitor command.
Arguments:
- command-line: the command name and its arguments, just like the
Human Monitor's shell (json-string)
- cpu-index: select the CPU number to be used by commands which access CPU
data, like 'info registers'. The Monitor selects CPU 0 if this
argument is not provided (json-int, optional)
Example:
-> { "execute": "human-monitor-command", "arguments": { "command-line": "info kvm" } }
<- { "return": "kvm support: enabled\r\n" }
Notes:
(1) The Human Monitor is NOT an stable interface, this means that command
names, arguments and responses can change or be removed at ANY time.
Applications that rely on long term stability guarantees should NOT
use this command
(2) Limitations:
o This command is stateless, this means that commands that depend
on state information (such as getfd) might not work
o Commands that prompt the user for data (eg. 'cont' when the block
device is encrypted) don't currently work
3. Query Commands
=================
HXCOMM Each query command below is inside a SQMP/EQMP section, do NOT change
HXCOMM this! We will possibly move query commands definitions inside those
HXCOMM sections, just like regular commands.
EQMP
SQMP
query-version
-------------
Show QEMU version.
Return a json-object with the following information:
- "qemu": A json-object containing three integer values:
- "major": QEMU's major version (json-int)
- "minor": QEMU's minor version (json-int)
- "micro": QEMU's micro version (json-int)
- "package": package's version (json-string)
Example:
-> { "execute": "query-version" }
<- {
"return":{
"qemu":{
"major":0,
"minor":11,
"micro":5
},
"package":""
}
}
EQMP
{
.name = "query-version",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_version,
},
SQMP
query-commands
--------------
List QMP available commands.
Each command is represented by a json-object, the returned value is a json-array
of all commands.
Each json-object contain:
- "name": command's name (json-string)
Example:
-> { "execute": "query-commands" }
<- {
"return":[
{
"name":"query-balloon"
},
{
"name":"system_powerdown"
}
]
}
Note: This example has been shortened as the real response is too long.
EQMP
{
.name = "query-commands",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_commands,
},
SQMP
query-events
--------------
List QMP available events.
Each event is represented by a json-object, the returned value is a json-array
of all events.
Each json-object contains:
- "name": event's name (json-string)
Example:
-> { "execute": "query-events" }
<- {
"return":[
{
"name":"SHUTDOWN"
},
{
"name":"RESET"
}
]
}
Note: This example has been shortened as the real response is too long.
EQMP
{
.name = "query-events",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_events,
},
qapi: New QMP command query-qmp-schema for QMP introspection qapi/introspect.json defines the introspection schema. It's designed for QMP introspection, but should do for similar uses, such as QGA. The introspection schema does not reflect all the rules and restrictions that apply to QAPI schemata. A valid QAPI schema has an introspection value conforming to the introspection schema, but the converse is not true. Introspection lowers away a number of schema details, and makes implicit things explicit: * The built-in types are declared with their JSON type. All integer types are mapped to 'int', because how many bits we use internally is an implementation detail. It could be pressed into external interface service as very approximate range information, but that's a bad idea. If we need range information, we better do it properly. * Implicit type definitions are made explicit, and given auto-generated names: - Array types, named by appending "List" to the name of their element type, like in generated C. - The enumeration types implicitly defined by simple union types, named by appending "Kind" to the name of their simple union type, like in generated C. - Types that don't occur in generated C. Their names start with ':' so they don't clash with the user's names. * All type references are by name. * The struct and union types are generalized into an object type. * Base types are flattened. * Commands take a single argument and return a single result. Dictionary argument or list result is an implicit type definition. The empty object type is used when a command takes no arguments or produces no results. The argument is always of object type, but the introspection schema doesn't reflect that. The 'gen': false directive is omitted as implementation detail. The 'success-response' directive is omitted as well for now, even though it's not an implementation detail, because it's not used by QMP. * Events carry a single data value. Implicit type definition and empty object type use, just like for commands. The value is of object type, but the introspection schema doesn't reflect that. * Types not used by commands or events are omitted. Indirect use counts as use. * Optional members have a default, which can only be null right now Instead of a mandatory "optional" flag, we have an optional default. No default means mandatory, default null means optional without default value. Non-null is available for optional with default (possible future extension). * Clients should *not* look up types by name, because type names are not ABI. Look up the command or event you're interested in, then follow the references. TODO Should we hide the type names to eliminate the temptation? New generator scripts/qapi-introspect.py computes an introspection value for its input, and generates a C variable holding it. It can generate awfully long lines. Marked TODO. A new test-qmp-input-visitor test case feeds its result for both tests/qapi-schema/qapi-schema-test.json and qapi-schema.json to a QmpInputVisitor to verify it actually conforms to the schema. New QMP command query-qmp-schema takes its return value from that variable. Its reply is some 85KiBytes for me right now. If this turns out to be too much, we have a couple of options: * We can use shorter names in the JSON. Not the QMP style. * Optionally return the sub-schema for commands and events given as arguments. Right now qmp_query_schema() sends the string literal computed by qmp-introspect.py. To compute sub-schema at run time, we'd have to duplicate parts of qapi-introspect.py in C. Unattractive. * Let clients cache the output of query-qmp-schema. It changes only on QEMU upgrades, i.e. rarely. Provide a command query-qmp-schema-hash. Clients can have a cache indexed by hash, and re-query the schema only when they don't have it cached. Even simpler: put the hash in the QMP greeting. Signed-off-by: Markus Armbruster <armbru@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com>
2015-09-16 14:06:28 +03:00
SQMP
query-qmp-schema
----------------
Return the QMP wire schema. The returned value is a json-array of
named schema entities. Entities are commands, events and various
types. See docs/qapi-code-gen.txt for information on their structure
and intended use.
EQMP
{
.name = "query-qmp-schema",
.args_type = "",
.mhandler.cmd_new = qmp_query_qmp_schema,
},
SQMP
query-chardev
-------------
Each device is represented by a json-object. The returned value is a json-array
of all devices.
Each json-object contain the following:
- "label": device's label (json-string)
- "filename": device's file (json-string)
- "frontend-open": open/closed state of the frontend device attached to this
backend (json-bool)
Example:
-> { "execute": "query-chardev" }
<- {
"return": [
{
"label": "charchannel0",
"filename": "unix:/var/lib/libvirt/qemu/seabios.rhel6.agent,server",
"frontend-open": false
},
{
"label": "charmonitor",
"filename": "unix:/var/lib/libvirt/qemu/seabios.rhel6.monitor,server",
"frontend-open": true
},
{
"label": "charserial0",
"filename": "pty:/dev/pts/2",
"frontend-open": true
}
]
}
EQMP
{
.name = "query-chardev",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_chardev,
},
SQMP
query-chardev-backends
-------------
List available character device backends.
Each backend is represented by a json-object, the returned value is a json-array
of all backends.
Each json-object contains:
- "name": backend name (json-string)
Example:
-> { "execute": "query-chardev-backends" }
<- {
"return":[
{
"name":"udp"
},
{
"name":"tcp"
},
{
"name":"unix"
},
{
"name":"spiceport"
}
]
}
EQMP
{
.name = "query-chardev-backends",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_chardev_backends,
},
SQMP
query-block
-----------
Show the block devices.
Each block device information is stored in a json-object and the returned value
is a json-array of all devices.
Each json-object contain the following:
- "device": device name (json-string)
- "type": device type (json-string)
- deprecated, retained for backward compatibility
- Possible values: "unknown"
- "removable": true if the device is removable, false otherwise (json-bool)
- "locked": true if the device is locked, false otherwise (json-bool)
- "tray_open": only present if removable, true if the device has a tray,
and it is open (json-bool)
- "inserted": only present if the device is inserted, it is a json-object
containing the following:
- "file": device file name (json-string)
- "ro": true if read-only, false otherwise (json-bool)
- "drv": driver format name (json-string)
block: delete cow block driver This patch removes support for the cow file format. Normally we do not break backwards compatibility but in this case there is no impact and it is the most logical option. Extraordinary claims require extraordinary evidence so I will show why removing the cow block driver is the right thing to do. The cow file format is the disk image format for Usermode Linux, a way of running a Linux system in userspace. The performance of UML was never great and it was hacky, but it enjoyed some popularity before hardware virtualization support became mainstream. QEMU's block/cow.c is supposed to read this image file format. Unfortunately the file format was underspecified: 1. Earlier Linux versions used the MAXPATHLEN constant for the backing filename field. The value of MAXPATHLEN can change, so Linux switched to a 4096 literal but QEMU has a 1024 literal. 2. Padding was not used on the header struct (both in the Linux kernel and in QEMU) so the struct layout varied across architectures. In particular, i386 and x86_64 were different due to int64_t alignment differences. Linux now uses __attribute__((packed)), QEMU does not. Therefore: 1. QEMU cow images do not conform to the Linux cow image file format. 2. cow images cannot be shared between different host architectures. This means QEMU cow images are useless and QEMU has not had bug reports from users actually hitting these issues. Let's get rid of this thing, it serves no purpose and no one will be affected. Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Message-id: 1410877464-20481-1-git-send-email-stefanha@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-09-16 18:24:24 +04:00
- Possible values: "blkdebug", "bochs", "cloop", "dmg",
"file", "file", "ftp", "ftps", "host_cdrom",
"host_device", "http", "https",
"nbd", "parallels", "qcow", "qcow2", "raw",
"tftp", "vdi", "vmdk", "vpc", "vvfat"
- "backing_file": backing file name (json-string, optional)
- "backing_file_depth": number of files in the backing file chain (json-int)
- "encrypted": true if encrypted, false otherwise (json-bool)
- "bps": limit total bytes per second (json-int)
- "bps_rd": limit read bytes per second (json-int)
- "bps_wr": limit write bytes per second (json-int)
- "iops": limit total I/O operations per second (json-int)
- "iops_rd": limit read operations per second (json-int)
- "iops_wr": limit write operations per second (json-int)
- "bps_max": total max in bytes (json-int)
- "bps_rd_max": read max in bytes (json-int)
- "bps_wr_max": write max in bytes (json-int)
- "iops_max": total I/O operations max (json-int)
- "iops_rd_max": read I/O operations max (json-int)
- "iops_wr_max": write I/O operations max (json-int)
- "iops_size": I/O size when limiting by iops (json-int)
- "detect_zeroes": detect and optimize zero writing (json-string)
- Possible values: "off", "on", "unmap"
block: add event when disk usage exceeds threshold Managing applications, like oVirt (http://www.ovirt.org), make extensive use of thin-provisioned disk images. To let the guest run smoothly and be not unnecessarily paused, oVirt sets a disk usage threshold (so called 'high water mark') based on the occupation of the device, and automatically extends the image once the threshold is reached or exceeded. In order to detect the crossing of the threshold, oVirt has no choice but aggressively polling the QEMU monitor using the query-blockstats command. This lead to unnecessary system load, and is made even worse under scale: deployments with hundreds of VMs are no longer rare. To fix this, this patch adds: * A new monitor command `block-set-write-threshold', to set a mark for a given block device. * A new event `BLOCK_WRITE_THRESHOLD', to report if a block device usage exceeds the threshold. * A new `write_threshold' field into the `BlockDeviceInfo' structure, to report the configured threshold. This will allow the managing application to use smarter and more efficient monitoring, greatly reducing the need of polling. [Updated qemu-iotests 067 output to add the new 'write_threshold' property. --Stefan] [Changed g_assert_false() to !g_assert() to fix the build on older glib versions. --Kevin] Signed-off-by: Francesco Romani <fromani@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Message-id: 1421068273-692-1-git-send-email-fromani@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2015-01-12 16:11:13 +03:00
- "write_threshold": write offset threshold in bytes, a event will be
emitted if crossed. Zero if disabled (json-int)
- "image": the detail of the image, it is a json-object containing
the following:
- "filename": image file name (json-string)
- "format": image format (json-string)
- "virtual-size": image capacity in bytes (json-int)
- "dirty-flag": true if image is not cleanly closed, not present
means clean (json-bool, optional)
- "actual-size": actual size on disk in bytes of the image, not
present when image does not support thin
provision (json-int, optional)
- "cluster-size": size of a cluster in bytes, not present if image
format does not support it (json-int, optional)
- "encrypted": true if the image is encrypted, not present means
false or the image format does not support
encryption (json-bool, optional)
- "backing_file": backing file name, not present means no backing
file is used or the image format does not
support backing file chain
(json-string, optional)
- "full-backing-filename": full path of the backing file, not
present if it equals backing_file or no
backing file is used
(json-string, optional)
- "backing-filename-format": the format of the backing file, not
present means unknown or no backing
file (json-string, optional)
- "snapshots": the internal snapshot info, it is an optional list
of json-object containing the following:
- "id": unique snapshot id (json-string)
- "name": snapshot name (json-string)
- "vm-state-size": size of the VM state in bytes (json-int)
- "date-sec": UTC date of the snapshot in seconds (json-int)
- "date-nsec": fractional part in nanoseconds to be used with
date-sec (json-int)
- "vm-clock-sec": VM clock relative to boot in seconds
(json-int)
- "vm-clock-nsec": fractional part in nanoseconds to be used
with vm-clock-sec (json-int)
- "backing-image": the detail of the backing image, it is an
optional json-object only present when a
backing image present for this image
- "io-status": I/O operation status, only present if the device supports it
and the VM is configured to stop on errors. It's always reset
to "ok" when the "cont" command is issued (json_string, optional)
- Possible values: "ok", "failed", "nospace"
Example:
-> { "execute": "query-block" }
<- {
"return":[
{
"io-status": "ok",
"device":"ide0-hd0",
"locked":false,
"removable":false,
"inserted":{
"ro":false,
"drv":"qcow2",
"encrypted":false,
"file":"disks/test.qcow2",
"backing_file_depth":1,
"bps":1000000,
"bps_rd":0,
"bps_wr":0,
"iops":1000000,
"iops_rd":0,
"iops_wr":0,
"bps_max": 8000000,
"bps_rd_max": 0,
"bps_wr_max": 0,
"iops_max": 0,
"iops_rd_max": 0,
"iops_wr_max": 0,
"iops_size": 0,
"detect_zeroes": "on",
block: add event when disk usage exceeds threshold Managing applications, like oVirt (http://www.ovirt.org), make extensive use of thin-provisioned disk images. To let the guest run smoothly and be not unnecessarily paused, oVirt sets a disk usage threshold (so called 'high water mark') based on the occupation of the device, and automatically extends the image once the threshold is reached or exceeded. In order to detect the crossing of the threshold, oVirt has no choice but aggressively polling the QEMU monitor using the query-blockstats command. This lead to unnecessary system load, and is made even worse under scale: deployments with hundreds of VMs are no longer rare. To fix this, this patch adds: * A new monitor command `block-set-write-threshold', to set a mark for a given block device. * A new event `BLOCK_WRITE_THRESHOLD', to report if a block device usage exceeds the threshold. * A new `write_threshold' field into the `BlockDeviceInfo' structure, to report the configured threshold. This will allow the managing application to use smarter and more efficient monitoring, greatly reducing the need of polling. [Updated qemu-iotests 067 output to add the new 'write_threshold' property. --Stefan] [Changed g_assert_false() to !g_assert() to fix the build on older glib versions. --Kevin] Signed-off-by: Francesco Romani <fromani@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Message-id: 1421068273-692-1-git-send-email-fromani@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2015-01-12 16:11:13 +03:00
"write_threshold": 0,
"image":{
"filename":"disks/test.qcow2",
"format":"qcow2",
"virtual-size":2048000,
"backing_file":"base.qcow2",
"full-backing-filename":"disks/base.qcow2",
"backing-filename-format":"qcow2",
"snapshots":[
{
"id": "1",
"name": "snapshot1",
"vm-state-size": 0,
"date-sec": 10000200,
"date-nsec": 12,
"vm-clock-sec": 206,
"vm-clock-nsec": 30
}
],
"backing-image":{
"filename":"disks/base.qcow2",
"format":"qcow2",
"virtual-size":2048000
}
}
},
"type":"unknown"
},
{
"io-status": "ok",
"device":"ide1-cd0",
"locked":false,
"removable":true,
"type":"unknown"
},
{
"device":"floppy0",
"locked":false,
"removable":true,
"type":"unknown"
},
{
"device":"sd0",
"locked":false,
"removable":true,
"type":"unknown"
}
]
}
EQMP
{
.name = "query-block",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_block,
},
SQMP
query-blockstats
----------------
Show block device statistics.
Each device statistic information is stored in a json-object and the returned
value is a json-array of all devices.
Each json-object contain the following:
- "device": device name (json-string)
- "stats": A json-object with the statistics information, it contains:
- "rd_bytes": bytes read (json-int)
- "wr_bytes": bytes written (json-int)
- "rd_operations": read operations (json-int)
- "wr_operations": write operations (json-int)
- "flush_operations": cache flush operations (json-int)
- "wr_total_time_ns": total time spend on writes in nano-seconds (json-int)
- "rd_total_time_ns": total time spend on reads in nano-seconds (json-int)
- "flush_total_time_ns": total time spend on cache flushes in nano-seconds (json-int)
- "wr_highest_offset": The offset after the greatest byte written to the
BlockDriverState since it has been opened (json-int)
- "rd_merged": number of read requests that have been merged into
another request (json-int)
- "wr_merged": number of write requests that have been merged into
another request (json-int)
- "parent": Contains recursively the statistics of the underlying
protocol (e.g. the host file for a qcow2 image). If there is
no underlying protocol, this field is omitted
(json-object, optional)
Example:
-> { "execute": "query-blockstats" }
<- {
"return":[
{
"device":"ide0-hd0",
"parent":{
"stats":{
"wr_highest_offset":3686448128,
"wr_bytes":9786368,
"wr_operations":751,
"rd_bytes":122567168,
"rd_operations":36772
"wr_total_times_ns":313253456
"rd_total_times_ns":3465673657
"flush_total_times_ns":49653
"flush_operations":61,
"rd_merged":0,
"wr_merged":0
}
},
"stats":{
"wr_highest_offset":2821110784,
"wr_bytes":9786368,
"wr_operations":692,
"rd_bytes":122739200,
"rd_operations":36604
"flush_operations":51,
"wr_total_times_ns":313253456
"rd_total_times_ns":3465673657
"flush_total_times_ns":49653,
"rd_merged":0,
"wr_merged":0
}
},
{
"device":"ide1-cd0",
"stats":{
"wr_highest_offset":0,
"wr_bytes":0,
"wr_operations":0,
"rd_bytes":0,
"rd_operations":0
"flush_operations":0,
"wr_total_times_ns":0
"rd_total_times_ns":0
"flush_total_times_ns":0,
"rd_merged":0,
"wr_merged":0
}
},
{
"device":"floppy0",
"stats":{
"wr_highest_offset":0,
"wr_bytes":0,
"wr_operations":0,
"rd_bytes":0,
"rd_operations":0
"flush_operations":0,
"wr_total_times_ns":0
"rd_total_times_ns":0
"flush_total_times_ns":0,
"rd_merged":0,
"wr_merged":0
}
},
{
"device":"sd0",
"stats":{
"wr_highest_offset":0,
"wr_bytes":0,
"wr_operations":0,
"rd_bytes":0,
"rd_operations":0
"flush_operations":0,
"wr_total_times_ns":0
"rd_total_times_ns":0
"flush_total_times_ns":0,
"rd_merged":0,
"wr_merged":0
}
}
]
}
EQMP
{
.name = "query-blockstats",
.args_type = "query-nodes:b?",
.mhandler.cmd_new = qmp_marshal_query_blockstats,
},
SQMP
query-cpus
----------
Show CPU information.
Return a json-array. Each CPU is represented by a json-object, which contains:
- "CPU": CPU index (json-int)
- "current": true if this is the current CPU, false otherwise (json-bool)
- "halted": true if the cpu is halted, false otherwise (json-bool)
- "qom_path": path to the CPU object in the QOM tree (json-str)
- Current program counter. The key's name depends on the architecture:
"pc": i386/x86_64 (json-int)
"nip": PPC (json-int)
"pc" and "npc": sparc (json-int)
"PC": mips (json-int)
- "thread_id": ID of the underlying host thread (json-int)
Example:
-> { "execute": "query-cpus" }
<- {
"return":[
{
"CPU":0,
"current":true,
"halted":false,
"qom_path":"/machine/unattached/device[0]",
"pc":3227107138,
"thread_id":3134
},
{
"CPU":1,
"current":false,
"halted":true,
"qom_path":"/machine/unattached/device[2]",
"pc":7108165,
"thread_id":3135
}
]
}
EQMP
{
.name = "query-cpus",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_cpus,
},
SQMP
query-iothreads
---------------
Returns a list of information about each iothread.
Note this list excludes the QEMU main loop thread, which is not declared
using the -object iothread command-line option. It is always the main thread
of the process.
Return a json-array. Each iothread is represented by a json-object, which contains:
- "id": name of iothread (json-str)
- "thread-id": ID of the underlying host thread (json-int)
Example:
-> { "execute": "query-iothreads" }
<- {
"return":[
{
"id":"iothread0",
"thread-id":3134
},
{
"id":"iothread1",
"thread-id":3135
}
]
}
EQMP
{
.name = "query-iothreads",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_iothreads,
},
SQMP
query-pci
---------
PCI buses and devices information.
The returned value is a json-array of all buses. Each bus is represented by
a json-object, which has a key with a json-array of all PCI devices attached
to it. Each device is represented by a json-object.
The bus json-object contains the following:
- "bus": bus number (json-int)
- "devices": a json-array of json-objects, each json-object represents a
PCI device
The PCI device json-object contains the following:
- "bus": identical to the parent's bus number (json-int)
- "slot": slot number (json-int)
- "function": function number (json-int)
- "class_info": a json-object containing:
- "desc": device class description (json-string, optional)
- "class": device class number (json-int)
- "id": a json-object containing:
- "device": device ID (json-int)
- "vendor": vendor ID (json-int)
- "irq": device's IRQ if assigned (json-int, optional)
- "qdev_id": qdev id string (json-string)
- "pci_bridge": It's a json-object, only present if this device is a
PCI bridge, contains:
- "bus": bus number (json-int)
- "secondary": secondary bus number (json-int)
- "subordinate": subordinate bus number (json-int)
- "io_range": I/O memory range information, a json-object with the
following members:
- "base": base address, in bytes (json-int)
- "limit": limit address, in bytes (json-int)
- "memory_range": memory range information, a json-object with the
following members:
- "base": base address, in bytes (json-int)
- "limit": limit address, in bytes (json-int)
- "prefetchable_range": Prefetchable memory range information, a
json-object with the following members:
- "base": base address, in bytes (json-int)
- "limit": limit address, in bytes (json-int)
- "devices": a json-array of PCI devices if there's any attached, each
each element is represented by a json-object, which contains
the same members of the 'PCI device json-object' described
above (optional)
- "regions": a json-array of json-objects, each json-object represents a
memory region of this device
The memory range json-object contains the following:
- "base": base memory address (json-int)
- "limit": limit value (json-int)
The region json-object can be an I/O region or a memory region, an I/O region
json-object contains the following:
- "type": "io" (json-string, fixed)
- "bar": BAR number (json-int)
- "address": memory address (json-int)
- "size": memory size (json-int)
A memory region json-object contains the following:
- "type": "memory" (json-string, fixed)
- "bar": BAR number (json-int)
- "address": memory address (json-int)
- "size": memory size (json-int)
- "mem_type_64": true or false (json-bool)
- "prefetch": true or false (json-bool)
Example:
-> { "execute": "query-pci" }
<- {
"return":[
{
"bus":0,
"devices":[
{
"bus":0,
"qdev_id":"",
"slot":0,
"class_info":{
"class":1536,
"desc":"Host bridge"
},
"id":{
"device":32902,
"vendor":4663
},
"function":0,
"regions":[
]
},
{
"bus":0,
"qdev_id":"",
"slot":1,
"class_info":{
"class":1537,
"desc":"ISA bridge"
},
"id":{
"device":32902,
"vendor":28672
},
"function":0,
"regions":[
]
},
{
"bus":0,
"qdev_id":"",
"slot":1,
"class_info":{
"class":257,
"desc":"IDE controller"
},
"id":{
"device":32902,
"vendor":28688
},
"function":1,
"regions":[
{
"bar":4,
"size":16,
"address":49152,
"type":"io"
}
]
},
{
"bus":0,
"qdev_id":"",
"slot":2,
"class_info":{
"class":768,
"desc":"VGA controller"
},
"id":{
"device":4115,
"vendor":184
},
"function":0,
"regions":[
{
"prefetch":true,
"mem_type_64":false,
"bar":0,
"size":33554432,
"address":4026531840,
"type":"memory"
},
{
"prefetch":false,
"mem_type_64":false,
"bar":1,
"size":4096,
"address":4060086272,
"type":"memory"
},
{
"prefetch":false,
"mem_type_64":false,
"bar":6,
"size":65536,
"address":-1,
"type":"memory"
}
]
},
{
"bus":0,
"qdev_id":"",
"irq":11,
"slot":4,
"class_info":{
"class":1280,
"desc":"RAM controller"
},
"id":{
"device":6900,
"vendor":4098
},
"function":0,
"regions":[
{
"bar":0,
"size":32,
"address":49280,
"type":"io"
}
]
}
]
}
]
}
Note: This example has been shortened as the real response is too long.
EQMP
{
.name = "query-pci",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_pci,
},
SQMP
query-kvm
---------
Show KVM information.
Return a json-object with the following information:
- "enabled": true if KVM support is enabled, false otherwise (json-bool)
- "present": true if QEMU has KVM support, false otherwise (json-bool)
Example:
-> { "execute": "query-kvm" }
<- { "return": { "enabled": true, "present": true } }
EQMP
{
.name = "query-kvm",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_kvm,
},
SQMP
query-status
------------
Return a json-object with the following information:
- "running": true if the VM is running, or false if it is paused (json-bool)
- "singlestep": true if the VM is in single step mode,
false otherwise (json-bool)
- "status": one of the following values (json-string)
"debug" - QEMU is running on a debugger
"inmigrate" - guest is paused waiting for an incoming migration
"internal-error" - An internal error that prevents further guest
execution has occurred
"io-error" - the last IOP has failed and the device is configured
to pause on I/O errors
"paused" - guest has been paused via the 'stop' command
"postmigrate" - guest is paused following a successful 'migrate'
"prelaunch" - QEMU was started with -S and guest has not started
"finish-migrate" - guest is paused to finish the migration process
"restore-vm" - guest is paused to restore VM state
"running" - guest is actively running
"save-vm" - guest is paused to save the VM state
"shutdown" - guest is shut down (and -no-shutdown is in use)
"watchdog" - the watchdog action is configured to pause and
has been triggered
Example:
-> { "execute": "query-status" }
<- { "return": { "running": true, "singlestep": false, "status": "running" } }
EQMP
{
.name = "query-status",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_status,
},
SQMP
query-mice
----------
Show VM mice information.
Each mouse is represented by a json-object, the returned value is a json-array
of all mice.
The mouse json-object contains the following:
- "name": mouse's name (json-string)
- "index": mouse's index (json-int)
- "current": true if this mouse is receiving events, false otherwise (json-bool)
- "absolute": true if the mouse generates absolute input events (json-bool)
Example:
-> { "execute": "query-mice" }
<- {
"return":[
{
"name":"QEMU Microsoft Mouse",
"index":0,
"current":false,
"absolute":false
},
{
"name":"QEMU PS/2 Mouse",
"index":1,
"current":true,
"absolute":true
}
]
}
EQMP
{
.name = "query-mice",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_mice,
},
SQMP
query-vnc
---------
Show VNC server information.
Return a json-object with server information. Connected clients are returned
as a json-array of json-objects.
The main json-object contains the following:
- "enabled": true or false (json-bool)
- "host": server's IP address (json-string)
- "family": address family (json-string)
- Possible values: "ipv4", "ipv6", "unix", "unknown"
- "service": server's port number (json-string)
- "auth": authentication method (json-string)
- Possible values: "invalid", "none", "ra2", "ra2ne", "sasl", "tight",
"tls", "ultra", "unknown", "vencrypt", "vencrypt",
"vencrypt+plain", "vencrypt+tls+none",
"vencrypt+tls+plain", "vencrypt+tls+sasl",
"vencrypt+tls+vnc", "vencrypt+x509+none",
"vencrypt+x509+plain", "vencrypt+x509+sasl",
"vencrypt+x509+vnc", "vnc"
- "clients": a json-array of all connected clients
Clients are described by a json-object, each one contain the following:
- "host": client's IP address (json-string)
- "family": address family (json-string)
- Possible values: "ipv4", "ipv6", "unix", "unknown"
- "service": client's port number (json-string)
- "x509_dname": TLS dname (json-string, optional)
- "sasl_username": SASL username (json-string, optional)
Example:
-> { "execute": "query-vnc" }
<- {
"return":{
"enabled":true,
"host":"0.0.0.0",
"service":"50402",
"auth":"vnc",
"family":"ipv4",
"clients":[
{
"host":"127.0.0.1",
"service":"50401",
"family":"ipv4"
}
]
}
}
EQMP
{
.name = "query-vnc",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_vnc,
},
{
.name = "query-vnc-servers",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_vnc_servers,
},
SQMP
query-spice
-----------
Show SPICE server information.
Return a json-object with server information. Connected clients are returned
as a json-array of json-objects.
The main json-object contains the following:
- "enabled": true or false (json-bool)
- "host": server's IP address (json-string)
- "port": server's port number (json-int, optional)
- "tls-port": server's port number (json-int, optional)
- "auth": authentication method (json-string)
- Possible values: "none", "spice"
- "channels": a json-array of all active channels clients
Channels are described by a json-object, each one contain the following:
- "host": client's IP address (json-string)
- "family": address family (json-string)
- Possible values: "ipv4", "ipv6", "unix", "unknown"
- "port": client's port number (json-string)
- "connection-id": spice connection id. All channels with the same id
belong to the same spice session (json-int)
- "channel-type": channel type. "1" is the main control channel, filter for
this one if you want track spice sessions only (json-int)
- "channel-id": channel id. Usually "0", might be different needed when
multiple channels of the same type exist, such as multiple
display channels in a multihead setup (json-int)
- "tls": whether the channel is encrypted (json-bool)
Example:
-> { "execute": "query-spice" }
<- {
"return": {
"enabled": true,
"auth": "spice",
"port": 5920,
"tls-port": 5921,
"host": "0.0.0.0",
"channels": [
{
"port": "54924",
"family": "ipv4",
"channel-type": 1,
"connection-id": 1804289383,
"host": "127.0.0.1",
"channel-id": 0,
"tls": true
},
{
"port": "36710",
"family": "ipv4",
"channel-type": 4,
"connection-id": 1804289383,
"host": "127.0.0.1",
"channel-id": 0,
"tls": false
},
[ ... more channels follow ... ]
]
}
}
EQMP
#if defined(CONFIG_SPICE)
{
.name = "query-spice",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_spice,
},
#endif
SQMP
query-name
----------
Show VM name.
Return a json-object with the following information:
- "name": VM's name (json-string, optional)
Example:
-> { "execute": "query-name" }
<- { "return": { "name": "qemu-name" } }
EQMP
{
.name = "query-name",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_name,
},
SQMP
query-uuid
----------
Show VM UUID.
Return a json-object with the following information:
- "UUID": Universally Unique Identifier (json-string)
Example:
-> { "execute": "query-uuid" }
<- { "return": { "UUID": "550e8400-e29b-41d4-a716-446655440000" } }
EQMP
{
.name = "query-uuid",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_uuid,
},
SQMP
query-command-line-options
--------------------------
Show command line option schema.
Return a json-array of command line option schema for all options (or for
the given option), returning an error if the given option doesn't exist.
Each array entry contains the following:
- "option": option name (json-string)
- "parameters": a json-array describes all parameters of the option:
- "name": parameter name (json-string)
- "type": parameter type (one of 'string', 'boolean', 'number',
or 'size')
- "help": human readable description of the parameter
(json-string, optional)
- "default": default value string for the parameter
(json-string, optional)
Example:
-> { "execute": "query-command-line-options", "arguments": { "option": "option-rom" } }
<- { "return": [
{
"parameters": [
{
"name": "romfile",
"type": "string"
},
{
"name": "bootindex",
"type": "number"
}
],
"option": "option-rom"
}
]
}
EQMP
{
.name = "query-command-line-options",
.args_type = "option:s?",
.mhandler.cmd_new = qmp_marshal_query_command_line_options,
},
SQMP
query-migrate
-------------
Migration status.
Return a json-object. If migration is active there will be another json-object
with RAM migration status and if block migration is active another one with
block migration status.
The main json-object contains the following:
- "status": migration status (json-string)
- Possible values: "setup", "active", "completed", "failed", "cancelled"
- "total-time": total amount of ms since migration started. If
migration has ended, it returns the total migration
time (json-int)
- "setup-time" amount of setup time in milliseconds _before_ the
iterations begin but _after_ the QMP command is issued.
This is designed to provide an accounting of any activities
(such as RDMA pinning) which may be expensive, but do not
actually occur during the iterative migration rounds
themselves. (json-int)
- "downtime": only present when migration has finished correctly
total amount in ms for downtime that happened (json-int)
- "expected-downtime": only present while migration is active
total amount in ms for downtime that was calculated on
the last bitmap round (json-int)
- "ram": only present if "status" is "active", it is a json-object with the
following RAM information:
- "transferred": amount transferred in bytes (json-int)
- "remaining": amount remaining to transfer in bytes (json-int)
- "total": total amount of memory in bytes (json-int)
- "duplicate": number of pages filled entirely with the same
byte (json-int)
These are sent over the wire much more efficiently.
- "skipped": number of skipped zero pages (json-int)
- "normal" : number of whole pages transferred. I.e. they
were not sent as duplicate or xbzrle pages (json-int)
- "normal-bytes" : number of bytes transferred in whole
pages. This is just normal pages times size of one page,
but this way upper levels don't need to care about page
size (json-int)
- "dirty-sync-count": times that dirty ram was synchronized (json-int)
- "disk": only present if "status" is "active" and it is a block migration,
it is a json-object with the following disk information:
- "transferred": amount transferred in bytes (json-int)
- "remaining": amount remaining to transfer in bytes json-int)
- "total": total disk size in bytes (json-int)
- "xbzrle-cache": only present if XBZRLE is active.
It is a json-object with the following XBZRLE information:
- "cache-size": XBZRLE cache size in bytes
- "bytes": number of bytes transferred for XBZRLE compressed pages
- "pages": number of XBZRLE compressed pages
- "cache-miss": number of XBRZRLE page cache misses
- "cache-miss-rate": rate of XBRZRLE page cache misses
- "overflow": number of times XBZRLE overflows. This means
that the XBZRLE encoding was bigger than just sent the
whole page, and then we sent the whole page instead (as as
normal page).
Examples:
1. Before the first migration
-> { "execute": "query-migrate" }
<- { "return": {} }
2. Migration is done and has succeeded
-> { "execute": "query-migrate" }
<- { "return": {
"status": "completed",
"ram":{
"transferred":123,
"remaining":123,
"total":246,
"total-time":12345,
"setup-time":12345,
"downtime":12345,
"duplicate":123,
"normal":123,
"normal-bytes":123456,
"dirty-sync-count":15
}
}
}
3. Migration is done and has failed
-> { "execute": "query-migrate" }
<- { "return": { "status": "failed" } }
4. Migration is being performed and is not a block migration:
-> { "execute": "query-migrate" }
<- {
"return":{
"status":"active",
"ram":{
"transferred":123,
"remaining":123,
"total":246,
"total-time":12345,
"setup-time":12345,
"expected-downtime":12345,
"duplicate":123,
"normal":123,
"normal-bytes":123456,
"dirty-sync-count":15
}
}
}
5. Migration is being performed and is a block migration:
-> { "execute": "query-migrate" }
<- {
"return":{
"status":"active",
"ram":{
"total":1057024,
"remaining":1053304,
"transferred":3720,
"total-time":12345,
"setup-time":12345,
"expected-downtime":12345,
"duplicate":123,
"normal":123,
"normal-bytes":123456,
"dirty-sync-count":15
},
"disk":{
"total":20971520,
"remaining":20880384,
"transferred":91136
}
}
}
6. Migration is being performed and XBZRLE is active:
-> { "execute": "query-migrate" }
<- {
"return":{
"status":"active",
"capabilities" : [ { "capability": "xbzrle", "state" : true } ],
"ram":{
"total":1057024,
"remaining":1053304,
"transferred":3720,
"total-time":12345,
"setup-time":12345,
"expected-downtime":12345,
"duplicate":10,
"normal":3333,
"normal-bytes":3412992,
"dirty-sync-count":15
},
"xbzrle-cache":{
"cache-size":67108864,
"bytes":20971520,
"pages":2444343,
"cache-miss":2244,
"cache-miss-rate":0.123,
"overflow":34434
}
}
}
EQMP
{
.name = "query-migrate",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_migrate,
},
SQMP
migrate-set-capabilities
------------------------
Enable/Disable migration capabilities
- "xbzrle": XBZRLE support
- "rdma-pin-all": pin all pages when using RDMA during migration
- "auto-converge": throttle down guest to help convergence of migration
- "zero-blocks": compress zero blocks during block migration
- "events": generate events for each migration state change
Arguments:
Example:
-> { "execute": "migrate-set-capabilities" , "arguments":
{ "capabilities": [ { "capability": "xbzrle", "state": true } ] } }
EQMP
{
.name = "migrate-set-capabilities",
.args_type = "capabilities:q",
.params = "capability:s,state:b",
.mhandler.cmd_new = qmp_marshal_migrate_set_capabilities,
},
SQMP
query-migrate-capabilities
--------------------------
Query current migration capabilities
- "capabilities": migration capabilities state
- "xbzrle" : XBZRLE state (json-bool)
- "rdma-pin-all" : RDMA Pin Page state (json-bool)
- "auto-converge" : Auto Converge state (json-bool)
- "zero-blocks" : Zero Blocks state (json-bool)
Arguments:
Example:
-> { "execute": "query-migrate-capabilities" }
<- { "return": [ { "state": false, "capability": "xbzrle" } ] }
EQMP
{
.name = "query-migrate-capabilities",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_migrate_capabilities,
},
SQMP
migrate-set-parameters
----------------------
Set migration parameters
- "compress-level": set compression level during migration (json-int)
- "compress-threads": set compression thread count for migration (json-int)
- "decompress-threads": set decompression thread count for migration (json-int)
Arguments:
Example:
-> { "execute": "migrate-set-parameters" , "arguments":
{ "compress-level": 1 } }
EQMP
{
.name = "migrate-set-parameters",
.args_type =
"compress-level:i?,compress-threads:i?,decompress-threads:i?",
.mhandler.cmd_new = qmp_marshal_migrate_set_parameters,
},
SQMP
query-migrate-parameters
------------------------
Query current migration parameters
- "parameters": migration parameters value
- "compress-level" : compression level value (json-int)
- "compress-threads" : compression thread count value (json-int)
- "decompress-threads" : decompression thread count value (json-int)
Arguments:
Example:
-> { "execute": "query-migrate-parameters" }
<- {
"return": {
"decompress-threads", 2,
"compress-threads", 8,
"compress-level", 1
}
}
EQMP
{
.name = "query-migrate-parameters",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_migrate_parameters,
},
SQMP
query-balloon
-------------
Show balloon information.
Make an asynchronous request for balloon info. When the request completes a
json-object will be returned containing the following data:
- "actual": current balloon value in bytes (json-int)
Example:
-> { "execute": "query-balloon" }
<- {
"return":{
"actual":1073741824,
}
}
EQMP
{
.name = "query-balloon",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_balloon,
},
{
.name = "query-block-jobs",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_block_jobs,
},
{
.name = "qom-list",
.args_type = "path:s",
.mhandler.cmd_new = qmp_marshal_qom_list,
},
{
.name = "qom-set",
.args_type = "path:s,property:s,value:q",
.mhandler.cmd_new = qmp_marshal_qom_set,
},
{
.name = "qom-get",
.args_type = "path:s,property:s",
.mhandler.cmd_new = qmp_marshal_qom_get,
},
{
.name = "nbd-server-start",
.args_type = "addr:q",
.mhandler.cmd_new = qmp_marshal_nbd_server_start,
},
{
.name = "nbd-server-add",
.args_type = "device:B,writable:b?",
.mhandler.cmd_new = qmp_marshal_nbd_server_add,
},
{
.name = "nbd-server-stop",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_nbd_server_stop,
},
{
.name = "change-vnc-password",
.args_type = "password:s",
.mhandler.cmd_new = qmp_marshal_change_vnc_password,
},
{
.name = "qom-list-types",
.args_type = "implements:s?,abstract:b?",
.mhandler.cmd_new = qmp_marshal_qom_list_types,
},
{
.name = "device-list-properties",
.args_type = "typename:s",
.mhandler.cmd_new = qmp_marshal_device_list_properties,
},
{
.name = "query-machines",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_machines,
},
{
.name = "query-cpu-definitions",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_cpu_definitions,
},
{
.name = "query-target",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_target,
},
{
.name = "query-tpm",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_tpm,
},
SQMP
query-tpm
---------
Return information about the TPM device.
Arguments: None
Example:
-> { "execute": "query-tpm" }
<- { "return":
[
{ "model": "tpm-tis",
"options":
{ "type": "passthrough",
"data":
{ "cancel-path": "/sys/class/misc/tpm0/device/cancel",
"path": "/dev/tpm0"
}
},
"id": "tpm0"
}
]
}
EQMP
{
.name = "query-tpm-models",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_tpm_models,
},
SQMP
query-tpm-models
----------------
Return a list of supported TPM models.
Arguments: None
Example:
-> { "execute": "query-tpm-models" }
<- { "return": [ "tpm-tis" ] }
EQMP
{
.name = "query-tpm-types",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_tpm_types,
},
SQMP
query-tpm-types
---------------
Return a list of supported TPM types.
Arguments: None
Example:
-> { "execute": "query-tpm-types" }
<- { "return": [ "passthrough" ] }
EQMP
{
.name = "chardev-add",
.args_type = "id:s,backend:q",
.mhandler.cmd_new = qmp_marshal_chardev_add,
},
SQMP
chardev-add
----------------
Add a chardev.
Arguments:
- "id": the chardev's ID, must be unique (json-string)
- "backend": chardev backend type + parameters
Examples:
-> { "execute" : "chardev-add",
"arguments" : { "id" : "foo",
"backend" : { "type" : "null", "data" : {} } } }
<- { "return": {} }
-> { "execute" : "chardev-add",
"arguments" : { "id" : "bar",
"backend" : { "type" : "file",
"data" : { "out" : "/tmp/bar.log" } } } }
<- { "return": {} }
-> { "execute" : "chardev-add",
"arguments" : { "id" : "baz",
"backend" : { "type" : "pty", "data" : {} } } }
<- { "return": { "pty" : "/dev/pty/42" } }
EQMP
{
.name = "chardev-remove",
.args_type = "id:s",
.mhandler.cmd_new = qmp_marshal_chardev_remove,
},
SQMP
chardev-remove
--------------
Remove a chardev.
Arguments:
- "id": the chardev's ID, must exist and not be in use (json-string)
Example:
-> { "execute": "chardev-remove", "arguments": { "id" : "foo" } }
<- { "return": {} }
net: add support of mac-programming over macvtap in QEMU side Currently macvtap based macvlan device is working in promiscuous mode, we want to implement mac-programming over macvtap through Libvirt for better performance. Design: QEMU notifies Libvirt when rx-filter config is changed in guest, then Libvirt query the rx-filter information by a monitor command, and sync the change to macvtap device. Related rx-filter config of the nic contains main mac, rx-mode items and vlan table. This patch adds a QMP event to notify management of rx-filter change, and adds a monitor command for management to query rx-filter information. Test: If we repeatedly add/remove vlan, and change macaddr of vlan interfaces in guest by a loop script. Result: The events will flood the QMP client(management), management takes too much resource to process the events. Event_throttle API (set rate to 1 ms) can avoid the events to flood QMP client, but it could cause an unexpected delay (~1ms), guests guests normally expect rx-filter updates immediately. So we use a flag for each nic to avoid events flooding, the event is emitted once until the query command is executed. The flag implementation could not introduce unexpected delay. There maybe exist an uncontrollable delay if we let Libvirt do the real change, guests normally expect rx-filter updates immediately. But it's another separate issue, we can investigate it when the work in Libvirt side is done. Michael S. Tsirkin: tweaked to enable events on start Michael S. Tsirkin: fixed not to crash when no id Michael S. Tsirkin: fold in patch: "additional fixes for mac-programming feature" Amos Kong: always notify QMP client if mactable is changed Amos Kong: return NULL list if no net client supports rx-filter query Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
2013-06-14 11:45:52 +04:00
EQMP
{
.name = "query-rx-filter",
.args_type = "name:s?",
.mhandler.cmd_new = qmp_marshal_query_rx_filter,
net: add support of mac-programming over macvtap in QEMU side Currently macvtap based macvlan device is working in promiscuous mode, we want to implement mac-programming over macvtap through Libvirt for better performance. Design: QEMU notifies Libvirt when rx-filter config is changed in guest, then Libvirt query the rx-filter information by a monitor command, and sync the change to macvtap device. Related rx-filter config of the nic contains main mac, rx-mode items and vlan table. This patch adds a QMP event to notify management of rx-filter change, and adds a monitor command for management to query rx-filter information. Test: If we repeatedly add/remove vlan, and change macaddr of vlan interfaces in guest by a loop script. Result: The events will flood the QMP client(management), management takes too much resource to process the events. Event_throttle API (set rate to 1 ms) can avoid the events to flood QMP client, but it could cause an unexpected delay (~1ms), guests guests normally expect rx-filter updates immediately. So we use a flag for each nic to avoid events flooding, the event is emitted once until the query command is executed. The flag implementation could not introduce unexpected delay. There maybe exist an uncontrollable delay if we let Libvirt do the real change, guests normally expect rx-filter updates immediately. But it's another separate issue, we can investigate it when the work in Libvirt side is done. Michael S. Tsirkin: tweaked to enable events on start Michael S. Tsirkin: fixed not to crash when no id Michael S. Tsirkin: fold in patch: "additional fixes for mac-programming feature" Amos Kong: always notify QMP client if mactable is changed Amos Kong: return NULL list if no net client supports rx-filter query Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
2013-06-14 11:45:52 +04:00
},
SQMP
query-rx-filter
---------------
Show rx-filter information.
Returns a json-array of rx-filter information for all NICs (or for the
given NIC), returning an error if the given NIC doesn't exist, or
given NIC doesn't support rx-filter querying, or given net client
isn't a NIC.
The query will clear the event notification flag of each NIC, then qemu
will start to emit event to QMP monitor.
Each array entry contains the following:
- "name": net client name (json-string)
- "promiscuous": promiscuous mode is enabled (json-bool)
- "multicast": multicast receive state (one of 'normal', 'none', 'all')
- "unicast": unicast receive state (one of 'normal', 'none', 'all')
- "vlan": vlan receive state (one of 'normal', 'none', 'all') (Since 2.0)
net: add support of mac-programming over macvtap in QEMU side Currently macvtap based macvlan device is working in promiscuous mode, we want to implement mac-programming over macvtap through Libvirt for better performance. Design: QEMU notifies Libvirt when rx-filter config is changed in guest, then Libvirt query the rx-filter information by a monitor command, and sync the change to macvtap device. Related rx-filter config of the nic contains main mac, rx-mode items and vlan table. This patch adds a QMP event to notify management of rx-filter change, and adds a monitor command for management to query rx-filter information. Test: If we repeatedly add/remove vlan, and change macaddr of vlan interfaces in guest by a loop script. Result: The events will flood the QMP client(management), management takes too much resource to process the events. Event_throttle API (set rate to 1 ms) can avoid the events to flood QMP client, but it could cause an unexpected delay (~1ms), guests guests normally expect rx-filter updates immediately. So we use a flag for each nic to avoid events flooding, the event is emitted once until the query command is executed. The flag implementation could not introduce unexpected delay. There maybe exist an uncontrollable delay if we let Libvirt do the real change, guests normally expect rx-filter updates immediately. But it's another separate issue, we can investigate it when the work in Libvirt side is done. Michael S. Tsirkin: tweaked to enable events on start Michael S. Tsirkin: fixed not to crash when no id Michael S. Tsirkin: fold in patch: "additional fixes for mac-programming feature" Amos Kong: always notify QMP client if mactable is changed Amos Kong: return NULL list if no net client supports rx-filter query Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
2013-06-14 11:45:52 +04:00
- "broadcast-allowed": allow to receive broadcast (json-bool)
- "multicast-overflow": multicast table is overflowed (json-bool)
- "unicast-overflow": unicast table is overflowed (json-bool)
- "main-mac": main macaddr string (json-string)
- "vlan-table": a json-array of active vlan id
- "unicast-table": a json-array of unicast macaddr string
- "multicast-table": a json-array of multicast macaddr string
Example:
-> { "execute": "query-rx-filter", "arguments": { "name": "vnet0" } }
<- { "return": [
{
"promiscuous": true,
"name": "vnet0",
"main-mac": "52:54:00:12:34:56",
"unicast": "normal",
"vlan": "normal",
net: add support of mac-programming over macvtap in QEMU side Currently macvtap based macvlan device is working in promiscuous mode, we want to implement mac-programming over macvtap through Libvirt for better performance. Design: QEMU notifies Libvirt when rx-filter config is changed in guest, then Libvirt query the rx-filter information by a monitor command, and sync the change to macvtap device. Related rx-filter config of the nic contains main mac, rx-mode items and vlan table. This patch adds a QMP event to notify management of rx-filter change, and adds a monitor command for management to query rx-filter information. Test: If we repeatedly add/remove vlan, and change macaddr of vlan interfaces in guest by a loop script. Result: The events will flood the QMP client(management), management takes too much resource to process the events. Event_throttle API (set rate to 1 ms) can avoid the events to flood QMP client, but it could cause an unexpected delay (~1ms), guests guests normally expect rx-filter updates immediately. So we use a flag for each nic to avoid events flooding, the event is emitted once until the query command is executed. The flag implementation could not introduce unexpected delay. There maybe exist an uncontrollable delay if we let Libvirt do the real change, guests normally expect rx-filter updates immediately. But it's another separate issue, we can investigate it when the work in Libvirt side is done. Michael S. Tsirkin: tweaked to enable events on start Michael S. Tsirkin: fixed not to crash when no id Michael S. Tsirkin: fold in patch: "additional fixes for mac-programming feature" Amos Kong: always notify QMP client if mactable is changed Amos Kong: return NULL list if no net client supports rx-filter query Reviewed-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
2013-06-14 11:45:52 +04:00
"vlan-table": [
4,
0
],
"unicast-table": [
],
"multicast": "normal",
"multicast-overflow": false,
"unicast-overflow": false,
"multicast-table": [
"01:00:5e:00:00:01",
"33:33:00:00:00:01",
"33:33:ff:12:34:56"
],
"broadcast-allowed": false
}
]
}
EQMP
{
.name = "blockdev-add",
.args_type = "options:q",
.mhandler.cmd_new = qmp_marshal_blockdev_add,
},
SQMP
blockdev-add
------------
Add a block device.
This command is still a work in progress. It doesn't support all
block drivers, it lacks a matching blockdev-del, and more. Stay away
from it unless you want to help with its development.
Arguments:
- "options": block driver options
Example (1):
-> { "execute": "blockdev-add",
"arguments": { "options" : { "driver": "qcow2",
"file": { "driver": "file",
"filename": "test.qcow2" } } } }
<- { "return": {} }
Example (2):
-> { "execute": "blockdev-add",
"arguments": {
"options": {
"driver": "qcow2",
"id": "my_disk",
"discard": "unmap",
"cache": {
"direct": true,
"writeback": true
},
"file": {
"driver": "file",
"filename": "/tmp/test.qcow2"
},
"backing": {
"driver": "raw",
"file": {
"driver": "file",
"filename": "/dev/fdset/4"
}
}
}
}
}
<- { "return": {} }
EQMP
{
.name = "query-named-block-nodes",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_named_block_nodes,
},
SQMP
@query-named-block-nodes
------------------------
Return a list of BlockDeviceInfo for all the named block driver nodes
Example:
-> { "execute": "query-named-block-nodes" }
<- { "return": [ { "ro":false,
"drv":"qcow2",
"encrypted":false,
"file":"disks/test.qcow2",
"node-name": "my-node",
"backing_file_depth":1,
"bps":1000000,
"bps_rd":0,
"bps_wr":0,
"iops":1000000,
"iops_rd":0,
"iops_wr":0,
"bps_max": 8000000,
"bps_rd_max": 0,
"bps_wr_max": 0,
"iops_max": 0,
"iops_rd_max": 0,
"iops_wr_max": 0,
"iops_size": 0,
block: add event when disk usage exceeds threshold Managing applications, like oVirt (http://www.ovirt.org), make extensive use of thin-provisioned disk images. To let the guest run smoothly and be not unnecessarily paused, oVirt sets a disk usage threshold (so called 'high water mark') based on the occupation of the device, and automatically extends the image once the threshold is reached or exceeded. In order to detect the crossing of the threshold, oVirt has no choice but aggressively polling the QEMU monitor using the query-blockstats command. This lead to unnecessary system load, and is made even worse under scale: deployments with hundreds of VMs are no longer rare. To fix this, this patch adds: * A new monitor command `block-set-write-threshold', to set a mark for a given block device. * A new event `BLOCK_WRITE_THRESHOLD', to report if a block device usage exceeds the threshold. * A new `write_threshold' field into the `BlockDeviceInfo' structure, to report the configured threshold. This will allow the managing application to use smarter and more efficient monitoring, greatly reducing the need of polling. [Updated qemu-iotests 067 output to add the new 'write_threshold' property. --Stefan] [Changed g_assert_false() to !g_assert() to fix the build on older glib versions. --Kevin] Signed-off-by: Francesco Romani <fromani@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Message-id: 1421068273-692-1-git-send-email-fromani@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2015-01-12 16:11:13 +03:00
"write_threshold": 0,
"image":{
"filename":"disks/test.qcow2",
"format":"qcow2",
"virtual-size":2048000,
"backing_file":"base.qcow2",
"full-backing-filename":"disks/base.qcow2",
"backing-filename-format":"qcow2",
"snapshots":[
{
"id": "1",
"name": "snapshot1",
"vm-state-size": 0,
"date-sec": 10000200,
"date-nsec": 12,
"vm-clock-sec": 206,
"vm-clock-nsec": 30
}
],
"backing-image":{
"filename":"disks/base.qcow2",
"format":"qcow2",
"virtual-size":2048000
}
} } ] }
EQMP
{
.name = "query-memdev",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_memdev,
},
SQMP
query-memdev
------------
Show memory devices information.
Example (1):
-> { "execute": "query-memdev" }
<- { "return": [
{
"size": 536870912,
"merge": false,
"dump": true,
"prealloc": false,
"host-nodes": [0, 1],
"policy": "bind"
},
{
"size": 536870912,
"merge": false,
"dump": true,
"prealloc": true,
"host-nodes": [2, 3],
"policy": "preferred"
}
]
}
EQMP
{
.name = "query-memory-devices",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_memory_devices,
},
SQMP
@query-memory-devices
--------------------
Return a list of memory devices.
Example:
-> { "execute": "query-memory-devices" }
<- { "return": [ { "data":
{ "addr": 5368709120,
"hotpluggable": true,
"hotplugged": true,
"id": "d1",
"memdev": "/objects/memX",
"node": 0,
"size": 1073741824,
"slot": 0},
"type": "dimm"
} ] }
EQMP
{
.name = "query-acpi-ospm-status",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_query_acpi_ospm_status,
},
SQMP
@query-acpi-ospm-status
--------------------
Return list of ACPIOSTInfo for devices that support status reporting
via ACPI _OST method.
Example:
-> { "execute": "query-acpi-ospm-status" }
<- { "return": [ { "device": "d1", "slot": "0", "slot-type": "DIMM", "source": 1, "status": 0},
{ "slot": "1", "slot-type": "DIMM", "source": 0, "status": 0},
{ "slot": "2", "slot-type": "DIMM", "source": 0, "status": 0},
{ "slot": "3", "slot-type": "DIMM", "source": 0, "status": 0}
]}
EQMP
#if defined TARGET_I386
{
.name = "rtc-reset-reinjection",
.args_type = "",
.mhandler.cmd_new = qmp_marshal_rtc_reset_reinjection,
},
#endif
SQMP
rtc-reset-reinjection
---------------------
Reset the RTC interrupt reinjection backlog.
Arguments: None.
Example:
-> { "execute": "rtc-reset-reinjection" }
<- { "return": {} }
EQMP
{
.name = "trace-event-get-state",
.args_type = "name:s",
.mhandler.cmd_new = qmp_marshal_trace_event_get_state,
},
SQMP
trace-event-get-state
---------------------
Query the state of events.
Example:
-> { "execute": "trace-event-get-state", "arguments": { "name": "qemu_memalign" } }
<- { "return": [ { "name": "qemu_memalign", "state": "disabled" } ] }
EQMP
{
.name = "trace-event-set-state",
.args_type = "name:s,enable:b,ignore-unavailable:b?",
.mhandler.cmd_new = qmp_marshal_trace_event_set_state,
},
SQMP
trace-event-set-state
---------------------
Set the state of events.
Example:
-> { "execute": "trace-event-set-state", "arguments": { "name": "qemu_memalign", "enable": "true" } }
<- { "return": {} }
EQMP
{
.name = "x-input-send-event",
QMP/input-send-event: make console parameter optional The 'QemuConsole' is the input source for handler, we share some input handlers to process the input events from different QemuConsole. Normally we only have one set of keyboard, mouse, usbtablet, etc. The devices have different mask, it's fine to just checking mask to insure that the handler has the ability to process the event. I saw we try to bind console to handler in usb/dev-hid.c, but display always isn't available at that time. If we have multiseat setup (as Gerd said), we only have 'problem' in this case. Actually event from different devices have the same effect for system, it's fine to always use the first available handler without caring about the console. For send-key command, we just pass a NULL for console parameter in calling qemu_input_event_send_key(NULL, ..), but 'input-send-event' needs to care more devices. Conclusion: Generally assigning the special console is meanless, and we can't directly remove the QMP parameter for compatibility. So we can make the parameter optional. The parameter might be useful for some special condition: we have multiple devices without binding console and they all have the ability(mask) to process events, and we don't want to use the first one. Cc: Gerd Hoffmann <kraxel@redhat.com> Cc: Markus Armbruster <armbru@redhat.com> Cc: Marcelo Tosatti <mtosatti@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Signed-off-by: Gerd Hoffmann <kraxel@redhat.com>
2014-11-07 07:41:25 +03:00
.args_type = "console:i?,events:q",
.mhandler.cmd_new = qmp_marshal_x_input_send_event,
},
SQMP
@x-input-send-event
-----------------
Send input event to guest.
Arguments:
QMP/input-send-event: make console parameter optional The 'QemuConsole' is the input source for handler, we share some input handlers to process the input events from different QemuConsole. Normally we only have one set of keyboard, mouse, usbtablet, etc. The devices have different mask, it's fine to just checking mask to insure that the handler has the ability to process the event. I saw we try to bind console to handler in usb/dev-hid.c, but display always isn't available at that time. If we have multiseat setup (as Gerd said), we only have 'problem' in this case. Actually event from different devices have the same effect for system, it's fine to always use the first available handler without caring about the console. For send-key command, we just pass a NULL for console parameter in calling qemu_input_event_send_key(NULL, ..), but 'input-send-event' needs to care more devices. Conclusion: Generally assigning the special console is meanless, and we can't directly remove the QMP parameter for compatibility. So we can make the parameter optional. The parameter might be useful for some special condition: we have multiple devices without binding console and they all have the ability(mask) to process events, and we don't want to use the first one. Cc: Gerd Hoffmann <kraxel@redhat.com> Cc: Markus Armbruster <armbru@redhat.com> Cc: Marcelo Tosatti <mtosatti@redhat.com> Signed-off-by: Amos Kong <akong@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Signed-off-by: Gerd Hoffmann <kraxel@redhat.com>
2014-11-07 07:41:25 +03:00
- "console": console index. (json-int, optional)
- "events": list of input events.
The consoles are visible in the qom tree, under
/backend/console[$index]. They have a device link and head property, so
it is possible to map which console belongs to which device and display.
Note: this command is experimental, and not a stable API.
Example (1):
Press left mouse button.
-> { "execute": "x-input-send-event",
"arguments": { "console": 0,
"events": [ { "type": "btn",
"data" : { "down": true, "button": "Left" } } ] } }
<- { "return": {} }
-> { "execute": "x-input-send-event",
"arguments": { "console": 0,
"events": [ { "type": "btn",
"data" : { "down": false, "button": "Left" } } ] } }
<- { "return": {} }
Example (2):
Press ctrl-alt-del.
-> { "execute": "x-input-send-event",
"arguments": { "console": 0, "events": [
{ "type": "key", "data" : { "down": true,
"key": {"type": "qcode", "data": "ctrl" } } },
{ "type": "key", "data" : { "down": true,
"key": {"type": "qcode", "data": "alt" } } },
{ "type": "key", "data" : { "down": true,
"key": {"type": "qcode", "data": "delete" } } } ] } }
<- { "return": {} }
Example (3):
Move mouse pointer to absolute coordinates (20000, 400).
-> { "execute": "x-input-send-event" ,
"arguments": { "console": 0, "events": [
{ "type": "abs", "data" : { "axis": "X", "value" : 20000 } },
{ "type": "abs", "data" : { "axis": "Y", "value" : 400 } } ] } }
<- { "return": {} }
block: add event when disk usage exceeds threshold Managing applications, like oVirt (http://www.ovirt.org), make extensive use of thin-provisioned disk images. To let the guest run smoothly and be not unnecessarily paused, oVirt sets a disk usage threshold (so called 'high water mark') based on the occupation of the device, and automatically extends the image once the threshold is reached or exceeded. In order to detect the crossing of the threshold, oVirt has no choice but aggressively polling the QEMU monitor using the query-blockstats command. This lead to unnecessary system load, and is made even worse under scale: deployments with hundreds of VMs are no longer rare. To fix this, this patch adds: * A new monitor command `block-set-write-threshold', to set a mark for a given block device. * A new event `BLOCK_WRITE_THRESHOLD', to report if a block device usage exceeds the threshold. * A new `write_threshold' field into the `BlockDeviceInfo' structure, to report the configured threshold. This will allow the managing application to use smarter and more efficient monitoring, greatly reducing the need of polling. [Updated qemu-iotests 067 output to add the new 'write_threshold' property. --Stefan] [Changed g_assert_false() to !g_assert() to fix the build on older glib versions. --Kevin] Signed-off-by: Francesco Romani <fromani@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Message-id: 1421068273-692-1-git-send-email-fromani@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2015-01-12 16:11:13 +03:00
EQMP
{
.name = "block-set-write-threshold",
.args_type = "node-name:s,write-threshold:l",
.mhandler.cmd_new = qmp_marshal_block_set_write_threshold,
block: add event when disk usage exceeds threshold Managing applications, like oVirt (http://www.ovirt.org), make extensive use of thin-provisioned disk images. To let the guest run smoothly and be not unnecessarily paused, oVirt sets a disk usage threshold (so called 'high water mark') based on the occupation of the device, and automatically extends the image once the threshold is reached or exceeded. In order to detect the crossing of the threshold, oVirt has no choice but aggressively polling the QEMU monitor using the query-blockstats command. This lead to unnecessary system load, and is made even worse under scale: deployments with hundreds of VMs are no longer rare. To fix this, this patch adds: * A new monitor command `block-set-write-threshold', to set a mark for a given block device. * A new event `BLOCK_WRITE_THRESHOLD', to report if a block device usage exceeds the threshold. * A new `write_threshold' field into the `BlockDeviceInfo' structure, to report the configured threshold. This will allow the managing application to use smarter and more efficient monitoring, greatly reducing the need of polling. [Updated qemu-iotests 067 output to add the new 'write_threshold' property. --Stefan] [Changed g_assert_false() to !g_assert() to fix the build on older glib versions. --Kevin] Signed-off-by: Francesco Romani <fromani@redhat.com> Reviewed-by: Eric Blake <eblake@redhat.com> Message-id: 1421068273-692-1-git-send-email-fromani@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com> Signed-off-by: Kevin Wolf <kwolf@redhat.com>
2015-01-12 16:11:13 +03:00
},
SQMP
block-set-write-threshold
------------
Change the write threshold for a block drive. The threshold is an offset,
thus must be non-negative. Default is no write threshold.
Setting the threshold to zero disables it.
Arguments:
- "node-name": the node name in the block driver state graph (json-string)
- "write-threshold": the write threshold in bytes (json-int)
Example:
-> { "execute": "block-set-write-threshold",
"arguments": { "node-name": "mydev",
"write-threshold": 17179869184 } }
<- { "return": {} }
EQMP
qmp/hmp: add rocker device support Add QMP/HMP support for rocker devices. This is mostly for debugging purposes to see inside the device's tables and port configurations. Some examples: (qemu) info rocker sw1 name: sw1 id: 0x0000013512005452 ports: 4 (qemu) info rocker-ports sw1 ena/ speed/ auto port link duplex neg? sw1.1 up 10G FD No sw1.2 up 10G FD No sw1.3 !ena 10G FD No sw1.4 !ena 10G FD No (qemu) info rocker-of-dpa-flows sw1 prio tbl hits key(mask) --> actions 2 60 pport 1 vlan 1 LLDP src 00:02:00:00:02:00 dst 01:80:c2:00:00:0e 2 60 pport 1 vlan 1 ARP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:00:02 proto 58 3 50 vlan 2 dst 33:33:ff:00:00:02 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:03:00 proto 58 3 50 1 vlan 2 dst 33:33:ff:00:03:00 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 ARP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 3 50 2 vlan 2 dst 00:02:00:00:02:00 --> write group 0x02000001 goto tbl 60 2 60 1 pport 2 vlan 2 IP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 proto 1 3 50 2 vlan 1 dst 00:02:00:00:03:00 --> write group 0x01000002 goto tbl 60 2 60 1 pport 1 vlan 1 IP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 proto 1 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:00:01 proto 58 3 50 vlan 1 dst 33:33:ff:00:00:01 --> write group 0x31000000 goto tbl 60 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:02:00 proto 58 3 50 1 vlan 1 dst 33:33:ff:00:02:00 --> write group 0x31000000 goto tbl 60 1 60 173 pport 2 vlan 2 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x02000000 1 60 6 pport 2 vlan 2 IPv6 src <any> dst <any> --> write group 0x02000000 1 60 174 pport 1 vlan 1 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x01000000 1 60 174 pport 2 vlan 2 IP src <any> dst <any> --> write group 0x02000000 1 60 6 pport 1 vlan 1 IPv6 src <any> dst <any> --> write group 0x01000000 1 60 181 pport 2 vlan 2 ARP src <any> dst <any> --> write group 0x02000000 1 10 715 pport 2 --> apply new vlan 2 goto tbl 20 1 60 177 pport 1 vlan 1 ARP src <any> dst <any> --> write group 0x01000000 1 60 174 pport 1 vlan 1 IP src <any> dst <any> --> write group 0x01000000 1 10 717 pport 1 --> apply new vlan 1 goto tbl 20 1 0 1432 pport 0(0xffff) --> goto tbl 10 (qemu) info rocker-of-dpa-groups sw1 id (decode) --> buckets 0x32000001 (type L2 multicast vlan 2 index 1) --> groups [0x02000001,0x02000000] 0x02000001 (type L2 interface vlan 2 pport 1) --> pop vlan out pport 1 0x01000002 (type L2 interface vlan 1 pport 2) --> pop vlan out pport 2 0x02000000 (type L2 interface vlan 2 pport 0) --> pop vlan out pport 0 0x01000000 (type L2 interface vlan 1 pport 0) --> pop vlan out pport 0 0x31000000 (type L2 multicast vlan 1 index 0) --> groups [0x01000002,0x01000000] [Added "query-" prefixes to rocker.json commands as suggested by Eric Blake <eblake@redhat.com>. --Stefan] Signed-off-by: Scott Feldman <sfeldma@gmail.com> Signed-off-by: Jiri Pirko <jiri@resnulli.us> Message-id: 1433985681-56138-5-git-send-email-sfeldma@gmail.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2015-06-11 04:21:21 +03:00
{
.name = "query-rocker",
.args_type = "name:s",
.mhandler.cmd_new = qmp_marshal_query_rocker,
qmp/hmp: add rocker device support Add QMP/HMP support for rocker devices. This is mostly for debugging purposes to see inside the device's tables and port configurations. Some examples: (qemu) info rocker sw1 name: sw1 id: 0x0000013512005452 ports: 4 (qemu) info rocker-ports sw1 ena/ speed/ auto port link duplex neg? sw1.1 up 10G FD No sw1.2 up 10G FD No sw1.3 !ena 10G FD No sw1.4 !ena 10G FD No (qemu) info rocker-of-dpa-flows sw1 prio tbl hits key(mask) --> actions 2 60 pport 1 vlan 1 LLDP src 00:02:00:00:02:00 dst 01:80:c2:00:00:0e 2 60 pport 1 vlan 1 ARP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:00:02 proto 58 3 50 vlan 2 dst 33:33:ff:00:00:02 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:03:00 proto 58 3 50 1 vlan 2 dst 33:33:ff:00:03:00 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 ARP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 3 50 2 vlan 2 dst 00:02:00:00:02:00 --> write group 0x02000001 goto tbl 60 2 60 1 pport 2 vlan 2 IP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 proto 1 3 50 2 vlan 1 dst 00:02:00:00:03:00 --> write group 0x01000002 goto tbl 60 2 60 1 pport 1 vlan 1 IP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 proto 1 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:00:01 proto 58 3 50 vlan 1 dst 33:33:ff:00:00:01 --> write group 0x31000000 goto tbl 60 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:02:00 proto 58 3 50 1 vlan 1 dst 33:33:ff:00:02:00 --> write group 0x31000000 goto tbl 60 1 60 173 pport 2 vlan 2 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x02000000 1 60 6 pport 2 vlan 2 IPv6 src <any> dst <any> --> write group 0x02000000 1 60 174 pport 1 vlan 1 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x01000000 1 60 174 pport 2 vlan 2 IP src <any> dst <any> --> write group 0x02000000 1 60 6 pport 1 vlan 1 IPv6 src <any> dst <any> --> write group 0x01000000 1 60 181 pport 2 vlan 2 ARP src <any> dst <any> --> write group 0x02000000 1 10 715 pport 2 --> apply new vlan 2 goto tbl 20 1 60 177 pport 1 vlan 1 ARP src <any> dst <any> --> write group 0x01000000 1 60 174 pport 1 vlan 1 IP src <any> dst <any> --> write group 0x01000000 1 10 717 pport 1 --> apply new vlan 1 goto tbl 20 1 0 1432 pport 0(0xffff) --> goto tbl 10 (qemu) info rocker-of-dpa-groups sw1 id (decode) --> buckets 0x32000001 (type L2 multicast vlan 2 index 1) --> groups [0x02000001,0x02000000] 0x02000001 (type L2 interface vlan 2 pport 1) --> pop vlan out pport 1 0x01000002 (type L2 interface vlan 1 pport 2) --> pop vlan out pport 2 0x02000000 (type L2 interface vlan 2 pport 0) --> pop vlan out pport 0 0x01000000 (type L2 interface vlan 1 pport 0) --> pop vlan out pport 0 0x31000000 (type L2 multicast vlan 1 index 0) --> groups [0x01000002,0x01000000] [Added "query-" prefixes to rocker.json commands as suggested by Eric Blake <eblake@redhat.com>. --Stefan] Signed-off-by: Scott Feldman <sfeldma@gmail.com> Signed-off-by: Jiri Pirko <jiri@resnulli.us> Message-id: 1433985681-56138-5-git-send-email-sfeldma@gmail.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2015-06-11 04:21:21 +03:00
},
SQMP
Show rocker switch
------------------
Arguments:
- "name": switch name
Example:
-> { "execute": "query-rocker", "arguments": { "name": "sw1" } }
<- { "return": {"name": "sw1", "ports": 2, "id": 1327446905938}}
EQMP
{
.name = "query-rocker-ports",
.args_type = "name:s",
.mhandler.cmd_new = qmp_marshal_query_rocker_ports,
qmp/hmp: add rocker device support Add QMP/HMP support for rocker devices. This is mostly for debugging purposes to see inside the device's tables and port configurations. Some examples: (qemu) info rocker sw1 name: sw1 id: 0x0000013512005452 ports: 4 (qemu) info rocker-ports sw1 ena/ speed/ auto port link duplex neg? sw1.1 up 10G FD No sw1.2 up 10G FD No sw1.3 !ena 10G FD No sw1.4 !ena 10G FD No (qemu) info rocker-of-dpa-flows sw1 prio tbl hits key(mask) --> actions 2 60 pport 1 vlan 1 LLDP src 00:02:00:00:02:00 dst 01:80:c2:00:00:0e 2 60 pport 1 vlan 1 ARP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:00:02 proto 58 3 50 vlan 2 dst 33:33:ff:00:00:02 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:03:00 proto 58 3 50 1 vlan 2 dst 33:33:ff:00:03:00 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 ARP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 3 50 2 vlan 2 dst 00:02:00:00:02:00 --> write group 0x02000001 goto tbl 60 2 60 1 pport 2 vlan 2 IP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 proto 1 3 50 2 vlan 1 dst 00:02:00:00:03:00 --> write group 0x01000002 goto tbl 60 2 60 1 pport 1 vlan 1 IP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 proto 1 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:00:01 proto 58 3 50 vlan 1 dst 33:33:ff:00:00:01 --> write group 0x31000000 goto tbl 60 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:02:00 proto 58 3 50 1 vlan 1 dst 33:33:ff:00:02:00 --> write group 0x31000000 goto tbl 60 1 60 173 pport 2 vlan 2 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x02000000 1 60 6 pport 2 vlan 2 IPv6 src <any> dst <any> --> write group 0x02000000 1 60 174 pport 1 vlan 1 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x01000000 1 60 174 pport 2 vlan 2 IP src <any> dst <any> --> write group 0x02000000 1 60 6 pport 1 vlan 1 IPv6 src <any> dst <any> --> write group 0x01000000 1 60 181 pport 2 vlan 2 ARP src <any> dst <any> --> write group 0x02000000 1 10 715 pport 2 --> apply new vlan 2 goto tbl 20 1 60 177 pport 1 vlan 1 ARP src <any> dst <any> --> write group 0x01000000 1 60 174 pport 1 vlan 1 IP src <any> dst <any> --> write group 0x01000000 1 10 717 pport 1 --> apply new vlan 1 goto tbl 20 1 0 1432 pport 0(0xffff) --> goto tbl 10 (qemu) info rocker-of-dpa-groups sw1 id (decode) --> buckets 0x32000001 (type L2 multicast vlan 2 index 1) --> groups [0x02000001,0x02000000] 0x02000001 (type L2 interface vlan 2 pport 1) --> pop vlan out pport 1 0x01000002 (type L2 interface vlan 1 pport 2) --> pop vlan out pport 2 0x02000000 (type L2 interface vlan 2 pport 0) --> pop vlan out pport 0 0x01000000 (type L2 interface vlan 1 pport 0) --> pop vlan out pport 0 0x31000000 (type L2 multicast vlan 1 index 0) --> groups [0x01000002,0x01000000] [Added "query-" prefixes to rocker.json commands as suggested by Eric Blake <eblake@redhat.com>. --Stefan] Signed-off-by: Scott Feldman <sfeldma@gmail.com> Signed-off-by: Jiri Pirko <jiri@resnulli.us> Message-id: 1433985681-56138-5-git-send-email-sfeldma@gmail.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2015-06-11 04:21:21 +03:00
},
SQMP
Show rocker switch ports
------------------------
Arguments:
- "name": switch name
Example:
-> { "execute": "query-rocker-ports", "arguments": { "name": "sw1" } }
<- { "return": [ {"duplex": "full", "enabled": true, "name": "sw1.1",
"autoneg": "off", "link-up": true, "speed": 10000},
{"duplex": "full", "enabled": true, "name": "sw1.2",
"autoneg": "off", "link-up": true, "speed": 10000}
]}
EQMP
{
.name = "query-rocker-of-dpa-flows",
.args_type = "name:s,tbl-id:i?",
.mhandler.cmd_new = qmp_marshal_query_rocker_of_dpa_flows,
qmp/hmp: add rocker device support Add QMP/HMP support for rocker devices. This is mostly for debugging purposes to see inside the device's tables and port configurations. Some examples: (qemu) info rocker sw1 name: sw1 id: 0x0000013512005452 ports: 4 (qemu) info rocker-ports sw1 ena/ speed/ auto port link duplex neg? sw1.1 up 10G FD No sw1.2 up 10G FD No sw1.3 !ena 10G FD No sw1.4 !ena 10G FD No (qemu) info rocker-of-dpa-flows sw1 prio tbl hits key(mask) --> actions 2 60 pport 1 vlan 1 LLDP src 00:02:00:00:02:00 dst 01:80:c2:00:00:0e 2 60 pport 1 vlan 1 ARP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:00:02 proto 58 3 50 vlan 2 dst 33:33:ff:00:00:02 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:03:00 proto 58 3 50 1 vlan 2 dst 33:33:ff:00:03:00 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 ARP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 3 50 2 vlan 2 dst 00:02:00:00:02:00 --> write group 0x02000001 goto tbl 60 2 60 1 pport 2 vlan 2 IP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 proto 1 3 50 2 vlan 1 dst 00:02:00:00:03:00 --> write group 0x01000002 goto tbl 60 2 60 1 pport 1 vlan 1 IP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 proto 1 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:00:01 proto 58 3 50 vlan 1 dst 33:33:ff:00:00:01 --> write group 0x31000000 goto tbl 60 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:02:00 proto 58 3 50 1 vlan 1 dst 33:33:ff:00:02:00 --> write group 0x31000000 goto tbl 60 1 60 173 pport 2 vlan 2 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x02000000 1 60 6 pport 2 vlan 2 IPv6 src <any> dst <any> --> write group 0x02000000 1 60 174 pport 1 vlan 1 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x01000000 1 60 174 pport 2 vlan 2 IP src <any> dst <any> --> write group 0x02000000 1 60 6 pport 1 vlan 1 IPv6 src <any> dst <any> --> write group 0x01000000 1 60 181 pport 2 vlan 2 ARP src <any> dst <any> --> write group 0x02000000 1 10 715 pport 2 --> apply new vlan 2 goto tbl 20 1 60 177 pport 1 vlan 1 ARP src <any> dst <any> --> write group 0x01000000 1 60 174 pport 1 vlan 1 IP src <any> dst <any> --> write group 0x01000000 1 10 717 pport 1 --> apply new vlan 1 goto tbl 20 1 0 1432 pport 0(0xffff) --> goto tbl 10 (qemu) info rocker-of-dpa-groups sw1 id (decode) --> buckets 0x32000001 (type L2 multicast vlan 2 index 1) --> groups [0x02000001,0x02000000] 0x02000001 (type L2 interface vlan 2 pport 1) --> pop vlan out pport 1 0x01000002 (type L2 interface vlan 1 pport 2) --> pop vlan out pport 2 0x02000000 (type L2 interface vlan 2 pport 0) --> pop vlan out pport 0 0x01000000 (type L2 interface vlan 1 pport 0) --> pop vlan out pport 0 0x31000000 (type L2 multicast vlan 1 index 0) --> groups [0x01000002,0x01000000] [Added "query-" prefixes to rocker.json commands as suggested by Eric Blake <eblake@redhat.com>. --Stefan] Signed-off-by: Scott Feldman <sfeldma@gmail.com> Signed-off-by: Jiri Pirko <jiri@resnulli.us> Message-id: 1433985681-56138-5-git-send-email-sfeldma@gmail.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2015-06-11 04:21:21 +03:00
},
SQMP
Show rocker switch OF-DPA flow tables
-------------------------------------
Arguments:
- "name": switch name
- "tbl-id": (optional) flow table ID
Example:
-> { "execute": "query-rocker-of-dpa-flows", "arguments": { "name": "sw1" } }
<- { "return": [ {"key": {"in-pport": 0, "priority": 1, "tbl-id": 0},
"hits": 138,
"cookie": 0,
"action": {"goto-tbl": 10},
"mask": {"in-pport": 4294901760}
},
{...more...},
]}
EQMP
{
.name = "query-rocker-of-dpa-groups",
.args_type = "name:s,type:i?",
.mhandler.cmd_new = qmp_marshal_query_rocker_of_dpa_groups,
qmp/hmp: add rocker device support Add QMP/HMP support for rocker devices. This is mostly for debugging purposes to see inside the device's tables and port configurations. Some examples: (qemu) info rocker sw1 name: sw1 id: 0x0000013512005452 ports: 4 (qemu) info rocker-ports sw1 ena/ speed/ auto port link duplex neg? sw1.1 up 10G FD No sw1.2 up 10G FD No sw1.3 !ena 10G FD No sw1.4 !ena 10G FD No (qemu) info rocker-of-dpa-flows sw1 prio tbl hits key(mask) --> actions 2 60 pport 1 vlan 1 LLDP src 00:02:00:00:02:00 dst 01:80:c2:00:00:0e 2 60 pport 1 vlan 1 ARP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:00:02 proto 58 3 50 vlan 2 dst 33:33:ff:00:00:02 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 IPv6 src 00:02:00:00:03:00 dst 33:33:ff:00:03:00 proto 58 3 50 1 vlan 2 dst 33:33:ff:00:03:00 --> write group 0x32000001 goto tbl 60 2 60 pport 2 vlan 2 ARP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 3 50 2 vlan 2 dst 00:02:00:00:02:00 --> write group 0x02000001 goto tbl 60 2 60 1 pport 2 vlan 2 IP src 00:02:00:00:03:00 dst 00:02:00:00:02:00 proto 1 3 50 2 vlan 1 dst 00:02:00:00:03:00 --> write group 0x01000002 goto tbl 60 2 60 1 pport 1 vlan 1 IP src 00:02:00:00:02:00 dst 00:02:00:00:03:00 proto 1 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:00:01 proto 58 3 50 vlan 1 dst 33:33:ff:00:00:01 --> write group 0x31000000 goto tbl 60 2 60 pport 1 vlan 1 IPv6 src 00:02:00:00:02:00 dst 33:33:ff:00:02:00 proto 58 3 50 1 vlan 1 dst 33:33:ff:00:02:00 --> write group 0x31000000 goto tbl 60 1 60 173 pport 2 vlan 2 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x02000000 1 60 6 pport 2 vlan 2 IPv6 src <any> dst <any> --> write group 0x02000000 1 60 174 pport 1 vlan 1 LLDP src <any> dst 01:80:c2:00:00:0e --> write group 0x01000000 1 60 174 pport 2 vlan 2 IP src <any> dst <any> --> write group 0x02000000 1 60 6 pport 1 vlan 1 IPv6 src <any> dst <any> --> write group 0x01000000 1 60 181 pport 2 vlan 2 ARP src <any> dst <any> --> write group 0x02000000 1 10 715 pport 2 --> apply new vlan 2 goto tbl 20 1 60 177 pport 1 vlan 1 ARP src <any> dst <any> --> write group 0x01000000 1 60 174 pport 1 vlan 1 IP src <any> dst <any> --> write group 0x01000000 1 10 717 pport 1 --> apply new vlan 1 goto tbl 20 1 0 1432 pport 0(0xffff) --> goto tbl 10 (qemu) info rocker-of-dpa-groups sw1 id (decode) --> buckets 0x32000001 (type L2 multicast vlan 2 index 1) --> groups [0x02000001,0x02000000] 0x02000001 (type L2 interface vlan 2 pport 1) --> pop vlan out pport 1 0x01000002 (type L2 interface vlan 1 pport 2) --> pop vlan out pport 2 0x02000000 (type L2 interface vlan 2 pport 0) --> pop vlan out pport 0 0x01000000 (type L2 interface vlan 1 pport 0) --> pop vlan out pport 0 0x31000000 (type L2 multicast vlan 1 index 0) --> groups [0x01000002,0x01000000] [Added "query-" prefixes to rocker.json commands as suggested by Eric Blake <eblake@redhat.com>. --Stefan] Signed-off-by: Scott Feldman <sfeldma@gmail.com> Signed-off-by: Jiri Pirko <jiri@resnulli.us> Message-id: 1433985681-56138-5-git-send-email-sfeldma@gmail.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2015-06-11 04:21:21 +03:00
},
SQMP
Show rocker OF-DPA group tables
-------------------------------
Arguments:
- "name": switch name
- "type": (optional) group type
Example:
-> { "execute": "query-rocker-of-dpa-groups", "arguments": { "name": "sw1" } }
<- { "return": [ {"type": 0, "out-pport": 2, "pport": 2, "vlan-id": 3841,
"pop-vlan": 1, "id": 251723778},
{"type": 0, "out-pport": 0, "pport": 0, "vlan-id": 3841,
"pop-vlan": 1, "id": 251723776},
{"type": 0, "out-pport": 1, "pport": 1, "vlan-id": 3840,
"pop-vlan": 1, "id": 251658241},
{"type": 0, "out-pport": 0, "pport": 0, "vlan-id": 3840,
"pop-vlan": 1, "id": 251658240}
]}