Provided by: qemu-system-common_6.2+dfsg-2ubuntu6.24_amd64 bug

NAME

       qemu - QEMU User Documentation

SYNOPSIS

          qemu-system-x86_64 [options] [disk_image]

DESCRIPTION

       The QEMU PC System emulator simulates the following peripherals:

       • i440FX host PCI bridge and PIIX3 PCI to ISA bridge

       • Cirrus  CLGD  5446  PCI  VGA card or dummy VGA card with Bochs VESA extensions (hardware
         level, including all non standard modes).

       • PS/2 mouse and keyboard

       • 2 PCI IDE interfaces with hard disk and CD-ROM support

       • Floppy disk

       • PCI and ISA network adapters

       • Serial ports

       • IPMI BMC, either and internal or external one

       • Creative SoundBlaster 16 sound card

       • ENSONIQ AudioPCI ES1370 sound card

       • Intel 82801AA AC97 Audio compatible sound card

       • Intel HD Audio Controller and HDA codec

       • Adlib (OPL2) - Yamaha YM3812 compatible chip

       • Gravis Ultrasound GF1 sound card

       • CS4231A compatible sound card

       • PC speaker

       • PCI UHCI, OHCI, EHCI or XHCI USB controller and a virtual USB-1.1 hub.

       SMP is supported with up to 255 CPUs.

       QEMU uses the PC BIOS from the Seabios project and the Plex86/Bochs LGPL VGA BIOS.

       QEMU uses YM3812 emulation by Tatsuyuki Satoh.

       QEMU uses GUS emulation (GUSEMU32 http://www.deinmeister.de/gusemu/) by Tibor "TS" Schütz.

       Note that, by default, GUS shares IRQ(7) with parallel ports and so QEMU must be  told  to
       not have parallel ports to have working GUS.

          qemu-system-x86_64 dos.img -device gus -parallel none

       Alternatively:

          qemu-system-x86_64 dos.img -device gus,irq=5

       Or some other unclaimed IRQ.

       CS4231A is the chip used in Windows Sound System and GUSMAX products

       The  PC  speaker audio device can be configured using the pcspk-audiodev machine property,
       i.e.

          qemu-system-x86_64 some.img -audiodev <backend>,id=<name> -machine pcspk-audiodev=<name>

OPTIONS

       disk_image is a raw hard disk image for IDE hard disk 0. Some targets do not need  a  disk
       image.

   Standard options
       -h     Display help and exit

       -version
              Display version information and exit

       -machine [type=]name[,prop=value[,...]]
              Select the emulated machine by name. Use -machine help to list available machines.

              For  architectures  which  aim  to  support  live  migration  compatibility  across
              releases, each release will introduce a new versioned machine  type.  For  example,
              the 2.8.0 release introduced machine types "pc-i440fx-2.8" and "pc-q35-2.8" for the
              x86_64/i686 architectures.

              To allow live migration of guests from QEMU version 2.8.0, to QEMU  version  2.9.0,
              the  2.9.0  version must support the "pc-i440fx-2.8" and "pc-q35-2.8" machines too.
              To allow users live migrating VMs  to  skip  multiple  intermediate  releases  when
              upgrading,  new  releases  of  QEMU  will  support machine types from many previous
              versions.

              Supported machine properties are:

              accel=accels1[:accels2[:...]]
                     This is used to enable an accelerator. Depending on the target architecture,
                     kvm,  xen, hax, hvf, nvmm, whpx or tcg can be available.  By default, tcg is
                     used. If there is more than one accelerator specified, the next one is  used
                     if the previous one fails to initialize.

              vmport=on|off|auto
                     Enables  emulation  of  VMWare IO port, for vmmouse etc. auto says to select
                     the value based on accel. For accel=xen the default  is  off  otherwise  the
                     default is on.

              dump-guest-core=on|off
                     Include guest memory in a core dump. The default is on.

              mem-merge=on|off
                     Enables  or  disables  memory merge support. This feature, when supported by
                     the host, de-duplicates identical memory pages among VMs instances  (enabled
                     by default).

              aes-key-wrap=on|off
                     Enables  or  disables  AES  key  wrapping  support  on s390-ccw hosts.  This
                     feature controls  whether  AES  wrapping  keys  will  be  created  to  allow
                     execution of AES cryptographic functions. The default is on.

              dea-key-wrap=on|off
                     Enables  or  disables  DEA  key  wrapping  support  on s390-ccw hosts.  This
                     feature controls  whether  DEA  wrapping  keys  will  be  created  to  allow
                     execution of DEA cryptographic functions. The default is on.

              nvdimm=on|off
                     Enables or disables NVDIMM support. The default is off.

              memory-encryption=
                     Memory encryption object to use. The default is none.

              hmat=on|off
                     Enables  or  disables  ACPI  Heterogeneous  Memory  Attribute  Table  (HMAT)
                     support. The default is off.

              memory-backend='id'
                     An alternative to legacy -mem-path and mem-prealloc options.  Allows to  use
                     a memory backend as main RAM.

                     For example:

                        -object memory-backend-file,id=pc.ram,size=512M,mem-path=/hugetlbfs,prealloc=on,share=on
                        -machine memory-backend=pc.ram
                        -m 512M

                     Migration compatibility note:

                     • as  backend  id  one  shall  use  value of 'default-ram-id', advertised by
                       machine type (available via  query-machines  QMP  command),  if  migration
                       to/from old QEMU (<5.0) is expected.

                     • for     machine     types     4.0    and    older,    user    shall    use
                       x-use-canonical-path-for-ramblock-id=off  backend  option   if   migration
                       to/from old QEMU (<5.0) is expected.

                     For example:

                        -object memory-backend-ram,id=pc.ram,size=512M,x-use-canonical-path-for-ramblock-id=off
                        -machine memory-backend=pc.ram
                        -m 512M

       sgx-epc.0.memdev=@var{memid}
              Define an SGX EPC section.

       -cpu model
              Select CPU model (-cpu help for list and additional feature selection)

       -accel name[,prop=value[,...]]
              This  is  used to enable an accelerator. Depending on the target architecture, kvm,
              xen, hax, hvf, nvmm, whpx or tcg can be available. By  default,  tcg  is  used.  If
              there  is more than one accelerator specified, the next one is used if the previous
              one fails to initialize.

              igd-passthru=on|off
                     When Xen is in use, this option controls whether Intel  integrated  graphics
                     devices can be passed through to the guest (default=off)

              kernel-irqchip=on|off|split
                     Controls  KVM in-kernel irqchip support. The default is full acceleration of
                     the interrupt controllers. On x86, split irqchip reduces the  kernel  attack
                     surface,  at  a  performance  cost  for  non-MSI  interrupts.  Disabling the
                     in-kernel  irqchip  completely  is  not  recommended  except  for  debugging
                     purposes.

              kvm-shadow-mem=size
                     Defines the size of the KVM shadow MMU.

              split-wx=on|off
                     Controls  the  use  of split w^x mapping for the TCG code generation buffer.
                     Some operating systems require this to be enabled, and in such a  case  this
                     will  default on. On other operating systems, this will default off, but one
                     may enable this for testing or debugging.

              tb-size=n
                     Controls the size (in MiB) of the TCG translation block cache.

              thread=single|multi
                     Controls number of TCG threads. When the TCG is multi-threaded there will be
                     one thread per vCPU therefore taking advantage of additional host cores. The
                     default is to enable multi-threading where both the back-end and  front-ends
                     support  it  and  no  incompatible  TCG  features  have  been  enabled (e.g.
                     icount/replay).

              dirty-ring-size=n
                     When the KVM accelerator is used, it controls the size of the per-vCPU dirty
                     page  ring  buffer  (number  of entries for each vCPU). It should be a value
                     that is power of two, and it should be 1024 or bigger (but still  less  than
                     the  maximum  value that the kernel supports).  4096 could be a good initial
                     value if you have no idea which is the best.  Set this value to 0 to disable
                     the  feature.   By  default,  this  feature is disabled (dirty-ring-size=0).
                     When enabled, KVM will instead record dirty pages in a bitmap.

       -smp
       [[cpus=]n][,maxcpus=maxcpus][,sockets=sockets][,dies=dies][,cores=cores][,threads=threads]
              Simulate a SMP system with 'n' CPUs initially present on the machine type board. On
              boards supporting CPU hotplug, the optional  'maxcpus'  parameter  can  be  set  to
              enable  further  CPUs to be added at runtime. When both parameters are omitted, the
              maximum number of CPUs will be calculated from the provided  topology  members  and
              the initial CPU count will match the maximum number. When only one of them is given
              then the omitted one will be set to its counterpart's value.  Both  parameters  may
              be  specified,  but the maximum number of CPUs must be equal to or greater than the
              initial CPU count. Both parameters are subject to an upper limit that is determined
              by the specific machine type chosen.

              To  control  reporting of CPU topology information, the number of sockets, dies per
              socket, cores per die, and threads per core can be specified.  The sum `` sockets *
              cores  *  dies * threads `` must be equal to the maximum CPU count. CPU targets may
              only support a subset of the topology parameters.  Where  a  CPU  target  does  not
              support use of a particular topology parameter, its value should be assumed to be 1
              for the purpose of computing the CPU maximum count.

              Either the initial CPU count, or at least one of the topology  parameters  must  be
              specified.   The   specified   parameters  must  be  greater  than  zero,  explicit
              configuration like "cpus=0" is not allowed. Values for any omitted parameters  will
              be  computed  from those which are given.  Historically preference was given to the
              coarsest topology parameters when computing missing values  (ie  sockets  preferred
              over  cores,  which  were  preferred  over  threads),  however,  this  behaviour is
              considered liable to change. Prior to 6.2 the preference  was  sockets  over  cores
              over threads. Since 6.2 the preference is cores over sockets over threads.

       -numa node[,mem=size][,cpus=firstcpu[-lastcpu]][,nodeid=node][,initiator=initiator]

       -numa node[,memdev=id][,cpus=firstcpu[-lastcpu]][,nodeid=node][,initiator=initiator]

       -numa dist,src=source,dst=destination,val=distance

       -numa cpu,node-id=node[,socket-id=x][,core-id=y][,thread-id=z]

       -numa
       hmat-lb,initiator=node,target=node,hierarchy=hierarchy,data-type=tpye[,latency=lat][,bandwidth=bw]

       -numa
       hmat-cache,node-id=node,size=size,level=level[,associativity=str][,policy=str][,line=size]
              Define a NUMA node and assign RAM and VCPUs to it. Set the  NUMA  distance  from  a
              source node to a destination node. Set the ACPI Heterogeneous Memory Attributes for
              the given nodes.

              Legacy VCPU assignment uses 'cpus'  option  where  firstcpu  and  lastcpu  are  CPU
              indexes.  Each  'cpus'  option  represent  a  contiguous range of CPU indexes (or a
              single VCPU  if  lastcpu  is  omitted).  A  non-contiguous  set  of  VCPUs  can  be
              represented  by  providing  multiple  'cpus'  options.  If 'cpus' is omitted on all
              nodes, VCPUs are automatically split between them.

              For example, the following option assigns VCPUs 0, 1, 2 and 5 to a NUMA node:

                 -numa node,cpus=0-2,cpus=5

              'cpu'   option   is   a   new   alternative   to   'cpus'   option    which    uses
              'socket-id|core-id|thread-id'  properties  to  assign  CPU  objects to a node using
              topology layout properties of CPU. The set of properties is machine  specific,  and
              depends   on   used   machine   type/'smp'   options.  It  could  be  queried  with
              'hotpluggable-cpus' monitor command. 'node-id' property specifies node to which CPU
              object  will  be assigned, it's required for node to be declared with 'node' option
              before it's used with 'cpu' option.

              For example:

                 -M pc \
                 -smp 1,sockets=2,maxcpus=2 \
                 -numa node,nodeid=0 -numa node,nodeid=1 \
                 -numa cpu,node-id=0,socket-id=0 -numa cpu,node-id=1,socket-id=1

              Legacy 'mem' assigns a given RAM amount to a node (not supported for 5.1 and  newer
              machine  types). 'memdev' assigns RAM from a given memory backend device to a node.
              If 'mem' and 'memdev' are omitted in all nodes, RAM is split equally between them.

              'mem' and 'memdev' are mutually exclusive.  Furthermore, if one node uses 'memdev',
              all of them have to use it.

              'initiator'  is an additional option that points to an initiator NUMA node that has
              best performance (the lowest latency or largest bandwidth) to this NUMA node.  Note
              that this option can be set only when the machine property 'hmat' is set to 'on'.

              Following  example  creates a machine with 2 NUMA nodes, node 0 has CPU. node 1 has
              only memory, and its initiator is node 0. Note that because  node  0  has  CPU,  by
              default the initiator of node 0 is itself and must be itself.

                 -machine hmat=on \
                 -m 2G,slots=2,maxmem=4G \
                 -object memory-backend-ram,size=1G,id=m0 \
                 -object memory-backend-ram,size=1G,id=m1 \
                 -numa node,nodeid=0,memdev=m0 \
                 -numa node,nodeid=1,memdev=m1,initiator=0 \
                 -smp 2,sockets=2,maxcpus=2  \
                 -numa cpu,node-id=0,socket-id=0 \
                 -numa cpu,node-id=0,socket-id=1

              source and destination are NUMA node IDs. distance is the NUMA distance from source
              to destination. The distance from a node to itself is always 10.  If  any  pair  of
              nodes  is  given a distance, then all pairs must be given distances. Although, when
              distances are only given in  one  direction  for  each  pair  of  nodes,  then  the
              distances  in  the  opposite directions are assumed to be the same. If, however, an
              asymmetrical pair of distances is given for even one node pair, then all node pairs
              must  be  provided  distance  values  for  both  directions,  even  when  they  are
              symmetrical. When a node is unreachable from another node, set the pair's  distance
              to 255.

              Note that the -numa option doesn't allocate any of the specified resources, it just
              assigns existing resources to NUMA nodes. This means that one still has to use  the
              -m, -smp options to allocate RAM and VCPUs respectively.

              Use  'hmat-lb'  to  set  System  Locality Latency and Bandwidth Information between
              initiator and target NUMA  nodes  in  ACPI  Heterogeneous  Attribute  Memory  Table
              (HMAT).  Initiator NUMA node can create memory requests, usually it has one or more
              processors.  Target NUMA node contains addressable memory.

              In 'hmat-lb' option, node are NUMA node IDs. hierarchy is the memory  hierarchy  of
              the target NUMA node: if hierarchy is 'memory', the structure represents the memory
              performance; if hierarchy is 'first-level|second-level|third-level', this structure
              represents  aggregated  performance  of memory side caches for each domain. type of
              'data-type' is type of data represented by this structure instance: if  'hierarchy'
              is  'memory',  'data-type'  is  'access|read|write'  latency or 'access|read|write'
              bandwidth     of      the      target      memory;      if      'hierarchy'      is
              'first-level|second-level|third-level',   'data-type'  is  'access|read|write'  hit
              latency or 'access|read|write' hit bandwidth of the target memory side cache.

              lat is latency value in nanoseconds. bw is bandwidth value, the possible value  and
              units  are  NUM[M|G|T],  mean  that the bandwidth value are NUM byte per second (or
              MB/s, GB/s or TB/s depending on used suffix). Note that  if  latency  or  bandwidth
              value  is  0,  means  the  corresponding  latency  or  bandwidth information is not
              provided.

              In 'hmat-cache' option, node-id is the NUMA-id of the memory belongs. size  is  the
              size  of  memory  side  cache  in bytes. level is the cache level described in this
              structure, note that the cache level 0 should not be used with 'hmat-cache' option.
              associativity    is    the    cache    associativity,   the   possible   value   is
              'none/direct(direct-mapped)/complex(complex cache indexing)'. policy is  the  write
              policy. line is the cache Line size in bytes.

              For  example,  the following options describe 2 NUMA nodes. Node 0 has 2 cpus and a
              ram, node 1 has only a ram. The processors in node 0 access memory in node  0  with
              access-latency  5 nanoseconds, access-bandwidth is 200 MB/s; The processors in NUMA
              node  0  access  memory  in  NUMA  node  1  with  access-latency  10   nanoseconds,
              access-bandwidth  is  100  MB/s. And for memory side cache information, NUMA node 0
              and 1 both have 1 level memory cache, size is 10KB, policy is write-back, the cache
              Line size is 8 bytes:

                 -machine hmat=on \
                 -m 2G \
                 -object memory-backend-ram,size=1G,id=m0 \
                 -object memory-backend-ram,size=1G,id=m1 \
                 -smp 2,sockets=2,maxcpus=2 \
                 -numa node,nodeid=0,memdev=m0 \
                 -numa node,nodeid=1,memdev=m1,initiator=0 \
                 -numa cpu,node-id=0,socket-id=0 \
                 -numa cpu,node-id=0,socket-id=1 \
                 -numa hmat-lb,initiator=0,target=0,hierarchy=memory,data-type=access-latency,latency=5 \
                 -numa hmat-lb,initiator=0,target=0,hierarchy=memory,data-type=access-bandwidth,bandwidth=200M \
                 -numa hmat-lb,initiator=0,target=1,hierarchy=memory,data-type=access-latency,latency=10 \
                 -numa hmat-lb,initiator=0,target=1,hierarchy=memory,data-type=access-bandwidth,bandwidth=100M \
                 -numa hmat-cache,node-id=0,size=10K,level=1,associativity=direct,policy=write-back,line=8 \
                 -numa hmat-cache,node-id=1,size=10K,level=1,associativity=direct,policy=write-back,line=8

       -add-fd fd=fd,set=set[,opaque=opaque]
              Add a file descriptor to an fd set. Valid options are:

              fd=fd  This  option defines the file descriptor of which a duplicate is added to fd
                     set. The file descriptor cannot be stdin, stdout, or stderr.

              set=set
                     This option defines the ID of the fd set to add the file descriptor to.

              opaque=opaque
                     This option defines a free-form string that can be used to describe fd.

              You can open an image using pre-opened file descriptors from an fd set:

                 qemu-system-x86_64 \
                  -add-fd fd=3,set=2,opaque="rdwr:/path/to/file" \
                  -add-fd fd=4,set=2,opaque="rdonly:/path/to/file" \
                  -drive file=/dev/fdset/2,index=0,media=disk

       -set group.id.arg=value
              Set parameter arg for item id of type group

       -global driver.prop=value

       -global driver=driver,property=property,value=value
              Set default value of driver's property prop to value, e.g.:

                 qemu-system-x86_64 -global ide-hd.physical_block_size=4096 disk-image.img

              In particular, you can use this to set driver  properties  for  devices  which  are
              created automatically by the machine model. To create a device which is not created
              automatically and set properties on it, use -device.

              -global       driver.prop=value       is        shorthand        for        -global
              driver=driver,property=prop,value=value. The longhand syntax works even when driver
              contains a dot.

       -boot
       [order=drives][,once=drives][,menu=on|off][,splash=sp_name][,splash-time=sp_time][,reboot-timeout=rb_timeout][,strict=on|off]
              Specify boot order drives as a string of drive letters. Valid drive letters  depend
              on  the  target architecture. The x86 PC uses: a, b (floppy 1 and 2), c (first hard
              disk), d (first CD-ROM), n-p (Etherboot from network adapter 1-4), hard  disk  boot
              is  the  default.   To  apply  a  particular  boot order only on the first startup,
              specify it via once. Note that the order or  once  parameter  should  not  be  used
              together with the bootindex property of devices, since the firmware implementations
              normally do not support both at the same time.

              Interactive boot menus/prompts can be enabled via menu=on as far  as  firmware/BIOS
              supports them. The default is non-interactive boot.

              A  splash  picture  could be passed to bios, enabling user to show it as logo, when
              option splash=sp_name  is  given  and  menu=on,  If  firmware/BIOS  supports  them.
              Currently Seabios for X86 system support it. limitation: The splash file could be a
              jpeg file or a BMP file in 24 BPP format(true  color).  The  resolution  should  be
              supported by the SVGA mode, so the recommended is 320x240, 640x480, 800x640.

              A  timeout  could  be  passed to bios, guest will pause for rb_timeout ms when boot
              failed, then reboot. If rb_timeout is '-1', guest will not reboot, qemu passes '-1'
              to bios by default. Currently Seabios for X86 system support it.

              Do strict boot via strict=on as far as firmware/BIOS supports it. This only effects
              when boot priority is changed by bootindex options. The default is non-strict boot.

                 # try to boot from network first, then from hard disk
                 qemu-system-x86_64 -boot order=nc
                 # boot from CD-ROM first, switch back to default order after reboot
                 qemu-system-x86_64 -boot once=d
                 # boot with a splash picture for 5 seconds.
                 qemu-system-x86_64 -boot menu=on,splash=/root/boot.bmp,splash-time=5000

              Note: The  legacy  format  '-boot  drives'  is  still  supported  but  its  use  is
              discouraged as it may be removed from future versions.

       -m [size=]megs[,slots=n,maxmem=size]
              Sets  guest  startup RAM size to megs megabytes. Default is 128 MiB.  Optionally, a
              suffix of "M" or "G" can be used to signify  a  value  in  megabytes  or  gigabytes
              respectively.  Optional  pair  slots,  maxmem  could  be  used  to  set  amount  of
              hotpluggable memory slots and maximum amount of memory. Note that  maxmem  must  be
              aligned to the page size.

              For  example,  the  following  command-line sets the guest startup RAM size to 1GB,
              creates 3 slots to hotplug additional memory and sets the maximum memory the  guest
              can reach to 4GB:

                 qemu-system-x86_64 -m 1G,slots=3,maxmem=4G

              If  slots  and  maxmem  are  not specified, memory hotplug won't be enabled and the
              guest startup RAM will never increase.

       -mem-path path
              Allocate guest RAM from a temporarily created file in path.

       -mem-prealloc
              Preallocate memory when using -mem-path.

       -k language
              Use keyboard layout language (for example fr  for  French).  This  option  is  only
              needed  where  it  is  not easy to get raw PC keycodes (e.g. on Macs, with some X11
              servers or with a VNC or curses display). You don't normally  need  to  use  it  on
              PC/Linux or PC/Windows hosts.

              The available layouts are:

                 ar  de-ch  es  fo     fr-ca  hu  ja  mk     no  pt-br  sv
                 da  en-gb  et  fr     fr-ch  is  lt  nl     pl  ru     th
                 de  en-us  fi  fr-be  hr     it  lv  nl-be  pt  sl     tr

              The default is en-us.

       -audio-help
              Will  show  the  -audiodev  equivalent  of  the  currently  specified  (deprecated)
              environment variables.

       -audiodev [driver=]driver,id=id[,prop[=value][,...]]
              Adds a new audio backend driver identified by  id.  There  are  global  and  driver
              specific  properties.  Some  values  can  be  set differently for input and output,
              they're marked with in|out.. You can set the input's property with in.prop and  the
              output's property with out.prop. For example:

                 -audiodev alsa,id=example,in.frequency=44110,out.frequency=8000
                 -audiodev alsa,id=example,out.channels=1 # leaves in.channels unspecified

              NOTE:  parameter  validation is known to be incomplete, in many cases specifying an
              invalid option causes QEMU to print an error message and continue emulation without
              sound.

              Valid global options are:

              id=identifier
                     Identifies the audio backend.

              timer-period=period
                     Sets  the  timer period used by the audio subsystem in microseconds. Default
                     is 10000 (10 ms).

              in|out.mixing-engine=on|off
                     Use QEMU's mixing engine to mix all streams inside QEMU  and  convert  audio
                     formats  when not supported by the backend. When off, fixed-settings must be
                     off too. Note that disabling this option means  that  the  selected  backend
                     must  support  multiple  streams  and  the audio formats used by the virtual
                     cards, otherwise you'll get no sound. It's not recommended to  disable  this
                     option  unless  you  want  to  use  5.1  or 7.1 audio, as mixing engine only
                     supports mono and stereo audio. Default is on.

              in|out.fixed-settings=on|off
                     Use fixed settings for host audio. When off, it will change based on how the
                     guest  opens  the  sound  card. In this case you must not specify frequency,
                     channels or format. Default is on.

              in|out.frequency=frequency
                     Specify the frequency to use when using fixed-settings. Default is 44100Hz.

              in|out.channels=channels
                     Specify the number of channels to use when using fixed-settings.  Default is
                     2 (stereo).

              in|out.format=format
                     Specify  the  sample  format to use when using fixed-settings.  Valid values
                     are: s8, s16, s32, u8, u16, u32, f32. Default is s16.

              in|out.voices=voices
                     Specify the number of voices to use. Default is 1.

              in|out.buffer-length=usecs
                     Sets the size of the buffer in microseconds.

       -audiodev none,id=id[,prop[=value][,...]]
              Creates a dummy backend that discards all outputs.  This  backend  has  no  backend
              specific properties.

       -audiodev alsa,id=id[,prop[=value][,...]]
              Creates backend using the ALSA. This backend is only available on Linux.

              ALSA specific options are:

              in|out.dev=device
                     Specify the ALSA device to use for input and/or output. Default is default.

              in|out.period-length=usecs
                     Sets the period length in microseconds.

              in|out.try-poll=on|off
                     Attempt to use poll mode with the device. Default is on.

              threshold=threshold
                     Threshold (in microseconds) when playback starts. Default is 0.

       -audiodev coreaudio,id=id[,prop[=value][,...]]
              Creates  a  backend using Apple's Core Audio. This backend is only available on Mac
              OS and only supports playback.

              Core Audio specific options are:

              in|out.buffer-count=count
                     Sets the count of the buffers.

       -audiodev dsound,id=id[,prop[=value][,...]]
              Creates a backend using Microsoft's DirectSound. This backend is only available  on
              Windows and only supports playback.

              DirectSound specific options are:

              latency=usecs
                     Add extra usecs microseconds latency to playback. Default is 10000 (10 ms).

       -audiodev oss,id=id[,prop[=value][,...]]
              Creates a backend using OSS. This backend is available on most Unix-like systems.

              OSS specific options are:

              in|out.dev=device
                     Specify the file name of the OSS device to use. Default is /dev/dsp.

              in|out.buffer-count=count
                     Sets the count of the buffers.

              in|out.try-poll=on|of
                     Attempt to use poll mode with the device. Default is on.

              try-mmap=on|off
                     Try using memory mapped device access. Default is off.

              exclusive=on|off
                     Open the device in exclusive mode (vmix won't work in this case). Default is
                     off.

              dsp-policy=policy
                     Sets the timing policy (between 0 and 10, where smaller number means smaller
                     latency  but  higher  CPU  usage).  Use  -1 to use buffer sizes specified by
                     buffer and buffer-count. This option is ignored if you do not  have  OSS  4.
                     Default is 5.

       -audiodev pa,id=id[,prop[=value][,...]]
              Creates a backend using PulseAudio. This backend is available on most systems.

              PulseAudio specific options are:

              server=server
                     Sets the PulseAudio server to connect to.

              in|out.name=sink
                     Use the specified source/sink for recording/playback.

              in|out.latency=usecs
                     Desired  latency  in  microseconds.  The PulseAudio server will try to honor
                     this value but actual latencies may be lower or higher.

       -audiodev sdl,id=id[,prop[=value][,...]]
              Creates a backend using SDL. This backend is available on  most  systems,  but  you
              should use your platform's native backend if possible.

              SDL specific options are:

              in|out.buffer-count=count
                     Sets the count of the buffers.

       -audiodev spice,id=id[,prop[=value][,...]]
              Creates  a backend that sends audio through SPICE. This backend requires -spice and
              automatically selected in that case, so usually you can ignore  this  option.  This
              backend has no backend specific properties.

       -audiodev wav,id=id[,prop[=value][,...]]
              Creates a backend that writes audio to a WAV file.

              Backend specific options are:

              path=path
                     Write recorded audio into the specified file. Default is qemu.wav.

       -soundhw card1[,card2,...] or -soundhw all
              Enable  audio  and selected sound hardware. Use 'help' to print all available sound
              hardware. For example:

                 qemu-system-x86_64 -soundhw sb16,adlib disk.img
                 qemu-system-x86_64 -soundhw es1370 disk.img
                 qemu-system-x86_64 -soundhw ac97 disk.img
                 qemu-system-x86_64 -soundhw hda disk.img
                 qemu-system-x86_64 -soundhw all disk.img
                 qemu-system-x86_64 -soundhw help

              Note that Linux's i810_audio OSS kernel (for AC97) module  might  require  manually
              specifying clocking.

                 modprobe i810_audio clocking=48000

       -device driver[,prop[=value][,...]]
              Add  device  driver.  prop=value sets driver properties. Valid properties depend on
              the driver. To get help on possible drivers and properties, use  -device  help  and
              -device driver,help.

              Some drivers are:

       -device ipmi-bmc-sim,id=id[,prop[=value][,...]]
              Add  an IPMI BMC. This is a simulation of a hardware management interface processor
              that normally sits on a system. It provides a watchdog and the ability to reset and
              power  control the system. You need to connect this to an IPMI interface to make it
              useful

              The IPMI slave address to use for the BMC. The default is 0x20. This address is the
              BMC's  address on the I2C network of management controllers. If you don't know what
              this means, it is safe to ignore it.

              id=id  The BMC id for interfaces to use this device.

              slave_addr=val
                     Define slave address to use for the BMC. The default is 0x20.

              sdrfile=file
                     file containing raw Sensor Data Records (SDR) data. The default is none.

              fruareasize=val
                     size of a Field Replaceable Unit (FRU) area. The default is 1024.

              frudatafile=file
                     file containing raw  Field  Replaceable  Unit  (FRU)  inventory  data.   The
                     default is none.

              guid=uuid
                     value for the GUID for the BMC, in standard UUID format. If this is set, get
                     "Get GUID" command to the BMC will return it.   Otherwise  "Get  GUID"  will
                     return an error.

       -device ipmi-bmc-extern,id=id,chardev=id[,slave_addr=val]
              Add  a  connection  to an external IPMI BMC simulator. Instead of locally emulating
              the BMC like the above item, instead connect to an external  entity  that  provides
              the IPMI services.

              A  connection  is made to an external BMC simulator. If you do this, it is strongly
              recommended that you use the  "reconnect="  chardev  option  to  reconnect  to  the
              simulator  if  the  connection is lost. Note that if this is not used carefully, it
              can be a security issue, as the interface has the ability to send resets, NMIs, and
              power  off  the  VM.  It's best if QEMU makes a connection to an external simulator
              running on a secure port on localhost, so neither the simulator nor QEMU is exposed
              to any outside network.

              See  the  "lanserv/README.vm"  file in the OpenIPMI library for more details on the
              external interface.

       -device isa-ipmi-kcs,bmc=id[,ioport=val][,irq=val]
              Add a KCS IPMI interafce on the ISA bus. This also adds a  corresponding  ACPI  and
              SMBIOS entries, if appropriate.

              bmc=id The BMC to connect to, one of ipmi-bmc-sim or ipmi-bmc-extern above.

              ioport=val
                     Define the I/O address of the interface. The default is 0xca0 for KCS.

              irq=val
                     Define  the  interrupt  to use. The default is 5. To disable interrupts, set
                     this to 0.

       -device isa-ipmi-bt,bmc=id[,ioport=val][,irq=val]
              Like the KCS interface, but defines a BT interface. The default port  is  0xe4  and
              the default interrupt is 5.

       -device pci-ipmi-kcs,bmc=id
              Add a KCS IPMI interafce on the PCI bus.

              bmc=id The BMC to connect to, one of ipmi-bmc-sim or ipmi-bmc-extern above.

       -device pci-ipmi-bt,bmc=id
              Like the KCS interface, but defines a BT interface on the PCI bus.

       -device intel-iommu[,option=...]
              This  is  only  supported  by  -machine q35, which will enable Intel VT-d emulation
              within the guest.  It supports below options:

              intremap=on|off (default: auto)
                     This enables interrupt remapping feature.  It's required to enable  complete
                     x2apic.   Currently  it only supports kvm kernel-irqchip modes off or split,
                     while full kernel-irqchip is  not  yet  supported.   The  default  value  is
                     "auto", which will be decided by the mode of kernel-irqchip.

              caching-mode=on|off (default: off)
                     This  enables  caching mode for the VT-d emulated device.  When caching-mode
                     is  enabled,  each  guest  DMA  buffer  mapping  will  generate   an   IOTLB
                     invalidation  from  the  guest  IOMMU  driver  to  the  vIOMMU  device  in a
                     synchronous way.  It is required for -device vfio-pci to work with the  VT-d
                     device,  because  host assigned devices requires to setup the DMA mapping on
                     the host before guest DMA starts.

              device-iotlb=on|off (default: off)
                     This enables device-iotlb capability for the emulated VT-d device.   So  far
                     virtio/vhost  should  be  the only real user for this parameter, paired with
                     ats=on configured for the device.

              aw-bits=39|48 (default: 39)
                     This decides the address width of IOVA address space.  The address space has
                     39  bits  width for 3-level IOMMU page tables, and 48 bits for 4-level IOMMU
                     page tables.

              Please also refer to the wiki page for general scenarios of VT-d emulation in QEMU:
              https://wiki.qemu.org/Features/VT-d.

       -name name
              Sets  the name of the guest. This name will be displayed in the SDL window caption.
              The name will also be used for the VNC server. Also optionally set the top  visible
              process name in Linux. Naming of individual threads can also be enabled on Linux to
              aid debugging.

       -uuid uuid
              Set system UUID.

   Block device options
       -fda file

       -fdb file
              Use file as floppy disk 0/1 image (see  the  disk  images  chapter  in  the  System
              Emulation Users Guide).

       -hda file

       -hdb file

       -hdc file

       -hdd file
              Use file as hard disk 0, 1, 2 or 3 image (see the disk images chapter in the System
              Emulation Users Guide).

       -cdrom file
              Use file as CD-ROM image (you cannot use -hdc and -cdrom at the same time). You can
              use the host CD-ROM by using /dev/cdrom as filename.

       -blockdev option[,option[,option[,...]]]
              Define  a  new  block  driver node. Some of the options apply to all block drivers,
              other options are only accepted for a specific block driver. See below for  a  list
              of generic options and options for the most common block drivers.

              Options  that  expect  a  reference to another node (e.g. file) can be given in two
              ways.  Either  you  specify  the  node   name   of   an   already   existing   node
              (file=node-name),  or  you  define  a  new  node  inline,  adding  options  for the
              referenced node after a dot (file.filename=path,file.aio=native).

              A block driver node created with -blockdev can  be  used  for  a  guest  device  by
              specifying  its node name for the drive property in a -device argument that defines
              a block device.

              Valid options for any block driver node:

                     driver Specifies the block driver to use for the given node.

                     node-name
                            This defines the name of the block driver node by which  it  will  be
                            referenced later. The name must be unique, i.e. it must not match the
                            name of a different block driver node, or (if you use -drive as well)
                            the ID of a drive.

                            If  no  node  name  is specified, it is automatically generated.  The
                            generated node name is not intended to  be  predictable  and  changes
                            between  QEMU  invocations.  For the top level, an explicit node name
                            must be specified.

                     read-only
                            Open the node read-only. Guest write attempts will fail.

                            Note that some block drivers support only  read-only  access,  either
                            generally  or  in  certain  configurations. In this case, the default
                            value read-only=off does not work and the option  must  be  specified
                            explicitly.

                     auto-read-only
                            If  auto-read-only=on  is  set, QEMU may fall back to read-only usage
                            even when read-only=off is requested, or even switch between modes as
                            needed,  e.g.  depending  on  whether  the  image file is writable or
                            whether a writing user is attached to the node.

                     force-share
                            Override the image locking system of QEMU  by  forcing  the  node  to
                            utilize  weaker shared access for permissions where it would normally
                            request exclusive access. When there is the  potential  for  multiple
                            instances to have the same file open (whether this invocation of QEMU
                            is the first or the second  instance),  both  instances  must  permit
                            shared access for the second instance to succeed at opening the file.

                            Enabling force-share=on requires read-only=on.

                     cache.direct
                            The  host  page cache can be avoided with cache.direct=on.  This will
                            attempt to do disk IO directly to the guest's memory. QEMU may  still
                            perform an internal copy of the data.

                     cache.no-flush
                            In  case  you don't care about data integrity over host failures, you
                            can use cache.no-flush=on. This option tells QEMU that it never needs
                            to  write  any data to the disk but can instead keep things in cache.
                            If anything goes wrong, like your host losing power, the disk storage
                            getting disconnected accidentally, etc. your image will most probably
                            be rendered unusable.

                     discard=discard
                            discard is one of "ignore"  (or  "off")  or  "unmap"  (or  "on")  and
                            controls  whether  discard (also known as trim or unmap) requests are
                            ignored or passed to the filesystem.   Some  machine  types  may  not
                            support discard requests.

                     detect-zeroes=detect-zeroes
                            detect-zeroes  is  "off",  "on"  or "unmap" and enables the automatic
                            conversion of  plain  zero  writes  by  the  OS  to  driver  specific
                            optimized zero write commands. You may even choose "unmap" if discard
                            is set to "unmap" to allow a zero write to be converted to  an  unmap
                            operation.

              Driver-specific options for file
                     This is the protocol-level block driver for accessing regular files.

                     filename
                            The path to the image file in the local filesystem

                     aio    Specifies the AIO backend (threads/native/io_uring, default: threads)

                     locking
                            Specifies  whether the image file is protected with Linux OFD / POSIX
                            locks. The default is to use the Linux Open File  Descriptor  API  if
                            available,  otherwise  no  lock  is  applied.  (auto/on/off, default:
                            auto)

                     Example:

                        -blockdev driver=file,node-name=disk,filename=disk.img

              Driver-specific options for raw
                     This is the image format block driver for raw images. It is usually  stacked
                     on top of a protocol level block driver such as file.

                     file   Reference to or definition of the data source block driver node (e.g.
                            a file driver node)

                     Example 1:

                        -blockdev driver=file,node-name=disk_file,filename=disk.img
                        -blockdev driver=raw,node-name=disk,file=disk_file

                     Example 2:

                        -blockdev driver=raw,node-name=disk,file.driver=file,file.filename=disk.img

              Driver-specific options for qcow2
                     This is the image format block  driver  for  qcow2  images.  It  is  usually
                     stacked on top of a protocol level block driver such as file.

                     file   Reference to or definition of the data source block driver node (e.g.
                            a file driver node)

                     backing
                            Reference to or definition of the backing file block device  (default
                            is  taken  from  the  image file). It is allowed to pass null here in
                            order to disable the default backing file.

                     lazy-refcounts
                            Whether to enable the lazy  refcounts  feature  (on/off;  default  is
                            taken from the image file)

                     cache-size
                            The  maximum  total size of the L2 table and refcount block caches in
                            bytes (default: the sum of l2-cache-size and refcount-cache-size)

                     l2-cache-size
                            The maximum size  of  the  L2  table  cache  in  bytes  (default:  if
                            cache-size  is  not  specified  -  32M  on Linux platforms, and 8M on
                            non-Linux platforms; otherwise,  as  large  as  possible  within  the
                            cache-size,  while  permitting  the requested or the minimal refcount
                            cache size)

                     refcount-cache-size
                            The maximum size of the refcount block cache  in  bytes  (default:  4
                            times the cluster size; or if cache-size is specified, the part of it
                            which is not used for the L2 cache)

                     cache-clean-interval
                            Clean unused entries in the L2 and refcount caches. The  interval  is
                            in  seconds.  The default value is 600 on supporting platforms, and 0
                            on other platforms. Setting it to 0 disables this feature.

                     pass-discard-request
                            Whether discard requests to the qcow2 device should be  forwarded  to
                            the  data  source (on/off; default: on if discard=unmap is specified,
                            off otherwise)

                     pass-discard-snapshot
                            Whether discard requests for the data source should be issued when  a
                            snapshot  operation  (e.g. deleting a snapshot) frees clusters in the
                            qcow2 file (on/off; default: on)

                     pass-discard-other
                            Whether discard requests for the data  source  should  be  issued  on
                            other occasions where a cluster gets freed (on/off; default: off)

                     overlap-check
                            Which   overlap   checks   to   perform   for  writes  to  the  image
                            (none/constant/cached/all; default: cached).  For  details  or  finer
                            granularity control refer to the QAPI documentation of blockdev-add.

                     Example 1:

                        -blockdev driver=file,node-name=my_file,filename=/tmp/disk.qcow2
                        -blockdev driver=qcow2,node-name=hda,file=my_file,overlap-check=none,cache-size=16777216

                     Example 2:

                        -blockdev driver=qcow2,node-name=disk,file.driver=http,file.filename=http://example.com/image.qcow2

              Driver-specific options for other drivers
                     Please refer to the QAPI documentation of the blockdev-add QMP command.

       -drive option[,option[,option[,...]]]
              Define  a  new  drive.  This includes creating a block driver node (the backend) as
              well as a guest device, and is mostly a shortcut  for  defining  the  corresponding
              -blockdev and -device options.

              -drive  accepts  all options that are accepted by -blockdev.  In addition, it knows
              the following options:

              file=file
                     This option defines which disk image (see the disk  images  chapter  in  the
                     System  Emulation  Users  Guide)  to  use  with this drive.  If the filename
                     contains comma, you must double it (for  instance,  "file=my,,file"  to  use
                     file "my,file").

                     Special files such as iSCSI devices can be specified using protocol specific
                     URLs. See the section for "Device URL Syntax" for more information.

              if=interface
                     This option defines on which type  on  interface  the  drive  is  connected.
                     Available types are: ide, scsi, sd, mtd, floppy, pflash, virtio, none.

              bus=bus,unit=unit
                     These options define where is connected the drive by defining the bus number
                     and the unit id.

              index=index
                     This option defines where is connected the drive by using an  index  in  the
                     list of available connectors of a given interface type.

              media=media
                     This option defines the type of the media: disk or cdrom.

              snapshot=snapshot
                     snapshot  is  "on"  or  "off" and controls snapshot mode for the given drive
                     (see -snapshot).

              cache=cache
                     cache is "none", "writeback", "unsafe", "directsync" or  "writethrough"  and
                     controls how the host cache is used to access block data. This is a shortcut
                     that sets the cache.direct and cache.no-flush options (as in -blockdev), and
                     additionally  cache.writeback,  which provides a default for the write-cache
                     option of block guest devices (as in -device). The modes correspond  to  the
                     following settings:

                           ┌─────────────┬─────────────────┬──────────────┬────────────────┐
                           │             │ cache.writeback │ cache.direct │ cache.no-flush │
                           ├─────────────┼─────────────────┼──────────────┼────────────────┤
                           │writeback    │ on              │ off          │ off            │
                           └─────────────┴─────────────────┴──────────────┴────────────────┘

                           │none         │ on              │ on           │ off            │
                           ├─────────────┼─────────────────┼──────────────┼────────────────┤
                           │writethrough │ off             │ off          │ off            │
                           ├─────────────┼─────────────────┼──────────────┼────────────────┤
                           │directsync   │ off             │ on           │ off            │
                           ├─────────────┼─────────────────┼──────────────┼────────────────┤
                           │unsafe       │ on              │ off          │ on             │
                           └─────────────┴─────────────────┴──────────────┴────────────────┘

                     The default mode is cache=writeback.

              aio=aio
                     aio  is "threads", "native", or "io_uring" and selects between pthread based
                     disk I/O, native Linux AIO, or Linux io_uring API.

              format=format
                     Specify which disk format will be used rather than detecting the format. Can
                     be  used  to  specify  format=raw  to avoid interpreting an untrusted format
                     header.

              werror=action,rerror=action
                     Specify which action to take on write and read errors.  Valid  actions  are:
                     "ignore"  (ignore  the  error  and  try  to  continue), "stop" (pause QEMU),
                     "report" (report the error to the guest), "enospc" (pause QEMU only  if  the
                     host  disk  is  full;  report the error to the guest otherwise). The default
                     setting is werror=enospc and rerror=report.

              copy-on-read=copy-on-read
                     copy-on-read is "on" or "off" and enables whether to copy read backing  file
                     sectors into the image file.

              bps=b,bps_rd=r,bps_wr=w
                     Specify  bandwidth  throttling  limits  in  bytes per second, either for all
                     request types or for reads or writes only. Small values can lead to timeouts
                     or hangs inside the guest. A safe minimum for disks is 2 MB/s.

              bps_max=bm,bps_rd_max=rm,bps_wr_max=wm
                     Specify  bursts  in  bytes  per  second, either for all request types or for
                     reads or writes only. Bursts allow the guest I/O to spike  above  the  limit
                     temporarily.

              iops=i,iops_rd=r,iops_wr=w
                     Specify  request  rate limits in requests per second, either for all request
                     types or for reads or writes only.

              iops_max=bm,iops_rd_max=rm,iops_wr_max=wm
                     Specify bursts in requests per second, either for all request types  or  for
                     reads  or  writes  only. Bursts allow the guest I/O to spike above the limit
                     temporarily.

              iops_size=is
                     Let every is bytes of a request count as a new request for  iops  throttling
                     purposes.  Use  this option to prevent guests from circumventing iops limits
                     by sending fewer but larger requests.

              group=g
                     Join a throttling quota group with given name g. All drives that are members
                     of  the  same  group  are accounted for together. Use this option to prevent
                     guests from circumventing  throttling  limits  by  using  many  small  disks
                     instead of a single larger disk.

              By  default,  the  cache.writeback=on  mode  is used. It will report data writes as
              completed as soon as the data is present in the host page cache. This  is  safe  as
              long  as  your  guest OS makes sure to correctly flush disk caches where needed. If
              your guest OS does not handle volatile disk write caches correctly  and  your  host
              crashes or loses power, then the guest may experience data corruption.

              For  such  guests,  you should consider using cache.writeback=off.  This means that
              the host page cache will be used to read and write  data,  but  write  notification
              will  be sent to the guest only after QEMU has made sure to flush each write to the
              disk. Be aware that this has a major impact on performance.

              When using the -snapshot option, unsafe caching is always used.

              Copy-on-read avoids accessing the same  backing  file  sectors  repeatedly  and  is
              useful  when  the  backing  file is over a slow network. By default copy-on-read is
              off.

              Instead of -cdrom you can use:

                 qemu-system-x86_64 -drive file=file,index=2,media=cdrom

              Instead of -hda, -hdb, -hdc, -hdd, you can use:

                 qemu-system-x86_64 -drive file=file,index=0,media=disk
                 qemu-system-x86_64 -drive file=file,index=1,media=disk
                 qemu-system-x86_64 -drive file=file,index=2,media=disk
                 qemu-system-x86_64 -drive file=file,index=3,media=disk

              You can open an image using pre-opened file descriptors from an fd set:

                 qemu-system-x86_64 \
                  -add-fd fd=3,set=2,opaque="rdwr:/path/to/file" \
                  -add-fd fd=4,set=2,opaque="rdonly:/path/to/file" \
                  -drive file=/dev/fdset/2,index=0,media=disk

              You can connect a CDROM to the slave of ide0:

                 qemu-system-x86_64 -drive file=file,if=ide,index=1,media=cdrom

              If you don't specify the "file=" argument, you define an empty drive:

                 qemu-system-x86_64 -drive if=ide,index=1,media=cdrom

              Instead of -fda, -fdb, you can use:

                 qemu-system-x86_64 -drive file=file,index=0,if=floppy
                 qemu-system-x86_64 -drive file=file,index=1,if=floppy

              By default, interface is "ide" and index is automatically incremented:

                 qemu-system-x86_64 -drive file=a -drive file=b"

              is interpreted like:

                 qemu-system-x86_64 -hda a -hdb b

       -mtdblock file
              Use file as on-board Flash memory image.

       -sd file
              Use file as SecureDigital card image.

       -pflash file
              Use file as a parallel flash image.

       -snapshot
              Write to temporary files instead of disk image files. In this case,  the  raw  disk
              image you use is not written back. You can however force the write back by pressing
              C-a s (see the disk images chapter in the System Emulation Users Guide).

       -fsdev                                 local,id=id,path=path,security_model=security_model
       [,writeout=writeout][,readonly=on][,fmode=fmode][,dmode=dmode]
       [,throttling.option=value[,throttling.option=value[,...]]]

       -fsdev proxy,id=id,socket=socket[,writeout=writeout][,readonly=on]

       -fsdev proxy,id=id,sock_fd=sock_fd[,writeout=writeout][,readonly=on]

       -fsdev synth,id=id[,readonly=on]
              Define a new file system device. Valid options are:

              local  Accesses to the filesystem are done by QEMU.

              proxy  Accesses to the filesystem are done by virtfs-proxy-helper(1).

              synth  Synthetic filesystem, only used by QTests.

              id=id  Specifies identifier for this device.

              path=path
                     Specifies the export path for the file system device. Files under this  path
                     will be available to the 9p client on the guest.

              security_model=security_model
                     Specifies  the  security  model  to be used for this export path.  Supported
                     security models are "passthrough", "mapped-xattr", "mapped-file" and "none".
                     In "passthrough" security model, files are stored using the same credentials
                     as they are created on the guest. This requires QEMU  to  run  as  root.  In
                     "mapped-xattr"  security  model,  some of the file attributes like uid, gid,
                     mode bits and link target are stored as file attributes.  For  "mapped-file"
                     these  attributes  are  stored  in  the  hidden  .virtfs_metadata directory.
                     Directories exported by this security model cannot interact with other  unix
                     tools.  "none"  security model is same as passthrough except the sever won't
                     report failures if it fails to set file attributes like ownership.  Security
                     model  is  mandatory  only for local fsdriver.  Other fsdrivers (like proxy)
                     don't take security model as a parameter.

              writeout=writeout
                     This is an optional argument. The only supported value is "immediate".  This
                     means  that  host  page  cache will be used to read and write data but write
                     notification will be sent to the guest only when the data has been  reported
                     as written by the storage subsystem.

              readonly=on
                     Enables  exporting  9p  share  as  a  readonly  mount for guests. By default
                     read-write access is given.

              socket=socket
                     Enables proxy filesystem driver to use passed socket file for  communicating
                     with virtfs-proxy-helper(1).

              sock_fd=sock_fd
                     Enables  proxy  filesystem  driver  to  use  passed  socket  descriptor  for
                     communicating with virtfs-proxy-helper(1). Usually  a  helper  like  libvirt
                     will create socketpair and pass one of the fds as sock_fd.

              fmode=fmode
                     Specifies  the default mode for newly created files on the host.  Works only
                     with security models "mapped-xattr" and "mapped-file".

              dmode=dmode
                     Specifies the default mode for newly created directories on the host.  Works
                     only with security models "mapped-xattr" and "mapped-file".

              throttling.bps-total=b,throttling.bps-read=r,throttling.bps-write=w
                     Specify  bandwidth  throttling  limits  in  bytes per second, either for all
                     request types or for reads or writes only.

              throttling.bps-total-max=bm,bps-read-max=rm,bps-write-max=wm
                     Specify bursts in bytes per second, either for  all  request  types  or  for
                     reads  or  writes  only. Bursts allow the guest I/O to spike above the limit
                     temporarily.

              throttling.iops-total=i,throttling.iops-read=r, throttling.iops-write=w
                     Specify request rate limits in requests per second, either for  all  request
                     types or for reads or writes only.

              throttling.iops-total-max=im,throttling.iops-read-max=irm,
              throttling.iops-write-max=iwm
                     Specify bursts in requests per second, either for all request types  or  for
                     reads  or  writes  only. Bursts allow the guest I/O to spike above the limit
                     temporarily.

              throttling.iops-size=is
                     Let every is bytes of a request count as a new request for  iops  throttling
                     purposes.

              -fsdev option is used along with -device driver "virtio-9p-...".

       -device virtio-9p-type,fsdev=id,mount_tag=mount_tag
              Options for virtio-9p-... driver are:

              type   Specifies  the  variant  to  be  used.  Supported values are "pci", "ccw" or
                     "device", depending on the machine type.

              fsdev=id
                     Specifies the id value specified along with -fsdev option.

              mount_tag=mount_tag
                     Specifies the tag name to be used by the guest to mount this export point.

       -virtfs                                                local,path=path,mount_tag=mount_tag
       ,security_model=security_model[,writeout=writeout][,readonly=on]
       [,fmode=fmode][,dmode=dmode][,multidevs=multidevs]

       -virtfs proxy,socket=socket,mount_tag=mount_tag [,writeout=writeout][,readonly=on]

       -virtfs proxy,sock_fd=sock_fd,mount_tag=mount_tag [,writeout=writeout][,readonly=on]

       -virtfs synth,mount_tag=mount_tag
              Define a new virtual  filesystem  device  and  expose  it  to  the  guest  using  a
              virtio-9p-device (a.k.a. 9pfs), which essentially means that a certain directory on
              host is made directly accessible by guest as a pass-through file  system  by  using
              the  9P network protocol for communication between host and guests, if desired even
              accessible, shared by several guests simultaniously.

              Note that -virtfs is actually just a convenience shortcut for its generalized  form
              -fsdev -device virtio-9p-pci.

              The general form of pass-through file system options are:

              local  Accesses to the filesystem are done by QEMU.

              proxy  Accesses to the filesystem are done by virtfs-proxy-helper(1).

              synth  Synthetic filesystem, only used by QTests.

              id=id  Specifies identifier for the filesystem device

              path=path
                     Specifies  the export path for the file system device. Files under this path
                     will be available to the 9p client on the guest.

              security_model=security_model
                     Specifies the security model to be used for  this  export  path.   Supported
                     security models are "passthrough", "mapped-xattr", "mapped-file" and "none".
                     In "passthrough" security model, files are stored using the same credentials
                     as  they  are  created  on  the guest. This requires QEMU to run as root. In
                     "mapped-xattr" security model, some of the file attributes  like  uid,  gid,
                     mode  bits  and link target are stored as file attributes. For "mapped-file"
                     these attributes  are  stored  in  the  hidden  .virtfs_metadata  directory.
                     Directories  exported by this security model cannot interact with other unix
                     tools. "none" security model is same as passthrough except the  sever  won't
                     report  failures if it fails to set file attributes like ownership. Security
                     model is mandatory only for local fsdriver.  Other  fsdrivers  (like  proxy)
                     don't take security model as a parameter.

              writeout=writeout
                     This  is an optional argument. The only supported value is "immediate". This
                     means that host page cache will be used to read and  write  data  but  write
                     notification  will be sent to the guest only when the data has been reported
                     as written by the storage subsystem.

              readonly=on
                     Enables exporting 9p share as  a  readonly  mount  for  guests.  By  default
                     read-write access is given.

              socket=socket
                     Enables  proxy filesystem driver to use passed socket file for communicating
                     with virtfs-proxy-helper(1). Usually  a  helper  like  libvirt  will  create
                     socketpair and pass one of the fds as sock_fd.

              sock_fd
                     Enables  proxy  filesystem  driver  to  use  passed  'sock_fd' as the socket
                     descriptor for interfacing with virtfs-proxy-helper(1).

              fmode=fmode
                     Specifies the default mode for newly created files on the host.  Works  only
                     with security models "mapped-xattr" and "mapped-file".

              dmode=dmode
                     Specifies  the default mode for newly created directories on the host. Works
                     only with security models "mapped-xattr" and "mapped-file".

              mount_tag=mount_tag
                     Specifies the tag name to be used by the guest to mount this export point.

              multidevs=multidevs
                     Specifies how to deal with multiple devices being shared with a  9p  export.
                     Supported  behaviours  are either "remap", "forbid" or "warn". The latter is
                     the default behaviour on which virtfs 9p  expects  only  one  device  to  be
                     shared  with  the  same  export,  and  if more than one device is shared and
                     accessed via the same 9p export then only a warning message is logged (once)
                     by  qemu  on  host  side.  In order to avoid file ID collisions on guest you
                     should either create a separate virtfs export for each device to  be  shared
                     with  guests (recommended way) or you might use "remap" instead which allows
                     you to share multiple  devices  with  only  one  export  instead,  which  is
                     achieved by remapping the original inode numbers from host to guest in a way
                     that would prevent such collisions. Remapping inodes in such  use  cases  is
                     required  because  the  original  device  IDs from host are never passed and
                     exposed on guest. Instead all files of an export shared with  virtfs  always
                     share the same device id on guest. So two files with identical inode numbers
                     but from actually different devices on host would otherwise cause a file  ID
                     collision  and hence potential misbehaviours on guest. "forbid" on the other
                     hand assumes like "warn" that only one device is shared by the same  export,
                     however  it  will  not  only  log  a warning message but also deny access to
                     additional devices on guest. Note though that "forbid"  does  currently  not
                     block all possible file access operations (e.g. readdir() would still return
                     entries from other devices).

       -iscsi Configure iSCSI session parameters.

   USB convenience options
       -usb   Enable USB emulation on machine types with an on-board USB host controller (if  not
              enabled  by  default).  Note that on-board USB host controllers may not support USB
              3.0. In this case -device qemu-xhci can be used instead on machines with PCI.

       -usbdevice devname
              Add the USB device devname, and enable an on-board USB controller if  possible  and
              necessary  (just like it can be done via -machine usb=on). Note that this option is
              mainly intended for the user's convenience only. More fine-grained control  can  be
              achieved  by  selecting  a  USB  host controller (if necessary) and the desired USB
              device via the -device option instead. For example,  instead  of  using  -usbdevice
              mouse  it is possible to use -device qemu-xhci -device usb-mouse to connect the USB
              mouse to a USB 3.0 controller instead (at least on machines that support PCI and do
              not  have  an  USB  controller  enabled by default yet).  For more details, see the
              chapter about Connecting USB devices in the System Emulation Users Guide.  Possible
              devices for devname are:

              braille
                     Braille device. This will use BrlAPI to display the braille output on a real
                     or fake device  (i.e.  it  also  creates  a  corresponding  braille  chardev
                     automatically beside the usb-braille USB device).

              keyboard
                     Standard USB keyboard. Will override the PS/2 keyboard (if present).

              mouse  Virtual Mouse. This will override the PS/2 mouse emulation when activated.

              tablet Pointer  device  that  uses  absolute coordinates (like a touchscreen). This
                     means QEMU is able to report the mouse position without having to  grab  the
                     mouse. Also overrides the PS/2 mouse emulation when activated.

              wacom-tablet
                     Wacom PenPartner USB tablet.

   Display options
       -display type
              Select  type  of  display  to  use.  This option is a replacement for the old style
              -sdl/-curses/... options. Use -display help to list the  available  display  types.
              Valid values for type are

              spice-app[,gl=on|off]
                     Start   QEMU  as  a  Spice  server  and  launch  the  default  Spice  client
                     application. The Spice server will redirect the  serial  consoles  and  QEMU
                     monitors. (Since 4.0)

              sdl    Display video output via SDL (usually in a separate graphics window; see the
                     SDL documentation for other possibilities).  Valid parameters are:

                     grab-mod=<mods> : Used to select the modifier keys for  toggling  the  mouse
                     grabbing   in   conjunction   with   the  "g"  key.  <mods>  can  be  either
                     lshift-lctrl-lalt or rctrl.

                     alt_grab=on|off : Use Control+Alt+Shift-g to toggle  mouse  grabbing.   This
                     parameter is deprecated - use grab-mod instead.

                     ctrl_grab=on|off  :  Use  Right-Control-g  to  toggle  mouse grabbing.  This
                     parameter is deprecated - use grab-mod instead.

                     gl=on|off|core|es : Use OpenGL for displaying

                     show-cursor=on|off :  Force showing the mouse cursor

                     window-close=on|off : Allow to quit qemu with window close button

              gtk    Display video output in a GTK  window.  This  interface  provides  drop-down
                     menus  and other UI elements to configure and control the VM during runtime.
                     Valid parameters are:

                     full-screen=on|off : Start in fullscreen mode

                     gl=on|off : Use OpenGL for displaying

                     grab-on-hover=on|off : Grab keyboard input on mouse hover

                     show-cursor=on|off :  Force showing the mouse cursor

                     window-close=on|off : Allow to quit qemu with window close button

              curses[,charset=<encoding>]
                     Display video output via curses. For graphics device models which support  a
                     text  mode,  QEMU  can display this output using a curses/ncurses interface.
                     Nothing is displayed when the graphics device is in graphical mode or if the
                     graphics  device does not support a text mode. Generally only the VGA device
                     models support text mode.  The  font  charset  used  by  the  guest  can  be
                     specified  with  the charset option, for example charset=CP850 for IBM CP850
                     encoding. The default is CP437.

              egl-headless[,rendernode=<file>]
                     Offload all OpenGL operations to a  local  DRI  device.  For  any  graphical
                     display, this display needs to be paired with either VNC or SPICE displays.

              vnc=<display>
                     Start a VNC server on display <display>

              none   Do  not  display video output. The guest will still see an emulated graphics
                     card, but its output will not be displayed to the  QEMU  user.  This  option
                     differs from the -nographic option in that it only affects what is done with
                     video output; -nographic also changes the  destination  of  the  serial  and
                     parallel port data.

       -nographic
              Normally,  if  QEMU  is  compiled with graphical window support, it displays output
              such as guest graphics, guest console, and the QEMU monitor in a window. With  this
              option,  you  can totally disable graphical output so that QEMU is a simple command
              line application.  The emulated serial port is redirected on the console and  muxed
              with the monitor (unless redirected elsewhere explicitly). Therefore, you can still
              use QEMU to debug a Linux kernel with a serial console.  Use  C-a  h  for  help  on
              switching between the console and monitor.

       -curses
              Normally,  if  QEMU  is  compiled with graphical window support, it displays output
              such as guest graphics, guest console, and the QEMU monitor in a window. With  this
              option,  QEMU  can  display the VGA output when in text mode using a curses/ncurses
              interface. Nothing is displayed in graphical mode.

       -alt-grab
              Use Ctrl-Alt-Shift to grab mouse (instead of Ctrl-Alt). Note that this also affects
              the  special  keys  (for  fullscreen,  monitor-mode switching, etc). This option is
              deprecated - please use -display sdl,grab-mod=lshift-lctrl-lalt instead.

       -ctrl-grab
              Use Right-Ctrl to grab mouse (instead of Ctrl-Alt). Note that this also affects the
              special  keys  (for  fullscreen,  monitor-mode  switching,  etc).  This  option  is
              deprecated - please use -display sdl,grab-mod=rctrl instead.

       -no-quit
              Disable window close capability (SDL and GTK  only).  This  option  is  deprecated,
              please use -display ...,window-close=off instead.

       -sdl   Enable SDL.

       -spice option[,option[,...]]
              Enable the spice remote desktop protocol. Valid options are

              port=<nr>
                     Set the TCP port spice is listening on for plaintext channels.

              addr=<addr>
                     Set the IP address spice is listening on. Default is any address.

              ipv4=on|off; ipv6=on|off; unix=on|off
                     Force using the specified IP version.

              password=<string>
                     Set the password you need to authenticate.

                     This  option  is  deprecated  and  insecure  because  it leaves the password
                     visible in the process listing. Use password-secret instead.

              password-secret=<secret-id>
                     Set the ID of  the  secret  object  containing  the  password  you  need  to
                     authenticate.

              sasl=on|off
                     Require  that the client use SASL to authenticate with the spice.  The exact
                     choice of authentication method used is controlled from the system /  user's
                     SASL  configuration  file for the 'qemu' service. This is typically found in
                     /etc/sasl2/qemu.conf.  If  running  QEMU  as  an   unprivileged   user,   an
                     environment  variable SASL_CONF_PATH can be used to make it search alternate
                     locations for the service config. While some  SASL  auth  methods  can  also
                     provide  data  encryption (eg GSSAPI), it is recommended that SASL always be
                     combined with the 'tls' and 'x509' settings to enable use of SSL and  server
                     certificates.  This  ensures  a  data  encryption  preventing  compromise of
                     authentication credentials.

              disable-ticketing=on|off
                     Allow client connects without authentication.

              disable-copy-paste=on|off
                     Disable copy paste between the client and the guest.

              disable-agent-file-xfer=on|off
                     Disable spice-vdagent based file-xfer between the client and the guest.

              tls-port=<nr>
                     Set the TCP port spice is listening on for encrypted channels.

              x509-dir=<dir>
                     Set  the   x509   file   directory.   Expects   same   filenames   as   -vnc
                     $display,x509=$dir

              x509-key-file=<file>;        x509-key-password=<file>;       x509-cert-file=<file>;
              x509-cacert-file=<file>; x509-dh-key-file=<file>
                     The x509 file names can also be configured individually.

              tls-ciphers=<list>
                     Specify which ciphers to use.

              tls-channel=[main|display|cursor|inputs|record|playback];
              plaintext-channel=[main|display|cursor|inputs|record|playback]
                     Force  specific  channel  to  be  used  with  or without TLS encryption. The
                     options can be specified multiple times to configure multiple channels.  The
                     special  name  "default"  can  be used to set the default mode. For channels
                     which are not explicitly forced into one mode the spice client is allowed to
                     pick tls/plaintext as he pleases.

              image-compression=[auto_glz|auto_lz|quic|glz|lz|off]
                     Configure image compression (lossless). Default is auto_glz.

              jpeg-wan-compression=[auto|never|always];
              zlib-glz-wan-compression=[auto|never|always]
                     Configure wan image compression (lossy for slow links). Default is auto.

              streaming-video=[off|all|filter]
                     Configure video stream detection. Default is off.

              agent-mouse=[on|off]
                     Enable/disable passing mouse events via vdagent. Default is on.

              playback-compression=[on|off]
                     Enable/disable audio stream compression (using celt 0.5.1).  Default is on.

              seamless-migration=[on|off]
                     Enable/disable spice seamless migration. Default is off.

              gl=[on|off]
                     Enable/disable OpenGL context. Default is off.

              rendernode=<file>
                     DRM render node for OpenGL rendering. If not specified,  it  will  pick  the
                     first available. (Since 2.9)

       -portrait
              Rotate graphical output 90 deg left (only PXA LCD).

       -rotate deg
              Rotate graphical output some deg left (only PXA LCD).

       -vga type
              Select type of VGA card to emulate. Valid values for type are

              cirrus Cirrus  Logic  GD5446 Video card. All Windows versions starting from Windows
                     95 should recognize and use this graphic card. For optimal performances, use
                     16  bit color depth in the guest and the host OS. (This card was the default
                     before QEMU 2.2)

              std    Standard VGA card with Bochs VBE extensions. If your guest OS  supports  the
                     VESA  2.0  VBE  extensions  (e.g.  Windows  XP)  and if you want to use high
                     resolution modes (>= 1280x1024x16) then you should use  this  option.  (This
                     card is the default since QEMU 2.2)

              vmware VMWare  SVGA-II  compatible  adapter. Use it if you have sufficiently recent
                     XFree86/XOrg server or Windows guest with a driver for this card.

              qxl    QXL paravirtual graphic card. It is VGA compatible (including VESA  2.0  VBE
                     support).  Works  best  with qxl guest drivers installed though. Recommended
                     choice when using the spice protocol.

              tcx    (sun4m only) Sun TCX framebuffer. This is the default framebuffer for  sun4m
                     machines  and  offers  both  8-bit  and  24-bit  colour  depths  at  a fixed
                     resolution of 1024x768.

              cg3    (sun4m only) Sun cgthree framebuffer. This is a simple 8-bit framebuffer for
                     sun4m  machines  available  in  both  1024x768 (OpenBIOS) and 1152x900 (OBP)
                     resolutions aimed at people wishing to run older Solaris versions.

              virtio Virtio VGA card.

              none   Disable VGA card.

       -full-screen
              Start in full screen.

       -g widthxheight[xdepth]
              Set the initial graphical resolution and depth (PPC, SPARC only).

              For PPC the default is 800x600x32.

              For SPARC with the TCX graphics device, the default is 1024x768x8 with  the  option
              of  1024x768x24.  For  cgthree,  the  default  is  1024x768x8  with  the  option of
              1152x900x8 for people who wish to use OBP.

       -vnc display[,option[,option[,...]]]
              Normally, if QEMU is compiled with graphical window  support,  it  displays  output
              such  as guest graphics, guest console, and the QEMU monitor in a window. With this
              option, you can have QEMU listen on  VNC  display  display  and  redirect  the  VGA
              display  over  the  VNC  session. It is very useful to enable the usb tablet device
              when using this option (option -device usb-tablet). When using the VNC display, you
              must  use  the  -k parameter to set the keyboard layout if you are not using en-us.
              Valid syntax for the display is

              to=L   With this option, QEMU will try  next  available  VNC  displays,  until  the
                     number  L,  if  the origianlly defined "-vnc display" is not available, e.g.
                     port 5900+display is already used by another application. By default, to=0.

              host:d TCP connections will only be allowed from host on display d.  By  convention
                     the  TCP  port  is 5900+d. Optionally, host can be omitted in which case the
                     server will accept connections from any host.

              unix:path
                     Connections will be allowed over UNIX  domain  sockets  where  path  is  the
                     location of a unix socket to listen for connections on.

              none   VNC  is  initialized but not started. The monitor change command can be used
                     to later start the VNC server.

              Following the display value there may be one or  more  option  flags  separated  by
              commas. Valid options are

              reverse=on|off
                     Connect to a listening VNC client via a "reverse" connection.  The client is
                     specified   by   the    display.    For    reverse    network    connections
                     (host:d,``reverse``),  the  d  argument  is a TCP port number, not a display
                     number.

              websocket=on|off
                     Opens  an  additional  TCP  listening  port  dedicated  to   VNC   Websocket
                     connections.  If  a  bare  websocket  option is given, the Websocket port is
                     5700+display.  An  alternative  port  can  be  specified  with  the   syntax
                     websocket=port.

                     If  host is specified connections will only be allowed from this host. It is
                     possible to control the websocket listen address  independently,  using  the
                     syntax websocket=host:port.

                     If  no  TLS  credentials  are  provided,  the  websocket  connection runs in
                     unencrypted mode. If TLS credentials are provided, the websocket  connection
                     requires encrypted client connections.

              password=on|off
                     Require that password based authentication is used for client connections.

                     The  password  must  be set separately using the set_password command in the
                     QEMU monitor. The syntax to change your password is: set_password <protocol>
                     <password> where <protocol> could be either "vnc" or "spice".

                     If  you  would like to change <protocol> password expiration, you should use
                     expire_password <protocol> <expiration-time> where expiration time could  be
                     one  of  the  following  options:  now,  never,  +seconds  or  UNIX  time of
                     expiration, e.g. +60 to make password expire in 60 seconds, or 1335196800 to
                     make  password  expire on "Mon Apr 23 12:00:00 EDT 2012" (UNIX time for this
                     date and time).

                     You can also use keywords "now" or "never" for the expiration time to  allow
                     <protocol> password to expire immediately or never expire.

              password-secret=<secret-id>
                     Require  that  password based authentication is used for client connections,
                     using the password provided by the secret object identified by secret-id.

              tls-creds=ID
                     Provides the ID of a set of TLS credentials to use to secure the VNC server.
                     They  will  apply  to  both  the  normal VNC server socket and the websocket
                     socket (if enabled). Setting TLS  credentials  will  cause  the  VNC  server
                     socket  to  enable  the VeNCrypt auth mechanism. The credentials should have
                     been previously created using the -object tls-creds argument.

              tls-authz=ID
                     Provides the ID  of  the  QAuthZ  authorization  object  against  which  the
                     client's  x509  distinguished  name  will  validated.  This  object  is only
                     resolved at time of use, so can be deleted and recreated on  the  fly  while
                     the VNC server is active. If missing, it will default to denying access.

              sasl=on|off
                     Require  that  the  client use SASL to authenticate with the VNC server. The
                     exact choice of authentication method used is controlled from the  system  /
                     user's  SASL  configuration  file  for the 'qemu' service. This is typically
                     found in /etc/sasl2/qemu.conf. If running QEMU as an unprivileged  user,  an
                     environment  variable SASL_CONF_PATH can be used to make it search alternate
                     locations for the service config. While some  SASL  auth  methods  can  also
                     provide  data  encryption (eg GSSAPI), it is recommended that SASL always be
                     combined with the 'tls' and 'x509' settings to enable use of SSL and  server
                     certificates.  This  ensures  a  data  encryption  preventing  compromise of
                     authentication credentials. See the  VNC  security  section  in  the  System
                     Emulation Users Guide for details on using SASL authentication.

              sasl-authz=ID
                     Provides  the  ID  of  the  QAuthZ  authorization  object  against which the
                     client's SASL username will validated. This object is only resolved at  time
                     of  use,  so can be deleted and recreated on the fly while the VNC server is
                     active. If missing, it will default to denying access.

              acl=on|off
                     Legacy method  for  enabling  authorization  of  clients  against  the  x509
                     distinguished  name  and  SASL  username.  It results in the creation of two
                     authz-list objects with IDs of vnc.username and vnc.x509dname. The rules for
                     these objects must be configured with the HMP ACL commands.

                     This  option  is deprecated and should no longer be used. The new sasl-authz
                     and tls-authz options are a replacement.

              lossy=on|off
                     Enable lossy compression methods (gradient, JPEG, ...). If  this  option  is
                     set,  VNC  client  may  receive  lossy  framebuffer updates depending on its
                     encoding settings. Enabling this option can save a lot of bandwidth  at  the
                     expense of quality.

              non-adaptive=on|off
                     Disable  adaptive  encodings.  Adaptive encodings are enabled by default. An
                     adaptive encoding will try to detect frequently updated screen regions,  and
                     send  updates  in these regions using a lossy encoding (like JPEG). This can
                     be really helpful to save bandwidth when playing videos. Disabling  adaptive
                     encodings restores the original static behavior of encodings like Tight.

              share=[allow-exclusive|force-shared|ignore]
                     Set  display  sharing  policy.  'allow-exclusive'  allows clients to ask for
                     exclusive access. As suggested by  the  rfb  spec  this  is  implemented  by
                     dropping other connections. Connecting multiple clients in parallel requires
                     all clients asking for a shared session (vncviewer: -shared switch). This is
                     the  default.   'force-shared'  disables exclusive client access. Useful for
                     shared desktop sessions, where you don't  want  someone  forgetting  specify
                     -shared  disconnect  everybody  else. 'ignore' completely ignores the shared
                     flag and allows everybody connect unconditionally. Doesn't  conform  to  the
                     rfb spec but is traditional QEMU behavior.

              key-delay-ms
                     Set keyboard delay, for key down and key up events, in milliseconds. Default
                     is 10. Keyboards are low-bandwidth devices, so this slowdown  can  help  the
                     device  and guest to keep up and not lose events in case events are arriving
                     in bulk.  Possible causes for the latter are flaky network  connections,  or
                     scripts for automated testing.

              audiodev=audiodev
                     Use  the specified audiodev when the VNC client requests audio transmission.
                     When not using an -audiodev argument, this option must be omitted, otherwise
                     is must be present and specify a valid audiodev.

              power-control=on|off
                     Permit  the  remote  client to issue shutdown, reboot or reset power control
                     requests.

   i386 target only
       -win2k-hack
              Use it when installing Windows 2000 to avoid a disk full bug. After Windows 2000 is
              installed,  you  no  longer  need  this  option  (this  option  slows  down the IDE
              transfers).

       -no-fd-bootchk
              Disable boot signature checking for floppy disks in BIOS. May  be  needed  to  boot
              from old floppy disks.

       -no-acpi
              Disable  ACPI (Advanced Configuration and Power Interface) support.  Use it if your
              guest OS complains about ACPI problems (PC target machine only).

       -no-hpet
              Disable HPET support.

       -acpitable                   [sig=str][,rev=n][,oem_id=str][,oem_table_id=str][,oem_rev=n]
       [,asl_compiler_id=str][,asl_compiler_rev=n][,data=file1[:file2]...]
              Add  ACPI  table with specified header fields and context from specified files. For
              file=, take whole ACPI table from the specified files, including all  ACPI  headers
              (possible  overridden  by other options). For data=, only data portion of the table
              is used, all header information is specified in the command line. If a  SLIC  table
              is  supplied  to QEMU, then the SLIC's oem_id and oem_table_id fields will override
              the same in the RSDT and the FADT (a.k.a.  FACP), in  order  to  ensure  the  field
              matches required by the Microsoft SLIC spec and the ACPI spec.

       -smbios file=binary
              Load SMBIOS entry from binary file.

       -smbios type=0[,vendor=str][,version=str][,date=str][,release=%d.%d][,uefi=on|off]
              Specify SMBIOS type 0 fields

       -smbios
       type=1[,manufacturer=str][,product=str][,version=str][,serial=str][,uuid=uuid][,sku=str][,family=str]
              Specify SMBIOS type 1 fields

       -smbios
       type=2[,manufacturer=str][,product=str][,version=str][,serial=str][,asset=str][,location=str]
              Specify SMBIOS type 2 fields

       -smbios type=3[,manufacturer=str][,version=str][,serial=str][,asset=str][,sku=str]
              Specify SMBIOS type 3 fields

       -smbios
       type=4[,sock_pfx=str][,manufacturer=str][,version=str][,serial=str][,asset=str][,part=str]
              Specify SMBIOS type 4 fields

       -smbios type=11[,value=str][,path=filename]
              Specify SMBIOS type 11 fields

              This argument can be repeated multiple times, and values are  added  in  the  order
              they  are parsed.  Applications intending to use OEM strings data are encouraged to
              use their application name as a prefix  for  the  value  string.  This  facilitates
              passing information for multiple applications concurrently.

              The  value=str  syntax  provides  the  string  data inline, while the path=filename
              syntax loads data from a file on disk. Note that  the  file  is  not  permitted  to
              contain any NUL bytes.

              Both the value and path options can be repeated multiple times and will be added to
              the SMBIOS table in the order in which they appear.

              Note that on the x86 architecture, the total size of all SMBIOS tables  is  limited
              to 65535 bytes. Thus the OEM strings data is not suitable for passing large amounts
              of data into the guest. Instead it should be used as  a  indicator  to  inform  the
              guest  where  to locate the real data set, for example, by specifying the serial ID
              of a block device.

              An example passing three strings is

                 -smbios type=11,value=cloud-init:ds=nocloud-net;s=http://10.10.0.1:8000/,\
                                 value=anaconda:method=http://dl.fedoraproject.org/pub/fedora/linux/releases/25/x86_64/os,\
                                 path=/some/file/with/oemstringsdata.txt

              In the guest OS this is visible with the dmidecode command

                     $ dmidecode -t 11
                     Handle 0x0E00, DMI type 11, 5 bytes
                     OEM Strings
                          String 1: cloud-init:ds=nocloud-net;s=http://10.10.0.1:8000/
                          String 2: anaconda:method=http://dl.fedoraproject.org/pub/fedora/linux/releases/25/x86_64/os
                          String 3: myapp:some extra data

       -smbios
       type=17[,loc_pfx=str][,bank=str][,manufacturer=str][,serial=str][,asset=str][,part=str][,speed=%d]
              Specify SMBIOS type 17 fields

       -smbios type=41[,designation=str][,kind=str][,instance=%d][,pcidev=str]
              Specify SMBIOS type 41 fields

              This argument can be repeated multiple times.  Its main use  is  to  allow  network
              interfaces  be  created as enoX on Linux, with X being the instance number, instead
              of the name depending on the interface position on the PCI bus.

              Here is an example of use:

                 -netdev user,id=internet \
                 -device virtio-net-pci,mac=50:54:00:00:00:42,netdev=internet,id=internet-dev \
                 -smbios type=41,designation='Onboard LAN',instance=1,kind=ethernet,pcidev=internet-dev

              In the guest OS, the device should then appear as eno1:

              ..parsed-literal:

                 $ ip -brief l
                 lo               UNKNOWN        00:00:00:00:00:00 <LOOPBACK,UP,LOWER_UP>
                 eno1             UP             50:54:00:00:00:42 <BROADCAST,MULTICAST,UP,LOWER_UP>

              Currently, the PCI device has to be attached to the root bus.

   Network options
       -nic [tap|bridge|user|l2tpv3|vde|netmap|vhost-user|socket][,...][,mac=macaddr][,model=mn]
              This option is a shortcut for configuring both the  on-board  (default)  guest  NIC
              hardware  and the host network backend in one go.  The host backend options are the
              same as with the corresponding -netdev options below. The guest NIC  model  can  be
              set  with  model=modelname.  Use model=help to list the available device types. The
              hardware MAC address can be set with mac=macaddr.

              The following two example do exactly the same, to show how  -nic  can  be  used  to
              shorten the command line length:

                 qemu-system-x86_64 -netdev user,id=n1,ipv6=off -device e1000,netdev=n1,mac=52:54:98:76:54:32
                 qemu-system-x86_64 -nic user,ipv6=off,model=e1000,mac=52:54:98:76:54:32

       -nic none
              Indicate  that  no network devices should be configured. It is used to override the
              default configuration (default NIC with  "user"  host  network  backend)  which  is
              activated if no other networking options are provided.

       -netdev user,id=id[,option][,option][,...]
              Configure  user mode host network backend which requires no administrator privilege
              to run. Valid options are:

              id=id  Assign symbolic name for use in monitor commands.

              ipv4=on|off and ipv6=on|off
                     Specify that either IPv4 or IPv6 must be enabled. If  neither  is  specified
                     both protocols are enabled.

              net=addr[/mask]
                     Set  IP  network address the guest will see. Optionally specify the netmask,
                     either in the form a.b.c.d or as number of valid top-most bits.  Default  is
                     10.0.2.0/24.

              host=addr
                     Specify  the guest-visible address of the host. Default is the 2nd IP in the
                     guest network, i.e. x.x.x.2.

              ipv6-net=addr[/int]
                     Set IPv6 network address the guest will  see  (default  is  fec0::/64).  The
                     network  prefix is given in the usual hexadecimal IPv6 address notation. The
                     prefix size is optional, and is given as the number of valid  top-most  bits
                     (default is 64).

              ipv6-host=addr
                     Specify  the guest-visible IPv6 address of the host. Default is the 2nd IPv6
                     in the guest network, i.e. xxxx::2.

              restrict=on|off
                     If this option is enabled, the guest will be isolated, i.e. it will  not  be
                     able  to  contact  the  host and no guest IP packets will be routed over the
                     host to the  outside.  This  option  does  not  affect  any  explicitly  set
                     forwarding rules.

              hostname=name
                     Specifies the client hostname reported by the built-in DHCP server.

              dhcpstart=addr
                     Specify the first of the 16 IPs the built-in DHCP server can assign. Default
                     is the 15th to 31st IP in the guest network, i.e. x.x.x.15 to x.x.x.31.

              dns=addr
                     Specify the guest-visible address of the  virtual  nameserver.  The  address
                     must  be different from the host address. Default is the 3rd IP in the guest
                     network, i.e. x.x.x.3.

              ipv6-dns=addr
                     Specify the guest-visible  address  of  the  IPv6  virtual  nameserver.  The
                     address  must  be different from the host address.  Default is the 3rd IP in
                     the guest network, i.e. xxxx::3.

              dnssearch=domain
                     Provides an entry for the domain-search  list  sent  by  the  built-in  DHCP
                     server.  More  than  one domain suffix can be transmitted by specifying this
                     option  multiple  times.  If  supported,  this  will  cause  the  guest   to
                     automatically  try  to  append  the given domain suffix(es) in case a domain
                     name can not be resolved.

                     Example:

                        qemu-system-x86_64 -nic user,dnssearch=mgmt.example.org,dnssearch=example.org

              domainname=domain
                     Specifies the client domain name reported by the built-in DHCP server.

              tftp=dir
                     When using the user mode network stack, activate a built-in TFTP server. The
                     files  in  dir will be exposed as the root of a TFTP server. The TFTP client
                     on the guest must be configured in binary mode (use the command bin  of  the
                     Unix TFTP client).

              tftp-server-name=name
                     In  BOOTP  reply,  broadcast  name as the "TFTP server name" (RFC2132 option
                     66).  This  can  be  used  to  advise  the  guest  to  load  boot  files  or
                     configurations from a different server than the host address.

              bootfile=file
                     When  using  the  user  mode  network  stack,  broadcast  file  as the BOOTP
                     filename. In conjunction with tftp, this can be used to network boot a guest
                     from a local directory.

                     Example (using pxelinux):

                        qemu-system-x86_64 -hda linux.img -boot n -device e1000,netdev=n1 \
                            -netdev user,id=n1,tftp=/path/to/tftp/files,bootfile=/pxelinux.0

              smb=dir[,smbserver=addr]
                     When  using  the  user mode network stack, activate a built-in SMB server so
                     that Windows OSes can access to the host files in dir transparently. The  IP
                     address  of  the SMB server can be set to addr. By default the 4th IP in the
                     guest network is used, i.e. x.x.x.4.

                     In the guest Windows OS, the line:

                        10.0.2.4 smbserver

                     must be  added  in  the  file  C:\WINDOWS\LMHOSTS  (for  windows  9x/Me)  or
                     C:\WINNT\SYSTEM32\DRIVERS\ETC\LMHOSTS (Windows NT/2000).

                     Then dir can be accessed in \\smbserver\qemu.

                     Note that a SAMBA server must be installed on the host OS.

              hostfwd=[tcp|udp]:[hostaddr]:hostport-[guestaddr]:guestport
                     Redirect  incoming  TCP  or UDP connections to the host port hostport to the
                     guest IP address guestaddr on guest port  guestport.  If  guestaddr  is  not
                     specified,  its  value  is  x.x.x.15  (default  first  address  given by the
                     built-in DHCP server). By specifying hostaddr, the rule can be  bound  to  a
                     specific  host  interface.  If  no connection type is set, TCP is used. This
                     option can be given multiple times.

                     For example, to redirect host X11 connection from screen 1 to  guest  screen
                     0, use the following:

                        # on the host
                        qemu-system-x86_64 -nic user,hostfwd=tcp:127.0.0.1:6001-:6000
                        # this host xterm should open in the guest X11 server
                        xterm -display :1

                     To  redirect  telnet  connections  from host port 5555 to telnet port on the
                     guest, use the following:

                        # on the host
                        qemu-system-x86_64 -nic user,hostfwd=tcp::5555-:23
                        telnet localhost 5555

                     Then when you use on the host telnet localhost  5555,  you  connect  to  the
                     guest telnet server.

              guestfwd=[tcp]:server:port-dev; guestfwd=[tcp]:server:port-cmd:command
                     Forward  guest  TCP connections to the IP address server on port port to the
                     character device dev or to a program  executed  by  cmd:command  which  gets
                     spawned for each connection. This option can be given multiple times.

                     You  can  either  use  a  chardev directly and have that one used throughout
                     QEMU's lifetime, like in the following example:

                        # open 10.10.1.1:4321 on bootup, connect 10.0.2.100:1234 to it whenever
                        # the guest accesses it
                        qemu-system-x86_64 -nic user,guestfwd=tcp:10.0.2.100:1234-tcp:10.10.1.1:4321

                     Or you can execute a command on every  TCP  connection  established  by  the
                     guest,  so  that  QEMU  behaves similar to an inetd process for that virtual
                     server:

                        # call "netcat 10.10.1.1 4321" on every TCP connection to 10.0.2.100:1234
                        # and connect the TCP stream to its stdin/stdout
                        qemu-system-x86_64 -nic  'user,id=n1,guestfwd=tcp:10.0.2.100:1234-cmd:netcat 10.10.1.1 4321'

       -netdev
       tap,id=id[,fd=h][,ifname=name][,script=file][,downscript=dfile][,br=bridge][,helper=helper]
              Configure a host TAP network backend with ID id.

              Use the network script file to  configure  it  and  the  network  script  dfile  to
              deconfigure  it.  If  name  is not provided, the OS automatically provides one. The
              default  network  configure  script  is  /etc/qemu-ifup  and  the  default  network
              deconfigure  script  is /etc/qemu-ifdown. Use script=no or downscript=no to disable
              script execution.

              If running QEMU as an unprivileged user, use the network helper  to  configure  the
              TAP  interface  and attach it to the bridge.  The default network helper executable
              is /path/to/qemu-bridge-helper and the default bridge device is br0.

              fd=h can be used to specify the handle of an already opened host TAP interface.

              Examples:

                 #launch a QEMU instance with the default network script
                 qemu-system-x86_64 linux.img -nic tap

                 #launch a QEMU instance with two NICs, each one connected
                 #to a TAP device
                 qemu-system-x86_64 linux.img \
                         -netdev tap,id=nd0,ifname=tap0 -device e1000,netdev=nd0 \
                         -netdev tap,id=nd1,ifname=tap1 -device rtl8139,netdev=nd1

                 #launch a QEMU instance with the default network helper to
                 #connect a TAP device to bridge br0
                 qemu-system-x86_64 linux.img -device virtio-net-pci,netdev=n1 \
                         -netdev tap,id=n1,"helper=/path/to/qemu-bridge-helper"

       -netdev bridge,id=id[,br=bridge][,helper=helper]
              Connect a host TAP network interface to a host bridge device.

              Use the network helper helper to configure the TAP interface and attach it  to  the
              bridge.  The  default  network helper executable is /path/to/qemu-bridge-helper and
              the default bridge device is br0.

              Examples:

                 #launch a QEMU instance with the default network helper to
                 #connect a TAP device to bridge br0
                 qemu-system-x86_64 linux.img -netdev bridge,id=n1 -device virtio-net,netdev=n1

                 #launch a QEMU instance with the default network helper to
                 #connect a TAP device to bridge qemubr0
                 qemu-system-x86_64 linux.img -netdev bridge,br=qemubr0,id=n1 -device virtio-net,netdev=n1

       -netdev socket,id=id[,fd=h][,listen=[host]:port][,connect=host:port]
              This host network backend can be used to connect the  guest's  network  to  another
              QEMU  virtual  machine  using a TCP socket connection. If listen is specified, QEMU
              waits for incoming connections on port (host  is  optional).  connect  is  used  to
              connect to another QEMU instance using the listen option. fd=h specifies an already
              opened TCP socket.

              Example:

                 # launch a first QEMU instance
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n1,mac=52:54:00:12:34:56 \
                                  -netdev socket,id=n1,listen=:1234
                 # connect the network of this instance to the network of the first instance
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n2,mac=52:54:00:12:34:57 \
                                  -netdev socket,id=n2,connect=127.0.0.1:1234

       -netdev socket,id=id[,fd=h][,mcast=maddr:port[,localaddr=addr]]
              Configure a socket host network backend to share the guest's network  traffic  with
              another  QEMU  virtual  machines using a UDP multicast socket, effectively making a
              bus for every QEMU with same multicast address maddr and port. NOTES:

              1. Several QEMU can be running on different hosts  and  share  same  bus  (assuming
                 correct multicast setup for these hosts).

              2. mcast  support  is  compatible  with  User Mode Linux (argument ethN=mcast), see
                 http://user-mode-linux.sf.net.

              3. Use fd=h to specify an already opened UDP multicast socket.

              Example:

                 # launch one QEMU instance
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n1,mac=52:54:00:12:34:56 \
                                  -netdev socket,id=n1,mcast=230.0.0.1:1234
                 # launch another QEMU instance on same "bus"
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n2,mac=52:54:00:12:34:57 \
                                  -netdev socket,id=n2,mcast=230.0.0.1:1234
                 # launch yet another QEMU instance on same "bus"
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n3,mac=52:54:00:12:34:58 \
                                  -netdev socket,id=n3,mcast=230.0.0.1:1234

              Example (User Mode Linux compat.):

                 # launch QEMU instance (note mcast address selected is UML's default)
                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n1,mac=52:54:00:12:34:56 \
                                  -netdev socket,id=n1,mcast=239.192.168.1:1102
                 # launch UML
                 /path/to/linux ubd0=/path/to/root_fs eth0=mcast

              Example (send packets from host's 1.2.3.4):

                 qemu-system-x86_64 linux.img \
                                  -device e1000,netdev=n1,mac=52:54:00:12:34:56 \
                                  -netdev socket,id=n1,mcast=239.192.168.1:1102,localaddr=1.2.3.4

       -netdev
       l2tpv3,id=id,src=srcaddr,dst=dstaddr[,srcport=srcport][,dstport=dstport],txsession=txsession[,rxsession=rxsession][,ipv6=on|off][,udp=on|off][,cookie64][,counter][,pincounter][,txcookie=txcookie][,rxcookie=rxcookie][,offset=offset]
              Configure a L2TPv3 pseudowire host network backend. L2TPv3 (RFC3931) is  a  popular
              protocol to transport Ethernet (and other Layer 2) data frames between two systems.
              It is present in  routers,  firewalls  and  the  Linux  kernel  (from  version  3.3
              onwards).

              This  transport  allows  a  VM  to  communicate  to  another VM, router or firewall
              directly.

              src=srcaddr
                     source address (mandatory)

              dst=dstaddr
                     destination address (mandatory)

              udp    select udp encapsulation (default is ip).

              srcport=srcport
                     source udp port.

              dstport=dstport
                     destination udp port.

              ipv6   force v6, otherwise defaults to v4.

              rxcookie=rxcookie; txcookie=txcookie
                     Cookies are a weak form of security  in  the  l2tpv3  specification.   Their
                     function is mostly to prevent misconfiguration. By default they are 32 bit.

              cookie64
                     Set cookie size to 64 bit instead of the default 32

              counter=off
                     Force     a     'cut-down'     L2TPv3     with     no    counter    as    in
                     draft-mkonstan-l2tpext-keyed-ipv6-tunnel-00

              pincounter=on
                     Work around broken counter handling in peer. This may also help on  networks
                     which have packet reorder.

              offset=offset
                     Add an extra offset between header and data

              For example, to attach a VM running on host 4.3.2.1 via L2TPv3 to the bridge br-lan
              on the remote Linux host 1.2.3.4:

                 # Setup tunnel on linux host using raw ip as encapsulation
                 # on 1.2.3.4
                 ip l2tp add tunnel remote 4.3.2.1 local 1.2.3.4 tunnel_id 1 peer_tunnel_id 1 \
                     encap udp udp_sport 16384 udp_dport 16384
                 ip l2tp add session tunnel_id 1 name vmtunnel0 session_id \
                     0xFFFFFFFF peer_session_id 0xFFFFFFFF
                 ifconfig vmtunnel0 mtu 1500
                 ifconfig vmtunnel0 up
                 brctl addif br-lan vmtunnel0

                 # on 4.3.2.1
                 # launch QEMU instance - if your network has reorder or is very lossy add ,pincounter

                 qemu-system-x86_64 linux.img -device e1000,netdev=n1 \
                     -netdev l2tpv3,id=n1,src=4.2.3.1,dst=1.2.3.4,udp,srcport=16384,dstport=16384,rxsession=0xffffffff,txsession=0xffffffff,counter

       -netdev vde,id=id[,sock=socketpath][,port=n][,group=groupname][,mode=octalmode]
              Configure VDE backend to connect to PORT n of a vde  switch  running  on  host  and
              listening  for  incoming  connections  on  socketpath. Use GROUP groupname and MODE
              octalmode to change default ownership and permissions for communication port.  This
              option is only available if QEMU has been compiled with vde support enabled.

              Example:

                 # launch vde switch
                 vde_switch -F -sock /tmp/myswitch
                 # launch QEMU instance
                 qemu-system-x86_64 linux.img -nic vde,sock=/tmp/myswitch

       -netdev vhost-user,chardev=id[,vhostforce=on|off][,queues=n]
              Establish a vhost-user netdev, backed by a chardev id. The chardev should be a unix
              domain socket backed one. The vhost-user uses a specifically  defined  protocol  to
              pass  vhost  ioctl  replacement  messages to an application on the other end of the
              socket. On non-MSIX  guests,  the  feature  can  be  forced  with  vhostforce.  Use
              'queues=n' to specify the number of queues to be created for multiqueue vhost-user.

              Example:

                 qemu -m 512 -object memory-backend-file,id=mem,size=512M,mem-path=/hugetlbfs,share=on \
                      -numa node,memdev=mem \
                      -chardev socket,id=chr0,path=/path/to/socket \
                      -netdev type=vhost-user,id=net0,chardev=chr0 \
                      -device virtio-net-pci,netdev=net0

       -netdev vhost-vdpa,vhostdev=/path/to/dev
              Establish a vhost-vdpa netdev.

              vDPA  device  is  a  device  that  uses  a  datapath which complies with the virtio
              specifications with a vendor specific control  path.   vDPA  devices  can  be  both
              physically located on the hardware or emulated by software.

       -netdev hubport,id=id,hubid=hubid[,netdev=nd]
              Create a hub port on the emulated hub with ID hubid.

              The  hubport  netdev  lets  you  connect  a NIC to a QEMU emulated hub instead of a
              single netdev. Alternatively, you can also connect the hubport  to  another  netdev
              with ID nd by using the netdev=nd option.

       -net nic[,netdev=nd][,macaddr=mac][,model=type] [,name=name][,addr=addr][,vectors=v]
              Legacy  option  to  configure  or  create  an on-board (or machine default) Network
              Interface Card(NIC) and connect it either to the emulated hub with ID 0  (i.e.  the
              default hub), or to the netdev nd.  If model is omitted, then the default NIC model
              associated with the machine type is used. Note  that  the  default  NIC  model  may
              change  in  future  QEMU  releases, so it is highly recommended to always specify a
              model. Optionally, the MAC address can be changed to mac, the device address set to
              addr  (PCI  cards  only),  and  a name can be assigned for use in monitor commands.
              Optionally, for PCI cards, you can specify the number v of MSI-X vectors  that  the
              card  should  have;  this  option currently only affects virtio cards; set v = 0 to
              disable MSI-X. If no -net option is specified, a single NIC is  created.  QEMU  can
              emulate  several  different  models of network card.  Use -net nic,model=help for a
              list of available devices for your target.

       -net user|tap|bridge|socket|l2tpv3|vde[,...][,name=name]
              Configure a host network backend  (with  the  options  corresponding  to  the  same
              -netdev option) and connect it to the emulated hub 0 (the default hub). Use name to
              specify the name of the hub port.

   Character device options
       The general form of a character device option is:

       -chardev backend,id=id[,mux=on|off][,options]
              Backend is one of: null, socket, udp, msmouse, vc, ringbuf,  file,  pipe,  console,
              serial,  pty,  stdio,  braille,  tty,  parallel,  parport, spicevmc, spiceport. The
              specific backend will determine the applicable options.

              Use -chardev help to print all available chardev backend types.

              All devices must have an id, which can be any string up to 127 characters long.  It
              is used to uniquely identify this device in other command line directives.

              A character device may be used in multiplexing mode by multiple front-ends. Specify
              mux=on to enable this mode. A multiplexer is a "1:N" device, and here the  "1"  end
              is  your  specified  chardev  backend, and the "N" end is the various parts of QEMU
              that can talk to a chardev. If you create a chardev with id=myid and  mux=on,  QEMU
              will  create  a  multiplexer  with  your  specified  ID, and you can then configure
              multiple front ends to use that chardev ID  for  their  input/output.  Up  to  four
              different  front  ends  can  be connected to a single multiplexed chardev. (Without
              multiplexing enabled, a chardev can only be  used  by  a  single  front  end.)  For
              instance  you  could  use  this  to  allow a single stdio chardev to be used by two
              serial ports and the QEMU monitor:

                 -chardev stdio,mux=on,id=char0 \
                 -mon chardev=char0,mode=readline \
                 -serial chardev:char0 \
                 -serial chardev:char0

              You can have more than one multiplexer in a system configuration; for instance  you
              could  have a TCP port multiplexed between UART 0 and UART 1, and stdio multiplexed
              between the QEMU monitor and a parallel port:

                 -chardev stdio,mux=on,id=char0 \
                 -mon chardev=char0,mode=readline \
                 -parallel chardev:char0 \
                 -chardev tcp,...,mux=on,id=char1 \
                 -serial chardev:char1 \
                 -serial chardev:char1

              When you're using  a  multiplexed  character  device,  some  escape  sequences  are
              interpreted  in  the  input.  See  the  chapter about keys in the character backend
              multiplexer in the System Emulation Users Guide for more details.

              Note that some  other  command  line  options  may  implicitly  create  multiplexed
              character  backends;  for  instance  -serial  mon:stdio creates a multiplexed stdio
              backend connected to the serial port and the  QEMU  monitor,  and  -nographic  also
              multiplexes the console and the monitor to stdio.

              There  is  currently  no  support  for multiplexing in the other direction (where a
              single QEMU front end takes input and output from multiple chardevs).

              Every backend supports the logfile option, which supplies the path  to  a  file  to
              record  all data transmitted via the backend. The logappend option controls whether
              the log file will be truncated or appended to when opened.

       The available backends are:

       -chardev null,id=id
              A void device. This device will not emit any  data,  and  will  drop  any  data  it
              receives. The null backend does not take any options.

       -chardev             socket,id=id[,TCP             options             or             unix
       options][,server=on|off][,wait=on|off][,telnet=on|off][,websocket=on|off][,reconnect=seconds][,tls-creds=id][,tls-authz=id]
              Create  a two-way stream socket, which can be either a TCP or a unix socket. A unix
              socket will be created if path is specified.  Behaviour is undefined if TCP options
              are specified for a unix socket.

              server=on|off specifies that the socket shall be a listening socket.

              wait=on|off specifies that QEMU should not block waiting for a client to connect to
              a listening socket.

              telnet=on|off specifies that traffic on the socket should interpret  telnet  escape
              sequences.

              websocket=on|off   specifies   that   the   socket   uses  WebSocket  protocol  for
              communication.

              reconnect sets the timeout for reconnecting on non-server sockets when  the  remote
              end  goes  away.  qemu  will delay this many seconds and then attempt to reconnect.
              Zero disables reconnecting, and is the default.

              tls-creds requests enablement of the TLS protocol for encryption, and specifies the
              id  of  the  TLS  credentials  to  use  for  the handshake. The credentials must be
              previously created with the -object tls-creds argument.

              tls-auth provides the ID of the  QAuthZ  authorization  object  against  which  the
              client's x509 distinguished name will be validated. This object is only resolved at
              time of use, so can be deleted and recreated on the fly while the chardev server is
              active.  If missing, it will default to denying access.

              TCP and unix socket options are given below:

              TCP                                                                        options:
              port=port[,host=host][,to=to][,ipv4=on|off][,ipv6=on|off][,nodelay=on|off]
                     host for a listening socket specifies the local address to be bound.  For  a
                     connecting  socket  species  the remote host to connect to. host is optional
                     for listening sockets. If not specified it defaults to 0.0.0.0.

                     port for a listening socket specifies the local port  to  be  bound.  For  a
                     connecting  socket specifies the port on the remote host to connect to. port
                     can be given as either a port number or a service name. port is required.

                     to is only relevant to listening sockets.  If  it  is  specified,  and  port
                     cannot  be  bound,  QEMU  will attempt to bind to subsequent ports up to and
                     including to until it succeeds. to must be specified as a port number.

                     ipv4=on|off and ipv6=on|off specify that either IPv4 or IPv6 must  be  used.
                     If neither is specified the socket may use either protocol.

                     nodelay=on|off disables the Nagle algorithm.

              unix options: path=path[,abstract=on|off][,tight=on|off]
                     path  specifies  the  local  path  of  the  unix  socket.  path is required.
                     abstract=on|off specifies the use of the abstract socket  namespace,  rather
                     than  the  filesystem.   Optional, defaults to false.  tight=on|off sets the
                     socket length of abstract sockets to their minimum,  rather  than  the  full
                     sun_path length.  Optional, defaults to true.

       -chardev
       udp,id=id[,host=host],port=port[,localaddr=localaddr][,localport=localport][,ipv4=on|off][,ipv6=on|off]
              Sends all traffic from the guest to a remote host over UDP.

              host  specifies  the  remote  host  to  connect to. If not specified it defaults to
              localhost.

              port specifies the port on the remote host to connect to.  port is required.

              localaddr specifies the local address to bind to. If not specified it  defaults  to
              0.0.0.0.

              localport specifies the local port to bind to. If not specified any available local
              port will be used.

              ipv4=on|off and ipv6=on|off specify that either IPv4 or  IPv6  must  be  used.   If
              neither is specified the device may use either protocol.

       -chardev msmouse,id=id
              Forward  QEMU's  emulated  msmouse  events  to the guest. msmouse does not take any
              options.

       -chardev vc,id=id[[,width=width][,height=height]][[,cols=cols][,rows=rows]]
              Connect to a QEMU text console. vc may optionally be given a specific size.

              width and height specify the width and  height  respectively  of  the  console,  in
              pixels.

              cols  and  rows  specify  that  the console be sized to fit a text console with the
              given dimensions.

       -chardev ringbuf,id=id[,size=size]
              Create a ring buffer with fixed size size. size must be a power of two and defaults
              to 64K.

       -chardev file,id=id,path=path
              Log all traffic received from the guest to a file.

              path  specifies  the path of the file to be opened. This file will be created if it
              does not already exist, and overwritten if it does.  path is required.

       -chardev pipe,id=id,path=path
              Create a two-way connection to the guest. The behaviour  differs  slightly  between
              Windows hosts and other hosts:

              On Windows, a single duplex pipe will be created at \\.pipe\path.

              On  other  hosts, 2 pipes will be created called path.in and path.out. Data written
              to path.in will be received by the guest. Data written by the  guest  can  be  read
              from path.out. QEMU will not create these fifos, and requires them to be present.

              path forms part of the pipe path as described above. path is required.

       -chardev console,id=id
              Send  traffic  from  the guest to QEMU's standard output. console does not take any
              options.

              console is only available on Windows hosts.

       -chardev serial,id=id,path=path
              Send traffic from the guest to a serial device on the host.

              On Unix hosts serial will actually accept any tty device, not only serial lines.

              path specifies the name of the serial device to open.

       -chardev pty,id=id
              Create a new pseudo-terminal on the host and connect to it. pty does not  take  any
              options.

              pty is not available on Windows hosts.

       -chardev stdio,id=id[,signal=on|off]
              Connect to standard input and standard output of the QEMU process.

              signal  controls if signals are enabled on the terminal, that includes exiting QEMU
              with the key sequence Control-c. This option is enabled by default, use  signal=off
              to disable it.

       -chardev braille,id=id
              Connect to a local BrlAPI server. braille does not take any options.

       -chardev tty,id=id,path=path
              tty  is  only  available  on  Linux, Sun, FreeBSD, NetBSD, OpenBSD and DragonFlyBSD
              hosts. It is an alias for serial.

              path specifies the path to the tty. path is required.

       -chardev parallel,id=id,path=path

       -chardev parport,id=id,path=path
              parallel is only available on Linux, FreeBSD and DragonFlyBSD hosts.

              Connect to a local parallel port.

              path specifies the path to the parallel port device. path is required.

       -chardev spicevmc,id=id,debug=debug,name=name
              spicevmc is only available when spice support is built in.

              debug debug level for spicevmc

              name name of spice channel to connect to

              Connect to a spice virtual machine channel, such as vdiport.

       -chardev spiceport,id=id,debug=debug,name=name
              spiceport is only available when spice support is built in.

              debug debug level for spicevmc

              name name of spice port to connect to

              Connect to a spice port, allowing a Spice client to handle the  traffic  identified
              by a name (preferably a fqdn).

   TPM device options
       The general form of a TPM device option is:

       -tpmdev backend,id=id[,options]
              The specific backend type will determine the applicable options. The -tpmdev option
              creates the TPM backend and requires  a  -device  option  that  specifies  the  TPM
              frontend interface model.

              Use -tpmdev help to print all available TPM backend types.

       The available backends are:

       -tpmdev passthrough,id=id,path=path,cancel-path=cancel-path
              (Linux-host only) Enable access to the host's TPM using the passthrough driver.

              path  specifies the path to the host's TPM device, i.e., on a Linux host this would
              be /dev/tpm0. path is optional and by default /dev/tpm0 is used.

              cancel-path specifies the path to the host TPM device's sysfs  entry  allowing  for
              cancellation  of  an  ongoing  TPM command.  cancel-path is optional and by default
              QEMU will search for the sysfs entry to use.

              Some notes about using the host's TPM with the passthrough driver:

              The TPM device accessed by the passthrough driver must not be  used  by  any  other
              application on the host.

              Since  the  host's  firmware  (BIOS/UEFI) has already initialized the TPM, the VM's
              firmware (BIOS/UEFI) will not be able to initialize the TPM again and may therefore
              not  show  a TPM-specific menu that would otherwise allow the user to configure the
              TPM, e.g., allow  the  user  to  enable/disable  or  activate/deactivate  the  TPM.
              Further, if TPM ownership is released from within a VM then the host's TPM will get
              disabled and deactivated. To enable and activate the TPM again afterwards, the host
              has  to be rebooted and the user is required to enter the firmware's menu to enable
              and activate the TPM. If the TPM is  left  disabled  and/or  deactivated  most  TPM
              commands will fail.

              To create a passthrough TPM use the following two options:

                 -tpmdev passthrough,id=tpm0 -device tpm-tis,tpmdev=tpm0

              Note  that  the  -tpmdev  id is tpm0 and is referenced by tpmdev=tpm0 in the device
              option.

       -tpmdev emulator,id=id,chardev=dev
              (Linux-host only) Enable access to a TPM emulator using Unix  domain  socket  based
              chardev backend.

              chardev  specifies  the  unique  ID  of  a  character  device backend that provides
              connection to the software TPM server.

              To create a TPM emulator backend device with chardev socket backend:

                 -chardev socket,id=chrtpm,path=/tmp/swtpm-sock -tpmdev emulator,id=tpm0,chardev=chrtpm -device tpm-tis,tpmdev=tpm0

   Linux/Multiboot boot specific
       When using these options, you can use a given Linux or Multiboot kernel without installing
       it in the disk image. It can be useful for easier testing of various kernels.

       -kernel bzImage
              Use  bzImage  as  kernel  image.  The  kernel  can  be  either a Linux kernel or in
              multiboot format.

       -append cmdline
              Use cmdline as kernel command line

       -initrd file
              Use file as initial ram disk.

       -initrd file1 arg=foo,file2
              This syntax is only available with multiboot.

              Use file1 and file2 as modules and pass arg=foo as parameter to the first module.

       -dtb file
              Use file as a device tree binary (dtb) image and pass it to the kernel on boot.

   Debug/Expert options
       -compat [deprecated-input=@var{input-policy}][,deprecated-output=@var{output-policy}]
              Set policy for handling deprecated management interfaces (experimental):

              deprecated-input=accept (default)
                     Accept deprecated commands and arguments

              deprecated-input=reject
                     Reject deprecated commands and arguments

              deprecated-input=crash
                     Crash on deprecated commands and arguments

              deprecated-output=accept (default)
                     Emit deprecated command results and events

              deprecated-output=hide
                     Suppress deprecated command results and events

              Limitation: covers only syntactic aspects of QMP.

       -compat [unstable-input=@var{input-policy}][,unstable-output=@var{output-policy}]
              Set policy for handling unstable management interfaces (experimental):

              unstable-input=accept (default)
                     Accept unstable commands and arguments

              unstable-input=reject
                     Reject unstable commands and arguments

              unstable-input=crash
                     Crash on unstable commands and arguments

              unstable-output=accept (default)
                     Emit unstable command results and events

              unstable-output=hide
                     Suppress unstable command results and events

              Limitation: covers only syntactic aspects of QMP.

       -fw_cfg [name=]name,file=file
              Add named fw_cfg entry with contents from file file.

       -fw_cfg [name=]name,string=str
              Add named fw_cfg entry with contents from string str.

              The terminating NUL character of the contents of str will not be included  as  part
              of  the fw_cfg item data. To insert contents with embedded NUL characters, you have
              to use the file parameter.

              The fw_cfg entries are passed by QEMU through to the guest.

              Example:

                 -fw_cfg name=opt/com.mycompany/blob,file=./my_blob.bin

              creates  an  fw_cfg  entry  named   opt/com.mycompany/blob   with   contents   from
              ./my_blob.bin.

       -serial dev
              Redirect  the  virtual serial port to host character device dev. The default device
              is vc in graphical mode and stdio in non graphical mode.

              This option can be used several times to simulate up to 4 serial ports.

              Use -serial none to disable all serial ports.

              Available character devices are:

              vc[:WxH]
                     Virtual console. Optionally, a width and height can be given in pixel with

                        vc:800x600

                     It is also possible to specify width or height in characters:

                        vc:80Cx24C

              pty    [Linux only] Pseudo TTY (a new PTY is automatically allocated)

              none   No device is allocated.

              null   void device

              chardev:id
                     Use a named character device defined with the -chardev option.

              /dev/XXX
                     [Linux only] Use host tty, e.g. /dev/ttyS0. The host serial port  parameters
                     are set according to the emulated ones.

              /dev/parportN
                     [Linux  only,  parallel  port only] Use host parallel port N.  Currently SPP
                     and EPP parallel port features can be used.

              file:filename
                     Write output to filename. No character can be read.

              stdio  [Unix only] standard input/output

              pipe:filename
                     name pipe filename

              COMn   [Windows only] Use host serial port n

              udp:[remote_host]:remote_port[@[src_ip]:src_port]
                     This implements  UDP  Net  Console.  When  remote_host  or  src_ip  are  not
                     specified  they  default  to  0.0.0.0. When not using a specified src_port a
                     random port is automatically chosen.

                     If you just want a simple readonly console you can  use  netcat  or  nc,  by
                     starting  QEMU with: -serial udp::4555 and nc as: nc -u -l -p 4555. Any time
                     QEMU writes something to that port it will appear in the netconsole session.

                     If you plan to send characters back via netconsole or you want to  stop  and
                     start  QEMU  a  lot  of times, you should have QEMU use the same source port
                     each time by using something like -serial udp::4555@:4556 to  QEMU.  Another
                     approach  is  to  use  a patched version of netcat which can listen to a TCP
                     port and send and receive characters via udp. If you have a patched  version
                     of  netcat which activates telnet remote echo and single char transfer, then
                     you can use the following options to set up a  netcat  redirector  to  allow
                     telnet on port 5555 to access the QEMU port.

                     QEMU Options:
                            -serial udp::4555@:4556

                     netcat options:
                            -u -P 4555 -L 0.0.0.0:4556 -t -p 5555 -I -T

                     telnet options:
                            localhost 5555

              tcp:[host]:port[,server=on|off][,wait=on|off][,nodelay=on|off][,reconnect=seconds]
                     The  TCP  Net Console has two modes of operation. It can send the serial I/O
                     to a location or wait for a connection from a location. By default  the  TCP
                     Net  Console  is  sent  to host at the port. If you use the server=on option
                     QEMU will wait for a client socket application to connect to the port before
                     continuing,  unless the wait=on|off option was specified. The nodelay=on|off
                     option disables the Nagle buffering algorithm. The reconnect=on option  only
                     applies  if server=no is set, if the connection goes down it will attempt to
                     reconnect at the given interval. If host is  omitted,  0.0.0.0  is  assumed.
                     Only  one  TCP  connection  at  a time is accepted. You can use telnet=on to
                     connect to the corresponding character device.

                     Example to send tcp console to 192.168.0.2 port 4444
                            -serial tcp:192.168.0.2:4444

                     Example to listen and wait on port 4444 for connection
                            -serial tcp::4444,server=on

                     Example to not wait and listen on ip 192.168.0.100 port 4444
                            -serial tcp:192.168.0.100:4444,server=on,wait=off

              telnet:host:port[,server=on|off][,wait=on|off][,nodelay=on|off]
                     The telnet protocol is used instead of raw tcp sockets. The options work the
                     same  as  if you had specified -serial tcp.  The difference is that the port
                     acts like a telnet server or client using telnet  option  negotiation.  This
                     will  also  allow  you  to send the MAGIC_SYSRQ sequence if you use a telnet
                     that supports sending the break sequence. Typically in unix telnet you do it
                     with  Control-]  and  then  type "send break" followed by pressing the enter
                     key.

              websocket:host:port,server=on[,wait=on|off][,nodelay=on|off]
                     The WebSocket protocol is used instead of raw tcp socket. The port acts as a
                     WebSocket server. Client mode is not supported.

              unix:path[,server=on|off][,wait=on|off][,reconnect=seconds]
                     A  unix  domain socket is used instead of a tcp socket. The option works the
                     same as if you had specified -serial tcp except the unix domain socket  path
                     is used for connections.

              mon:dev_string
                     This is a special option to allow the monitor to be multiplexed onto another
                     serial port. The monitor is accessed with key sequence of Control-a and then
                     pressing  c.  dev_string  should  be any one of the serial devices specified
                     above. An example to multiplex the monitor onto a telnet server listening on
                     port 4444 would be:

                     -serial mon:telnet::4444,server=on,wait=off

                     When  the  monitor  is  multiplexed  to  stdio  in this way, Ctrl+C will not
                     terminate QEMU any more but will be passed to the guest instead.

              braille
                     Braille device. This will use BrlAPI to display the braille output on a real
                     or fake device.

              msmouse
                     Three button serial mouse. Configure the guest to use Microsoft protocol.

       -parallel dev
              Redirect  the  virtual parallel port to host device dev (same devices as the serial
              port). On Linux hosts, /dev/parportN can be used to use hardware devices  connected
              on the corresponding host parallel port.

              This option can be used several times to simulate up to 3 parallel ports.

              Use -parallel none to disable all parallel ports.

       -monitor dev
              Redirect  the  monitor  to  host  device dev (same devices as the serial port). The
              default device is vc in graphical  mode  and  stdio  in  non  graphical  mode.  Use
              -monitor none to disable the default monitor.

       -qmp dev
              Like -monitor but opens in 'control' mode.

       -qmp-pretty dev
              Like -qmp but uses pretty JSON formatting.

       -mon [chardev=]name[,mode=readline|control][,pretty[=on|off]]
              Setup  monitor  on  chardev  name.  mode=control  configures  a QMP monitor (a JSON
              RPC-style protocol) and it is not the same as HMP, the human  monitor  that  has  a
              "(qemu)"  prompt.   pretty  is only valid when mode=control, turning on JSON pretty
              printing to ease human reading and debugging.

       -debugcon dev
              Redirect the debug console to host device dev (same devices as  the  serial  port).
              The  debug console is an I/O port which is typically port 0xe9; writing to that I/O
              port sends output to this device. The default device is vc in  graphical  mode  and
              stdio in non graphical mode.

       -pidfile file
              Store the QEMU process PID in file. It is useful if you launch QEMU from a script.

       -singlestep
              Run the emulation in single step mode.

       --preconfig
              Pause  QEMU  for  interactive  configuration  before  the machine is created, which
              allows querying and configuring properties that will affect machine initialization.
              Use QMP command 'x-exit-preconfig' to exit the preconfig state and move to the next
              state (i.e. run guest if -S isn't used or pause the second time  if  -S  is  used).
              This option is experimental.

       -S     Do not start CPU at startup (you must type 'c' in the monitor).

       -overcommit mem-lock=on|off

       -overcommit cpu-pm=on|off
              Run  qemu  with hints about host resource overcommit. The default is to assume that
              host overcommits all resources.

              Locking qemu and guest memory can be enabled via mem-lock=on (disabled by default).
              This works when host memory is not overcommitted and reduces the worst-case latency
              for guest.

              Guest ability to manage power state of host  cpus  (increasing  latency  for  other
              processes  on  the  same host cpu, but decreasing latency for guest) can be enabled
              via cpu-pm=on (disabled  by  default).  This  works  best  when  host  CPU  is  not
              overcommitted. When used, host estimates of CPU cycle and power utilization will be
              incorrect, not taking into account guest idle time.

       -gdb dev
              Accept a gdb connection on device dev (see the GDB  usage  chapter  in  the  System
              Emulation  Users  Guide). Note that this option does not pause QEMU execution -- if
              you want QEMU to not start the guest  until  you  connect  with  gdb  and  issue  a
              continue command, you will need to also pass the -S option to QEMU.

              The most usual configuration is to listen on a local TCP socket:

                 -gdb tcp::3117

              but  you  can  specify  other  backends;  UDP,  pseudo  TTY,  or even stdio are all
              reasonable use cases. For example, a stdio connection allows you to start QEMU from
              within gdb and establish the connection via a pipe:

                 (gdb) target remote | exec qemu-system-x86_64 -gdb stdio ...

       -s     Shorthand  for  -gdb tcp::1234, i.e. open a gdbserver on TCP port 1234 (see the GDB
              usage chapter in the System Emulation Users Guide).

       -d item1[,...]
              Enable logging of specified items. Use '-d help' for a list of log items.

       -D logfile
              Output log in logfile instead of to stderr

       -dfilter range1[,...]
              Filter debug output to that relevant to a range of target  addresses.   The  filter
              spec  can  be  either start+size, start-size or start..end where start end and size
              are the addresses and sizes required. For example:

                 -dfilter 0x8000..0x8fff,0xffffffc000080000+0x200,0xffffffc000060000-0x1000

              Will dump output for any code in the 0x1000 sized block starting at 0x8000 and  the
              0x200  sized  block  starting  at 0xffffffc000080000 and another 0x1000 sized block
              starting at 0xffffffc00005f000.

       -seed number
              Force the guest to use a deterministic pseudo-random number generator, seeded  with
              number. This does not affect crypto routines within the host.

       -L path
              Set the directory for the BIOS, VGA BIOS and keymaps.

              To list all the data directories, use -L help.

       -bios file
              Set the filename for the BIOS.

       -enable-kvm
              Enable  KVM  full  virtualization  support.  This  option  is only available if KVM
              support is enabled when compiling.

       -xen-domid id
              Specify xen guest domain id (XEN only).

       -xen-attach
              Attach to existing xen domain. libxl will use this when starting QEMU  (XEN  only).
              Restrict set of available xen operations to specified domain id (XEN only).

       -no-reboot
              Exit instead of rebooting.

       -no-shutdown
              Don't exit QEMU on guest shutdown, but instead only stop the emulation. This allows
              for instance switching to monitor to commit changes to the disk image.

       -action event=action
              The action parameter serves to modify QEMU's default behavior  when  certain  guest
              events  occur.  It provides a generic method for specifying the same behaviors that
              are modified by the -no-reboot and -no-shutdown parameters.

              Examples:

              -action  panic=none  -action  reboot=shutdown,shutdown=pause   -watchdog   i6300esb
              -action watchdog=pause

       -loadvm file
              Start right away with a saved state (loadvm in monitor)

       -daemonize
              Daemonize the QEMU process after initialization. QEMU will not detach from standard
              IO until it is ready to receive connections on any of its devices. This option is a
              useful  way  for  external  programs  to  launch  QEMU  without having to cope with
              initialization race conditions.

       -option-rom file
              Load the contents of file as an option ROM. This option is useful  to  load  things
              like EtherBoot.

       -rtc [base=utc|localtime|datetime][,clock=host|rt|vm][,driftfix=none|slew]
              Specify  base  as utc or localtime to let the RTC start at the current UTC or local
              time, respectively. localtime is required for correct date in MS-DOS or Windows. To
              start   at   a   specific   point   in   time,   provide  datetime  in  the  format
              2006-06-17T16:01:21 or 2006-06-17. The default base is UTC.

              By default the RTC is driven by the host system time. This allows using of the  RTC
              as  accurate  reference  clock  inside  the guest, specifically if the host time is
              smoothly following an accurate external reference clock, e.g. via NTP. If you  want
              to  isolate  the  guest  time from the host, you can set clock to rt instead, which
              provides a host monotonic clock if host support it. To even prevent  the  RTC  from
              progressing  during suspension, you can set clock to vm (virtual clock). 'clock=vm'
              is recommended especially in icount mode in order to preserve determinism; however,
              note  that  in  icount  mode  the speed of the virtual clock is variable and can in
              general differ from the host clock.

              Enable driftfix  (i386  targets  only)  if  you  experience  time  drift  problems,
              specifically  with  Windows'  ACPI HAL. This option will try to figure out how many
              timer interrupts were not processed by the Windows guest and will re-inject them.

       -icount
       [shift=N|auto][,align=on|off][,sleep=on|off][,rr=record|replay,rrfile=filename[,rrsnapshot=snapshot]]
              Enable virtual instruction counter. The virtual cpu will  execute  one  instruction
              every  2^N ns of virtual time. If auto is specified then the virtual cpu speed will
              be automatically adjusted to keep virtual time within a few seconds of real time.

              Note that while this option can give deterministic behavior, it  does  not  provide
              cycle  accurate  emulation. Modern CPUs contain superscalar out of order cores with
              complex cache hierarchies. The number of instructions executed often has little  or
              no correlation with actual performance.

              When  the  virtual  cpu is sleeping, the virtual time will advance at default speed
              unless sleep=on is specified. With sleep=on, the virtual time will jump to the next
              timer  deadline  instantly whenever the virtual cpu goes to sleep mode and will not
              advance if no timer is enabled. This behavior gives deterministic  execution  times
              from  the  guest  point  of  view.   The default if icount is enabled is sleep=off.
              sleep=on cannot be used together with either shift=auto or align=on.

              align=on will activate the delay algorithm which will try to synchronise  the  host
              clock  and  the  virtual  clock.  The  goal  is to have a guest running at the real
              frequency imposed by the shift option. Whenever the guest clock is behind the  host
              clock  and  if  align=on is specified then we print a message to the user to inform
              about the delay. Currently this option does not work when shift is auto. Note:  The
              sync  algorithm  will  work  for  those shift values for which the guest clock runs
              ahead of the host clock.  Typically this happens when the shift value is high  (how
              high depends on the host machine). The default if icount is enabled is align=off.

              When the rr option is specified deterministic record/replay is enabled. The rrfile=
              option must also be provided to specify the path to the replay log. In record  mode
              data  is  written  to  this  file,  and  in  replay  mode  it is read back.  If the
              rrsnapshot option is given then it specifies a VM snapshot name. In record mode,  a
              new VM snapshot with the given name is created at the start of execution recording.
              In replay mode this option specifies the snapshot name used to load the initial  VM
              state.

       -watchdog model
              Create  a  virtual  hardware watchdog device. Once enabled (by a guest action), the
              watchdog must be periodically polled by an agent inside the guest or else the guest
              will be restarted. Choose a model for which your guest has drivers.

              The  model is the model of hardware watchdog to emulate. Use -watchdog help to list
              available hardware models. Only one watchdog can be enabled for a guest.

              The following models may be available:

              ib700  iBASE 700 is a very simple ISA watchdog with a single timer.

              i6300esb
                     Intel 6300ESB I/O  controller  hub  is  a  much  more  featureful  PCI-based
                     dual-timer watchdog.

              diag288
                     A virtual watchdog for s390x backed by the diagnose 288 hypercall (currently
                     KVM only).

       -watchdog-action action
              The action controls what QEMU will do when the watchdog timer expires. The  default
              is  reset  (forcefully  reset  the  guest).   Other  possible actions are: shutdown
              (attempt to gracefully shutdown  the  guest),  poweroff  (forcefully  poweroff  the
              guest),  inject-nmi  (inject  a NMI into the guest), pause (pause the guest), debug
              (print a debug message and continue), or none (do nothing).

              Note that the shutdown action requires that the guest  responds  to  ACPI  signals,
              which  it  may not be able to do in the sort of situations where the watchdog would
              have expired, and thus -watchdog-action shutdown is not recommended for  production
              use.

              Examples:

              -watchdog i6300esb -watchdog-action pause; -watchdog ib700

       -echr numeric_ascii_value
              Change  the  escape  character used for switching to the monitor when using monitor
              and serial sharing. The default is 0x01 when using the -nographic option.  0x01  is
              equal  to  pressing  Control-a. You can select a different character from the ascii
              control keys where 1 through 26 map to Control-a through Control-z.   For  instance
              you  could  use  the  either  of  the  following  to change the escape character to
              Control-t.

              -echr 0x14; -echr 20

       -incoming tcp:[host]:port[,to=maxport][,ipv4=on|off][,ipv6=on|off]

       -incoming rdma:host:port[,ipv4=on|off][,ipv6=on|off]
              Prepare for incoming migration, listen on a given tcp port.

       -incoming unix:socketpath
              Prepare for incoming migration, listen on a given unix socket.

       -incoming fd:fd
              Accept incoming migration from a given filedescriptor.

       -incoming exec:cmdline
              Accept incoming migration as an output from specified external command.

       -incoming defer
              Wait for the URI to be specified via migrate_incoming. The monitor can be  used  to
              change   settings   (such   as   migration   parameters)   prior   to  issuing  the
              migrate_incoming to allow the migration to begin.

       -only-migratable
              Only allow migratable devices. Devices will not be allowed to enter an unmigratable
              state.

       -nodefaults
              Don't  create  default devices. Normally, QEMU sets the default devices like serial
              port, parallel port, virtual console,  monitor  device,  VGA  adapter,  floppy  and
              CD-ROM  drive  and  others.  The  -nodefaults option will disable all those default
              devices.

       -chroot dir
              Immediately before starting guest execution, chroot  to  the  specified  directory.
              Especially useful in combination with -runas.

       -runas user
              Immediately before starting guest execution, drop root privileges, switching to the
              specified user.

       -prom-env variable=value
              Set OpenBIOS nvram variable to given value (PPC, SPARC only).

                 qemu-system-sparc -prom-env 'auto-boot?=false' \
                  -prom-env 'boot-device=sd(0,2,0):d' -prom-env 'boot-args=linux single'

                 qemu-system-ppc -prom-env 'auto-boot?=false' \
                  -prom-env 'boot-device=hd:2,\yaboot' \
                  -prom-env 'boot-args=conf=hd:2,\yaboot.conf'

       -semihosting
              Enable semihosting mode (ARM, M68K, Xtensa, MIPS, Nios II, RISC-V only).

              Note that this allows guest direct access to the host filesystem, so should only be
              used with a trusted guest OS.

              See  the -semihosting-config option documentation for further information about the
              facilities this enables.

       -semihosting-config [enable=on|off][,target=native|gdb|auto][,chardev=id][,arg=str[,...]]
              Enable and configure semihosting (ARM, M68K, Xtensa, MIPS, Nios II, RISC-V only).

              Note that this allows guest direct access to the host filesystem, so should only be
              used with a trusted guest OS.

              On Arm this implements the standard semihosting API, version 2.0.

              On M68K this implements the "ColdFire GDB" interface used by libgloss.

              Xtensa     semihosting     provides     basic    file    IO    calls,    such    as
              open/read/write/seek/select. Tensilica baremetal libc for ISS  and  linux  platform
              "sim" use this interface.

              On RISC-V this implements the standard semihosting API, version 0.2.

              target=native|gdb|auto
                     Defines  where  the semihosting calls will be addressed, to QEMU (native) or
                     to GDB (gdb). The default is auto, which means gdb during debug sessions and
                     native otherwise.

              chardev=str1
                     Send  the  output to a chardev backend output for native or auto output when
                     not in gdb

              arg=str1,arg=str2,...
                     Allows the user to pass input arguments, and can be used multiple  times  to
                     build  up  a list. The old-style -kernel/-append method of passing a command
                     line  is  still  supported  for  backward   compatibility.   If   both   the
                     --semihosting-config  arg  and the -kernel/-append are specified, the former
                     is passed to semihosting as it always takes precedence.

       -old-param
              Old param mode (ARM only).

       -sandbox
       arg[,obsolete=string][,elevateprivileges=string][,spawn=string][,resourcecontrol=string]
              Enable  Seccomp  mode  2 system call filter. 'on' will enable syscall filtering and
              'off' will disable it. The default is 'off'.

              obsolete=string
                     Enable Obsolete system calls

              elevateprivileges=string
                     Disable set*uid|gid system calls

              spawn=string
                     Disable *fork and execve

              resourcecontrol=string
                     Disable process affinity and schedular priority

       -readconfig file
              Read device configuration from file. This approach is useful when you want to spawn
              QEMU  process  with  many  command  line  options  but you don't want to exceed the
              command line character limit.

       -no-user-config
              The -no-user-config option makes QEMU not load  any  of  the  user-provided  config
              files on sysconfdir.

       -trace [[enable=]pattern][,events=file][,file=file]
              Specify tracing options.

              [enable=]PATTERN
                 Immediately  enable  events  matching  PATTERN  (either event name or a globbing
                 pattern).  This option is only available if QEMU  has  been  compiled  with  the
                 simple,  log or ftrace tracing backend.  To specify multiple events or patterns,
                 specify the -trace option multiple times.

                 Use -trace help to print a list of names of trace points.

              events=FILE
                 Immediately enable events listed in FILE.  The file must contain one event  name
                 (as  listed  in  the  trace-events-all  file)  per  line;  globbing patterns are
                 accepted too.  This option is only available if QEMU has been compiled with  the
                 simple, log or ftrace tracing backend.

              file=FILE
                 Log  output  traces  to  FILE.   This  option is only available if QEMU has been
                 compiled with the simple tracing backend.

       -plugin file=file[,argname=argvalue]
              Load a plugin.

              file=file
                     Load the given plugin from a shared library file.

              argname=argvalue
                     Argument passed to the plugin. (Can be given multiple times.)

       -enable-fips
              Enable FIPS 140-2 compliance mode.

       -msg [timestamp[=on|off]][,guest-name[=on|off]]
              Control error message format.

              timestamp=on|off
                     Prefix messages with a timestamp. Default is off.

              guest-name=on|off
                     Prefix messages with guest name but  only  if  -name  guest  option  is  set
                     otherwise the option is ignored. Default is off.

       -dump-vmstate file
              Dump json-encoded vmstate information for current machine type to file in file

       -enable-sync-profile
              Enable synchronization profiling.

   Generic object creation
       -object typename[,prop1=value1,...]
              Create  a  new  object  of  type  typename setting properties in the order they are
              specified. Note that the 'id' property must be set. These objects are placed in the
              '/objects' path.

              -object
              memory-backend-file,id=id,size=size,mem-path=dir,share=on|off,discard-data=on|off,merge=on|off,dump=on|off,prealloc=on|off,host-nodes=host-nodes,policy=default|preferred|bind|interleave,align=align,readonly=on|off
                     Creates  a  memory  file backend object, which can be used to back the guest
                     RAM with huge pages.

                     The id parameter is a unique ID that will be used to reference  this  memory
                     region in other parameters, e.g. -numa, -device nvdimm, etc.

                     The  size  option provides the size of the memory region, and accepts common
                     suffixes, e.g. 500M.

                     The mem-path provides the path to  either  a  shared  memory  or  huge  page
                     filesystem mount.

                     The  share  boolean option determines whether the memory region is marked as
                     private to QEMU, or  shared.  The  latter  allows  a  co-operating  external
                     process to access the QEMU memory region.

                     The share is also required for pvrdma devices due to limitations in the RDMA
                     API provided by Linux.

                     Setting share=on might affect the ability to configure NUMA bindings for the
                     memory        backend        under       some       circumstances,       see
                     Documentation/vm/numa_memory_policy.txt on the Linux kernel source tree  for
                     additional details.

                     Setting  the  discard-data boolean option to on indicates that file contents
                     can be destroyed when QEMU exits, to avoid unnecessarily  flushing  data  to
                     the  backing  file. Note that discard-data is only an optimization, and QEMU
                     might not discard file contents if it aborts unexpectedly or  is  terminated
                     using SIGKILL.

                     The merge boolean option enables memory merge, also known as MADV_MERGEABLE,
                     so  that  Kernel  Samepage  Merging  will  consider  the  pages  for  memory
                     deduplication.

                     Setting  the dump boolean option to off excludes the memory from core dumps.
                     This feature is also known as MADV_DONTDUMP.

                     The prealloc boolean option enables memory preallocation.

                     The host-nodes option binds the memory range to a list of NUMA host nodes.

                     The policy option sets the NUMA policy to one of the following values:

                     default
                            default host policy

                     preferred
                            prefer the given host node list for allocation

                     bind   restrict memory allocation to the given host node list

                     interleave
                            interleave memory allocations across the given host node list

                     The align option specifies the base  address  alignment  when  QEMU  mmap(2)
                     mem-path,  and  accepts common suffixes, eg 2M. Some backend store specified
                     by mem-path requires an alignment different than the  default  one  used  by
                     QEMU, eg the device DAX /dev/dax0.0 requires 2M alignment rather than 4K. In
                     such cases, users can specify the required alignment via this option.

                     The pmem option specifies whether the backing file specified by mem-path  is
                     in  host  persistent  memory  that  can  be  accessed  using  the  SNIA  NVM
                     programming model (e.g. Intel NVDIMM). If pmem is set  to  'on',  QEMU  will
                     take  necessary operations to guarantee the persistence of its own writes to
                     mem-path (e.g. in vNVDIMM label emulation and live migration). Also, we will
                     map  the backend-file with MAP_SYNC flag, which ensures the file metadata is
                     in sync for mem-path in case of host crash  or  a  power  failure.  MAP_SYNC
                     requires support from both the host kernel (since Linux kernel 4.15) and the
                     filesystem of mem-path mounted with DAX option.

                     The readonly option specifies whether the backing file is  opened  read-only
                     or read-write (default).

              -object
              memory-backend-ram,id=id,merge=on|off,dump=on|off,share=on|off,prealloc=on|off,size=size,host-nodes=host-nodes,policy=default|preferred|bind|interleave
                     Creates  a  memory  backend object, which can be used to back the guest RAM.
                     Memory backend objects offer  more  control  than  the  -m  option  that  is
                     traditionally used to define guest RAM.  Please refer to memory-backend-file
                     for a description of the options.

              -object
              memory-backend-memfd,id=id,merge=on|off,dump=on|off,share=on|off,prealloc=on|off,size=size,host-nodes=host-nodes,policy=default|preferred|bind|interleave,seal=on|off,hugetlb=on|off,hugetlbsize=size
                     Creates an anonymous memory file backend object, which allows QEMU to  share
                     the memory with an external process (e.g. when using vhost-user). The memory
                     is allocated with memfd and optional sealing. (Linux only)

                     The seal option creates a sealed-file, that will block further resizing  the
                     memory ('on' by default).

                     The  hugetlb  option specify the file to be created resides in the hugetlbfs
                     filesystem (since Linux 4.14). Used in conjunction with the hugetlb  option,
                     the hugetlbsize option specify the hugetlb page size on systems that support
                     multiple hugetlb page sizes (it must be a power of 2 value supported by  the
                     system).

                     In  some versions of Linux, the hugetlb option is incompatible with the seal
                     option (requires at least Linux 4.16).

                     Please refer to memory-backend-file for a description of the other options.

                     The share boolean option is on by default with memfd.

              -object rng-builtin,id=id
                     Creates a random number generator backend which obtains  entropy  from  QEMU
                     builtin  functions.  The  id  parameter  is a unique ID that will be used to
                     reference this entropy backend from the virtio-rng device. By  default,  the
                     virtio-rng device uses this RNG backend.

              -object rng-random,id=id,filename=/dev/random
                     Creates  a  random  number  generator  backend  which obtains entropy from a
                     device on the host. The id parameter is a unique ID that  will  be  used  to
                     reference  this  entropy  backend  from  the virtio-rng device. The filename
                     parameter specifies which  file  to  obtain  entropy  from  and  if  omitted
                     defaults to /dev/urandom.

              -object rng-egd,id=id,chardev=chardevid
                     Creates  a  random  number  generator  backend which obtains entropy from an
                     external daemon running on the host. The id parameter is a  unique  ID  that
                     will  be  used to reference this entropy backend from the virtio-rng device.
                     The chardev parameter is the unique ID of a character  device  backend  that
                     provides the connection to the RNG daemon.

              -object
              tls-creds-anon,id=id,endpoint=endpoint,dir=/path/to/cred/dir,verify-peer=on|off
                     Creates a TLS anonymous credentials object, which can be used to provide TLS
                     support  on  network backends. The id parameter is a unique ID which network
                     backends will use to access the credentials. The endpoint is  either  server
                     or  client  depending  on  whether  the  QEMU  network backend that uses the
                     credentials will be acting as a client or as a  server.  If  verify-peer  is
                     enabled  (the  default)  then  once  the  handshake  is  completed, the peer
                     credentials  will  be  verified,  though  this  is  a  no-op  for  anonymous
                     credentials.

                     The dir parameter tells QEMU where to find the credential files.  For server
                     endpoints,  this  directory  may  contain  a  file  dh-params.pem  providing
                     diffie-hellman parameters to use for the TLS server. If the file is missing,
                     QEMU  will  generate  a  set  of  DH  parameters  at  startup.  This  is   a
                     computationally expensive operation that consumes random pool entropy, so it
                     is recommended that a persistent set of parameters be generated upfront  and
                     saved.

              -object
              tls-creds-psk,id=id,endpoint=endpoint,dir=/path/to/keys/dir[,username=username]
                     Creates a TLS Pre-Shared Keys (PSK) credentials object, which can be used to
                     provide  TLS  support  on  network backends. The id parameter is a unique ID
                     which network backends will use to access the credentials. The  endpoint  is
                     either  server  or client depending on whether the QEMU network backend that
                     uses the credentials will be acting as a client or as a server.  For clients
                     only,  username is the username which will be sent to the server. If omitted
                     it defaults to "qemu".

                     The dir parameter tells QEMU where to find  the  keys  file.  It  is  called
                     "dir/keys.psk"  and contains "username:key" pairs. This file can most easily
                     be created using the GnuTLS psktool program.

                     For server endpoints, dir may also contain a  file  dh-params.pem  providing
                     diffie-hellman  parameters  to  use  for  the  TLS  server.   If the file is
                     missing, QEMU will generate a set of DH parameters at  startup.  This  is  a
                     computationally expensive operation that consumes random pool entropy, so it
                     is recommended that a persistent set of parameters be generated up front and
                     saved.

              -object
              tls-creds-x509,id=id,endpoint=endpoint,dir=/path/to/cred/dir,priority=priority,verify-peer=on|off,passwordid=id
                     Creates a TLS anonymous credentials object, which can be used to provide TLS
                     support on network backends. The id parameter is a unique ID  which  network
                     backends  will  use to access the credentials. The endpoint is either server
                     or client depending on whether  the  QEMU  network  backend  that  uses  the
                     credentials  will  be  acting  as a client or as a server. If verify-peer is
                     enabled (the default)  then  once  the  handshake  is  completed,  the  peer
                     credentials  will be verified. With x509 certificates, this implies that the
                     clients must be provided with valid client certificates too.

                     The dir parameter tells QEMU where to find the credential files.  For server
                     endpoints,  this  directory  may  contain  a  file  dh-params.pem  providing
                     diffie-hellman parameters to use for the TLS server. If the file is missing,
                     QEMU   will  generate  a  set  of  DH  parameters  at  startup.  This  is  a
                     computationally expensive operation that consumes random pool entropy, so it
                     is  recommended that a persistent set of parameters be generated upfront and
                     saved.

                     For x509 certificate credentials the directory will  contain  further  files
                     providing  the  x509  certificates.  The  certificates must be stored in PEM
                     format, in filenames  ca-cert.pem,  ca-crl.pem  (optional),  server-cert.pem
                     (only   servers),   server-key.pem  (only  servers),  client-cert.pem  (only
                     clients), and client-key.pem (only clients).

                     For the server-key.pem and  client-key.pem  files  which  contain  sensitive
                     private  keys,  it  is possible to use an encrypted version by providing the
                     passwordid parameter. This provides the ID of a  previously  created  secret
                     object containing the password for decryption.

                     The  priority  parameter allows to override the global default priority used
                     by gnutls. This can be useful if the system administrator  needs  to  use  a
                     weaker  set  of  crypto  priorities for QEMU without potentially forcing the
                     weakness onto all applications. Or conversely if one wants wants a  stronger
                     default  for  QEMU than for all other applications, they can do this through
                     this parameter. Its format is a  gnutls  priority  string  as  described  at
                     https://gnutls.org/manual/html_node/Priority-Strings.html.

              -object tls-cipher-suites,id=id,priority=priority
                     Creates  a  TLS  cipher  suites object, which can be used to control the TLS
                     cipher/protocol algorithms that applications are permitted to use.

                     The id parameter is a unique ID which  frontends  will  use  to  access  the
                     ordered list of permitted TLS cipher suites from the host.

                     The  priority  parameter allows to override the global default priority used
                     by gnutls. This can be useful if the system administrator  needs  to  use  a
                     weaker  set  of  crypto  priorities for QEMU without potentially forcing the
                     weakness onto all applications. Or conversely if one wants wants a  stronger
                     default  for  QEMU than for all other applications, they can do this through
                     this parameter. Its format is a  gnutls  priority  string  as  described  at
                     https://gnutls.org/manual/html_node/Priority-Strings.html.

                     An  example  of  use  of  this  object  is  to control UEFI HTTPS Boot.  The
                     tls-cipher-suites object exposes the ordered list of  permitted  TLS  cipher
                     suites  from  the  host  side to the guest firmware, via fw_cfg. The list is
                     represented as an array of IANA_TLS_CIPHER objects. The  firmware  uses  the
                     IANA_TLS_CIPHER array for configuring guest-side TLS.

                     In  the  following  example,  the  priority at which the host-side policy is
                     retrieved is given by the priority property.  Given that QEMU  uses  GNUTLS,
                     priority=@SYSTEM       may       be       used       to       refer       to
                     /etc/crypto-policies/back-ends/gnutls.config.

                        # qemu-system-x86_64 \
                            -object tls-cipher-suites,id=mysuite0,priority=@SYSTEM \
                            -fw_cfg name=etc/edk2/https/ciphers,gen_id=mysuite0

              -object
              filter-buffer,id=id,netdev=netdevid,interval=t[,queue=all|rx|tx][,status=on|off][,position=head|tail|id=<id>][,insert=behind|before]
                     Interval t can't be 0, this filter batches the packet delivery: all  packets
                     arriving in a given interval on netdev netdevid are delayed until the end of
                     the interval. Interval is in microseconds. status is optional that  indicate
                     whether  the netfilter is on (enabled) or off (disabled), the default status
                     for netfilter will be 'on'.

                     queue all|rx|tx is an option that can be applied to any netfilter.

                     all: the filter is attached both to the receive and the  transmit  queue  of
                     the netdev (default).

                     rx: the filter is attached to the receive queue of the netdev, where it will
                     receive packets sent to the netdev.

                     tx: the filter is attached to the transmit queue of  the  netdev,  where  it
                     will receive packets sent by the netdev.

                     position  head|tail|id=<id>  is an option to specify where the filter should
                     be inserted in the filter list. It can be applied to any netfilter.

                     head: the filter is inserted at the head of  the  filter  list,  before  any
                     existing filters.

                     tail:  the  filter  is  inserted  at the tail of the filter list, behind any
                     existing filters (default).

                     id=<id>: the filter is inserted before or behind  the  filter  specified  by
                     <id>, see the insert option below.

                     insert  behind|before is an option to specify where to insert the new filter
                     relative to the one specified with position=id=<id>. It can  be  applied  to
                     any netfilter.

                     before: insert before the specified filter.

                     behind: insert behind the specified filter (default).

              -object
              filter-mirror,id=id,netdev=netdevid,outdev=chardevid,queue=all|rx|tx[,vnet_hdr_support][,position=head|tail|id=<id>][,insert=behind|before]
                     filter-mirror  on  netdev netdevid,mirror net packet to chardevchardevid, if
                     it has the vnet_hdr_support flag,  filter-mirror  will  mirror  packet  with
                     vnet_hdr_len.

              -object
              filter-redirector,id=id,netdev=netdevid,indev=chardevid,outdev=chardevid,queue=all|rx|tx[,vnet_hdr_support][,position=head|tail|id=<id>][,insert=behind|before]
                     filter-redirector on netdev netdevid,redirect filter's net packet to chardev
                     chardevid,and  redirect   indev's   packet   to   filter.if   it   has   the
                     vnet_hdr_support   flag,   filter-redirector   will   redirect  packet  with
                     vnet_hdr_len. Create a filter-redirector we need to differ  outdev  id  from
                     indev  id,  id  can not be the same. we can just use indev or outdev, but at
                     least one of indev or outdev need to be specified.

              -object
              filter-rewriter,id=id,netdev=netdevid,queue=all|rx|tx,[vnet_hdr_support][,position=head|tail|id=<id>][,insert=behind|before]
                     Filter-rewriter is a part of COLO project.It  will  rewrite  tcp  packet  to
                     secondary  from  primary  to  keep  secondary tcp connection,and rewrite tcp
                     packet to primary from secondary make tcp packet can be handled by client.if
                     it has the vnet_hdr_support flag, we can parse packet with vnet header.

                     usage:                 colo                secondary:                -object
                     filter-redirector,id=f1,netdev=hn0,queue=tx,indev=red0               -object
                     filter-redirector,id=f2,netdev=hn0,queue=rx,outdev=red1              -object
                     filter-rewriter,id=rew0,netdev=hn0,queue=all

              -object
              filter-dump,id=id,netdev=dev[,file=filename][,maxlen=len][,position=head|tail|id=<id>][,insert=behind|before]
                     Dump the network traffic on netdev dev to the file specified by filename. At
                     most  len  bytes  (64k by default) per packet are stored. The file format is
                     libpcap, so it can be analyzed with tools such as tcpdump or Wireshark.

              -object
              colo-compare,id=id,primary_in=chardevid,secondary_in=chardevid,outdev=chardevid,iothread=id[,vnet_hdr_support][,notify_dev=id][,compare_timeout=@var{ms}][,expired_scan_cycle=@var{ms}][,max_queue_size=@var{size}]
                     Colo-compare gets packet from primary_in chardevid  and  secondary_in,  then
                     compare  whether  the payload of primary packet and secondary packet are the
                     same. If same, it will output primary packet to out_dev, else it will notify
                     COLO-framework to do checkpoint and send primary packet to out_dev. In order
                     to improve efficiency, we need to put the  task  of  comparison  in  another
                     iothread.  If  it has the vnet_hdr_support flag, colo compare will send/recv
                     packet  with  vnet_hdr_len.   The  compare_timeout=@var{ms}  determines  the
                     maximum    time    of    the    colo-compare    hold    the    packet.   The
                     expired_scan_cycle=@var{ms} is to set the period of scanning expired primary
                     node  network  packets.   The  max_queue_size=@var{size}  is  to set the max
                     compare queue size depend on user environment.  If  user  want  to  use  Xen
                     COLO, need to add the notify_dev to notify Xen colo-frame to do checkpoint.

                     COLO-compare  must be used with the help of filter-mirror, filter-redirector
                     and filter-rewriter.

                        KVM COLO

                        primary:
                        -netdev tap,id=hn0,vhost=off,script=/etc/qemu-ifup,downscript=/etc/qemu-ifdown
                        -device e1000,id=e0,netdev=hn0,mac=52:a4:00:12:78:66
                        -chardev socket,id=mirror0,host=3.3.3.3,port=9003,server=on,wait=off
                        -chardev socket,id=compare1,host=3.3.3.3,port=9004,server=on,wait=off
                        -chardev socket,id=compare0,host=3.3.3.3,port=9001,server=on,wait=off
                        -chardev socket,id=compare0-0,host=3.3.3.3,port=9001
                        -chardev socket,id=compare_out,host=3.3.3.3,port=9005,server=on,wait=off
                        -chardev socket,id=compare_out0,host=3.3.3.3,port=9005
                        -object iothread,id=iothread1
                        -object filter-mirror,id=m0,netdev=hn0,queue=tx,outdev=mirror0
                        -object filter-redirector,netdev=hn0,id=redire0,queue=rx,indev=compare_out
                        -object filter-redirector,netdev=hn0,id=redire1,queue=rx,outdev=compare0
                        -object colo-compare,id=comp0,primary_in=compare0-0,secondary_in=compare1,outdev=compare_out0,iothread=iothread1

                        secondary:
                        -netdev tap,id=hn0,vhost=off,script=/etc/qemu-ifup,down script=/etc/qemu-ifdown
                        -device e1000,netdev=hn0,mac=52:a4:00:12:78:66
                        -chardev socket,id=red0,host=3.3.3.3,port=9003
                        -chardev socket,id=red1,host=3.3.3.3,port=9004
                        -object filter-redirector,id=f1,netdev=hn0,queue=tx,indev=red0
                        -object filter-redirector,id=f2,netdev=hn0,queue=rx,outdev=red1

                        Xen COLO

                        primary:
                        -netdev tap,id=hn0,vhost=off,script=/etc/qemu-ifup,downscript=/etc/qemu-ifdown
                        -device e1000,id=e0,netdev=hn0,mac=52:a4:00:12:78:66
                        -chardev socket,id=mirror0,host=3.3.3.3,port=9003,server=on,wait=off
                        -chardev socket,id=compare1,host=3.3.3.3,port=9004,server=on,wait=off
                        -chardev socket,id=compare0,host=3.3.3.3,port=9001,server=on,wait=off
                        -chardev socket,id=compare0-0,host=3.3.3.3,port=9001
                        -chardev socket,id=compare_out,host=3.3.3.3,port=9005,server=on,wait=off
                        -chardev socket,id=compare_out0,host=3.3.3.3,port=9005
                        -chardev socket,id=notify_way,host=3.3.3.3,port=9009,server=on,wait=off
                        -object filter-mirror,id=m0,netdev=hn0,queue=tx,outdev=mirror0
                        -object filter-redirector,netdev=hn0,id=redire0,queue=rx,indev=compare_out
                        -object filter-redirector,netdev=hn0,id=redire1,queue=rx,outdev=compare0
                        -object iothread,id=iothread1
                        -object colo-compare,id=comp0,primary_in=compare0-0,secondary_in=compare1,outdev=compare_out0,notify_dev=nofity_way,iothread=iothread1

                        secondary:
                        -netdev tap,id=hn0,vhost=off,script=/etc/qemu-ifup,down script=/etc/qemu-ifdown
                        -device e1000,netdev=hn0,mac=52:a4:00:12:78:66
                        -chardev socket,id=red0,host=3.3.3.3,port=9003
                        -chardev socket,id=red1,host=3.3.3.3,port=9004
                        -object filter-redirector,id=f1,netdev=hn0,queue=tx,indev=red0
                        -object filter-redirector,id=f2,netdev=hn0,queue=rx,outdev=red1

                     If you want to know the detail of above  command  line,  you  can  read  the
                     colo-compare git log.

              -object cryptodev-backend-builtin,id=id[,queues=queues]
                     Creates  a  cryptodev  backend which executes crypto opreation from the QEMU
                     cipher APIS. The id parameter is a unique ID that will be used to  reference
                     this  cryptodev  backend from the virtio-crypto device. The queues parameter
                     is optional, which specify  the  queue  number  of  cryptodev  backend,  the
                     default of queues is 1.

                        # qemu-system-x86_64 \
                          [...] \
                              -object cryptodev-backend-builtin,id=cryptodev0 \
                              -device virtio-crypto-pci,id=crypto0,cryptodev=cryptodev0 \
                          [...]

              -object cryptodev-vhost-user,id=id,chardev=chardevid[,queues=queues]
                     Creates  a  vhost-user cryptodev backend, backed by a chardev chardevid. The
                     id parameter is a unique ID that will be used to  reference  this  cryptodev
                     backend  from  the virtio-crypto device. The chardev should be a unix domain
                     socket backed one.  The vhost-user uses a specifically defined  protocol  to
                     pass  vhost ioctl replacement messages to an application on the other end of
                     the socket. The queues parameter is optional, which specify the queue number
                     of cryptodev backend for multiqueue vhost-user, the default of queues is 1.

                        # qemu-system-x86_64 \
                          [...] \
                              -chardev socket,id=chardev0,path=/path/to/socket \
                              -object cryptodev-vhost-user,id=cryptodev0,chardev=chardev0 \
                              -device virtio-crypto-pci,id=crypto0,cryptodev=cryptodev0 \
                          [...]

              -object secret,id=id,data=string,format=raw|base64[,keyid=secretid,iv=string]

              -object secret,id=id,file=filename,format=raw|base64[,keyid=secretid,iv=string]
                     Defines  a  secret  to  store  a  password,  encryption  key,  or some other
                     sensitive data. The sensitive data can either be  passed  directly  via  the
                     data  parameter,  or  indirectly  via  the  file  parameter.  Using the data
                     parameter is insecure unless the sensitive data is encrypted.

                     The sensitive data can be provided in raw format (the default),  or  base64.
                     When  encoded  as JSON, the raw format only supports valid UTF-8 characters,
                     so base64 is recommended for sending binary data.  QEMU  will  convert  from
                     which  ever format is provided to the format it needs internally. eg, an RBD
                     password can be provided in raw  format,  even  though  it  will  be  base64
                     encoded when passed onto the RBD sever.

                     For  added  protection, it is possible to encrypt the data associated with a
                     secret using the AES-256-CBC cipher.  Use  of  encryption  is  indicated  by
                     providing  the  keyid and iv parameters. The keyid parameter provides the ID
                     of a previously defined secret that contains  the  AES-256  decryption  key.
                     This  key  should  be  32-bytes long and be base64 encoded. The iv parameter
                     provides the random  initialization  vector  used  for  encryption  of  this
                     particular secret and should be a base64 encrypted string of the 16-byte IV.

                     The simplest (insecure) usage is to provide the secret inline

                        # qemu-system-x86_64 -object secret,id=sec0,data=letmein,format=raw

                     The simplest secure usage is to provide the secret via a file

                     #    printf   "letmein"   >   mypasswd.txt   #   QEMU_SYSTEM_MACRO   -object
                     secret,id=sec0,file=mypasswd.txt,format=raw

                     For greater security, AES-256-CBC  should  be  used.  To  illustrate  usage,
                     consider the openssl command line tool which can encrypt the data. Note that
                     when encrypting, the plaintext must be padded to the cipher block  size  (32
                     bytes) using the standard PKCS#5/6 compatible padding algorithm.

                     First a master key needs to be created in base64 encoding:

                        # openssl rand -base64 32 > key.b64
                        # KEY=$(base64 -d key.b64 | hexdump  -v -e '/1 "%02X"')

                     Each  secret  to  be  encrypted needs to have a random initialization vector
                     generated. These do not need to be kept secret

                        # openssl rand -base64 16 > iv.b64
                        # IV=$(base64 -d iv.b64 | hexdump  -v -e '/1 "%02X"')

                     The secret to be defined can now be encrypted, in this  case  we're  telling
                     openssl  to  base64  encode the result, but it could be left as raw bytes if
                     desired.

                        # SECRET=$(printf "letmein" |
                                   openssl enc -aes-256-cbc -a -K $KEY -iv $IV)

                     When launching QEMU, create a master secret pointing to key.b64 and  specify
                     that to be used to decrypt the user password. Pass the contents of iv.b64 to
                     the second secret

                        # qemu-system-x86_64 \
                            -object secret,id=secmaster0,format=base64,file=key.b64 \
                            -object secret,id=sec0,keyid=secmaster0,format=base64,\
                                data=$SECRET,iv=$(<iv.b64)

              -object
              sev-guest,id=id,cbitpos=cbitpos,reduced-phys-bits=val,[sev-device=string,policy=policy,handle=handle,dh-cert-file=file,session-file=file,kernel-hashes=on|off]
                     Create a Secure Encrypted Virtualization (SEV) guest object,  which  can  be
                     used to provide the guest memory encryption support on AMD processors.

                     When  memory encryption is enabled, one of the physical address bit (aka the
                     C-bit) is utilized to mark if a memory page is  protected.  The  cbitpos  is
                     used  to  provide  the  C-bit  position.  The  C-bit position is Host family
                     dependent hence user must provide this value. On EPYC, the value  should  be
                     47.

                     When memory encryption is enabled, we loose certain bits in physical address
                     space. The reduced-phys-bits is used to provide the number of bits we  loose
                     in  physical  address  space.   Similar  to  C-bit, the value is Host family
                     dependent. On EPYC, the value should be 5.

                     The sev-device provides the device file to use for  communicating  with  the
                     SEV  firmware  running  inside  AMD  Secure Processor. The default device is
                     '/dev/sev'. If hardware supports memory encryption then /dev/sev devices are
                     created by CCP driver.

                     The  policy provides the guest policy to be enforced by the SEV firmware and
                     restrict what configuration and operational commands  can  be  performed  on
                     this  guest  by  the  hypervisor. The policy should be provided by the guest
                     owner and is bound to  the  guest  and  cannot  be  changed  throughout  the
                     lifetime of the guest. The default is 0.

                     If  guest  policy  allows sharing the key with another SEV guest then handle
                     can be use to provide handle of the guest from which to share the key.

                     The  dh-cert-file  and  session-file  provides  the  guest  owner's   Public
                     Diffie-Hillman  key  defined in SEV spec. The PDH and session parameters are
                     used for establishing a  cryptographic  session  with  the  guest  owner  to
                     negotiate keys used for attestation. The file must be encoded in base64.

                     The  kernel-hashes  adds  the  hashes  of  given kernel/initrd/ cmdline to a
                     designated guest firmware page for measured Linux  boot  with  -kernel.  The
                     default is off. (Since 6.2)

                     e.g to launch a SEV guest

                        # qemu-system-x86_64 \
                            ...... \
                            -object sev-guest,id=sev0,cbitpos=47,reduced-phys-bits=5 \
                            -machine ...,memory-encryption=sev0 \
                            .....

              -object authz-simple,id=id,identity=string
                     Create an authorization object that will control access to network services.

                     The  identity parameter is identifies the user and its format depends on the
                     network  service  that  authorization  object  is   associated   with.   For
                     authorizing  based  on  TLS x509 certificates, the identity must be the x509
                     distinguished name. Note that care must be taken to escape any commas in the
                     distinguished name.

                     An  example authorization object to validate a x509 distinguished name would
                     look like:

                        # qemu-system-x86_64 \
                            ... \
                            -object 'authz-simple,id=auth0,identity=CN=laptop.example.com,,O=Example Org,,L=London,,ST=London,,C=GB' \
                            ...

                     Note the use of  quotes  due  to  the  x509  distinguished  name  containing
                     whitespace, and escaping of ','.

              -object authz-listfile,id=id,filename=path,refresh=on|off
                     Create an authorization object that will control access to network services.

                     The  filename parameter is the fully qualified path to a file containing the
                     access control list rules in JSON format.

                     An example set of rules that match against SASL usernames might look like:

                        {
                          "rules": [
                             { "match": "fred", "policy": "allow", "format": "exact" },
                             { "match": "bob", "policy": "allow", "format": "exact" },
                             { "match": "danb", "policy": "deny", "format": "glob" },
                             { "match": "dan*", "policy": "allow", "format": "exact" },
                          ],
                          "policy": "deny"
                        }

                     When checking access the object will iterate over  all  the  rules  and  the
                     first rule to match will have its policy value returned as the result. If no
                     rules match, then the default policy value is returned.

                     The rules can either be an exact string match, or they can  use  the  simple
                     UNIX glob pattern matching to allow wildcards to be used.

                     If  refresh  is  set  to  true  the file will be monitored and automatically
                     reloaded whenever its content changes.

                     As with the authz-simple object, the format of the  identity  strings  being
                     matched  depends  on  the  network  service,  but  is  usually  a  TLS  x509
                     distinguished name, or a SASL username.

                     An example authorization object to validate a SASL username would look like:

                        # qemu-system-x86_64 \
                            ... \
                            -object authz-simple,id=auth0,filename=/etc/qemu/vnc-sasl.acl,refresh=on \
                            ...

              -object authz-pam,id=id,service=string
                     Create an authorization object that will control access to network services.

                     The service parameter provides  the  name  of  a  PAM  service  to  use  for
                     authorization.  It  requires that a file /etc/pam.d/service exist to provide
                     the configuration for the account subsystem.

                     An example authorization object to validate a TLS  x509  distinguished  name
                     would look like:

                        # qemu-system-x86_64 \
                            ... \
                            -object authz-pam,id=auth0,service=qemu-vnc \
                            ...

                     There   would   then   be   a   corresponding   config   file   for  PAM  at
                     /etc/pam.d/qemu-vnc that contains:

                        account requisite  pam_listfile.so item=user sense=allow \
                                   file=/etc/qemu/vnc.allow

                     Finally  the  /etc/qemu/vnc.allow  file  would  contain  the  list  of  x509
                     distingished names that are permitted access

                        CN=laptop.example.com,O=Example Home,L=London,ST=London,C=GB

              -object
              iothread,id=id,poll-max-ns=poll-max-ns,poll-grow=poll-grow,poll-shrink=poll-shrink,aio-max-batch=aio-max-batch
                     Creates  a dedicated event loop thread that devices can be assigned to. This
                     is known as an IOThread. By default device emulation happens in vCPU threads
                     or  the  main  event loop thread.  This can become a scalability bottleneck.
                     IOThreads allow device emulation and I/O to run on other host CPUs.

                     The id parameter is a unique ID that will be used to reference this IOThread
                     from  -device  ...,iothread=id.   Multiple  devices  can  be  assigned to an
                     IOThread. Note that not all devices support an iothread parameter.

                     The query-iothreads QMP command lists IOThreads and reports their thread IDs
                     so that the user can configure host CPU pinning/affinity.

                     IOThreads  use  an  adaptive polling algorithm to reduce event loop latency.
                     Instead of entering a blocking system call to monitor file  descriptors  and
                     then  pay  the  cost  of  being  woken  up when an event occurs, the polling
                     algorithm spins waiting for events for a short time. The algorithm's default
                     parameters  are  suitable  for  many  cases  but  can  be  adjusted based on
                     knowledge of the workload and/or host device latency.

                     The poll-max-ns parameter is the maximum number of nanoseconds to busy  wait
                     for events. Polling can be disabled by setting this value to 0.

                     The  poll-grow parameter is the multiplier used to increase the polling time
                     when the algorithm detects it is missing events  due  to  not  polling  long
                     enough.

                     The  poll-shrink  parameter is the divisor used to decrease the polling time
                     when  the  algorithm  detects  it  is  spending  too  long  polling  without
                     encountering events.

                     The aio-max-batch parameter is the maximum number of requests in a batch for
                     the AIO engine, 0 means that the engine will use its default.

                     The IOThread parameters can  be  modified  at  run-time  using  the  qom-set
                     command (where iothread1 is the IOThread's id):

                        (qemu) qom-set /objects/iothread1 poll-max-ns 100000

       During  the graphical emulation, you can use special key combinations to change modes. The
       default key mappings are shown below, but if  you  use  -alt-grab  then  the  modifier  is
       Ctrl-Alt-Shift  (instead  of  Ctrl-Alt) and if you use -ctrl-grab then the modifier is the
       right Ctrl key (instead of Ctrl-Alt):

       Ctrl-Alt-f
              Toggle full screen

       Ctrl-Alt-+
              Enlarge the screen

       Ctrl-Alt--
              Shrink the screen

       Ctrl-Alt-u
              Restore the screen's un-scaled dimensions

       Ctrl-Alt-n
              Switch to virtual console 'n'. Standard console mappings are:

              1      Target system display

              2      Monitor

              3      Serial port

       Ctrl-Alt
              Toggle mouse and keyboard grab.

       In the virtual consoles, you can use Ctrl-Up, Ctrl-Down, Ctrl-PageUp and Ctrl-PageDown  to
       move in the back log.

       During  emulation,  if you are using a character backend multiplexer (which is the default
       if you are using -nographic) then several commands are available via an  escape  sequence.
       These  key  sequences  all start with an escape character, which is Ctrl-a by default, but
       can be changed with -echr. The list below assumes you're using the default.

       Ctrl-a h
              Print this help

       Ctrl-a x
              Exit emulator

       Ctrl-a s
              Save disk data back to file (if -snapshot)

       Ctrl-a t
              Toggle console timestamps

       Ctrl-a b
              Send break (magic sysrq in Linux)

       Ctrl-a c
              Rotate between the frontends connected to the multiplexer  (usually  this  switches
              between the monitor and the console)

       Ctrl-a Ctrl-a
              Send the escape character to the frontend

NOTES

       In  addition  to  using normal file images for the emulated storage devices, QEMU can also
       use networked resources such as iSCSI devices.  These are specified using  a  special  URL
       syntax.

       iSCSI  iSCSI  support allows QEMU to access iSCSI resources directly and use as images for
              the guest storage. Both disk and cdrom images are supported.

              Syntax          for          specifying           iSCSI           LUNs           is
              "iscsi://<target-ip>[:<port>]/<target-iqn>/<lun>"

              By      default      qemu      will      use      the      iSCSI     initiator-name
              'iqn.2008-11.org.linux-kvm[:<name>]' but this can also be set from the command line
              or a configuration file.

              Since  version QEMU 2.4 it is possible to specify a iSCSI request timeout to detect
              stalled requests and force  a  reestablishment  of  the  session.  The  timeout  is
              specified  in  seconds. The default is 0 which means no timeout. Libiscsi 1.15.0 or
              greater is required for this feature.

              Example (without authentication):

                 qemu-system-x86_64 -iscsi initiator-name=iqn.2001-04.com.example:my-initiator \
                                  -cdrom iscsi://192.0.2.1/iqn.2001-04.com.example/2 \
                                  -drive file=iscsi://192.0.2.1/iqn.2001-04.com.example/1

              Example (CHAP username/password via URL):

                 qemu-system-x86_64 -drive file=iscsi://user%password@192.0.2.1/iqn.2001-04.com.example/1

              Example (CHAP username/password via environment variables):

                 LIBISCSI_CHAP_USERNAME="user" \
                 LIBISCSI_CHAP_PASSWORD="password" \
                 qemu-system-x86_64 -drive file=iscsi://192.0.2.1/iqn.2001-04.com.example/1

       NBD    QEMU supports NBD (Network Block Devices) both using TCP protocol as well  as  Unix
              Domain Sockets. With TCP, the default port is 10809.

              Syntax   for   specifying   a   NBD  device  using  TCP,  in  preferred  URI  form:
              "nbd://<server-ip>[:<port>]/[<export>]"

              Syntax for specifying a NBD device using Unix Domain Sockets; remember that '?'  is
              a       shell       glob       character       and      may      need      quoting:
              "nbd+unix:///[<export>]?socket=<domain-socket>"

              Older          syntax          that          is          also           recognized:
              "nbd:<server-ip>:<port>[:exportname=<export>]"

              Syntax    for    specifying    a    NBD    device   using   Unix   Domain   Sockets
              "nbd:unix:<domain-socket>[:exportname=<export>]"

              Example for TCP

                 qemu-system-x86_64 --drive file=nbd:192.0.2.1:30000

              Example for Unix Domain Sockets

                 qemu-system-x86_64 --drive file=nbd:unix:/tmp/nbd-socket

       SSH    QEMU supports SSH (Secure Shell) access to remote disks.

              Examples:

                 qemu-system-x86_64 -drive file=ssh://user@host/path/to/disk.img
                 qemu-system-x86_64 -drive file.driver=ssh,file.user=user,file.host=host,file.port=22,file.path=/path/to/disk.img

              Currently authentication must be done using ssh-agent. Other authentication methods
              may be supported in future.

       GlusterFS
              GlusterFS  is  a  user  space  distributed  file  system.  QEMU supports the use of
              GlusterFS volumes for hosting VM disk images using TCP,  Unix  Domain  Sockets  and
              RDMA transport protocols.

              Syntax for specifying a VM disk image on GlusterFS volume is

                 URI:
                 gluster[+type]://[host[:port]]/volume/path[?socket=...][,debug=N][,logfile=...]

                 JSON:
                 'json:{"driver":"qcow2","file":{"driver":"gluster","volume":"testvol","path":"a.img","debug":N,"logfile":"...",
                                                  "server":[{"type":"tcp","host":"...","port":"..."},
                                                            {"type":"unix","socket":"..."}]}}'

              Example

                 URI:
                 qemu-system-x86_64 --drive file=gluster://192.0.2.1/testvol/a.img,
                                                file.debug=9,file.logfile=/var/log/qemu-gluster.log

                 JSON:
                 qemu-system-x86_64 'json:{"driver":"qcow2",
                                           "file":{"driver":"gluster",
                                                    "volume":"testvol","path":"a.img",
                                                    "debug":9,"logfile":"/var/log/qemu-gluster.log",
                                                    "server":[{"type":"tcp","host":"1.2.3.4","port":24007},
                                                              {"type":"unix","socket":"/var/run/glusterd.socket"}]}}'
                 qemu-system-x86_64 -drive driver=qcow2,file.driver=gluster,file.volume=testvol,file.path=/path/a.img,
                                                       file.debug=9,file.logfile=/var/log/qemu-gluster.log,
                                                       file.server.0.type=tcp,file.server.0.host=1.2.3.4,file.server.0.port=24007,
                                                       file.server.1.type=unix,file.server.1.socket=/var/run/glusterd.socket

              See also http://www.gluster.org.

       HTTP/HTTPS/FTP/FTPS
              QEMU supports read-only access to files accessed over http(s) and ftp(s).

              Syntax using a single filename:

                 <protocol>://[<username>[:<password>]@]<host>/<path>

              where:

              protocol
                     'http', 'https', 'ftp', or 'ftps'.

              username
                     Optional username for authentication to the remote server.

              password
                     Optional password for authentication to the remote server.

              host   Address of the remote server.

              path   Path on the remote server, including any query string.

              The following options are also supported:

              url    The full URL when passing options to the driver explicitly.

              readahead
                     The  amount  of  data  to  read  ahead with each range request to the remote
                     server. This value may optionally have the suffix 'T', 'G', 'M', 'K', 'k' or
                     'b'.  If  it  does not have a suffix, it will be assumed to be in bytes. The
                     value must be a multiple of 512 bytes.  It defaults to 256k.

              sslverify
                     Whether to verify the remote server's certificate when connecting over  SSL.
                     It can have the value 'on' or 'off'. It defaults to 'on'.

              cookie Send  this  cookie  (it can also be a list of cookies separated by ';') with
                     each outgoing request. Only supported when  using  protocols  such  as  HTTP
                     which support cookies, otherwise ignored.

              timeout
                     Set  the timeout in seconds of the CURL connection. This timeout is the time
                     that CURL waits for a response from the remote server to get the size of the
                     image  to  be  downloaded.  If  not set, the default timeout of 5 seconds is
                     used.

              Note that when  passing  options  to  qemu  explicitly,  driver  is  the  value  of
              <protocol>.

              Example: boot from a remote Fedora 20 live ISO image

                 qemu-system-x86_64 --drive media=cdrom,file=https://archives.fedoraproject.org/pub/archive/fedora/linux/releases/20/Live/x86_64/Fedora-Live-Desktop-x86_64-20-1.iso,readonly

                 qemu-system-x86_64 --drive media=cdrom,file.driver=http,file.url=http://archives.fedoraproject.org/pub/fedora/linux/releases/20/Live/x86_64/Fedora-Live-Desktop-x86_64-20-1.iso,readonly

              Example: boot from a remote Fedora 20 cloud image using a local overlay for writes,
              copy-on-read, and a readahead of 64k

                 qemu-img create -f qcow2 -o backing_file='json:{"file.driver":"http",, "file.url":"http://archives.fedoraproject.org/pub/archive/fedora/linux/releases/20/Images/x86_64/Fedora-x86_64-20-20131211.1-sda.qcow2",, "file.readahead":"64k"}' /tmp/Fedora-x86_64-20-20131211.1-sda.qcow2

                 qemu-system-x86_64 -drive file=/tmp/Fedora-x86_64-20-20131211.1-sda.qcow2,copy-on-read=on

              Example: boot from an image stored on a VMware vSphere server  with  a  self-signed
              certificate  using  a local overlay for writes, a readahead of 64k and a timeout of
              10 seconds.

                 qemu-img create -f qcow2 -o backing_file='json:{"file.driver":"https",, "file.url":"https://user:password@vsphere.example.com/folder/test/test-flat.vmdk?dcPath=Datacenter&dsName=datastore1",, "file.sslverify":"off",, "file.readahead":"64k",, "file.timeout":10}' /tmp/test.qcow2

                 qemu-system-x86_64 -drive file=/tmp/test.qcow2

SEE ALSO

       The HTML documentation of QEMU for more precise information and Linux user  mode  emulator
       invocation.

AUTHOR

       Fabrice Bellard

COPYRIGHT

       2024, The QEMU Project Developers