QEMU Emulator User Documentation
********************************


1 Introduction
  1.1 Features
2 QEMU PC System emulator
  2.1 Introduction
  2.2 Quick Start
  2.3 Invocation
    2.3.1 Standard options
    2.3.2 Block device options
    2.3.3 USB options
    2.3.4 Display options
    2.3.5 i386 target only
    2.3.6 Network options
    2.3.7 Character device options
    2.3.8 Device URL Syntax
    2.3.9 Bluetooth(R) options
    2.3.10 TPM device options
    2.3.11 Linux/Multiboot boot specific
    2.3.12 Debug/Expert options
    2.3.13 Generic object creation
  2.4 Keys in the graphical frontends
  2.5 Keys in the character backend multiplexer
  2.6 QEMU Monitor
    2.6.1 Commands
    2.6.2 Integer expressions
  2.7 Disk Images
    2.7.1 Quick start for disk image creation
    2.7.2 Snapshot mode
    2.7.3 VM snapshots
    2.7.4 ‘qemu-img’ Invocation
    2.7.5 ‘qemu-nbd’ Invocation
    2.7.6 ‘qemu-ga’ Invocation
    2.7.7 Disk image file formats
      2.7.7.1 Read-only formats
    2.7.8 Using host drives
      2.7.8.1 Linux
      2.7.8.2 Windows
      2.7.8.3 Mac OS X
    2.7.9 Virtual FAT disk images
    2.7.10 NBD access
    2.7.11 Sheepdog disk images
    2.7.12 iSCSI LUNs
    2.7.13 GlusterFS disk images
    2.7.14 Secure Shell (ssh) disk images
  2.8 Network emulation
    2.8.1 VLANs
    2.8.2 Using TAP network interfaces
      2.8.2.1 Linux host
      2.8.2.2 Windows host
    2.8.3 Using the user mode network stack
    2.8.4 Connecting VLANs between QEMU instances
  2.9 Other Devices
    2.9.1 Inter-VM Shared Memory device
      2.9.1.1 Migration with ivshmem
      2.9.1.2 ivshmem and hugepages
  2.10 Direct Linux Boot
  2.11 USB emulation
    2.11.1 Connecting USB devices
    2.11.2 Using host USB devices on a Linux host
  2.12 VNC security
    2.12.1 Without passwords
    2.12.2 With passwords
    2.12.3 With x509 certificates
    2.12.4 With x509 certificates and client verification
    2.12.5 With x509 certificates, client verification and passwords
    2.12.6 With SASL authentication
    2.12.7 With x509 certificates and SASL authentication
    2.12.8 Generating certificates for VNC
      2.12.8.1 Setup the Certificate Authority
      2.12.8.2 Issuing server certificates
      2.12.8.3 Issuing client certificates
    2.12.9 Configuring SASL mechanisms
  2.13 GDB usage
  2.14 Target OS specific information
    2.14.1 Linux
    2.14.2 Windows
      2.14.2.1 SVGA graphic modes support
      2.14.2.2 CPU usage reduction
      2.14.2.3 Windows 2000 disk full problem
      2.14.2.4 Windows 2000 shutdown
      2.14.2.5 Share a directory between Unix and Windows
      2.14.2.6 Windows XP security problem
    2.14.3 MS-DOS and FreeDOS
      2.14.3.1 CPU usage reduction
3 QEMU System emulator for non PC targets
  3.1 PowerPC System emulator
  3.2 Sparc32 System emulator
  3.3 Sparc64 System emulator
  3.4 MIPS System emulator
  3.5 ARM System emulator
  3.6 ColdFire System emulator
  3.7 Cris System emulator
  3.8 Microblaze System emulator
  3.9 SH4 System emulator
  3.10 Xtensa System emulator
4 QEMU User space emulator
  4.1 Supported Operating Systems
  4.2 Features
  4.3 Linux User space emulator
    4.3.1 Quick Start
    4.3.2 Wine launch
    4.3.3 Command line options
    4.3.4 Other binaries
  4.4 BSD User space emulator
    4.4.1 BSD Status
    4.4.2 Quick Start
    4.4.3 Command line options
Appendix A Implementation notes
  A.1 CPU emulation
    A.1.1 x86 and x86-64 emulation
    A.1.2 ARM emulation
    A.1.3 MIPS emulation
    A.1.4 PowerPC emulation
    A.1.5 Sparc32 and Sparc64 emulation
    A.1.6 Xtensa emulation
  A.2 Translator Internals
  A.3 QEMU compared to other emulators
  A.4 Bibliography
Appendix B License
Appendix C Index
  C.1 Concept Index
  C.2 Function Index
  C.3 Keystroke Index
  C.4 Program Index
  C.5 Data Type Index
  C.6 Variable Index
1 Introduction
**************

1.1 Features
============

QEMU is a FAST! processor emulator using dynamic translation to achieve
good emulation speed.

QEMU has two operating modes:

   • Full system emulation.  In this mode, QEMU emulates a full system
     (for example a PC), including one or several processors and various
     peripherals.  It can be used to launch different Operating Systems
     without rebooting the PC or to debug system code.

   • User mode emulation.  In this mode, QEMU can launch processes
     compiled for one CPU on another CPU. It can be used to launch the
     Wine Windows API emulator (<http://www.winehq.org>) or to ease
     cross-compilation and cross-debugging.

QEMU has the following features:

   • QEMU can run without a host kernel driver and yet gives acceptable
     performance.  It uses dynamic translation to native code for
     reasonable speed, with support for self-modifying code and precise
     exceptions.

   • It is portable to several operating systems (GNU/Linux, *BSD, Mac
     OS X, Windows) and architectures.

   • It performs accurate software emulation of the FPU.

QEMU user mode emulation has the following features:
   • Generic Linux system call converter, including most ioctls.

   • clone() emulation using native CPU clone() to use Linux scheduler
     for threads.

   • Accurate signal handling by remapping host signals to target
     signals.

QEMU full system emulation has the following features:
   • QEMU uses a full software MMU for maximum portability.

   • QEMU can optionally use an in-kernel accelerator, like kvm.  The
     accelerators execute most of the guest code natively, while
     continuing to emulate the rest of the machine.

   • Various hardware devices can be emulated and in some cases, host
     devices (e.g.  serial and parallel ports, USB, drives) can be used
     transparently by the guest Operating System.  Host device
     passthrough can be used for talking to external physical
     peripherals (e.g.  a webcam, modem or tape drive).

   • Symmetric multiprocessing (SMP) support.  Currently, an in-kernel
     accelerator is required to use more than one host CPU for
     emulation.

2 QEMU PC System emulator
*************************

2.1 Introduction
================

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
   − PCI UHCI USB controller and a virtual USB 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-i386 dos.img -soundhw gus -parallel none

Alternatively:
     qemu-system-i386 dos.img -device gus,irq=5

Or some other unclaimed IRQ.

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

2.2 Quick Start
===============

Download and uncompress the linux image (‘linux.img’) and type:

     qemu-system-i386 linux.img

Linux should boot and give you a prompt.

2.3 Invocation
==============

     qemu-system-i386 [OPTIONS] [DISK_IMAGE]

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

2.3.1 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.  Supported machine properties are:
     ‘accel=ACCELS1[:ACCELS2[:...]]’
          This is used to enable an accelerator.  Depending on the
          target architecture, kvm, xen, 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.
     ‘kernel_irqchip=on|off’
          Controls in-kernel irqchip support for the chosen accelerator
          when available.
     ‘gfx_passthru=on|off’
          Enables IGD GFX passthrough support for the chosen machine
          when available.
     ‘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.
     ‘kvm_shadow_mem=size’
          Defines the size of the KVM shadow MMU.
     ‘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.
‘-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, 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.
     ‘thread=single|multi’
          Controls number of TCG threads.  When the TCG is
          multi-threaded there will be one thread per vCPU therefor
          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).
‘-smp [cpus=]N[,cores=CORES][,threads=THREADS][,sockets=SOCKETS][,maxcpus=MAXCPUS]’
     Simulate an SMP system with N CPUs.  On the PC target, up to 255
     CPUs are supported.  On Sparc32 target, Linux limits the number of
     usable CPUs to 4.  For the PC target, the number of CORES per
     socket, the number of THREADS per cores and the total number of
     SOCKETS can be specified.  Missing values will be computed.  If any
     on the three values is given, the total number of CPUs N can be
     omitted.  MAXCPUS specifies the maximum number of hotpluggable
     CPUs.
‘-numa node[,mem=SIZE][,cpus=FIRSTCPU[-LASTCPU]][,nodeid=NODE]’
‘-numa node[,memdev=ID][,cpus=FIRSTCPU[-LASTCPU]][,nodeid=NODE]’
     Define a NUMA node and assign RAM and VCPUs to it.

     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

     ‘mem’ assigns a given RAM amount to a node.  ‘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.

     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.

‘-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-i386
          -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-i386 -global ide-drive.physical_block_size=4096 -drive file=file,if=ide,index=0,media=disk

     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-i386 -boot order=nc
          # boot from CD-ROM first, switch back to default order after reboot
          qemu-system-i386 -boot once=d
          # boot with a splash picture for 5 seconds.
          qemu-system-i386 -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 audio subsystem help: list of drivers, tunable
     parameters.
‘-soundhw CARD1[,CARD2,...] or -soundhw all’
     Enable audio and selected sound hardware.  Use ’help’ to print all
     available sound hardware.

          qemu-system-i386 -soundhw sb16,adlib disk.img
          qemu-system-i386 -soundhw es1370 disk.img
          qemu-system-i386 -soundhw ac97 disk.img
          qemu-system-i386 -soundhw hda disk.img
          qemu-system-i386 -soundhw all disk.img
          qemu-system-i386 -soundhw help

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

          modprobe i810_audio clocking=48000
‘-balloon none’
     Disable balloon device.
‘-balloon virtio[,addr=ADDR]’
     Enable virtio balloon device (default), optionally with PCI address
     ADDR.
‘-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[,slave_addr=VAL]’

     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.

‘-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.

‘-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.

2.3.2 Block device options
--------------------------

‘-fda FILE’
‘-fdb FILE’
     Use FILE as floppy disk 0/1 image (*note disk_images::).
‘-hda FILE’
‘-hdb FILE’
‘-hdc FILE’
‘-hdd FILE’
     Use FILE as hard disk 0, 1, 2 or 3 image (*note disk_images::).
‘-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 (*note host_drives::).
‘-drive OPTION[,OPTION[,OPTION[,...]]]’

     Define a new drive.  Valid options are:

     ‘file=FILE’
          This option defines which disk image (*note disk_images::) 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.
     ‘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.
     ‘cyls=C,heads=H,secs=S[,trans=T]’
          These options have the same definition as they have in
          ‘-hdachs’.
     ‘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.
     ‘aio=AIO’
          AIO is "threads", or "native" and selects between pthread
          based disk I/O and native Linux AIO.
     ‘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.
     ‘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.
     ‘serial=SERIAL’
          This option specifies the serial number to assign to the
          device.
     ‘addr=ADDR’
          Specify the controller’s PCI address (if=virtio only).
     ‘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’.
     ‘readonly’
          Open drive ‘file’ as read-only.  Guest write attempts will
          fail.
     ‘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.
     ‘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.

     By default, the ‘cache=writeback’ 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=writethrough’.
     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.

     The host page cache can be avoided entirely with ‘cache=none’.
     This will attempt to do disk IO directly to the guest’s memory.
     QEMU may still perform an internal copy of the data.  Note that
     this is considered a writeback mode and the guest OS must handle
     the disk write cache correctly in order to avoid data corruption on
     host crashes.

     The host page cache can be avoided while only sending write
     notifications to the guest when the data has been flushed to the
     disk using ‘cache=directsync’.

     In case you don’t care about data integrity over host failures, use
     ‘cache=unsafe’.  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.  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-i386 -drive file=file,index=2,media=cdrom

     Instead of ‘-hda’, ‘-hdb’, ‘-hdc’, ‘-hdd’, you can use:
          qemu-system-i386 -drive file=file,index=0,media=disk
          qemu-system-i386 -drive file=file,index=1,media=disk
          qemu-system-i386 -drive file=file,index=2,media=disk
          qemu-system-i386 -drive file=file,index=3,media=disk

     You can open an image using pre-opened file descriptors from an fd
     set:
          qemu-system-i386
          -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-i386 -drive file=file,if=ide,index=1,media=cdrom

     If you don’t specify the "file=" argument, you define an empty
     drive:
          qemu-system-i386 -drive if=ide,index=1,media=cdrom

     Instead of ‘-fda’, ‘-fdb’, you can use:
          qemu-system-i386 -drive file=file,index=0,if=floppy
          qemu-system-i386 -drive file=file,index=1,if=floppy

     By default, INTERFACE is "ide" and INDEX is automatically
     incremented:
          qemu-system-i386 -drive file=a -drive file=b"
     is interpreted like:
          qemu-system-i386 -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> (*note
     disk_images::).
‘-hdachs C,H,S,[,T]’
     Force hard disk 0 physical geometry (1 <= C <= 16383, 1 <= H <= 16,
     1 <= S <= 63) and optionally force the BIOS translation mode
     (T=none, lba or auto).  Usually QEMU can guess all those
     parameters.  This option is useful for old MS-DOS disk images.

‘-fsdev FSDRIVER,id=ID,path=PATH,[security_model=SECURITY_MODEL][,writeout=WRITEOUT][,readonly][,socket=SOCKET|sock_fd=SOCK_FD]’
     Define a new file system device.  Valid options are:
     ‘FSDRIVER’
          This option specifies the fs driver backend to use.  Currently
          "local", "handle" and "proxy" file system drivers are
          supported.
     ‘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 handle, 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’
          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
     ‘sock_fd=SOCK_FD’
          Enables proxy filesystem driver to use passed socket
          descriptor for communicating with virtfs-proxy-helper.
          Usually a helper like libvirt will create socketpair and pass
          one of the fds as sock_fd

     -fsdev option is used along with -device driver "virtio-9p-pci".
‘-device virtio-9p-pci,fsdev=ID,mount_tag=MOUNT_TAG’
     Options for virtio-9p-pci driver are:
     ‘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 FSDRIVER[,path=PATH],mount_tag=MOUNT_TAG[,security_model=SECURITY_MODEL][,writeout=WRITEOUT][,readonly][,socket=SOCKET|sock_fd=SOCK_FD]’

     The general form of a Virtual File system pass-through options are:
     ‘FSDRIVER’
          This option specifies the fs driver backend to use.  Currently
          "local", "handle" and "proxy" file system drivers are
          supported.
     ‘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 handle, 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’
          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.  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
‘-virtfs_synth’
     Create synthetic file system image

2.3.3 USB options
-----------------

‘-usb’
     Enable the USB driver (will be the default soon)

‘-usbdevice DEVNAME’
     Add the USB device DEVNAME.  *Note usb_devices::.

     ‘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.

     ‘disk:[format=FORMAT]:FILE’
          Mass storage device based on file.  The optional FORMAT
          argument will be used rather than detecting the format.  Can
          be used to specify ‘format=raw’ to avoid interpreting an
          untrusted format header.

     ‘host:BUS.ADDR’
          Pass through the host device identified by BUS.ADDR (Linux
          only).

     ‘host:VENDOR_ID:PRODUCT_ID’
          Pass through the host device identified by
          VENDOR_ID:PRODUCT_ID (Linux only).

     ‘serial:[vendorid=VENDOR_ID][,productid=PRODUCT_ID]:DEV’
          Serial converter to host character device DEV, see ‘-serial’
          for the available devices.

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

     ‘net:OPTIONS’
          Network adapter that supports CDC ethernet and RNDIS
          protocols.

2.3.4 Display options
---------------------

‘-display TYPE’
     Select type of display to use.  This option is a replacement for
     the old style -sdl/-curses/...  options.  Valid values for TYPE are
     ‘sdl’
          Display video output via SDL (usually in a separate graphics
          window; see the SDL documentation for other possibilities).
     ‘curses’
          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.
     ‘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.
     ‘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.
     ‘vnc’
          Start a VNC server on display <arg>
‘-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.
‘-no-frame’
     Do not use decorations for SDL windows and start them using the
     whole available screen space.  This makes the using QEMU in a
     dedicated desktop workspace more convenient.
‘-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).
‘-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).
‘-no-quit’
     Disable SDL window close capability.
‘-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’
     ‘ipv6’
     ‘unix’
          Force using the specified IP version.

     ‘password=<secret>’
          Set the password you need to authenticate.

     ‘sasl’
          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’
          Allow client connects without authentication.

     ‘disable-copy-paste’
          Disable copy paste between the client and the guest.

     ‘disable-agent-file-xfer’
          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).
‘-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 ‘-usbdevice 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’

          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’

          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’

          Require that password based authentication is used for client
          connections.

          The password must be set separately using the ‘set_password’
          command in the *note pcsys_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.

     ‘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.

          The ‘tls-creds’ parameter obsoletes the ‘tls’, ‘x509’, and
          ‘x509verify’ options, and as such it is not permitted to set
          both new and old type options at the same time.

     ‘tls’

          Require that client use TLS when communicating with the VNC
          server.  This uses anonymous TLS credentials so is susceptible
          to a man-in-the-middle attack.  It is recommended that this
          option be combined with either the ‘x509’ or ‘x509verify’
          options.

          This option is now deprecated in favor of using the
          ‘tls-creds’ argument.

     ‘x509=/PATH/TO/CERTIFICATE/DIR’

          Valid if ‘tls’ is specified.  Require that x509 credentials
          are used for negotiating the TLS session.  The server will
          send its x509 certificate to the client.  It is recommended
          that a password be set on the VNC server to provide
          authentication of the client when this is used.  The path
          following this option specifies where the x509 certificates
          are to be loaded from.  See the *note vnc_security:: section
          for details on generating certificates.

          This option is now deprecated in favour of using the
          ‘tls-creds’ argument.

     ‘x509verify=/PATH/TO/CERTIFICATE/DIR’

          Valid if ‘tls’ is specified.  Require that x509 credentials
          are used for negotiating the TLS session.  The server will
          send its x509 certificate to the client, and request that the
          client send its own x509 certificate.  The server will
          validate the client’s certificate against the CA certificate,
          and reject clients when validation fails.  If the certificate
          authority is trusted, this is a sufficient authentication
          mechanism.  You may still wish to set a password on the VNC
          server as a second authentication layer.  The path following
          this option specifies where the x509 certificates are to be
          loaded from.  See the *note vnc_security:: section for details
          on generating certificates.

          This option is now deprecated in favour of using the
          ‘tls-creds’ argument.

     ‘sasl’

          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
          *note vnc_security:: section for details on using SASL
          authentication.

     ‘acl’

          Turn on access control lists for checking of the x509 client
          certificate and SASL party.  For x509 certs, the ACL check is
          made against the certificate’s distinguished name.  This is
          something that looks like ‘C=GB,O=ACME,L=Boston,CN=bob’.  For
          SASL party, the ACL check is made against the username, which
          depending on the SASL plugin, may include a realm component,
          eg ‘bob’ or ‘bob@EXAMPLE.COM’.  When the ‘acl’ flag is set,
          the initial access list will be empty, with a ‘deny’ policy.
          Thus no one will be allowed to use the VNC server until the
          ACLs have been loaded.  This can be achieved using the ‘acl’
          monitor command.

     ‘lossy’

          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’

          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 1.  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.

2.3.5 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][,family=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=17[,loc_pfx=STR][,bank=STR][,manufacturer=STR][,serial=STR][,asset=STR][,part=STR][,speed=%D]’
     Specify SMBIOS type 17 fields

2.3.6 Network options
---------------------

‘-net nic[,vlan=N][,macaddr=MAC][,model=TYPE] [,name=NAME][,addr=ADDR][,vectors=V]’
     Create a new Network Interface Card and connect it to VLAN N (N = 0
     is the default).  The NIC is an e1000 by default on the PC target.
     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.  Valid values for TYPE are ‘virtio’, ‘i82551’, ‘i82557b’,
     ‘i82559er’, ‘ne2k_pci’, ‘ne2k_isa’, ‘pcnet’, ‘rtl8139’, ‘e1000’,
     ‘smc91c111’, ‘lance’ and ‘mcf_fec’.  Not all devices are supported
     on all targets.  Use ‘-net nic,model=help’ for a list of available
     devices for your target.

‘-netdev user,id=ID[,OPTION][,OPTION][,...]’
‘-net user[,OPTION][,OPTION][,...]’
     Use the user mode network stack which requires no administrator
     privilege to run.  Valid options are:

     ‘vlan=N’
          Connect user mode stack to VLAN N (N = 0 is the default).

     ‘id=ID’
     ‘name=NAME’
          Assign symbolic name for use in monitor commands.

          ‘ipv4’ and ‘ipv6’ 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 -net user,dnssearch=mgmt.example.org,dnssearch=example.org [...]

     ‘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).

     ‘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-i386 -hda linux.img -boot n -net user,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.
          QEMU was tested successfully with smbd versions from Red Hat
          9, Fedora Core 3 and OpenSUSE 11.x.

     ‘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-i386 -net 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-i386 -net 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 -net 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 -net 'user,guestfwd=tcp:10.0.2.100:1234-cmd:netcat 10.10.1.1 4321'

     Note: Legacy stand-alone options -tftp, -bootp, -smb and -redir are
     still processed and applied to -net user.  Mixing them with the new
     configuration syntax gives undefined results.  Their use for new
     applications is discouraged as they will be removed from future
     versions.

‘-netdev tap,id=ID[,fd=H][,ifname=NAME][,script=FILE][,downscript=DFILE][,br=BRIDGE][,helper=HELPER]’
‘-net tap[,vlan=N][,name=NAME][,fd=H][,ifname=NAME][,script=FILE][,downscript=DFILE][,br=BRIDGE][,helper=HELPER]’
     Connect the host TAP network interface NAME to VLAN N.

     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
     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-i386 linux.img -net nic -net tap

          #launch a QEMU instance with two NICs, each one connected
          #to a TAP device
          qemu-system-i386 linux.img \
          -net nic,vlan=0 -net tap,vlan=0,ifname=tap0 \
          -net nic,vlan=1 -net tap,vlan=1,ifname=tap1

          #launch a QEMU instance with the default network helper to
          #connect a TAP device to bridge br0
          qemu-system-i386 linux.img \
          -net nic -net tap,"helper=/path/to/qemu-bridge-helper"

‘-netdev bridge,id=ID[,br=BRIDGE][,helper=HELPER]’
‘-net bridge[,vlan=N][,name=NAME][,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-i386 linux.img -net bridge -net nic,model=virtio

          #launch a QEMU instance with the default network helper to
          #connect a TAP device to bridge qemubr0
          qemu-system-i386 linux.img -net bridge,br=qemubr0 -net nic,model=virtio

‘-netdev socket,id=ID[,fd=H][,listen=[HOST]:PORT][,connect=HOST:PORT]’
‘-net socket[,vlan=N][,name=NAME][,fd=H] [,listen=[HOST]:PORT][,connect=HOST:PORT]’

     Connect the VLAN N to a remote VLAN in 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-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:56 \
          -net socket,listen=:1234
          # connect the VLAN 0 of this instance to the VLAN 0
          # of the first instance
          qemu-system-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:57 \
          -net socket,connect=127.0.0.1:1234

‘-netdev socket,id=ID[,fd=H][,mcast=MADDR:PORT[,localaddr=ADDR]]’
‘-net socket[,vlan=N][,name=NAME][,fd=H][,mcast=MADDR:PORT[,localaddr=ADDR]]’

     Create a VLAN N shared 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-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:56 \
          -net socket,mcast=230.0.0.1:1234
          # launch another QEMU instance on same "bus"
          qemu-system-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:57 \
          -net socket,mcast=230.0.0.1:1234
          # launch yet another QEMU instance on same "bus"
          qemu-system-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:58 \
          -net socket,mcast=230.0.0.1:1234

     Example (User Mode Linux compat.):
          # launch QEMU instance (note mcast address selected
          # is UML's default)
          qemu-system-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:56 \
          -net socket,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-i386 linux.img \
          -net nic,macaddr=52:54:00:12:34:56 \
          -net socket,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][,udp][,cookie64][,counter][,pincounter][,txcookie=TXCOOKIE][,rxcookie=RXCOOKIE][,offset=OFFSET]’
‘-net l2tpv3[,vlan=N][,name=NAME],src=SRCADDR,dst=DSTADDR[,srcport=SRCPORT][,dstport=DSTPORT],txsession=TXSESSION[,rxsession=RXSESSION][,ipv6][,udp][,cookie64][,counter][,pincounter][,txcookie=TXCOOKIE][,rxcookie=RXCOOKIE][,offset=OFFSET]’
     Connect VLAN N to L2TPv3 pseudowire.  L2TPv3 (RFC3391) 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-i386 linux.img -net nic -net l2tpv3,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]’
‘-net vde[,vlan=N][,name=NAME][,sock=SOCKETPATH] [,port=N][,group=GROUPNAME][,mode=OCTALMODE]’
     Connect VLAN N 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-i386 linux.img -net nic -net vde,sock=/tmp/myswitch

‘-netdev hubport,id=ID,hubid=HUBID’

     Create a hub port on QEMU "vlan" HUBID.

     The hubport netdev lets you connect a NIC to a QEMU "vlan" instead
     of a single netdev.  ‘-net’ and ‘-device’ with parameter ‘vlan’
     create the required hub automatically.

‘-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

‘-net dump[,vlan=N][,file=FILE][,len=LEN]’
     Dump network traffic on VLAN N to file FILE (‘qemu-vlan0.pcap’ by
     default).  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.  Note: For devices created with
     ’-netdev’, use ’-object filter-dump,...’ instead.

‘-net none’
     Indicate that no network devices should be configured.  It is used
     to override the default configuration (‘-net nic -net user’) which
     is activated if no ‘-net’ options are provided.

2.3.7 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.  *Note Keys in the
     character backend multiplexer: mux_keys.

     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.

     Further options to each backend are described below.

‘-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] [,nowait] [,telnet] [,reconnect=SECONDS] [,tls-creds=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’ specifies that the socket shall be a listening socket.

     ‘nowait’ specifies that QEMU should not block waiting for a client
     to connect to a listening socket.

     ‘telnet’ specifies that traffic on the socket should interpret
     telnet escape sequences.

     ‘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.

     TCP and unix socket options are given below:

     ‘TCP options: port=PORT [,host=HOST] [,to=TO] [,ipv4] [,ipv6] [,nodelay]’

          ‘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’ and ‘ipv6’ specify that either IPv4 or IPv6 must be
          used.  If neither is specified the socket may use either
          protocol.

          ‘nodelay’ disables the Nagle algorithm.

     ‘unix options: path=PATH’

          ‘path’ specifies the local path of the unix socket.  ‘path’ is
          required.

‘-chardev udp ,id=ID [,host=HOST] ,port=PORT [,localaddr=LOCALADDR] [,localport=LOCALPORT] [,ipv4] [,ipv6]’

     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’ and ‘ipv6’ 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).

2.3.8 Device URL Syntax
-----------------------

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-i386 -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-i386 -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-i386 -drive file=iscsi://192.0.2.1/iqn.2001-04.com.example/1

     iSCSI support is an optional feature of QEMU and only available
     when compiled and linked against libiscsi.

     iSCSI parameters such as username and password can also be
     specified via a configuration file.  See qemu-doc for more
     information and examples.

‘NBD’
     QEMU supports NBD (Network Block Devices) both using TCP protocol
     as well as Unix Domain Sockets.

     Syntax for specifying a NBD device using TCP
     “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-i386 --drive file=nbd:192.0.2.1:30000

     Example for Unix Domain Sockets
          qemu-system-i386 --drive file=nbd:unix:/tmp/nbd-socket

‘SSH’
     QEMU supports SSH (Secure Shell) access to remote disks.

     Examples:
          qemu-system-i386 -drive file=ssh://user@host/path/to/disk.img
          qemu-system-i386 -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.

‘Sheepdog’
     Sheepdog is a distributed storage system for QEMU. QEMU supports
     using either local sheepdog devices or remote networked devices.

     Syntax for specifying a sheepdog device
          sheepdog[+tcp|+unix]://[host:port]/vdiname[?socket=path][#snapid|#tag]

     Example
          qemu-system-i386 --drive file=sheepdog://192.0.2.1:30000/MyVirtualMachine

     See also <https://sheepdog.github.io/sheepdog/>.

‘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=http://dl.fedoraproject.org/pub/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://dl.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":"https://dl.fedoraproject.org/pub/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

2.3.9 Bluetooth(R) options
--------------------------

‘-bt hci[...]’
     Defines the function of the corresponding Bluetooth HCI. -bt
     options are matched with the HCIs present in the chosen machine
     type.  For example when emulating a machine with only one HCI built
     into it, only the first ‘-bt hci[...]’ option is valid and defines
     the HCI’s logic.  The Transport Layer is decided by the machine
     type.  Currently the machines ‘n800’ and ‘n810’ have one HCI and
     all other machines have none.

     The following three types are recognized:

     ‘-bt hci,null’
          (default) The corresponding Bluetooth HCI assumes no internal
          logic and will not respond to any HCI commands or emit events.

     ‘-bt hci,host[:ID]’
          (‘bluez’ only) The corresponding HCI passes commands / events
          to / from the physical HCI identified by the name ID (default:
          ‘hci0’) on the computer running QEMU. Only available on
          ‘bluez’ capable systems like Linux.

     ‘-bt hci[,vlan=N]’
          Add a virtual, standard HCI that will participate in the
          Bluetooth scatternet N (default ‘0’).  Similarly to ‘-net’
          VLANs, devices inside a bluetooth network N can only
          communicate with other devices in the same network
          (scatternet).

‘-bt vhci[,vlan=N]’
     (Linux-host only) Create a HCI in scatternet N (default 0) attached
     to the host bluetooth stack instead of to the emulated target.
     This allows the host and target machines to participate in a common
     scatternet and communicate.  Requires the Linux ‘vhci’ driver
     installed.  Can be used as following:

          qemu-system-i386 [...OPTIONS...] -bt hci,vlan=5 -bt vhci,vlan=5

‘-bt device:DEV[,vlan=N]’
     Emulate a bluetooth device DEV and place it in network N (default
     ‘0’).  QEMU can only emulate one type of bluetooth devices
     currently:

     ‘keyboard’
          Virtual wireless keyboard implementing the HIDP bluetooth
          profile.

2.3.10 TPM device options
-------------------------

The general form of a TPM device option is:

‘-tpmdev BACKEND ,id=ID [,OPTIONS]’
     Backend type must be: ‘passthrough’.

     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.

     Options to each backend are described below.

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

‘-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.

2.3.11 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.

2.3.12 Debug/Expert options
---------------------------

‘-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][,nowait][,nodelay][,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 option QEMU will wait for a
          client socket application to connect to the port before
          continuing, unless the ‘nowait’ option was specified.  The
          ‘nodelay’ option disables the Nagle buffering algorithm.  The
          ‘reconnect’ option only applies if NOSERVER 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’ 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
          ‘Example to not wait and listen on ip 192.168.0.100 port 4444’
               -serial tcp:192.168.0.100:4444,server,nowait

     ‘telnet:HOST:PORT[,server][,nowait][,nodelay]’
          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.

     ‘unix:PATH[,server][,nowait][,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,nowait’
          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]’
     Setup monitor on chardev NAME.
‘-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.
‘-S’
     Do not start CPU at startup (you must type ’c’ in the monitor).
‘-realtime mlock=on|off’
     Run qemu with realtime features.  mlocking qemu and guest memory
     can be enabled via ‘mlock=on’ (enabled by default).
‘-gdb DEV’
     Wait for gdb connection on device DEV (*note gdb_usage::).  Typical
     connections will likely be TCP-based, but also UDP, pseudo TTY, or
     even stdio are reasonable use case.  The latter is allowing to
     start QEMU from within gdb and establish the connection via a pipe:
          (gdb) target remote | exec qemu-system-i386 -gdb stdio ...
‘-s’
     Shorthand for -gdb tcp::1234, i.e.  open a gdbserver on TCP port
     1234 (*note gdb_usage::).
‘-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.
‘-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.
‘-enable-hax’
     Enable HAX (Hardware-based Acceleration eXecution) support.  This
     option is only available if HAX support is enabled when compiling.
     HAX is only applicable to MAC and Windows platform, and thus does
     not conflict with KVM.
‘-xen-domid ID’
     Specify xen guest domain ID (XEN only).
‘-xen-create’
     Create domain using xen hypercalls, bypassing xend.  Warning:
     should not be used when xend is in use (XEN only).
‘-xen-attach’
     Attach to existing xen domain.  xend will use this when starting
     QEMU (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.
‘-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|DATE][,clock=host|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 DATE 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.  To
     even prevent it from progressing during suspension, you can set it
     to ‘vm’.

     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][,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.

     When the virtual cpu is sleeping, the virtual time will advance at
     default speed unless ‘sleep=on|off’ is specified.  With
     ‘sleep=on|off’, 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 give
     deterministic execution times from the guest point of view.

     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.

     ‘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).

     When ‘rr’ option is specified deterministic record/replay is
     enabled.  Replay log is written into FILENAME file in record mode
     and read from this file in replay mode.

     Option rrsnapshot is used to create new vm snapshot named SNAPSHOT
     at the start of execution recording.  In replay mode this option is
     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),
     ‘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’
‘-virtioconsole C’
     Set virtio console.

     This option is maintained for backward compatibility.

     Please use ‘-device virtconsole’ for the new way of invocation.
‘-show-cursor’
     Show cursor.
‘-tb-size N’
     Set TB size.
‘-incoming tcp:[HOST]:PORT[,to=MAXPORT][,ipv4][,ipv6]’
‘-incoming rdma:HOST:PORT[,ipv4][,ipv6]’
     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).
‘-semihosting’
     Enable semihosting mode (ARM, M68K, Xtensa, MIPS only).
‘-semihosting-config [enable=on|off][,target=native|gdb|auto][,arg=str[,...]]’
     Enable and configure semihosting (ARM, M68K, Xtensa, MIPS only).
     ‘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.
     ‘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’
     Enable Seccomp mode 2 system call filter.  ’on’ will enable syscall
     filtering and ’off’ will disable it.  The default is ’off’.
‘-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.
‘-writeconfig FILE’
     Write device configuration to FILE.  The FILE can be either
     filename to save command line and device configuration into file or
     dash ‘-’) character to print the output to stdout.  This can be
     later used as input file for ‘-readconfig’ option.
‘-nodefconfig’
     Normally QEMU loads configuration files from SYSCONFDIR and DATADIR
     at startup.  The ‘-nodefconfig’ option will prevent QEMU from
     loading any of those config files.
‘-no-user-config’
     The ‘-no-user-config’ option makes QEMU not load any of the
     user-provided config files on SYSCONFDIR, but won’t make it skip
     the QEMU-provided config files from DATADIR.
‘-trace [[enable=]PATTERN][,events=FILE][,file=FILE]’
     Specify tracing options.

     ‘[enable=]PATTERN’
          Immediately enable events matching PATTERN.  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.  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.
‘-enable-fips’
     Enable FIPS 140-2 compliance mode.
‘-msg timestamp[=on|off]’
     prepend a timestamp to each log message.(default:on)
‘-dump-vmstate FILE’
     Dump json-encoded vmstate information for current machine type to
     file in FILE

2.3.13 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’

          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
          when configuring the ‘-numa’ argument.  The ‘size’ option
          provides the size of the memory region, and accepts common
          suffixes, eg ‘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.

     ‘-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/random’.

     ‘-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-x509,id=ID,endpoint=ENDPOINT,dir=/PATH/TO/CRED/DIR,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.

     ‘-object filter-buffer,id=ID,netdev=NETDEVID,interval=T[,queue=ALL|RX|TX][,status=ON|OFF]’

          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.

     ‘-object filter-mirror,id=ID,netdev=NETDEVID,outdev=CHARDEVID[,queue=ALL|RX|TX]’

          filter-mirror on netdev NETDEVID,mirror net packet to chardev
          CHARDEVID

     ‘-object filter-redirector,id=ID,netdev=NETDEVID,indev=CHARDEVID,’
          outdev=CHARDEVID[,queue=ALL|RX|TX]

          filter-redirector on netdev NETDEVID,redirect filter’s net
          packet to chardev CHARDEVID,and redirect indev’s packet to
          filter.  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,rewriter-mode=MODE[,queue=ALL|RX|TX]’

          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.

          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]’

          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

          Colo-compare gets packet from primary_inCHARDEVID and
          secondary_inCHARDEVID, than compare primary packet with
          secondary packet.  If the packets are same, we will output
          primary packet to outdevCHARDEVID, else we will notify
          colo-frame do checkpoint and send primary packet to
          outdevCHARDEVID.

          we must use it with the help of filter-mirror and
          filter-redirector.


               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,nowait
               -chardev socket,id=compare1,host=3.3.3.3,port=9004,server,nowait
               -chardev socket,id=compare0,host=3.3.3.3,port=9001,server,nowait
               -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,nowait
               -chardev socket,id=compare_out0,host=3.3.3.3,port=9005
               -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

               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 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 -object secret,id=sec0,data=letmein,format=raw


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

          # echo -n "letmein" > mypasswd.txt # $QEMU -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=$(echo -n "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

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

2.4 Keys in the graphical frontends
===================================

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.

2.5 Keys in the character backend multiplexer
=============================================

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

2.6 QEMU Monitor
================

The QEMU monitor is used to give complex commands to the QEMU emulator.
You can use it to:

   − Remove or insert removable media images (such as CD-ROM or
     floppies).

   − Freeze/unfreeze the Virtual Machine (VM) and save or restore its
     state from a disk file.

   − Inspect the VM state without an external debugger.

2.6.1 Commands
--------------

The following commands are available:

‘help or ? [CMD]’
     Show the help for all commands or just for command CMD.
‘commit’
     Commit changes to the disk images (if -snapshot is used) or backing
     files.  If the backing file is smaller than the snapshot, then the
     backing file will be resized to be the same size as the snapshot.
     If the snapshot is smaller than the backing file, the backing file
     will not be truncated.  If you want the backing file to match the
     size of the smaller snapshot, you can safely truncate it yourself
     once the commit operation successfully completes.
‘q or quit’
     Quit the emulator.
‘block_resize’
     Resize a block image while a guest is running.  Usually requires
     guest action to see the updated size.  Resize to a lower size is
     supported, but should be used with extreme caution.  Note that this
     command only resizes image files, it can not resize block devices
     like LVM volumes.
‘block_stream’
     Copy data from a backing file into a block device.
‘block_job_set_speed’
     Set maximum speed for a background block operation.
‘block_job_cancel’
     Stop an active background block operation (streaming, mirroring).
‘block_job_complete’
     Manually trigger completion of an active background block
     operation.  For mirroring, this will switch the device to the
     destination path.
‘block_job_pause’
     Pause an active block streaming operation.
‘block_job_resume’
     Resume a paused block streaming operation.
‘eject [-f] DEVICE’
     Eject a removable medium (use -f to force it).
‘drive_del DEVICE’
     Remove host block device.  The result is that guest generated IO is
     no longer submitted against the host device underlying the disk.
     Once a drive has been deleted, the QEMU Block layer returns -EIO
     which results in IO errors in the guest for applications that are
     reading/writing to the device.  These errors are always reported to
     the guest, regardless of the drive’s error actions (drive options
     rerror, werror).
‘change DEVICE SETTING’
     Change the configuration of a device.

     ‘change DISKDEVICE FILENAME [FORMAT [READ-ONLY-MODE]]’
          Change the medium for a removable disk device to point to
          FILENAME.  eg

               (qemu) change ide1-cd0 /path/to/some.iso

          FORMAT is optional.

          READ-ONLY-MODE may be used to change the read-only status of
          the device.  It accepts the following values:

          RETAIN
               Retains the current status; this is the default.

          READ-ONLY
               Makes the device read-only.

          READ-WRITE
               Makes the device writable.

     ‘change vnc DISPLAY,OPTIONS’
          Change the configuration of the VNC server.  The valid syntax
          for DISPLAY and OPTIONS are described at *note
          sec_invocation::.  eg

               (qemu) change vnc localhost:1

     ‘change vnc password [PASSWORD]’

          Change the password associated with the VNC server.  If the
          new password is not supplied, the monitor will prompt for it
          to be entered.  VNC passwords are only significant up to 8
          letters.  eg

               (qemu) change vnc password
               Password: ********

‘screendump FILENAME’
     Save screen into PPM image FILENAME.
‘logfile FILENAME’
     Output logs to FILENAME.
‘trace-event’
     changes status of a trace event
‘trace-file on|off|flush’
     Open, close, or flush the trace file.  If no argument is given, the
     status of the trace file is displayed.
‘log ITEM1[,...]’
     Activate logging of the specified items.
‘savevm [TAG|ID]’
     Create a snapshot of the whole virtual machine.  If TAG is
     provided, it is used as human readable identifier.  If there is
     already a snapshot with the same tag or ID, it is replaced.  More
     info at *note vm_snapshots::.
‘loadvm TAG|ID’
     Set the whole virtual machine to the snapshot identified by the tag
     TAG or the unique snapshot ID ID.
‘delvm TAG|ID’
     Delete the snapshot identified by TAG or ID.
‘singlestep [off]’
     Run the emulation in single step mode.  If called with option off,
     the emulation returns to normal mode.
‘stop’
     Stop emulation.
‘c or cont’
     Resume emulation.
‘system_wakeup’
     Wakeup guest from suspend.
‘gdbserver [PORT]’
     Start gdbserver session (default PORT=1234)
‘x/fmt ADDR’
     Virtual memory dump starting at ADDR.
‘xp /FMT ADDR’
     Physical memory dump starting at ADDR.

     FMT is a format which tells the command how to format the data.
     Its syntax is: ‘/{count}{format}{size}’

     COUNT
          is the number of items to be dumped.

     FORMAT
          can be x (hex), d (signed decimal), u (unsigned decimal), o
          (octal), c (char) or i (asm instruction).

     SIZE
          can be b (8 bits), h (16 bits), w (32 bits) or g (64 bits).
          On x86, ‘h’ or ‘w’ can be specified with the ‘i’ format to
          respectively select 16 or 32 bit code instruction size.

     Examples:
        • Dump 10 instructions at the current instruction pointer:
               (qemu) x/10i $eip
               0x90107063:  ret
               0x90107064:  sti
               0x90107065:  lea    0x0(%esi,1),%esi
               0x90107069:  lea    0x0(%edi,1),%edi
               0x90107070:  ret
               0x90107071:  jmp    0x90107080
               0x90107073:  nop
               0x90107074:  nop
               0x90107075:  nop
               0x90107076:  nop

        • Dump 80 16 bit values at the start of the video memory.
               (qemu) xp/80hx 0xb8000
               0x000b8000: 0x0b50 0x0b6c 0x0b65 0x0b78 0x0b38 0x0b36 0x0b2f 0x0b42
               0x000b8010: 0x0b6f 0x0b63 0x0b68 0x0b73 0x0b20 0x0b56 0x0b47 0x0b41
               0x000b8020: 0x0b42 0x0b69 0x0b6f 0x0b73 0x0b20 0x0b63 0x0b75 0x0b72
               0x000b8030: 0x0b72 0x0b65 0x0b6e 0x0b74 0x0b2d 0x0b63 0x0b76 0x0b73
               0x000b8040: 0x0b20 0x0b30 0x0b35 0x0b20 0x0b4e 0x0b6f 0x0b76 0x0b20
               0x000b8050: 0x0b32 0x0b30 0x0b30 0x0b33 0x0720 0x0720 0x0720 0x0720
               0x000b8060: 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720
               0x000b8070: 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720
               0x000b8080: 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720
               0x000b8090: 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720 0x0720
‘p or print/FMT EXPR’
     Print expression value.  Only the FORMAT part of FMT is used.
‘i/FMT ADDR [.INDEX]’
     Read I/O port.
‘o/FMT ADDR VAL’
     Write to I/O port.
‘sendkey KEYS’
     Send KEYS to the guest.  KEYS could be the name of the key or the
     raw value in hexadecimal format.  Use ‘-’ to press several keys
     simultaneously.  Example:
          sendkey ctrl-alt-f1

     This command is useful to send keys that your graphical user
     interface intercepts at low level, such as ‘ctrl-alt-f1’ in X
     Window.
‘system_reset’
     Reset the system.
‘system_powerdown’
     Power down the system (if supported).
‘sum ADDR SIZE’
     Compute the checksum of a memory region.
‘usb_add DEVNAME’
     Add the USB device DEVNAME.  For details of available devices see
     *note usb_devices::
‘usb_del DEVNAME’
     Remove the USB device DEVNAME from the QEMU virtual USB hub.
     DEVNAME has the syntax ‘bus.addr’.  Use the monitor command ‘info
     usb’ to see the devices you can remove.
‘device_add CONFIG’
     Add device.
‘device_del ID’
     Remove device ID.  ID may be a short ID or a QOM object path.
‘cpu INDEX’
     Set the default CPU.
‘mouse_move DX DY [DZ]’
     Move the active mouse to the specified coordinates DX DY with
     optional scroll axis DZ.
‘mouse_button VAL’
     Change the active mouse button state VAL (1=L, 2=M, 4=R).
‘mouse_set INDEX’
     Set which mouse device receives events at given INDEX, index can be
     obtained with
          info mice
‘wavcapture FILENAME [FREQUENCY [BITS [CHANNELS]]]’
     Capture audio into FILENAME.  Using sample rate FREQUENCY bits per
     sample BITS and number of channels CHANNELS.

     Defaults:
        − Sample rate = 44100 Hz - CD quality
        − Bits = 16
        − Number of channels = 2 - Stereo
‘stopcapture INDEX’
     Stop capture with a given INDEX, index can be obtained with
          info capture
‘memsave ADDR SIZE FILE’
     save to disk virtual memory dump starting at ADDR of size SIZE.
‘pmemsave ADDR SIZE FILE’
     save to disk physical memory dump starting at ADDR of size SIZE.
‘boot_set BOOTDEVICELIST’
     Define new values for the boot device list.  Those values will
     override the values specified on the command line through the
     ‘-boot’ option.

     The values that can be specified here depend on the machine type,
     but are the same that can be specified in the ‘-boot’ command line
     option.
‘nmi CPU’
     Inject an NMI on the default CPU (x86/s390) or all CPUs (ppc64).

‘ringbuf_write DEVICE DATA’
     Write DATA to ring buffer character device DEVICE.  DATA must be a
     UTF-8 string.

‘ringbuf_read DEVICE’
     Read and print up to SIZE bytes from ring buffer character device
     DEVICE.  Certain non-printable characters are printed \uXXXX, where
     XXXX is the character code in hexadecimal.  Character \ is printed
     \\.  Bug: can screw up when the buffer contains invalid UTF-8
     sequences, NUL characters, after the ring buffer lost data, and
     when reading stops because the size limit is reached.

‘migrate [-d] [-b] [-i] URI’
     Migrate to URI (using -d to not wait for completion).  -b for
     migration with full copy of disk -i for migration with incremental
     copy of disk (base image is shared)
‘migrate_cancel’
     Cancel the current VM migration.

‘migrate_incoming URI’
     Continue an incoming migration using the URI (that has the same
     syntax as the -incoming option).

‘migrate_set_cache_size VALUE’
     Set cache size to VALUE (in bytes) for xbzrle migrations.
‘migrate_set_speed VALUE’
     Set maximum speed to VALUE (in bytes) for migrations.
‘migrate_set_downtime SECOND’
     Set maximum tolerated downtime (in seconds) for migration.
‘migrate_set_capability CAPABILITY STATE’
     Enable/Disable the usage of a capability CAPABILITY for migration.
‘migrate_set_parameter PARAMETER VALUE’
     Set the parameter PARAMETER for migration.
‘migrate_start_postcopy’
     Switch in-progress migration to postcopy mode.  Ignored after the
     end of migration (or once already in postcopy).
‘x_colo_lost_heartbeat’
     Tell COLO that heartbeat is lost, a failover or takeover is needed.
‘client_migrate_info PROTOCOL HOSTNAME PORT TLS-PORT CERT-SUBJECT’
     Set migration information for remote display.  This makes the
     server ask the client to automatically reconnect using the new
     parameters once migration finished successfully.  Only implemented
     for SPICE.
‘dump-guest-memory [-p] FILENAME BEGIN LENGTH’
‘dump-guest-memory [-z|-l|-s] FILENAME’
     Dump guest memory to PROTOCOL.  The file can be processed with
     crash or gdb.  Without -z|-l|-s, the dump format is ELF. -p: do
     paging to get guest’s memory mapping.  -z: dump in kdump-compressed
     format, with zlib compression.  -l: dump in kdump-compressed
     format, with lzo compression.  -s: dump in kdump-compressed format,
     with snappy compression.  filename: dump file name.  begin: the
     starting physical address.  It’s optional, and should be specified
     together with length.  length: the memory size, in bytes.  It’s
     optional, and should be specified together with begin.
‘dump-skeys FILENAME’
     Save guest storage keys to a file.
‘snapshot_blkdev’
     Snapshot device, using snapshot file as target if provided
‘snapshot_blkdev_internal’
     Take an internal snapshot on device if it support
‘snapshot_delete_blkdev_internal’
     Delete an internal snapshot on device if it support
‘drive_mirror’
     Start mirroring a block device’s writes to a new destination, using
     the specified target.
‘drive_backup’
     Start a point-in-time copy of a block device to a specificed
     target.
‘drive_add’
     Add drive to PCI storage controller.
‘pcie_aer_inject_error’
     Inject PCIe AER error
‘host_net_add’
     Add host VLAN client.
‘host_net_remove’
     Remove host VLAN client.
‘netdev_add’
     Add host network device.
‘netdev_del’
     Remove host network device.
‘object_add’
     Create QOM object.
‘object_del’
     Destroy QOM object.
‘hostfwd_add’
     Redirect TCP or UDP connections from host to guest (requires -net
     user).
‘hostfwd_remove’
     Remove host-to-guest TCP or UDP redirection.
‘balloon VALUE’
     Request VM to change its memory allocation to VALUE (in MB).
‘set_link NAME [on|off]’
     Switch link NAME on (i.e.  up) or off (i.e.  down).
‘watchdog_action’
     Change watchdog action.
‘acl_show ACLNAME’
     List all the matching rules in the access control list, and the
     default policy.  There are currently two named access control
     lists, VNC.X509DNAME and VNC.USERNAME matching on the x509 client
     certificate distinguished name, and SASL username respectively.
‘acl_policy ACLNAME allow|deny’
     Set the default access control list policy, used in the event that
     none of the explicit rules match.  The default policy at startup is
     always ‘deny’.
‘acl_add ACLNAME MATCH allow|deny [INDEX]’
     Add a match rule to the access control list, allowing or denying
     access.  The match will normally be an exact username or x509
     distinguished name, but can optionally include wildcard globs.  eg
     ‘*@EXAMPLE.COM’ to allow all users in the ‘EXAMPLE.COM’ kerberos
     realm.  The match will normally be appended to the end of the ACL,
     but can be inserted earlier in the list if the optional INDEX
     parameter is supplied.
‘acl_remove ACLNAME MATCH’
     Remove the specified match rule from the access control list.
‘acl_reset ACLNAME’
     Remove all matches from the access control list, and set the
     default policy back to ‘deny’.
‘nbd_server_start HOST:PORT’
     Start an NBD server on the given host and/or port.  If the ‘-a’
     option is included, all of the virtual machine’s block devices that
     have an inserted media on them are automatically exported; in this
     case, the ‘-w’ option makes the devices writable too.
‘nbd_server_add DEVICE’
     Export a block device through QEMU’s NBD server, which must be
     started beforehand with ‘nbd_server_start’.  The ‘-w’ option makes
     the exported device writable too.
‘nbd_server_stop’
     Stop the QEMU embedded NBD server.
‘mce CPU BANK STATUS MCGSTATUS ADDR MISC’
     Inject an MCE on the given CPU (x86 only).
‘getfd FDNAME’
     If a file descriptor is passed alongside this command using the
     SCM_RIGHTS mechanism on unix sockets, it is stored using the name
     FDNAME for later use by other monitor commands.
‘closefd FDNAME’
     Close the file descriptor previously assigned to FDNAME using the
     ‘getfd’ command.  This is only needed if the file descriptor was
     never used by another monitor command.
‘block_passwd DEVICE PASSWORD’
     Set the encrypted device DEVICE password to PASSWORD
‘block_set_io_throttle DEVICE BPS BPS_RD BPS_WR IOPS IOPS_RD IOPS_WR’
     Change I/O throttle limits for a block drive to BPS BPS_RD BPS_WR
     IOPS IOPS_RD IOPS_WR
‘set_password [ vnc | spice ] password [ action-if-connected ]’
     Change spice/vnc password.  Use zero to make the password stay
     valid forever.  ACTION-IF-CONNECTED specifies what should happen in
     case a connection is established: FAIL makes the password change
     fail.  DISCONNECT changes the password and disconnects the client.
     KEEP changes the password and keeps the connection up.  KEEP is the
     default.
‘expire_password [ vnc | spice ] expire-time’
     Specify when a password for spice/vnc becomes invalid.  EXPIRE-TIME
     accepts:

     NOW
          Invalidate password instantly.

     NEVER
          Password stays valid forever.

     +NSEC
          Password stays valid for NSEC seconds starting now.

     NSEC
          Password is invalidated at the given time.  NSEC are the
          seconds passed since 1970, i.e.  unix epoch.

‘chardev-add args’
     chardev_add accepts the same parameters as the -chardev command
     line switch.

‘chardev-remove id’
     Removes the chardev ID.

‘qemu-io DEVICE COMMAND’
     Executes a qemu-io command on the given block device.

‘cpu-add ID’
     Add CPU with id ID
‘qom-list [PATH]’
     Print QOM properties of object at location PATH
‘qom-set PATH PROPERTY VALUE’
     Set QOM property PROPERTY of object at location PATH to value VALUE

‘info SUBCOMMAND’
     Show various information about the system state.
     ‘info version’
          Show the version of QEMU.
     ‘info network’
          Show the network state.
     ‘info chardev’
          Show the character devices.
     ‘info block’
          Show info of one block device or all block devices.
     ‘info blockstats’
          Show block device statistics.
     ‘info block-jobs’
          Show progress of ongoing block device operations.
     ‘info registers’
          Show the cpu registers.
     ‘info lapic’
          Show local APIC state
     ‘info ioapic’
          Show io APIC state
     ‘info cpus’
          Show infos for each CPU.
     ‘info history’
          Show the command line history.
     ‘info irq’
          Show the interrupts statistics (if available).
     ‘info pic’
          Show i8259 (PIC) state.
     ‘info pci’
          Show PCI information.
     ‘info tlb’
          Show virtual to physical memory mappings.
     ‘info mem’
          Show the active virtual memory mappings.
     ‘info mtree’
          Show memory tree.
     ‘info jit’
          Show dynamic compiler info.
     ‘info opcount’
          Show dynamic compiler opcode counters
     ‘info kvm’
          Show KVM information.
     ‘info numa’
          Show NUMA information.
     ‘info usb’
          Show guest USB devices.
     ‘info usbhost’
          Show host USB devices.
     ‘info profile’
          Show profiling information.
     ‘info capture’
          Show capture information.
     ‘info snapshots’
          Show the currently saved VM snapshots.
     ‘info status’
          Show the current VM status (running|paused).
     ‘info mice’
          Show which guest mouse is receiving events.
     ‘info vnc’
          Show the vnc server status.
     ‘info spice’
          Show the spice server status.
     ‘info name’
          Show the current VM name.
     ‘info uuid’
          Show the current VM UUID.
     ‘info cpustats’
          Show CPU statistics.
     ‘info usernet’
          Show user network stack connection states.
     ‘info migrate’
          Show migration status.
     ‘info migrate_capabilities’
          Show current migration capabilities.
     ‘info migrate_parameters’
          Show current migration parameters.
     ‘info migrate_cache_size’
          Show current migration xbzrle cache size.
     ‘info balloon’
          Show balloon information.
     ‘info qtree’
          Show device tree.
     ‘info qdm’
          Show qdev device model list.
     ‘info qom-tree’
          Show QOM composition tree.
     ‘info roms’
          Show roms.
     ‘info trace-events’
          Show available trace-events & their state.
     ‘info tpm’
          Show the TPM device.
     ‘info memdev’
          Show memory backends
     ‘info memory-devices’
          Show memory devices.
     ‘info iothreads’
          Show iothread’s identifiers.
     ‘info rocker NAME’
          Show rocker switch.
     ‘info rocker_ports NAME-ports’
          Show rocker ports.
     ‘info rocker_of_dpa_flows NAME [TBL_ID]’
          Show rocker OF-DPA flow tables.
     ‘info rocker-of-dpa-groups NAME [TYPE]’
          Show rocker OF-DPA groups.
     ‘info skeys ADDRESS’
          Display the value of a storage key (s390 only)
     ‘info dump’
          Display the latest dump status.
     ‘info hotpluggable-cpus’
          Show information about hotpluggable CPUs
     ‘info vm-generation-id’
          Show Virtual Machine Generation ID

2.6.2 Integer expressions
-------------------------

The monitor understands integers expressions for every integer argument.
You can use register names to get the value of specifics CPU registers
by prefixing them with _$_.

2.7 Disk Images
===============

Since version 0.6.1, QEMU supports many disk image formats, including
growable disk images (their size increase as non empty sectors are
written), compressed and encrypted disk images.  Version 0.8.3 added the
new qcow2 disk image format which is essential to support VM snapshots.

2.7.1 Quick start for disk image creation
-----------------------------------------

You can create a disk image with the command:
     qemu-img create myimage.img mysize
where MYIMAGE.IMG is the disk image filename and MYSIZE is its size in
kilobytes.  You can add an ‘M’ suffix to give the size in megabytes and
a ‘G’ suffix for gigabytes.

See *note qemu_img_invocation:: for more information.

2.7.2 Snapshot mode
-------------------

If you use the option ‘-snapshot’, all disk images are considered as
read only.  When sectors in written, they are written in a temporary
file created in ‘/tmp’.  You can however force the write back to the raw
disk images by using the ‘commit’ monitor command (or <C-a s> in the
serial console).

2.7.3 VM snapshots
------------------

VM snapshots are snapshots of the complete virtual machine including CPU
state, RAM, device state and the content of all the writable disks.  In
order to use VM snapshots, you must have at least one non removable and
writable block device using the ‘qcow2’ disk image format.  Normally
this device is the first virtual hard drive.

Use the monitor command ‘savevm’ to create a new VM snapshot or replace
an existing one.  A human readable name can be assigned to each snapshot
in addition to its numerical ID.

Use ‘loadvm’ to restore a VM snapshot and ‘delvm’ to remove a VM
snapshot.  ‘info snapshots’ lists the available snapshots with their
associated information:

     (qemu) info snapshots
     Snapshot devices: hda
     Snapshot list (from hda):
     ID        TAG                 VM SIZE                DATE       VM CLOCK
     1         start                   41M 2006-08-06 12:38:02   00:00:14.954
     2                                 40M 2006-08-06 12:43:29   00:00:18.633
     3         msys                    40M 2006-08-06 12:44:04   00:00:23.514

A VM snapshot is made of a VM state info (its size is shown in ‘info
snapshots’) and a snapshot of every writable disk image.  The VM state
info is stored in the first ‘qcow2’ non removable and writable block
device.  The disk image snapshots are stored in every disk image.  The
size of a snapshot in a disk image is difficult to evaluate and is not
shown by ‘info snapshots’ because the associated disk sectors are shared
among all the snapshots to save disk space (otherwise each snapshot
would need a full copy of all the disk images).

When using the (unrelated) ‘-snapshot’ option (*note
disk_images_snapshot_mode::), you can always make VM snapshots, but they
are deleted as soon as you exit QEMU.

VM snapshots currently have the following known limitations:
   • They cannot cope with removable devices if they are removed or
     inserted after a snapshot is done.
   • A few device drivers still have incomplete snapshot support so
     their state is not saved or restored properly (in particular USB).

2.7.4 ‘qemu-img’ Invocation
---------------------------

     qemu-img [STANDARD OPTIONS] COMMAND [COMMAND OPTIONS]

qemu-img allows you to create, convert and modify images offline.  It
can handle all image formats supported by QEMU.

Warning: Never use qemu-img to modify images in use by a running virtual
machine or any other process; this may destroy the image.  Also, be
aware that querying an image that is being modified by another process
may encounter inconsistent state.

Standard options:
‘-h, --help’
     Display this help and exit
‘-V, --version’
     Display version information and exit
‘-T, --trace [[enable=]PATTERN][,events=FILE][,file=FILE]’
     Specify tracing options.

     ‘[enable=]PATTERN’
          Immediately enable events matching PATTERN.  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.  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.

The following commands are supported:

‘bench [-c COUNT] [-d DEPTH] [-f FMT] [--flush-interval=FLUSH_INTERVAL] [-n] [--no-drain] [-o OFFSET] [--pattern=PATTERN] [-q] [-s BUFFER_SIZE] [-S STEP_SIZE] [-t CACHE] [-w] FILENAME’
‘check [--object OBJECTDEF] [--image-opts] [-q] [-f FMT] [--output=OFMT] [-r [leaks | all]] [-T SRC_CACHE] FILENAME’
‘create [--object OBJECTDEF] [-q] [-f FMT] [-o OPTIONS] FILENAME [SIZE]’
‘commit [--object OBJECTDEF] [--image-opts] [-q] [-f FMT] [-t CACHE] [-b BASE] [-d] [-p] FILENAME’
‘compare [--object OBJECTDEF] [--image-opts] [-f FMT] [-F FMT] [-T SRC_CACHE] [-p] [-q] [-s] FILENAME1 FILENAME2’
‘convert [--object OBJECTDEF] [--image-opts] [-c] [-p] [-q] [-n] [-f FMT] [-t CACHE] [-T SRC_CACHE] [-O OUTPUT_FMT] [-o OPTIONS] [-s SNAPSHOT_ID_OR_NAME] [-l SNAPSHOT_PARAM] [-S SPARSE_SIZE] [-m NUM_COROUTINES] [-W] FILENAME [FILENAME2 [...]] OUTPUT_FILENAME’
‘dd [--image-opts] [-f FMT] [-O OUTPUT_FMT] [bs=BLOCK_SIZE] [count=BLOCKS] [skip=BLOCKS] if=INPUT of=OUTPUT’
‘info [--object OBJECTDEF] [--image-opts] [-f FMT] [--output=OFMT] [--backing-chain] FILENAME’
‘map [--object OBJECTDEF] [--image-opts] [-f FMT] [--output=OFMT] FILENAME’
‘snapshot [--object OBJECTDEF] [--image-opts] [-q] [-l | -a SNAPSHOT | -c SNAPSHOT | -d SNAPSHOT] FILENAME’
‘rebase [--object OBJECTDEF] [--image-opts] [-q] [-f FMT] [-t CACHE] [-T SRC_CACHE] [-p] [-u] -b BACKING_FILE [-F BACKING_FMT] FILENAME’
‘resize [--object OBJECTDEF] [--image-opts] [-q] FILENAME [+ | -]SIZE’
‘amend [--object OBJECTDEF] [--image-opts] [-p] [-q] [-f FMT] [-t CACHE] -o OPTIONS FILENAME’

Command parameters:
FILENAME
     is a disk image filename

–OBJECT OBJECTDEF

     is a QEMU user creatable object definition.  See the ‘qemu(1)’
     manual page for a description of the object properties.  The most
     common object type is a ‘secret’, which is used to supply passwords
     and/or encryption keys.

–IMAGE-OPTS

     Indicates that the FILENAME parameter is to be interpreted as a
     full option string, not a plain filename.  This parameter is
     mutually exclusive with the -F and -F parameters.

FMT
     is the disk image format.  It is guessed automatically in most
     cases.  See below for a description of the supported disk formats.

–BACKING-CHAIN
     will enumerate information about backing files in a disk image
     chain.  Refer below for further description.

SIZE
     is the disk image size in bytes.  Optional suffixes ‘k’ or ‘K’
     (kilobyte, 1024) ‘M’ (megabyte, 1024k) and ‘G’ (gigabyte, 1024M)
     and T (terabyte, 1024G) are supported.  ‘b’ is ignored.

OUTPUT_FILENAME
     is the destination disk image filename

OUTPUT_FMT
     is the destination format
OPTIONS
     is a comma separated list of format specific options in a
     name=value format.  Use ‘-o ?’ for an overview of the options
     supported by the used format or see the format descriptions below
     for details.
SNAPSHOT_PARAM
     is param used for internal snapshot, format is
     ’snapshot.id=[ID],snapshot.name=[NAME]’ or ’[ID_OR_NAME]’
SNAPSHOT_ID_OR_NAME
     is deprecated, use snapshot_param instead

-C
     indicates that target image must be compressed (qcow format only)
-H
     with or without a command shows help and lists the supported
     formats
-P
     display progress bar (compare, convert and rebase commands only).
     If the -P option is not used for a command that supports it, the
     progress is reported when the process receives a ‘SIGUSR1’ signal.
-Q
     Quiet mode - do not print any output (except errors).  There’s no
     progress bar in case both -Q and -P options are used.
-S SIZE
     indicates the consecutive number of bytes that must contain only
     zeros for qemu-img to create a sparse image during conversion.
     This value is rounded down to the nearest 512 bytes.  You may use
     the common size suffixes like ‘k’ for kilobytes.
-T CACHE
     specifies the cache mode that should be used with the (destination)
     file.  See the documentation of the emulator’s ‘-drive cache=...’
     option for allowed values.
-T SRC_CACHE
     specifies the cache mode that should be used with the source
     file(s).  See the documentation of the emulator’s ‘-drive
     cache=...’ option for allowed values.

Parameters to snapshot subcommand:

‘snapshot’
     is the name of the snapshot to create, apply or delete
‘-a’
     applies a snapshot (revert disk to saved state)
‘-c’
     creates a snapshot
‘-d’
     deletes a snapshot
‘-l’
     lists all snapshots in the given image

Parameters to compare subcommand:

‘-f’
     First image format
‘-F’
     Second image format
‘-s’
     Strict mode - fail on different image size or sector allocation

Parameters to convert subcommand:

‘-n’
     Skip the creation of the target volume
‘-m’
     Number of parallel coroutines for the convert process
‘-W’
     Allow out-of-order writes to the destination.  This option improves
     performance, but is only recommended for preallocated devices like
     host devices or other raw block devices.

Parameters to dd subcommand:

‘bs=BLOCK_SIZE’
     defines the block size
‘count=BLOCKS’
     sets the number of input blocks to copy
‘if=INPUT’
     sets the input file
‘of=OUTPUT’
     sets the output file
‘skip=BLOCKS’
     sets the number of input blocks to skip

Command description:

‘bench [-c COUNT] [-d DEPTH] [-f FMT] [--flush-interval=FLUSH_INTERVAL] [-n] [--no-drain] [-o OFFSET] [--pattern=PATTERN] [-q] [-s BUFFER_SIZE] [-S STEP_SIZE] [-t CACHE] [-w] FILENAME’

     Run a simple sequential I/O benchmark on the specified image.  If
     ‘-w’ is specified, a write test is performed, otherwise a read test
     is performed.

     A total number of COUNT I/O requests is performed, each BUFFER_SIZE
     bytes in size, and with DEPTH requests in parallel.  The first
     request starts at the position given by OFFSET, each following
     request increases the current position by STEP_SIZE.  If STEP_SIZE
     is not given, BUFFER_SIZE is used for its value.

     If FLUSH_INTERVAL is specified for a write test, the request queue
     is drained and a flush is issued before new writes are made
     whenever the number of remaining requests is a multiple of
     FLUSH_INTERVAL.  If additionally ‘--no-drain’ is specified, a flush
     is issued without draining the request queue first.

     If ‘-n’ is specified, the native AIO backend is used if possible.
     On Linux, this option only works if ‘-t none’ or ‘-t directsync’ is
     specified as well.

     For write tests, by default a buffer filled with zeros is written.
     This can be overridden with a pattern byte specified by PATTERN.

‘check [-f FMT] [--output=OFMT] [-r [leaks | all]] [-T SRC_CACHE] FILENAME’

     Perform a consistency check on the disk image FILENAME.  The
     command can output in the format OFMT which is either ‘human’ or
     ‘json’.

     If ‘-r’ is specified, qemu-img tries to repair any inconsistencies
     found during the check.  ‘-r leaks’ repairs only cluster leaks,
     whereas ‘-r all’ fixes all kinds of errors, with a higher risk of
     choosing the wrong fix or hiding corruption that has already
     occurred.

     Only the formats ‘qcow2’, ‘qed’ and ‘vdi’ support consistency
     checks.

     In case the image does not have any inconsistencies, check exits
     with ‘0’.  Other exit codes indicate the kind of inconsistency
     found or if another error occurred.  The following table summarizes
     all exit codes of the check subcommand:

     ‘0’
          Check completed, the image is (now) consistent
     ‘1’
          Check not completed because of internal errors
     ‘2’
          Check completed, image is corrupted
     ‘3’
          Check completed, image has leaked clusters, but is not
          corrupted
     ‘63’
          Checks are not supported by the image format

     If ‘-r’ is specified, exit codes representing the image state refer
     to the state after (the attempt at) repairing it.  That is, a
     successful ‘-r all’ will yield the exit code 0, independently of
     the image state before.

‘create [-f FMT] [-o OPTIONS] FILENAME [SIZE]’

     Create the new disk image FILENAME of size SIZE and format FMT.
     Depending on the file format, you can add one or more OPTIONS that
     enable additional features of this format.

     If the option BACKING_FILE is specified, then the image will record
     only the differences from BACKING_FILE.  No size needs to be
     specified in this case.  BACKING_FILE will never be modified unless
     you use the ‘commit’ monitor command (or qemu-img commit).

     The size can also be specified using the SIZE option with ‘-o’, it
     doesn’t need to be specified separately in this case.

‘commit [-q] [-f FMT] [-t CACHE] [-b BASE] [-d] [-p] FILENAME’

     Commit the changes recorded in FILENAME in its base image or
     backing file.  If the backing file is smaller than the snapshot,
     then the backing file will be resized to be the same size as the
     snapshot.  If the snapshot is smaller than the backing file, the
     backing file will not be truncated.  If you want the backing file
     to match the size of the smaller snapshot, you can safely truncate
     it yourself once the commit operation successfully completes.

     The image FILENAME is emptied after the operation has succeeded.
     If you do not need FILENAME afterwards and intend to drop it, you
     may skip emptying FILENAME by specifying the ‘-d’ flag.

     If the backing chain of the given image file FILENAME has more than
     one layer, the backing file into which the changes will be
     committed may be specified as BASE (which has to be part of
     FILENAME’s backing chain).  If BASE is not specified, the immediate
     backing file of the top image (which is FILENAME) will be used.
     For reasons of consistency, explicitly specifying BASE will always
     imply ‘-d’ (since emptying an image after committing to an indirect
     backing file would lead to different data being read from the image
     due to content in the intermediate backing chain overruling the
     commit target).

‘compare [-f FMT] [-F FMT] [-T SRC_CACHE] [-p] [-s] [-q] FILENAME1 FILENAME2’

     Check if two images have the same content.  You can compare images
     with different format or settings.

     The format is probed unless you specify it by -F (used for
     FILENAME1) and/or -F (used for FILENAME2) option.

     By default, images with different size are considered identical if
     the larger image contains only unallocated and/or zeroed sectors in
     the area after the end of the other image.  In addition, if any
     sector is not allocated in one image and contains only zero bytes
     in the second one, it is evaluated as equal.  You can use Strict
     mode by specifying the -S option.  When compare runs in Strict
     mode, it fails in case image size differs or a sector is allocated
     in one image and is not allocated in the second one.

     By default, compare prints out a result message.  This message
     displays information that both images are same or the position of
     the first different byte.  In addition, result message can report
     different image size in case Strict mode is used.

     Compare exits with ‘0’ in case the images are equal and with ‘1’ in
     case the images differ.  Other exit codes mean an error occurred
     during execution and standard error output should contain an error
     message.  The following table sumarizes all exit codes of the
     compare subcommand:

     ‘0’
          Images are identical
     ‘1’
          Images differ
     ‘2’
          Error on opening an image
     ‘3’
          Error on checking a sector allocation
     ‘4’
          Error on reading data

‘convert [-c] [-p] [-n] [-f FMT] [-t CACHE] [-T SRC_CACHE] [-O OUTPUT_FMT] [-o OPTIONS] [-s SNAPSHOT_ID_OR_NAME] [-l SNAPSHOT_PARAM] [-m NUM_COROUTINES] [-W] [-S SPARSE_SIZE] FILENAME [FILENAME2 [...]] OUTPUT_FILENAME’

     Convert the disk image FILENAME or a snapshot
     SNAPSHOT_PARAM(SNAPSHOT_ID_OR_NAME is deprecated) to disk image
     OUTPUT_FILENAME using format OUTPUT_FMT.  It can be optionally
     compressed (‘-c’ option) or use any format specific options like
     encryption (‘-o’ option).

     Only the formats ‘qcow’ and ‘qcow2’ support compression.  The
     compression is read-only.  It means that if a compressed sector is
     rewritten, then it is rewritten as uncompressed data.

     Image conversion is also useful to get smaller image when using a
     growable format such as ‘qcow’: the empty sectors are detected and
     suppressed from the destination image.

     SPARSE_SIZE indicates the consecutive number of bytes (defaults to
     4k) that must contain only zeros for qemu-img to create a sparse
     image during conversion.  If SPARSE_SIZE is 0, the source will not
     be scanned for unallocated or zero sectors, and the destination
     image will always be fully allocated.

     You can use the BACKING_FILE option to force the output image to be
     created as a copy on write image of the specified base image; the
     BACKING_FILE should have the same content as the input’s base
     image, however the path, image format, etc may differ.

     If the ‘-n’ option is specified, the target volume creation will be
     skipped.  This is useful for formats such as ‘rbd’ if the target
     volume has already been created with site specific options that
     cannot be supplied through qemu-img.

     Out of order writes can be enabled with ‘-W’ to improve
     performance.  This is only recommended for preallocated devices
     like host devices or other raw block devices.  Out of order write
     does not work in combination with creating compressed images.

     NUM_COROUTINES specifies how many coroutines work in parallel
     during the convert process (defaults to 8).

‘dd [-f FMT] [-O OUTPUT_FMT] [bs=BLOCK_SIZE] [count=BLOCKS] [skip=BLOCKS] if=INPUT of=OUTPUT’

     Dd copies from INPUT file to OUTPUT file converting it from FMT
     format to OUTPUT_FMT format.

     The data is by default read and written using blocks of 512 bytes
     but can be modified by specifying BLOCK_SIZE.  If count=BLOCKS is
     specified dd will stop reading input after reading BLOCKS input
     blocks.

     The size syntax is similar to dd(1)’s size syntax.

‘info [-f FMT] [--output=OFMT] [--backing-chain] FILENAME’

     Give information about the disk image FILENAME.  Use it in
     particular to know the size reserved on disk which can be different
     from the displayed size.  If VM snapshots are stored in the disk
     image, they are displayed too.  The command can output in the
     format OFMT which is either ‘human’ or ‘json’.

     If a disk image has a backing file chain, information about each
     disk image in the chain can be recursively enumerated by using the
     option ‘--backing-chain’.

     For instance, if you have an image chain like:

          base.qcow2 <- snap1.qcow2 <- snap2.qcow2

     To enumerate information about each disk image in the above chain,
     starting from top to base, do:

          qemu-img info --backing-chain snap2.qcow2

‘map [-f FMT] [--output=OFMT] FILENAME’

     Dump the metadata of image FILENAME and its backing file chain.  In
     particular, this commands dumps the allocation state of every
     sector of FILENAME, together with the topmost file that allocates
     it in the backing file chain.

     Two option formats are possible.  The default format (‘human’) only
     dumps known-nonzero areas of the file.  Known-zero parts of the
     file are omitted altogether, and likewise for parts that are not
     allocated throughout the chain.  ‘qemu-img’ output will identify a
     file from where the data can be read, and the offset in the file.
     Each line will include four fields, the first three of which are
     hexadecimal numbers.  For example the first line of:
          Offset          Length          Mapped to       File
          0               0x20000         0x50000         /tmp/overlay.qcow2
          0x100000        0x10000         0x95380000      /tmp/backing.qcow2
     means that 0x20000 (131072) bytes starting at offset 0 in the image
     are available in /tmp/overlay.qcow2 (opened in ‘raw’ format)
     starting at offset 0x50000 (327680).  Data that is compressed,
     encrypted, or otherwise not available in raw format will cause an
     error if ‘human’ format is in use.  Note that file names can
     include newlines, thus it is not safe to parse this output format
     in scripts.

     The alternative format ‘json’ will return an array of dictionaries
     in JSON format.  It will include similar information in the
     ‘start’, ‘length’, ‘offset’ fields; it will also include other more
     specific information:
        − whether the sectors contain actual data or not (boolean field
          ‘data’; if false, the sectors are either unallocated or stored
          as optimized all-zero clusters);

        − whether the data is known to read as zero (boolean field
          ‘zero’);

        − in order to make the output shorter, the target file is
          expressed as a ‘depth’; for example, a depth of 2 refers to
          the backing file of the backing file of FILENAME.

     In JSON format, the ‘offset’ field is optional; it is absent in
     cases where ‘human’ format would omit the entry or exit with an
     error.  If ‘data’ is false and the ‘offset’ field is present, the
     corresponding sectors in the file are not yet in use, but they are
     preallocated.

     For more information, consult ‘include/block/block.h’ in QEMU’s
     source code.

‘snapshot [-l | -a SNAPSHOT | -c SNAPSHOT | -d SNAPSHOT ] FILENAME’

     List, apply, create or delete snapshots in image FILENAME.

‘rebase [-f FMT] [-t CACHE] [-T SRC_CACHE] [-p] [-u] -b BACKING_FILE [-F BACKING_FMT] FILENAME’

     Changes the backing file of an image.  Only the formats ‘qcow2’ and
     ‘qed’ support changing the backing file.

     The backing file is changed to BACKING_FILE and (if the image
     format of FILENAME supports this) the backing file format is
     changed to BACKING_FMT.  If BACKING_FILE is specified as “” (the
     empty string), then the image is rebased onto no backing file (i.e.
     it will exist independently of any backing file).

     CACHE specifies the cache mode to be used for FILENAME, whereas
     SRC_CACHE specifies the cache mode for reading backing files.

     There are two different modes in which ‘rebase’ can operate:
     ‘Safe mode’
          This is the default mode and performs a real rebase operation.
          The new backing file may differ from the old one and qemu-img
          rebase will take care of keeping the guest-visible content of
          FILENAME unchanged.

          In order to achieve this, any clusters that differ between
          BACKING_FILE and the old backing file of FILENAME are merged
          into FILENAME before actually changing the backing file.

          Note that the safe mode is an expensive operation, comparable
          to converting an image.  It only works if the old backing file
          still exists.

     ‘Unsafe mode’
          qemu-img uses the unsafe mode if ‘-u’ is specified.  In this
          mode, only the backing file name and format of FILENAME is
          changed without any checks on the file contents.  The user
          must take care of specifying the correct new backing file, or
          the guest-visible content of the image will be corrupted.

          This mode is useful for renaming or moving the backing file to
          somewhere else.  It can be used without an accessible old
          backing file, i.e.  you can use it to fix an image whose
          backing file has already been moved/renamed.

     You can use ‘rebase’ to perform a “diff” operation on two disk
     images.  This can be useful when you have copied or cloned a guest,
     and you want to get back to a thin image on top of a template or
     base image.

     Say that ‘base.img’ has been cloned as ‘modified.img’ by copying
     it, and that the ‘modified.img’ guest has run so there are now some
     changes compared to ‘base.img’.  To construct a thin image called
     ‘diff.qcow2’ that contains just the differences, do:

          qemu-img create -f qcow2 -b modified.img diff.qcow2
          qemu-img rebase -b base.img diff.qcow2

     At this point, ‘modified.img’ can be discarded, since ‘base.img +
     diff.qcow2’ contains the same information.

‘resize FILENAME [+ | -]SIZE’

     Change the disk image as if it had been created with SIZE.

     Before using this command to shrink a disk image, you MUST use file
     system and partitioning tools inside the VM to reduce allocated
     file systems and partition sizes accordingly.  Failure to do so
     will result in data loss!

     After using this command to grow a disk image, you must use file
     system and partitioning tools inside the VM to actually begin using
     the new space on the device.

‘amend [-p] [-f FMT] [-t CACHE] -o OPTIONS FILENAME’

     Amends the image format specific OPTIONS for the image file
     FILENAME.  Not all file formats support this operation.

2.7.5 ‘qemu-nbd’ Invocation
---------------------------

     qemu-nbd [OPTION]... FILENAME

     qemu-nbd -d DEV

Export a QEMU disk image using the NBD protocol.

FILENAME is a disk image filename, or a set of block driver options if
–IMAGE-OPTS is specified.

DEV is an NBD device.

‘--object type,id=ID,...props...’
     Define a new instance of the TYPE object class identified by ID.
     See the ‘qemu(1)’ manual page for full details of the properties
     supported.  The common object types that it makes sense to define
     are the ‘secret’ object, which is used to supply passwords and/or
     encryption keys, and the ‘tls-creds’ object, which is used to
     supply TLS credentials for the qemu-nbd server.
‘-p, --port=PORT’
     The TCP port to listen on (default ‘10809’)
‘-o, --offset=OFFSET’
     The offset into the image
‘-b, --bind=IFACE’
     The interface to bind to (default ‘0.0.0.0’)
‘-k, --socket=PATH’
     Use a unix socket with path PATH
‘--image-opts’
     Treat FILENAME as a set of image options, instead of a plain
     filename.  If this flag is specified, the -F flag should not be
     used, instead the ’‘format=’’ option should be set.
‘-f, --format=FMT’
     Force the use of the block driver for format FMT instead of
     auto-detecting
‘-r, --read-only’
     Export the disk as read-only
‘-P, --partition=NUM’
     Only expose partition NUM
‘-s, --snapshot’
     Use FILENAME as an external snapshot, create a temporary file with
     backing_file=FILENAME, redirect the write to the temporary one
‘-l, --load-snapshot=SNAPSHOT_PARAM’
     Load an internal snapshot inside FILENAME and export it as an
     read-only device, SNAPSHOT_PARAM format is
     ’snapshot.id=[ID],snapshot.name=[NAME]’ or ’[ID_OR_NAME]’
‘-n, --nocache’
‘--cache=CACHE’
     The cache mode to be used with the file.  See the documentation of
     the emulator’s ‘-drive cache=...’ option for allowed values.
‘--aio=AIO’
     Set the asynchronous I/O mode between ‘threads’ (the default) and
     ‘native’ (Linux only).
‘--discard=DISCARD’
     Control whether “discard” (also known as “trim” or “unmap”)
     requests are ignored or passed to the filesystem.  DISCARD is one
     of ‘ignore’ (or ‘off’), ‘unmap’ (or ‘on’).  The default is
     ‘ignore’.
‘--detect-zeroes=DETECT-ZEROES’
     Control the automatic conversion of plain zero writes by the OS to
     driver-specific optimized zero write commands.  DETECT-ZEROES is
     one of ‘off’, ‘on’ or ‘unmap’.  ‘unmap’ converts a zero write to an
     unmap operation and can only be used if DISCARD is set to ‘unmap’.
     The default is ‘off’.
‘-c, --connect=DEV’
     Connect FILENAME to NBD device DEV
‘-d, --disconnect’
     Disconnect the device DEV
‘-e, --shared=NUM’
     Allow up to NUM clients to share the device (default ‘1’)
‘-t, --persistent’
     Don’t exit on the last connection
‘-x, --export-name=NAME’
     Set the NBD volume export name.  This switches the server to use
     the new style NBD protocol negotiation
‘-D, --description=DESCRIPTION’
     Set the NBD volume export description, as a human-readable string.
     Requires the use of ‘-x’
‘--tls-creds=ID’
     Enable mandatory TLS encryption for the server by setting the ID of
     the TLS credentials object previously created with the –object
     option.
‘--fork’
     Fork off the server process and exit the parent once the server is
     running.
‘-v, --verbose’
     Display extra debugging information
‘-h, --help’
     Display this help and exit
‘-V, --version’
     Display version information and exit
‘-T, --trace [[enable=]PATTERN][,events=FILE][,file=FILE]’
     Specify tracing options.

     ‘[enable=]PATTERN’
          Immediately enable events matching PATTERN.  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.  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.

2.7.6 ‘qemu-ga’ Invocation
--------------------------

     qemu-ga [OPTIONS]

The QEMU Guest Agent is a daemon intended to be run within virtual
machines.  It allows the hypervisor host to perform various operations
in the guest, such as:

   • get information from the guest
   • set the guest’s system time
   • read/write a file
   • sync and freeze the filesystems
   • suspend the guest
   • reconfigure guest local processors
   • set user’s password
   • ...

qemu-ga will read a system configuration file on startup (located at
‘/etc/qemu/qemu-ga.conf’ by default), then parse remaining configuration
options on the command line.  For the same key, the last option wins,
but the lists accumulate (see below for configuration file format).

‘-m, --method=METHOD’
     Transport method: one of ‘unix-listen’, ‘virtio-serial’, or
     ‘isa-serial’ (‘virtio-serial’ is the default).

‘-p, --path=PATH’
     Device/socket path (the default for virtio-serial is
     ‘/dev/virtio-ports/org.qemu.guest_agent.0’, the default for
     isa-serial is ‘/dev/ttyS0’)

‘-l, --logfile=PATH’
     Set log file path (default is stderr).

‘-f, --pidfile=PATH’
     Specify pid file (default is ‘/var/run/qemu-ga.pid’).

‘-F, --fsfreeze-hook=PATH’
     Enable fsfreeze hook.  Accepts an optional argument that specifies
     script to run on freeze/thaw.  Script will be called with
     ’freeze’/’thaw’ arguments accordingly (default is
     ‘/etc/qemu/fsfreeze-hook’).  If using -F with an argument, do not
     follow -F with a space (for example: ‘-F/var/run/fsfreezehook.sh’).

‘-t, --statedir=PATH’
     Specify the directory to store state information (absolute paths
     only, default is ‘/var/run’).

‘-v, --verbose’
     Log extra debugging information.

‘-V, --version’
     Print version information and exit.

‘-d, --daemon’
     Daemonize after startup (detach from terminal).

‘-b, --blacklist=LIST’
     Comma-separated list of RPCs to disable (no spaces, ‘?’ to list
     available RPCs).

‘-D, --dump-conf’
     Dump the configuration in a format compatible with ‘qemu-ga.conf’
     and exit.

‘-h, --help’
     Display this help and exit.

The syntax of the ‘qemu-ga.conf’ configuration file follows the Desktop
Entry Specification, here is a quick summary: it consists of groups of
key-value pairs, interspersed with comments.

     # qemu-ga configuration sample
     [general]
     daemonize = 0
     pidfile = /var/run/qemu-ga.pid
     verbose = 0
     method = virtio-serial
     path = /dev/virtio-ports/org.qemu.guest_agent.0
     statedir = /var/run

The list of keys follows the command line options:
‘daemon= boolean’
‘method= string’
‘path= string’
‘logfile= string’
‘pidfile= string’
‘fsfreeze-hook= string’
‘statedir= string’
‘verbose= boolean’
‘blacklist= string list’

2.7.7 Disk image file formats
-----------------------------

QEMU supports many image file formats that can be used with VMs as well
as with any of the tools (like ‘qemu-img’).  This includes the preferred
formats raw and qcow2 as well as formats that are supported for
compatibility with older QEMU versions or other hypervisors.

Depending on the image format, different options can be passed to
‘qemu-img create’ and ‘qemu-img convert’ using the ‘-o’ option.  This
section describes each format and the options that are supported for it.

‘raw’

     Raw disk image format.  This format has the advantage of being
     simple and easily exportable to all other emulators.  If your file
     system supports _holes_ (for example in ext2 or ext3 on Linux or
     NTFS on Windows), then only the written sectors will reserve space.
     Use ‘qemu-img info’ to know the real size used by the image or ‘ls
     -ls’ on Unix/Linux.

     Supported options:
     ‘preallocation’
          Preallocation mode (allowed values: ‘off’, ‘falloc’, ‘full’).
          ‘falloc’ mode preallocates space for image by calling
          posix_fallocate().  ‘full’ mode preallocates space for image
          by writing zeros to underlying storage.

‘qcow2’
     QEMU image format, the most versatile format.  Use it to have
     smaller images (useful if your filesystem does not supports holes,
     for example on Windows), zlib based compression and support of
     multiple VM snapshots.

     Supported options:
     ‘compat’
          Determines the qcow2 version to use.  ‘compat=0.10’ uses the
          traditional image format that can be read by any QEMU since
          0.10.  ‘compat=1.1’ enables image format extensions that only
          QEMU 1.1 and newer understand (this is the default).  Amongst
          others, this includes zero clusters, which allow efficient
          copy-on-read for sparse images.

     ‘backing_file’
          File name of a base image (see ‘create’ subcommand)
     ‘backing_fmt’
          Image format of the base image
     ‘encryption’
          If this option is set to ‘on’, the image is encrypted with
          128-bit AES-CBC.

          The use of encryption in qcow and qcow2 images is considered
          to be flawed by modern cryptography standards, suffering from
          a number of design problems:

             − The AES-CBC cipher is used with predictable
               initialization vectors based on the sector number.  This
               makes it vulnerable to chosen plaintext attacks which can
               reveal the existence of encrypted data.
             − The user passphrase is directly used as the encryption
               key.  A poorly chosen or short passphrase will compromise
               the security of the encryption.
             − In the event of the passphrase being compromised there is
               no way to change the passphrase to protect data in any
               qcow images.  The files must be cloned, using a different
               encryption passphrase in the new file.  The original file
               must then be securely erased using a program like shred,
               though even this is ineffective with many modern storage
               technologies.

          Use of qcow / qcow2 encryption with QEMU is deprecated, and
          support for it will go away in a future release.  Users are
          recommended to use an alternative encryption technology such
          as the Linux dm-crypt / LUKS system.

     ‘cluster_size’
          Changes the qcow2 cluster size (must be between 512 and 2M).
          Smaller cluster sizes can improve the image file size whereas
          larger cluster sizes generally provide better performance.

     ‘preallocation’
          Preallocation mode (allowed values: ‘off’, ‘metadata’,
          ‘falloc’, ‘full’).  An image with preallocated metadata is
          initially larger but can improve performance when the image
          needs to grow.  ‘falloc’ and ‘full’ preallocations are like
          the same options of ‘raw’ format, but sets up metadata also.

     ‘lazy_refcounts’
          If this option is set to ‘on’, reference count updates are
          postponed with the goal of avoiding metadata I/O and improving
          performance.  This is particularly interesting with
          ‘cache=writethrough’ which doesn’t batch metadata updates.
          The tradeoff is that after a host crash, the reference count
          tables must be rebuilt, i.e.  on the next open an (automatic)
          ‘qemu-img check -r all’ is required, which may take some time.

          This option can only be enabled if ‘compat=1.1’ is specified.

     ‘nocow’
          If this option is set to ‘on’, it will turn off COW of the
          file.  It’s only valid on btrfs, no effect on other file
          systems.

          Btrfs has low performance when hosting a VM image file, even
          more when the guest on the VM also using btrfs as file system.
          Turning off COW is a way to mitigate this bad performance.
          Generally there are two ways to turn off COW on btrfs: a)
          Disable it by mounting with nodatacow, then all newly created
          files will be NOCOW. b) For an empty file, add the NOCOW file
          attribute.  That’s what this option does.

          Note: this option is only valid to new or empty files.  If
          there is an existing file which is COW and has data blocks
          already, it couldn’t be changed to NOCOW by setting
          ‘nocow=on’.  One can issue ‘lsattr filename’ to check if the
          NOCOW flag is set or not (Capital ’C’ is NOCOW flag).

‘qed’
     Old QEMU image format with support for backing files and compact
     image files (when your filesystem or transport medium does not
     support holes).

     When converting QED images to qcow2, you might want to consider
     using the ‘lazy_refcounts=on’ option to get a more QED-like
     behaviour.

     Supported options:
     ‘backing_file’
          File name of a base image (see ‘create’ subcommand).
     ‘backing_fmt’
          Image file format of backing file (optional).  Useful if the
          format cannot be autodetected because it has no header, like
          some vhd/vpc files.
     ‘cluster_size’
          Changes the cluster size (must be power-of-2 between 4K and
          64K). Smaller cluster sizes can improve the image file size
          whereas larger cluster sizes generally provide better
          performance.
     ‘table_size’
          Changes the number of clusters per L1/L2 table (must be
          power-of-2 between 1 and 16).  There is normally no need to
          change this value but this option can be used for performance
          benchmarking.

‘qcow’
     Old QEMU image format with support for backing files, compact image
     files, encryption and compression.

     Supported options:
     ‘backing_file’
          File name of a base image (see ‘create’ subcommand)
     ‘encryption’
          If this option is set to ‘on’, the image is encrypted.

‘vdi’
     VirtualBox 1.1 compatible image format.  Supported options:
     ‘static’
          If this option is set to ‘on’, the image is created with
          metadata preallocation.

‘vmdk’
     VMware 3 and 4 compatible image format.

     Supported options:
     ‘backing_file’
          File name of a base image (see ‘create’ subcommand).
     ‘compat6’
          Create a VMDK version 6 image (instead of version 4)
     ‘hwversion’
          Specify vmdk virtual hardware version.  Compat6 flag cannot be
          enabled if hwversion is specified.
     ‘subformat’
          Specifies which VMDK subformat to use.  Valid options are
          ‘monolithicSparse’ (default), ‘monolithicFlat’,
          ‘twoGbMaxExtentSparse’, ‘twoGbMaxExtentFlat’ and
          ‘streamOptimized’.

‘vpc’
     VirtualPC compatible image format (VHD). Supported options:
     ‘subformat’
          Specifies which VHD subformat to use.  Valid options are
          ‘dynamic’ (default) and ‘fixed’.

‘VHDX’
     Hyper-V compatible image format (VHDX). Supported options:
     ‘subformat’
          Specifies which VHDX subformat to use.  Valid options are
          ‘dynamic’ (default) and ‘fixed’.
     ‘block_state_zero’
          Force use of payload blocks of type ’ZERO’.  Can be set to
          ‘on’ (default) or ‘off’.  When set to ‘off’, new blocks will
          be created as ‘PAYLOAD_BLOCK_NOT_PRESENT’, which means parsers
          are free to return arbitrary data for those blocks.  Do not
          set to ‘off’ when using ‘qemu-img convert’ with
          ‘subformat=dynamic’.
     ‘block_size’
          Block size; min 1 MB, max 256 MB. 0 means auto-calculate based
          on image size.
     ‘log_size’
          Log size; min 1 MB.

2.7.7.1 Read-only formats
.........................

More disk image file formats are supported in a read-only mode.
‘bochs’
     Bochs images of ‘growing’ type.
‘cloop’
     Linux Compressed Loop image, useful only to reuse directly
     compressed CD-ROM images present for example in the Knoppix
     CD-ROMs.
‘dmg’
     Apple disk image.
‘parallels’
     Parallels disk image format.

2.7.8 Using host drives
-----------------------

In addition to disk image files, QEMU can directly access host devices.
We describe here the usage for QEMU version >= 0.8.3.

2.7.8.1 Linux
.............

On Linux, you can directly use the host device filename instead of a
disk image filename provided you have enough privileges to access it.
For example, use ‘/dev/cdrom’ to access to the CDROM.

‘CD’
     You can specify a CDROM device even if no CDROM is loaded.  QEMU
     has specific code to detect CDROM insertion or removal.  CDROM
     ejection by the guest OS is supported.  Currently only data CDs are
     supported.
‘Floppy’
     You can specify a floppy device even if no floppy is loaded.
     Floppy removal is currently not detected accurately (if you change
     floppy without doing floppy access while the floppy is not loaded,
     the guest OS will think that the same floppy is loaded).  Use of
     the host’s floppy device is deprecated, and support for it will be
     removed in a future release.
‘Hard disks’
     Hard disks can be used.  Normally you must specify the whole disk
     (‘/dev/hdb’ instead of ‘/dev/hdb1’) so that the guest OS can see it
     as a partitioned disk.  WARNING: unless you know what you do, it is
     better to only make READ-ONLY accesses to the hard disk otherwise
     you may corrupt your host data (use the ‘-snapshot’ command line
     option or modify the device permissions accordingly).

2.7.8.2 Windows
...............

‘CD’
     The preferred syntax is the drive letter (e.g.  ‘d:’).  The
     alternate syntax ‘\\.\d:’ is supported.  ‘/dev/cdrom’ is supported
     as an alias to the first CDROM drive.

     Currently there is no specific code to handle removable media, so
     it is better to use the ‘change’ or ‘eject’ monitor commands to
     change or eject media.
‘Hard disks’
     Hard disks can be used with the syntax: ‘\\.\PhysicalDriveN’ where
     N is the drive number (0 is the first hard disk).

     WARNING: unless you know what you do, it is better to only make
     READ-ONLY accesses to the hard disk otherwise you may corrupt your
     host data (use the ‘-snapshot’ command line so that the
     modifications are written in a temporary file).

2.7.8.3 Mac OS X
................

‘/dev/cdrom’ is an alias to the first CDROM.

Currently there is no specific code to handle removable media, so it is
better to use the ‘change’ or ‘eject’ monitor commands to change or
eject media.

2.7.9 Virtual FAT disk images
-----------------------------

QEMU can automatically create a virtual FAT disk image from a directory
tree.  In order to use it, just type:

     qemu-system-i386 linux.img -hdb fat:/my_directory

Then you access access to all the files in the ‘/my_directory’ directory
without having to copy them in a disk image or to export them via SAMBA
or NFS. The default access is _read-only_.

Floppies can be emulated with the ‘:floppy:’ option:

     qemu-system-i386 linux.img -fda fat:floppy:/my_directory

A read/write support is available for testing (beta stage) with the
‘:rw:’ option:

     qemu-system-i386 linux.img -fda fat:floppy:rw:/my_directory

What you should _never_ do:
   • use non-ASCII filenames ;
   • use "-snapshot" together with ":rw:" ;
   • expect it to work when loadvm’ing ;
   • write to the FAT directory on the host system while accessing it
     with the guest system.

2.7.10 NBD access
-----------------

QEMU can access directly to block device exported using the Network
Block Device protocol.

     qemu-system-i386 linux.img -hdb nbd://my_nbd_server.mydomain.org:1024/

If the NBD server is located on the same host, you can use an unix
socket instead of an inet socket:

     qemu-system-i386 linux.img -hdb nbd+unix://?socket=/tmp/my_socket

In this case, the block device must be exported using qemu-nbd:

     qemu-nbd --socket=/tmp/my_socket my_disk.qcow2

The use of qemu-nbd allows sharing of a disk between several guests:
     qemu-nbd --socket=/tmp/my_socket --share=2 my_disk.qcow2

and then you can use it with two guests:
     qemu-system-i386 linux1.img -hdb nbd+unix://?socket=/tmp/my_socket
     qemu-system-i386 linux2.img -hdb nbd+unix://?socket=/tmp/my_socket

If the nbd-server uses named exports (supported since NBD 2.9.18, or
with QEMU’s own embedded NBD server), you must specify an export name in
the URI:
     qemu-system-i386 -cdrom nbd://localhost/debian-500-ppc-netinst
     qemu-system-i386 -cdrom nbd://localhost/openSUSE-11.1-ppc-netinst

The URI syntax for NBD is supported since QEMU 1.3.  An alternative
syntax is also available.  Here are some example of the older syntax:
     qemu-system-i386 linux.img -hdb nbd:my_nbd_server.mydomain.org:1024
     qemu-system-i386 linux2.img -hdb nbd:unix:/tmp/my_socket
     qemu-system-i386 -cdrom nbd:localhost:10809:exportname=debian-500-ppc-netinst

2.7.11 Sheepdog disk images
---------------------------

Sheepdog is a distributed storage system for QEMU. It provides highly
available block level storage volumes that can be attached to QEMU-based
virtual machines.

You can create a Sheepdog disk image with the command:
     qemu-img create sheepdog:///IMAGE SIZE
where IMAGE is the Sheepdog image name and SIZE is its size.

To import the existing FILENAME to Sheepdog, you can use a convert
command.
     qemu-img convert FILENAME sheepdog:///IMAGE

You can boot from the Sheepdog disk image with the command:
     qemu-system-i386 sheepdog:///IMAGE

You can also create a snapshot of the Sheepdog image like qcow2.
     qemu-img snapshot -c TAG sheepdog:///IMAGE
where TAG is a tag name of the newly created snapshot.

To boot from the Sheepdog snapshot, specify the tag name of the
snapshot.
     qemu-system-i386 sheepdog:///IMAGE#TAG

You can create a cloned image from the existing snapshot.
     qemu-img create -b sheepdog:///BASE#TAG sheepdog:///IMAGE
where BASE is a image name of the source snapshot and TAG is its tag
name.

You can use an unix socket instead of an inet socket:

     qemu-system-i386 sheepdog+unix:///IMAGE?socket=PATH

If the Sheepdog daemon doesn’t run on the local host, you need to
specify one of the Sheepdog servers to connect to.
     qemu-img create sheepdog://HOSTNAME:PORT/IMAGE SIZE
     qemu-system-i386 sheepdog://HOSTNAME:PORT/IMAGE

2.7.12 iSCSI LUNs
-----------------

iSCSI is a popular protocol used to access SCSI devices across a
computer network.

There are two different ways iSCSI devices can be used by QEMU.

The first method is to mount the iSCSI LUN on the host, and make it
appear as any other ordinary SCSI device on the host and then to access
this device as a /dev/sd device from QEMU. How to do this differs
between host OSes.

The second method involves using the iSCSI initiator that is built into
QEMU. This provides a mechanism that works the same way regardless of
which host OS you are running QEMU on.  This section will describe this
second method of using iSCSI together with QEMU.

In QEMU, iSCSI devices are described using special iSCSI URLs

     URL syntax:
     iscsi://[<username>[%<password>]@]<host>[:<port>]/<target-iqn-name>/<lun>

Username and password are optional and only used if your target is set
up using CHAP authentication for access control.  Alternatively the
username and password can also be set via environment variables to have
these not show up in the process list

     export LIBISCSI_CHAP_USERNAME=<username>
     export LIBISCSI_CHAP_PASSWORD=<password>
     iscsi://<host>/<target-iqn-name>/<lun>

Various session related parameters can be set via special options,
either in a configuration file provided via ’-readconfig’ or directly on
the command line.

If the initiator-name is not specified qemu will use a default name of
’iqn.2008-11.org.linux-kvm[:<name>’] where <name> is the name of the
virtual machine.

     Setting a specific initiator name to use when logging in to the target
     -iscsi initiator-name=iqn.qemu.test:my-initiator

     Controlling which type of header digest to negotiate with the target
     -iscsi header-digest=CRC32C|CRC32C-NONE|NONE-CRC32C|NONE

These can also be set via a configuration file
     [iscsi]
       user = "CHAP username"
       password = "CHAP password"
       initiator-name = "iqn.qemu.test:my-initiator"
       # header digest is one of CRC32C|CRC32C-NONE|NONE-CRC32C|NONE
       header-digest = "CRC32C"

Setting the target name allows different options for different targets
     [iscsi "iqn.target.name"]
       user = "CHAP username"
       password = "CHAP password"
       initiator-name = "iqn.qemu.test:my-initiator"
       # header digest is one of CRC32C|CRC32C-NONE|NONE-CRC32C|NONE
       header-digest = "CRC32C"

Howto use a configuration file to set iSCSI configuration options:
     cat >iscsi.conf <<EOF
     [iscsi]
       user = "me"
       password = "my password"
       initiator-name = "iqn.qemu.test:my-initiator"
       header-digest = "CRC32C"
     EOF

     qemu-system-i386 -drive file=iscsi://127.0.0.1/iqn.qemu.test/1 \
         -readconfig iscsi.conf

Howto set up a simple iSCSI target on loopback and accessing it via
QEMU:
     This example shows how to set up an iSCSI target with one CDROM and one DISK
     using the Linux STGT software target. This target is available on Red Hat based
     systems as the package 'scsi-target-utils'.

     tgtd --iscsi portal=127.0.0.1:3260
     tgtadm --lld iscsi --op new --mode target --tid 1 -T iqn.qemu.test
     tgtadm --lld iscsi --mode logicalunit --op new --tid 1 --lun 1 \
         -b /IMAGES/disk.img --device-type=disk
     tgtadm --lld iscsi --mode logicalunit --op new --tid 1 --lun 2 \
         -b /IMAGES/cd.iso --device-type=cd
     tgtadm --lld iscsi --op bind --mode target --tid 1 -I ALL

     qemu-system-i386 -iscsi initiator-name=iqn.qemu.test:my-initiator \
         -boot d -drive file=iscsi://127.0.0.1/iqn.qemu.test/1 \
         -cdrom iscsi://127.0.0.1/iqn.qemu.test/2

2.7.13 GlusterFS disk images
----------------------------

GlusterFS is a user space distributed file system.

You can boot from the GlusterFS disk image with the command:
     URI:
     qemu-system-x86_64 -drive file=gluster[+TYPE]://[HOST[:PORT]]/VOLUME/PATH
                                    [?socket=...][,file.debug=9][,file.logfile=...]

     JSON:
     qemu-system-x86_64 'json:{"driver":"qcow2",
                                "file":{"driver":"gluster",
                                         "volume":"testvol","path":"a.img","debug":9,"logfile":"...",
                                         "server":[{"type":"tcp","host":"...","port":"..."},
                                                   {"type":"unix","socket":"..."}]}}'

GLUSTER is the protocol.

TYPE specifies the transport type used to connect to gluster management
daemon (glusterd).  Valid transport types are tcp and unix.  In the URI
form, if a transport type isn’t specified, then tcp type is assumed.

HOST specifies the server where the volume file specification for the
given volume resides.  This can be either a hostname or an ipv4 address.
If transport type is unix, then HOST field should not be specified.
Instead SOCKET field needs to be populated with the path to unix domain
socket.

PORT is the port number on which glusterd is listening.  This is
optional and if not specified, it defaults to port 24007.  If the
transport type is unix, then PORT should not be specified.

VOLUME is the name of the gluster volume which contains the disk image.

PATH is the path to the actual disk image that resides on gluster
volume.

DEBUG is the logging level of the gluster protocol driver.  Debug levels
are 0-9, with 9 being the most verbose, and 0 representing no debugging
output.  The default level is 4.  The current logging levels defined in
the gluster source are 0 - None, 1 - Emergency, 2 - Alert, 3 - Critical,
4 - Error, 5 - Warning, 6 - Notice, 7 - Info, 8 - Debug, 9 - Trace

LOGFILE is a commandline option to mention log file path which helps in
logging to the specified file and also help in persisting the gfapi
logs.  The default is stderr.

You can create a GlusterFS disk image with the command:
     qemu-img create gluster://HOST/VOLUME/PATH SIZE

Examples
     qemu-system-x86_64 -drive file=gluster://1.2.3.4/testvol/a.img
     qemu-system-x86_64 -drive file=gluster+tcp://1.2.3.4/testvol/a.img
     qemu-system-x86_64 -drive file=gluster+tcp://1.2.3.4:24007/testvol/dir/a.img
     qemu-system-x86_64 -drive file=gluster+tcp://[1:2:3:4:5:6:7:8]/testvol/dir/a.img
     qemu-system-x86_64 -drive file=gluster+tcp://[1:2:3:4:5:6:7:8]:24007/testvol/dir/a.img
     qemu-system-x86_64 -drive file=gluster+tcp://server.domain.com:24007/testvol/dir/a.img
     qemu-system-x86_64 -drive file=gluster+unix:///testvol/dir/a.img?socket=/tmp/glusterd.socket
     qemu-system-x86_64 -drive file=gluster+rdma://1.2.3.4:24007/testvol/a.img
     qemu-system-x86_64 -drive file=gluster://1.2.3.4/testvol/a.img,file.debug=9,file.logfile=/var/log/qemu-gluster.log
     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

2.7.14 Secure Shell (ssh) disk images
-------------------------------------

You can access disk images located on a remote ssh server by using the
ssh protocol:

     qemu-system-x86_64 -drive file=ssh://[USER@]SERVER[:PORT]/PATH[?host_key_check=HOST_KEY_CHECK]

Alternative syntax using properties:

     qemu-system-x86_64 -drive file.driver=ssh[,file.user=USER],file.host=SERVER[,file.port=PORT],file.path=PATH[,file.host_key_check=HOST_KEY_CHECK]

SSH is the protocol.

USER is the remote user.  If not specified, then the local username is
tried.

SERVER specifies the remote ssh server.  Any ssh server can be used, but
it must implement the sftp-server protocol.  Most Unix/Linux systems
should work without requiring any extra configuration.

PORT is the port number on which sshd is listening.  By default the
standard ssh port (22) is used.

PATH is the path to the disk image.

The optional HOST_KEY_CHECK parameter controls how the remote host’s key
is checked.  The default is ‘yes’ which means to use the local
‘.ssh/known_hosts’ file.  Setting this to ‘no’ turns off known-hosts
checking.  Or you can check that the host key matches a specific
fingerprint:
‘host_key_check=md5:78:45:8e:14:57:4f:d5:45:83:0a:0e:f3:49:82:c9:c8’
(‘sha1:’ can also be used as a prefix, but note that OpenSSH tools only
use MD5 to print fingerprints).

Currently authentication must be done using ssh-agent.  Other
authentication methods may be supported in future.

Note: Many ssh servers do not support an ‘fsync’-style operation.  The
ssh driver cannot guarantee that disk flush requests are obeyed, and
this causes a risk of disk corruption if the remote server or network
goes down during writes.  The driver will print a warning when ‘fsync’
is not supported:

warning: ssh server ‘ssh.example.com:22’ does not support fsync

With sufficiently new versions of libssh2 and OpenSSH, ‘fsync’ is
supported.

2.8 Network emulation
=====================

QEMU can simulate several network cards (PCI or ISA cards on the PC
target) and can connect them to an arbitrary number of Virtual Local
Area Networks (VLANs).  Host TAP devices can be connected to any QEMU
VLAN. VLAN can be connected between separate instances of QEMU to
simulate large networks.  For simpler usage, a non privileged user mode
network stack can replace the TAP device to have a basic network
connection.

2.8.1 VLANs
-----------

QEMU simulates several VLANs.  A VLAN can be symbolised as a virtual
connection between several network devices.  These devices can be for
example QEMU virtual Ethernet cards or virtual Host ethernet devices
(TAP devices).

2.8.2 Using TAP network interfaces
----------------------------------

This is the standard way to connect QEMU to a real network.  QEMU adds a
virtual network device on your host (called ‘tapN’), and you can then
configure it as if it was a real ethernet card.

2.8.2.1 Linux host
..................

As an example, you can download the ‘linux-test-xxx.tar.gz’ archive and
copy the script ‘qemu-ifup’ in ‘/etc’ and configure properly ‘sudo’ so
that the command ‘ifconfig’ contained in ‘qemu-ifup’ can be executed as
root.  You must verify that your host kernel supports the TAP network
interfaces: the device ‘/dev/net/tun’ must be present.

See *note sec_invocation:: to have examples of command lines using the
TAP network interfaces.

2.8.2.2 Windows host
....................

There is a virtual ethernet driver for Windows 2000/XP systems, called
TAP-Win32.  But it is not included in standard QEMU for Windows, so you
will need to get it separately.  It is part of OpenVPN package, so
download OpenVPN from : <http://openvpn.net/>.

2.8.3 Using the user mode network stack
---------------------------------------

By using the option ‘-net user’ (default configuration if no ‘-net’
option is specified), QEMU uses a completely user mode network stack
(you don’t need root privilege to use the virtual network).  The virtual
network configuration is the following:


              QEMU VLAN      <------>  Firewall/DHCP server <-----> Internet
                                |          (10.0.2.2)
                                |
                                ---->  DNS server (10.0.2.3)
                                |
                                ---->  SMB server (10.0.2.4)

The QEMU VM behaves as if it was behind a firewall which blocks all
incoming connections.  You can use a DHCP client to automatically
configure the network in the QEMU VM. The DHCP server assign addresses
to the hosts starting from 10.0.2.15.

In order to check that the user mode network is working, you can ping
the address 10.0.2.2 and verify that you got an address in the range
10.0.2.x from the QEMU virtual DHCP server.

Note that ICMP traffic in general does not work with user mode
networking.  ‘ping’, aka.  ICMP echo, to the local router (10.0.2.2)
shall work, however.  If you’re using QEMU on Linux >= 3.0, it can use
unprivileged ICMP ping sockets to allow ‘ping’ to the Internet.  The
host admin has to set the ping_group_range in order to grant access to
those sockets.  To allow ping for GID 100 (usually users group):

     echo 100 100 > /proc/sys/net/ipv4/ping_group_range

When using the built-in TFTP server, the router is also the TFTP server.

When using the ‘'-netdev user,hostfwd=...'’ option, TCP or UDP
connections can be redirected from the host to the guest.  It allows for
example to redirect X11, telnet or SSH connections.

2.8.4 Connecting VLANs between QEMU instances
---------------------------------------------

Using the ‘-net socket’ option, it is possible to make VLANs that span
several QEMU instances.  See *note sec_invocation:: to have a basic
example.

2.9 Other Devices
=================

2.9.1 Inter-VM Shared Memory device
-----------------------------------

On Linux hosts, a shared memory device is available.  The basic syntax
is:

     qemu-system-x86_64 -device ivshmem-plain,memdev=HOSTMEM

where HOSTMEM names a host memory backend.  For a POSIX shared memory
backend, use something like

     -object memory-backend-file,size=1M,share,mem-path=/dev/shm/ivshmem,id=HOSTMEM

If desired, interrupts can be sent between guest VMs accessing the same
shared memory region.  Interrupt support requires using a shared memory
server and using a chardev socket to connect to it.  The code for the
shared memory server is qemu.git/contrib/ivshmem-server.  An example
syntax when using the shared memory server is:

     # First start the ivshmem server once and for all
     ivshmem-server -p PIDFILE -S PATH -m SHM-NAME -l SHM-SIZE -n VECTORS

     # Then start your qemu instances with matching arguments
     qemu-system-x86_64 -device ivshmem-doorbell,vectors=VECTORS,chardev=ID
                      -chardev socket,path=PATH,id=ID

When using the server, the guest will be assigned a VM ID (>=0) that
allows guests using the same server to communicate via interrupts.
Guests can read their VM ID from a device register (see
ivshmem-spec.txt).

2.9.1.1 Migration with ivshmem
..............................

With device property ‘master=on’, the guest will copy the shared memory
on migration to the destination host.  With ‘master=off’, the guest will
not be able to migrate with the device attached.  In the latter case,
the device should be detached and then reattached after migration using
the PCI hotplug support.

At most one of the devices sharing the same memory can be master.  The
master must complete migration before you plug back the other devices.

2.9.1.2 ivshmem and hugepages
.............................

Instead of specifying the <shm size> using POSIX shm, you may specify a
memory backend that has hugepage support:

     qemu-system-x86_64 -object memory-backend-file,size=1G,mem-path=/dev/hugepages/my-shmem-file,share,id=mb1
                      -device ivshmem-plain,memdev=mb1

ivshmem-server also supports hugepages mount points with the ‘-m’ memory
path argument.

2.10 Direct Linux Boot
======================

This section explains how to launch a Linux kernel inside QEMU without
having to make a full bootable image.  It is very useful for fast Linux
kernel testing.

The syntax is:
     qemu-system-i386 -kernel arch/i386/boot/bzImage -hda root-2.4.20.img -append "root=/dev/hda"

Use ‘-kernel’ to provide the Linux kernel image and ‘-append’ to give
the kernel command line arguments.  The ‘-initrd’ option can be used to
provide an INITRD image.

When using the direct Linux boot, a disk image for the first hard disk
‘hda’ is required because its boot sector is used to launch the Linux
kernel.

If you do not need graphical output, you can disable it and redirect the
virtual serial port and the QEMU monitor to the console with the
‘-nographic’ option.  The typical command line is:
     qemu-system-i386 -kernel arch/i386/boot/bzImage -hda root-2.4.20.img \
                      -append "root=/dev/hda console=ttyS0" -nographic

Use <Ctrl-a c> to switch between the serial console and the monitor
(*note pcsys_keys::).

2.11 USB emulation
==================

QEMU emulates a PCI UHCI USB controller.  You can virtually plug virtual
USB devices or real host USB devices (experimental, works only on Linux
hosts).  QEMU will automatically create and connect virtual USB hubs as
necessary to connect multiple USB devices.

2.11.1 Connecting USB devices
-----------------------------

USB devices can be connected with the ‘-usbdevice’ commandline option or
the ‘usb_add’ monitor command.  Available devices are:

‘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.
‘disk:FILE’
     Mass storage device based on FILE (*note disk_images::)
‘host:BUS.ADDR’
     Pass through the host device identified by BUS.ADDR (Linux only)
‘host:VENDOR_ID:PRODUCT_ID’
     Pass through the host device identified by VENDOR_ID:PRODUCT_ID
     (Linux only)
‘wacom-tablet’
     Virtual Wacom PenPartner tablet.  This device is similar to the
     ‘tablet’ above but it can be used with the tslib library because in
     addition to touch coordinates it reports touch pressure.
‘keyboard’
     Standard USB keyboard.  Will override the PS/2 keyboard (if
     present).
‘serial:[vendorid=VENDOR_ID][,product_id=PRODUCT_ID]:DEV’
     Serial converter.  This emulates an FTDI FT232BM chip connected to
     host character device DEV.  The available character devices are the
     same as for the ‘-serial’ option.  The ‘vendorid’ and ‘productid’
     options can be used to override the default 0403:6001.  For
     instance,
          usb_add serial:productid=FA00:tcp:192.168.0.2:4444
     will connect to tcp port 4444 of ip 192.168.0.2, and plug that to
     the virtual serial converter, faking a Matrix Orbital LCD Display
     (USB ID 0403:FA00).
‘braille’
     Braille device.  This will use BrlAPI to display the braille output
     on a real or fake device.
‘net:OPTIONS’
     Network adapter that supports CDC ethernet and RNDIS protocols.
     OPTIONS specifies NIC options as with ‘-net nic,’OPTIONS (see
     description).  For instance, user-mode networking can be used with
          qemu-system-i386 [...OPTIONS...] -net user,vlan=0 -usbdevice net:vlan=0
     Currently this cannot be used in machines that support PCI NICs.
‘bt[:HCI-TYPE]’
     Bluetooth dongle whose type is specified in the same format as with
     the ‘-bt hci’ option, *note allowed HCI types: bt-hcis.  If no type
     is given, the HCI logic corresponds to ‘-bt hci,vlan=0’.  This USB
     device implements the USB Transport Layer of HCI. Example usage:
          qemu-system-i386 [...OPTIONS...] -usbdevice bt:hci,vlan=3 -bt device:keyboard,vlan=3

2.11.2 Using host USB devices on a Linux host
---------------------------------------------

WARNING: this is an experimental feature.  QEMU will slow down when
using it.  USB devices requiring real time streaming (i.e.  USB Video
Cameras) are not supported yet.

  1. If you use an early Linux 2.4 kernel, verify that no Linux driver
     is actually using the USB device.  A simple way to do that is
     simply to disable the corresponding kernel module by renaming it
     from ‘mydriver.o’ to ‘mydriver.o.disabled’.

  2. Verify that ‘/proc/bus/usb’ is working (most Linux distributions
     should enable it by default).  You should see something like that:
          ls /proc/bus/usb
          001  devices  drivers

  3. Since only root can access to the USB devices directly, you can
     either launch QEMU as root or change the permissions of the USB
     devices you want to use.  For testing, the following suffices:
          chown -R myuid /proc/bus/usb

  4. Launch QEMU and do in the monitor:
          info usbhost
            Device 1.2, speed 480 Mb/s
              Class 00: USB device 1234:5678, USB DISK
     You should see the list of the devices you can use (Never try to
     use hubs, it won’t work).

  5. Add the device in QEMU by using:
          usb_add host:1234:5678

     Normally the guest OS should report that a new USB device is
     plugged.  You can use the option ‘-usbdevice’ to do the same.

  6. Now you can try to use the host USB device in QEMU.

When relaunching QEMU, you may have to unplug and plug again the USB
device to make it work again (this is a bug).

2.12 VNC security
=================

The VNC server capability provides access to the graphical console of
the guest VM across the network.  This has a number of security
considerations depending on the deployment scenarios.

2.12.1 Without passwords
------------------------

The simplest VNC server setup does not include any form of
authentication.  For this setup it is recommended to restrict it to
listen on a UNIX domain socket only.  For example

     qemu-system-i386 [...OPTIONS...] -vnc unix:/home/joebloggs/.qemu-myvm-vnc

This ensures that only users on local box with read/write access to that
path can access the VNC server.  To securely access the VNC server from
a remote machine, a combination of netcat+ssh can be used to provide a
secure tunnel.

2.12.2 With passwords
---------------------

The VNC protocol has limited support for password based authentication.
Since the protocol limits passwords to 8 characters it should not be
considered to provide high security.  The password can be fairly easily
brute-forced by a client making repeat connections.  For this reason, a
VNC server using password authentication should be restricted to only
listen on the loopback interface or UNIX domain sockets.  Password
authentication is not supported when operating in FIPS 140-2 compliance
mode as it requires the use of the DES cipher.  Password authentication
is requested with the ‘password’ option, and then once QEMU is running
the password is set with the monitor.  Until the monitor is used to set
the password all clients will be rejected.

     qemu-system-i386 [...OPTIONS...] -vnc :1,password -monitor stdio
     (qemu) change vnc password
     Password: ********
     (qemu)

2.12.3 With x509 certificates
-----------------------------

The QEMU VNC server also implements the VeNCrypt extension allowing use
of TLS for encryption of the session, and x509 certificates for
authentication.  The use of x509 certificates is strongly recommended,
because TLS on its own is susceptible to man-in-the-middle attacks.
Basic x509 certificate support provides a secure session, but no
authentication.  This allows any client to connect, and provides an
encrypted session.

     qemu-system-i386 [...OPTIONS...] -vnc :1,tls,x509=/etc/pki/qemu -monitor stdio

In the above example ‘/etc/pki/qemu’ should contain at least three
files, ‘ca-cert.pem’, ‘server-cert.pem’ and ‘server-key.pem’.
Unprivileged users will want to use a private directory, for example
‘$HOME/.pki/qemu’.  NB the ‘server-key.pem’ file should be protected
with file mode 0600 to only be readable by the user owning it.

2.12.4 With x509 certificates and client verification
-----------------------------------------------------

Certificates can also provide a means to authenticate the client
connecting.  The server will request that the client provide a
certificate, which it will then validate against the CA certificate.
This is a good choice if deploying in an environment with a private
internal certificate authority.

     qemu-system-i386 [...OPTIONS...] -vnc :1,tls,x509verify=/etc/pki/qemu -monitor stdio

2.12.5 With x509 certificates, client verification and passwords
----------------------------------------------------------------

Finally, the previous method can be combined with VNC password
authentication to provide two layers of authentication for clients.

     qemu-system-i386 [...OPTIONS...] -vnc :1,password,tls,x509verify=/etc/pki/qemu -monitor stdio
     (qemu) change vnc password
     Password: ********
     (qemu)

2.12.6 With SASL authentication
-------------------------------

The SASL authentication method is a VNC extension, that provides an
easily extendable, pluggable authentication method.  This allows for
integration with a wide range of authentication mechanisms, such as PAM,
GSSAPI/Kerberos, LDAP, SQL databases, one-time keys and more.  The
strength of the authentication depends on the exact mechanism
configured.  If the chosen mechanism also provides a SSF layer, then it
will encrypt the datastream as well.

Refer to the later docs on how to choose the exact SASL mechanism used
for authentication, but assuming use of one supporting SSF, then QEMU
can be launched with:

     qemu-system-i386 [...OPTIONS...] -vnc :1,sasl -monitor stdio

2.12.7 With x509 certificates and SASL authentication
-----------------------------------------------------

If the desired SASL authentication mechanism does not supported SSF
layers, then it is strongly advised to run it in combination with TLS
and x509 certificates.  This provides securely encrypted data stream,
avoiding risk of compromising of the security credentials.  This can be
enabled, by combining the ’sasl’ option with the aforementioned TLS +
x509 options:

     qemu-system-i386 [...OPTIONS...] -vnc :1,tls,x509,sasl -monitor stdio

2.12.8 Generating certificates for VNC
--------------------------------------

The GNU TLS packages provides a command called ‘certtool’ which can be
used to generate certificates and keys in PEM format.  At a minimum it
is necessary to setup a certificate authority, and issue certificates to
each server.  If using certificates for authentication, then each client
will also need to be issued a certificate.  The recommendation is for
the server to keep its certificates in either ‘/etc/pki/qemu’ or for
unprivileged users in ‘$HOME/.pki/qemu’.

2.12.8.1 Setup the Certificate Authority
........................................

This step only needs to be performed once per organization /
organizational unit.  First the CA needs a private key.  This key must
be kept VERY secret and secure.  If this key is compromised the entire
trust chain of the certificates issued with it is lost.

     # certtool --generate-privkey > ca-key.pem

A CA needs to have a public certificate.  For simplicity it can be a
self-signed certificate, or one issue by a commercial certificate
issuing authority.  To generate a self-signed certificate requires one
core piece of information, the name of the organization.

     # cat > ca.info <<EOF
     cn = Name of your organization
     ca
     cert_signing_key
     EOF
     # certtool --generate-self-signed \
                --load-privkey ca-key.pem
                --template ca.info \
                --outfile ca-cert.pem

The ‘ca-cert.pem’ file should be copied to all servers and clients
wishing to utilize TLS support in the VNC server.  The ‘ca-key.pem’ must
not be disclosed/copied at all.

2.12.8.2 Issuing server certificates
....................................

Each server (or host) needs to be issued with a key and certificate.
When connecting the certificate is sent to the client which validates it
against the CA certificate.  The core piece of information for a server
certificate is the hostname.  This should be the fully qualified
hostname that the client will connect with, since the client will
typically also verify the hostname in the certificate.  On the host
holding the secure CA private key:

     # cat > server.info <<EOF
     organization = Name  of your organization
     cn = server.foo.example.com
     tls_www_server
     encryption_key
     signing_key
     EOF
     # certtool --generate-privkey > server-key.pem
     # certtool --generate-certificate \
                --load-ca-certificate ca-cert.pem \
                --load-ca-privkey ca-key.pem \
                --load-privkey server-key.pem \
                --template server.info \
                --outfile server-cert.pem

The ‘server-key.pem’ and ‘server-cert.pem’ files should now be securely
copied to the server for which they were generated.  The
‘server-key.pem’ is security sensitive and should be kept protected with
file mode 0600 to prevent disclosure.

2.12.8.3 Issuing client certificates
....................................

If the QEMU VNC server is to use the ‘x509verify’ option to validate
client certificates as its authentication mechanism, each client also
needs to be issued a certificate.  The client certificate contains
enough metadata to uniquely identify the client, typically organization,
state, city, building, etc.  On the host holding the secure CA private
key:

     # cat > client.info <<EOF
     country = GB
     state = London
     locality = London
     organization = Name of your organization
     cn = client.foo.example.com
     tls_www_client
     encryption_key
     signing_key
     EOF
     # certtool --generate-privkey > client-key.pem
     # certtool --generate-certificate \
                --load-ca-certificate ca-cert.pem \
                --load-ca-privkey ca-key.pem \
                --load-privkey client-key.pem \
                --template client.info \
                --outfile client-cert.pem

The ‘client-key.pem’ and ‘client-cert.pem’ files should now be securely
copied to the client for which they were generated.

2.12.9 Configuring SASL mechanisms
----------------------------------

The following documentation assumes use of the Cyrus SASL implementation
on a Linux host, but the principals should apply to any other SASL impl.
When SASL is enabled, the mechanism configuration will be loaded from
system default SASL service config /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.

The default configuration might contain

     mech_list: digest-md5
     sasldb_path: /etc/qemu/passwd.db

This says to use the ’Digest MD5’ mechanism, which is similar to the
HTTP Digest-MD5 mechanism.  The list of valid usernames & passwords is
maintained in the /etc/qemu/passwd.db file, and can be updated using the
saslpasswd2 command.  While this mechanism is easy to configure and use,
it is not considered secure by modern standards, so only suitable for
developers / ad-hoc testing.

A more serious deployment might use Kerberos, which is done with the
’gssapi’ mechanism

     mech_list: gssapi
     keytab: /etc/qemu/krb5.tab

For this to work the administrator of your KDC must generate a Kerberos
principal for the server, with a name of
’qemu/somehost.example.com@EXAMPLE.COM’ replacing ’somehost.example.com’
with the fully qualified host name of the machine running QEMU, and
’EXAMPLE.COM’ with the Kerberos Realm.

Other configurations will be left as an exercise for the reader.  It
should be noted that only Digest-MD5 and GSSAPI provides a SSF layer for
data encryption.  For all other mechanisms, VNC should always be
configured to use TLS and x509 certificates to protect security
credentials from snooping.

2.13 GDB usage
==============

QEMU has a primitive support to work with gdb, so that you can do
’Ctrl-C’ while the virtual machine is running and inspect its state.

In order to use gdb, launch QEMU with the ’-s’ option.  It will wait for
a gdb connection:
     qemu-system-i386 -s -kernel arch/i386/boot/bzImage -hda root-2.4.20.img \
                         -append "root=/dev/hda"
     Connected to host network interface: tun0
     Waiting gdb connection on port 1234

Then launch gdb on the ’vmlinux’ executable:
     > gdb vmlinux

In gdb, connect to QEMU:
     (gdb) target remote localhost:1234

Then you can use gdb normally.  For example, type ’c’ to launch the
kernel:
     (gdb) c

Here are some useful tips in order to use gdb on system code:

  1. Use ‘info reg’ to display all the CPU registers.
  2. Use ‘x/10i $eip’ to display the code at the PC position.
  3. Use ‘set architecture i8086’ to dump 16 bit code.  Then use ‘x/10i
     $cs*16+$eip’ to dump the code at the PC position.

Advanced debugging options:

The default single stepping behavior is step with the IRQs and timer
service routines off.  It is set this way because when gdb executes a
single step it expects to advance beyond the current instruction.  With
the IRQs and timer service routines on, a single step might jump into
the one of the interrupt or exception vectors instead of executing the
current instruction.  This means you may hit the same breakpoint a
number of times before executing the instruction gdb wants to have
executed.  Because there are rare circumstances where you want to single
step into an interrupt vector the behavior can be controlled from GDB.
There are three commands you can query and set the single step behavior:
‘maintenance packet qqemu.sstepbits’

     This will display the MASK bits used to control the single stepping
     IE:
          (gdb) maintenance packet qqemu.sstepbits
          sending: "qqemu.sstepbits"
          received: "ENABLE=1,NOIRQ=2,NOTIMER=4"
‘maintenance packet qqemu.sstep’

     This will display the current value of the mask used when single
     stepping IE:
          (gdb) maintenance packet qqemu.sstep
          sending: "qqemu.sstep"
          received: "0x7"
‘maintenance packet Qqemu.sstep=HEX_VALUE’

     This will change the single step mask, so if wanted to enable IRQs
     on the single step, but not timers, you would use:
          (gdb) maintenance packet Qqemu.sstep=0x5
          sending: "qemu.sstep=0x5"
          received: "OK"

2.14 Target OS specific information
===================================

2.14.1 Linux
------------

To have access to SVGA graphic modes under X11, use the ‘vesa’ or the
‘cirrus’ X11 driver.  For optimal performances, use 16 bit color depth
in the guest and the host OS.

When using a 2.6 guest Linux kernel, you should add the option
‘clock=pit’ on the kernel command line because the 2.6 Linux kernels
make very strict real time clock checks by default that QEMU cannot
simulate exactly.

When using a 2.6 guest Linux kernel, verify that the 4G/4G patch is not
activated because QEMU is slower with this patch.  The QEMU Accelerator
Module is also much slower in this case.  Earlier Fedora Core 3 Linux
kernel (< 2.6.9-1.724_FC3) were known to incorporate this patch by
default.  Newer kernels don’t have it.

2.14.2 Windows
--------------

If you have a slow host, using Windows 95 is better as it gives the best
speed.  Windows 2000 is also a good choice.

2.14.2.1 SVGA graphic modes support
...................................

QEMU emulates a 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.

If you are using Windows XP as guest OS and if you want to use high
resolution modes which the Cirrus Logic BIOS does not support (i.e.  >=
1280x1024x16), then you should use the VESA VBE virtual graphic card
(option ‘-std-vga’).

2.14.2.2 CPU usage reduction
............................

Windows 9x does not correctly use the CPU HLT instruction.  The result
is that it takes host CPU cycles even when idle.  You can install the
utility from <http://www.user.cityline.ru/~maxamn/amnhltm.zip> to solve
this problem.  Note that no such tool is needed for NT, 2000 or XP.

2.14.2.3 Windows 2000 disk full problem
.......................................

Windows 2000 has a bug which gives a disk full problem during its
installation.  When installing it, use the ‘-win2k-hack’ QEMU option to
enable a specific workaround.  After Windows 2000 is installed, you no
longer need this option (this option slows down the IDE transfers).

2.14.2.4 Windows 2000 shutdown
..............................

Windows 2000 cannot automatically shutdown in QEMU although Windows 98
can.  It comes from the fact that Windows 2000 does not automatically
use the APM driver provided by the BIOS.

In order to correct that, do the following (thanks to Struan Bartlett):
go to the Control Panel => Add/Remove Hardware & Next =>
Add/Troubleshoot a device => Add a new device & Next => No, select the
hardware from a list & Next => NT Apm/Legacy Support & Next => Next
(again) a few times.  Now the driver is installed and Windows 2000 now
correctly instructs QEMU to shutdown at the appropriate moment.

2.14.2.5 Share a directory between Unix and Windows
...................................................

See *note sec_invocation:: about the help of the option ‘'-netdev
user,smb=...'’.

2.14.2.6 Windows XP security problem
....................................

Some releases of Windows XP install correctly but give a security error
when booting:
     A problem is preventing Windows from accurately checking the
     license for this computer. Error code: 0x800703e6.

The workaround is to install a service pack for XP after a boot in safe
mode.  Then reboot, and the problem should go away.  Since there is no
network while in safe mode, its recommended to download the full
installation of SP1 or SP2 and transfer that via an ISO or using the
vvfat block device ("-hdb fat:directory_which_holds_the_SP").

2.14.3 MS-DOS and FreeDOS
-------------------------

2.14.3.1 CPU usage reduction
............................

DOS does not correctly use the CPU HLT instruction.  The result is that
it takes host CPU cycles even when idle.  You can install the utility
from <http://www.vmware.com/software/dosidle210.zip> to solve this
problem.

3 QEMU System emulator for non PC targets
*****************************************

QEMU is a generic emulator and it emulates many non PC machines.  Most
of the options are similar to the PC emulator.  The differences are
mentioned in the following sections.

3.1 PowerPC System emulator
===========================

Use the executable ‘qemu-system-ppc’ to simulate a complete PREP or
PowerMac PowerPC system.

QEMU emulates the following PowerMac peripherals:

   − UniNorth or Grackle PCI Bridge
   − PCI VGA compatible card with VESA Bochs Extensions
   − 2 PMAC IDE interfaces with hard disk and CD-ROM support
   − NE2000 PCI adapters
   − Non Volatile RAM
   − VIA-CUDA with ADB keyboard and mouse.

QEMU emulates the following PREP peripherals:

   − PCI Bridge
   − PCI VGA compatible card with VESA Bochs Extensions
   − 2 IDE interfaces with hard disk and CD-ROM support
   − Floppy disk
   − NE2000 network adapters
   − Serial port
   − PREP Non Volatile RAM
   − PC compatible keyboard and mouse.

QEMU uses the Open Hack’Ware Open Firmware Compatible BIOS available at
<http://perso.magic.fr/l_indien/OpenHackWare/index.htm>.

Since version 0.9.1, QEMU uses OpenBIOS <http://www.openbios.org/> for
the g3beige and mac99 PowerMac machines.  OpenBIOS is a free (GPL v2)
portable firmware implementation.  The goal is to implement a 100% IEEE
1275-1994 (referred to as Open Firmware) compliant firmware.

The following options are specific to the PowerPC emulation:

‘-g WxH[xDEPTH]’

     Set the initial VGA graphic mode.  The default is 800x600x32.

‘-prom-env STRING’

     Set OpenBIOS variables in NVRAM, for example:

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

     These variables are not used by Open Hack’Ware.

More information is available at
<http://perso.magic.fr/l_indien/qemu-ppc/>.

3.2 Sparc32 System emulator
===========================

Use the executable ‘qemu-system-sparc’ to simulate the following Sun4m
architecture machines:
   − SPARCstation 4
   − SPARCstation 5
   − SPARCstation 10
   − SPARCstation 20
   − SPARCserver 600MP
   − SPARCstation LX
   − SPARCstation Voyager
   − SPARCclassic
   − SPARCbook

The emulation is somewhat complete.  SMP up to 16 CPUs is supported, but
Linux limits the number of usable CPUs to 4.

QEMU emulates the following sun4m peripherals:

   − IOMMU
   − TCX or cgthree Frame buffer
   − Lance (Am7990) Ethernet
   − Non Volatile RAM M48T02/M48T08
   − Slave I/O: timers, interrupt controllers, Zilog serial ports,
     keyboard and power/reset logic
   − ESP SCSI controller with hard disk and CD-ROM support
   − Floppy drive (not on SS-600MP)
   − CS4231 sound device (only on SS-5, not working yet)

The number of peripherals is fixed in the architecture.  Maximum memory
size depends on the machine type, for SS-5 it is 256MB and for others
2047MB.

Since version 0.8.2, QEMU uses OpenBIOS <http://www.openbios.org/>.
OpenBIOS is a free (GPL v2) portable firmware implementation.  The goal
is to implement a 100% IEEE 1275-1994 (referred to as Open Firmware)
compliant firmware.

A sample Linux 2.6 series kernel and ram disk image are available on the
QEMU web site.  There are still issues with NetBSD and OpenBSD, but most
kernel versions work.  Please note that currently older Solaris kernels
don’t work probably due to interface issues between OpenBIOS and
Solaris.

The following options are specific to the Sparc32 emulation:

‘-g WxHx[xDEPTH]’

     Set the initial graphics mode.  For TCX, 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.

‘-prom-env STRING’

     Set OpenBIOS variables in NVRAM, for example:

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

‘-M [SS-4|SS-5|SS-10|SS-20|SS-600MP|LX|Voyager|SPARCClassic] [|SPARCbook]’

     Set the emulated machine type.  Default is SS-5.

3.3 Sparc64 System emulator
===========================

Use the executable ‘qemu-system-sparc64’ to simulate a Sun4u (UltraSPARC
PC-like machine), Sun4v (T1 PC-like machine), or generic Niagara (T1)
machine.  The Sun4u emulator is mostly complete, being able to run
Linux, NetBSD and OpenBSD in headless (-nographic) mode.  The Sun4v
emulator is still a work in progress.

The Niagara T1 emulator makes use of firmware and OS binaries supplied
in the S10image/ directory of the OpenSPARC T1 project
<http://download.oracle.com/technetwork/systems/opensparc/OpenSPARCT1_Arch.1.5.tar.bz2>
and is able to boot the disk.s10hw2 Solaris image.
     qemu-system-sparc64 -M niagara -L /path-to/S10image/ \
                         -nographic -m 256 \
                         -drive if=pflash,readonly=on,file=/S10image/disk.s10hw2

QEMU emulates the following peripherals:

   − UltraSparc IIi APB PCI Bridge
   − PCI VGA compatible card with VESA Bochs Extensions
   − PS/2 mouse and keyboard
   − Non Volatile RAM M48T59
   − PC-compatible serial ports
   − 2 PCI IDE interfaces with hard disk and CD-ROM support
   − Floppy disk

The following options are specific to the Sparc64 emulation:

‘-prom-env STRING’

     Set OpenBIOS variables in NVRAM, for example:

          qemu-system-sparc64 -prom-env 'auto-boot?=false'

‘-M [sun4u|sun4v|niagara]’

     Set the emulated machine type.  The default is sun4u.

3.4 MIPS System emulator
========================

Four executables cover simulation of 32 and 64-bit MIPS systems in both
endian options, ‘qemu-system-mips’, ‘qemu-system-mipsel’
‘qemu-system-mips64’ and ‘qemu-system-mips64el’.  Five different machine
types are emulated:

   − A generic ISA PC-like machine "mips"
   − The MIPS Malta prototype board "malta"
   − An ACER Pica "pica61".  This machine needs the 64-bit emulator.
   − MIPS emulator pseudo board "mipssim"
   − A MIPS Magnum R4000 machine "magnum".  This machine needs the
     64-bit emulator.

The generic emulation is supported by Debian ’Etch’ and is able to
install Debian into a virtual disk image.  The following devices are
emulated:

   − A range of MIPS CPUs, default is the 24Kf
   − PC style serial port
   − PC style IDE disk
   − NE2000 network card

The Malta emulation supports the following devices:

   − Core board with MIPS 24Kf CPU and Galileo system controller
   − PIIX4 PCI/USB/SMbus controller
   − The Multi-I/O chip’s serial device
   − PCI network cards (PCnet32 and others)
   − Malta FPGA serial device
   − Cirrus (default) or any other PCI VGA graphics card

The ACER Pica emulation supports:

   − MIPS R4000 CPU
   − PC-style IRQ and DMA controllers
   − PC Keyboard
   − IDE controller

The mipssim pseudo board emulation provides an environment similar to
what the proprietary MIPS emulator uses for running Linux.  It supports:

   − A range of MIPS CPUs, default is the 24Kf
   − PC style serial port
   − MIPSnet network emulation

The MIPS Magnum R4000 emulation supports:

   − MIPS R4000 CPU
   − PC-style IRQ controller
   − PC Keyboard
   − SCSI controller
   − G364 framebuffer

3.5 ARM System emulator
=======================

Use the executable ‘qemu-system-arm’ to simulate a ARM machine.  The ARM
Integrator/CP board is emulated with the following devices:

   − ARM926E, ARM1026E, ARM946E, ARM1136 or Cortex-A8 CPU
   − Two PL011 UARTs
   − SMC 91c111 Ethernet adapter
   − PL110 LCD controller
   − PL050 KMI with PS/2 keyboard and mouse.
   − PL181 MultiMedia Card Interface with SD card.

The ARM Versatile baseboard is emulated with the following devices:

   − ARM926E, ARM1136 or Cortex-A8 CPU
   − PL190 Vectored Interrupt Controller
   − Four PL011 UARTs
   − SMC 91c111 Ethernet adapter
   − PL110 LCD controller
   − PL050 KMI with PS/2 keyboard and mouse.
   − PCI host bridge.  Note the emulated PCI bridge only provides access
     to PCI memory space.  It does not provide access to PCI IO space.
     This means some devices (eg.  ne2k_pci NIC) are not usable, and
     others (eg.  rtl8139 NIC) are only usable when the guest drivers
     use the memory mapped control registers.
   − PCI OHCI USB controller.
   − LSI53C895A PCI SCSI Host Bus Adapter with hard disk and CD-ROM
     devices.
   − PL181 MultiMedia Card Interface with SD card.

Several variants of the ARM RealView baseboard are emulated, including
the EB, PB-A8 and PBX-A9.  Due to interactions with the bootloader, only
certain Linux kernel configurations work out of the box on these boards.

Kernels for the PB-A8 board should have CONFIG_REALVIEW_HIGH_PHYS_OFFSET
enabled in the kernel, and expect 512M RAM. Kernels for The PBX-A9 board
should have CONFIG_SPARSEMEM enabled, CONFIG_REALVIEW_HIGH_PHYS_OFFSET
disabled and expect 1024M RAM.

The following devices are emulated:

   − ARM926E, ARM1136, ARM11MPCore, Cortex-A8 or Cortex-A9 MPCore CPU
   − ARM AMBA Generic/Distributed Interrupt Controller
   − Four PL011 UARTs
   − SMC 91c111 or SMSC LAN9118 Ethernet adapter
   − PL110 LCD controller
   − PL050 KMI with PS/2 keyboard and mouse
   − PCI host bridge
   − PCI OHCI USB controller
   − LSI53C895A PCI SCSI Host Bus Adapter with hard disk and CD-ROM
     devices
   − PL181 MultiMedia Card Interface with SD card.

The XScale-based clamshell PDA models ("Spitz", "Akita", "Borzoi" and
"Terrier") emulation includes the following peripherals:

   − Intel PXA270 System-on-chip (ARM V5TE core)
   − NAND Flash memory
   − IBM/Hitachi DSCM microdrive in a PXA PCMCIA slot - not in "Akita"
   − On-chip OHCI USB controller
   − On-chip LCD controller
   − On-chip Real Time Clock
   − TI ADS7846 touchscreen controller on SSP bus
   − Maxim MAX1111 analog-digital converter on I^2C bus
   − GPIO-connected keyboard controller and LEDs
   − Secure Digital card connected to PXA MMC/SD host
   − Three on-chip UARTs
   − WM8750 audio CODEC on I^2C and I^2S busses

The Palm Tungsten|E PDA (codename "Cheetah") emulation includes the
following elements:

   − Texas Instruments OMAP310 System-on-chip (ARM 925T core)
   − ROM and RAM memories (ROM firmware image can be loaded with
     -option-rom)
   − On-chip LCD controller
   − On-chip Real Time Clock
   − TI TSC2102i touchscreen controller / analog-digital converter /
     Audio CODEC, connected through MicroWire and I^2S busses
   − GPIO-connected matrix keypad
   − Secure Digital card connected to OMAP MMC/SD host
   − Three on-chip UARTs

Nokia N800 and N810 internet tablets (known also as RX-34 and RX-44 /
48) emulation supports the following elements:

   − Texas Instruments OMAP2420 System-on-chip (ARM 1136 core)
   − RAM and non-volatile OneNAND Flash memories
   − Display connected to EPSON remote framebuffer chip and OMAP on-chip
     display controller and a LS041y3 MIPI DBI-C controller
   − TI TSC2301 (in N800) and TI TSC2005 (in N810) touchscreen
     controllers driven through SPI bus
   − National Semiconductor LM8323-controlled qwerty keyboard driven
     through I^2C bus
   − Secure Digital card connected to OMAP MMC/SD host
   − Three OMAP on-chip UARTs and on-chip STI debugging console
   − A Bluetooth(R) transceiver and HCI connected to an UART
   − Mentor Graphics "Inventra" dual-role USB controller embedded in a
     TI TUSB6010 chip - only USB host mode is supported
   − TI TMP105 temperature sensor driven through I^2C bus
   − TI TWL92230C power management companion with an RTC on I^2C bus
   − Nokia RETU and TAHVO multi-purpose chips with an RTC, connected
     through CBUS

The Luminary Micro Stellaris LM3S811EVB emulation includes the following
devices:

   − Cortex-M3 CPU core.
   − 64k Flash and 8k SRAM.
   − Timers, UARTs, ADC and I^2C interface.
   − OSRAM Pictiva 96x16 OLED with SSD0303 controller on I^2C bus.

The Luminary Micro Stellaris LM3S6965EVB emulation includes the
following devices:

   − Cortex-M3 CPU core.
   − 256k Flash and 64k SRAM.
   − Timers, UARTs, ADC, I^2C and SSI interfaces.
   − OSRAM Pictiva 128x64 OLED with SSD0323 controller connected via
     SSI.

The Freecom MusicPal internet radio emulation includes the following
elements:

   − Marvell MV88W8618 ARM core.
   − 32 MB RAM, 256 KB SRAM, 8 MB flash.
   − Up to 2 16550 UARTs
   − MV88W8xx8 Ethernet controller
   − MV88W8618 audio controller, WM8750 CODEC and mixer
   − 128×64 display with brightness control
   − 2 buttons, 2 navigation wheels with button function

The Siemens SX1 models v1 and v2 (default) basic emulation.  The
emulation includes the following elements:

   − Texas Instruments OMAP310 System-on-chip (ARM 925T core)
   − ROM and RAM memories (ROM firmware image can be loaded with
     -pflash) V1 1 Flash of 16MB and 1 Flash of 8MB V2 1 Flash of 32MB
   − On-chip LCD controller
   − On-chip Real Time Clock
   − Secure Digital card connected to OMAP MMC/SD host
   − Three on-chip UARTs

A Linux 2.6 test image is available on the QEMU web site.  More
information is available in the QEMU mailing-list archive.

The following options are specific to the ARM emulation:

‘-semihosting’
     Enable semihosting syscall emulation.

     On ARM this implements the "Angel" interface.

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

3.6 ColdFire System emulator
============================

Use the executable ‘qemu-system-m68k’ to simulate a ColdFire machine.
The emulator is able to boot a uClinux kernel.

The M5208EVB emulation includes the following devices:

   − MCF5208 ColdFire V2 Microprocessor (ISA A+ with EMAC).
   − Three Two on-chip UARTs.
   − Fast Ethernet Controller (FEC)

The AN5206 emulation includes the following devices:

   − MCF5206 ColdFire V2 Microprocessor.
   − Two on-chip UARTs.

The following options are specific to the ColdFire emulation:

‘-semihosting’
     Enable semihosting syscall emulation.

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

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

3.7 Cris System emulator
========================

TODO

3.8 Microblaze System emulator
==============================

TODO

3.9 SH4 System emulator
=======================

TODO

3.10 Xtensa System emulator
===========================

Two executables cover simulation of both Xtensa endian options,
‘qemu-system-xtensa’ and ‘qemu-system-xtensaeb’.  Two different machine
types are emulated:

   − Xtensa emulator pseudo board "sim"
   − Avnet LX60/LX110/LX200 board

The sim pseudo board emulation provides an environment similar to one
provided by the proprietary Tensilica ISS. It supports:

   − A range of Xtensa CPUs, default is the DC232B
   − Console and filesystem access via semihosting calls

The Avnet LX60/LX110/LX200 emulation supports:

   − A range of Xtensa CPUs, default is the DC232B
   − 16550 UART
   − OpenCores 10/100 Mbps Ethernet MAC

The following options are specific to the Xtensa emulation:

‘-semihosting’
     Enable semihosting syscall emulation.

     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.

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

4 QEMU User space emulator
**************************

4.1 Supported Operating Systems
===============================

The following OS are supported in user space emulation:

   − Linux (referred as qemu-linux-user)
   − BSD (referred as qemu-bsd-user)

4.2 Features
============

QEMU user space emulation has the following notable features:

*System call translation:*
     QEMU includes a generic system call translator.  This means that
     the parameters of the system calls can be converted to fix
     endianness and 32/64-bit mismatches between hosts and targets.
     IOCTLs can be converted too.

*POSIX signal handling:*
     QEMU can redirect to the running program all signals coming from
     the host (such as ‘SIGALRM’), as well as synthesize signals from
     virtual CPU exceptions (for example ‘SIGFPE’ when the program
     executes a division by zero).

     QEMU relies on the host kernel to emulate most signal system calls,
     for example to emulate the signal mask.  On Linux, QEMU supports
     both normal and real-time signals.

*Threading:*
     On Linux, QEMU can emulate the ‘clone’ syscall and create a real
     host thread (with a separate virtual CPU) for each emulated thread.
     Note that not all targets currently emulate atomic operations
     correctly.  x86 and ARM use a global lock in order to preserve
     their semantics.

QEMU was conceived so that ultimately it can emulate itself.  Although
it is not very useful, it is an important test to show the power of the
emulator.

4.3 Linux User space emulator
=============================

4.3.1 Quick Start
-----------------

In order to launch a Linux process, QEMU needs the process executable
itself and all the target (x86) dynamic libraries used by it.

   • On x86, you can just try to launch any process by using the native
     libraries:

          qemu-i386 -L / /bin/ls

     ‘-L /’ tells that the x86 dynamic linker must be searched with a
     ‘/’ prefix.

   • Since QEMU is also a linux process, you can launch QEMU with QEMU
     (NOTE: you can only do that if you compiled QEMU from the sources):

          qemu-i386 -L / qemu-i386 -L / /bin/ls

   • On non x86 CPUs, you need first to download at least an x86 glibc
     (‘qemu-runtime-i386-XXX-.tar.gz’ on the QEMU web page).  Ensure
     that ‘LD_LIBRARY_PATH’ is not set:

          unset LD_LIBRARY_PATH

     Then you can launch the precompiled ‘ls’ x86 executable:

          qemu-i386 tests/i386/ls
     You can look at ‘scripts/qemu-binfmt-conf.sh’ so that QEMU is
     automatically launched by the Linux kernel when you try to launch
     x86 executables.  It requires the ‘binfmt_misc’ module in the Linux
     kernel.

   • The x86 version of QEMU is also included.  You can try weird things
     such as:
          qemu-i386 /usr/local/qemu-i386/bin/qemu-i386 \
                    /usr/local/qemu-i386/bin/ls-i386

4.3.2 Wine launch
-----------------

   • Ensure that you have a working QEMU with the x86 glibc distribution
     (see previous section).  In order to verify it, you must be able to
     do:

          qemu-i386 /usr/local/qemu-i386/bin/ls-i386

   • Download the binary x86 Wine install (‘qemu-XXX-i386-wine.tar.gz’
     on the QEMU web page).

   • Configure Wine on your account.  Look at the provided script
     ‘/usr/local/qemu-i386/bin/wine-conf.sh’.  Your previous
     ‘${HOME}/.wine’ directory is saved to ‘${HOME}/.wine.org’.

   • Then you can try the example ‘putty.exe’:

          qemu-i386 /usr/local/qemu-i386/wine/bin/wine \
                    /usr/local/qemu-i386/wine/c/Program\ Files/putty.exe

4.3.3 Command line options
--------------------------

     qemu-i386 [-h] [-d] [-L PATH] [-s SIZE] [-cpu MODEL] [-g PORT] [-B OFFSET] [-R SIZE] PROGRAM [ARGUMENTS...]

‘-h’
     Print the help
‘-L path’
     Set the x86 elf interpreter prefix (default=/usr/local/qemu-i386)
‘-s size’
     Set the x86 stack size in bytes (default=524288)
‘-cpu model’
     Select CPU model (-cpu help for list and additional feature
     selection)
‘-E VAR=VALUE’
     Set environment VAR to VALUE.
‘-U VAR’
     Remove VAR from the environment.
‘-B offset’
     Offset guest address by the specified number of bytes.  This is
     useful when the address region required by guest applications is
     reserved on the host.  This option is currently only supported on
     some hosts.
‘-R size’
     Pre-allocate a guest virtual address space of the given size (in
     bytes).  "G", "M", and "k" suffixes may be used when specifying the
     size.

Debug options:

‘-d item1,...’
     Activate logging of the specified items (use ’-d help’ for a list
     of log items)
‘-p pagesize’
     Act as if the host page size was ’pagesize’ bytes
‘-g port’
     Wait gdb connection to port
‘-singlestep’
     Run the emulation in single step mode.

Environment variables:

‘QEMU_STRACE’
     Print system calls and arguments similar to the ’strace’ program
     (NOTE: the actual ’strace’ program will not work because the user
     space emulator hasn’t implemented ptrace).  At the moment this is
     incomplete.  All system calls that don’t have a specific argument
     format are printed with information for six arguments.  Many
     flag-style arguments don’t have decoders and will show up as
     numbers.

4.3.4 Other binaries
--------------------

‘qemu-alpha’ TODO.

‘qemu-armeb’ TODO.

‘qemu-arm’ is also capable of running ARM "Angel" semihosted ELF
binaries (as implemented by the arm-elf and arm-eabi Newlib/GDB
configurations), and arm-uclinux bFLT format binaries.

‘qemu-m68k’ is capable of running semihosted binaries using the BDM
(m5xxx-ram-hosted.ld) or m68k-sim (sim.ld) syscall interfaces, and
coldfire uClinux bFLT format binaries.

The binary format is detected automatically.

‘qemu-cris’ TODO.

‘qemu-i386’ TODO. ‘qemu-x86_64’ TODO.

‘qemu-microblaze’ TODO.

‘qemu-mips’ TODO. ‘qemu-mipsel’ TODO.

‘qemu-nios2’ TODO.

‘qemu-ppc64abi32’ TODO. ‘qemu-ppc64’ TODO. ‘qemu-ppc’ TODO.

‘qemu-sh4eb’ TODO. ‘qemu-sh4’ TODO.

‘qemu-sparc’ can execute Sparc32 binaries (Sparc32 CPU, 32 bit ABI).

‘qemu-sparc32plus’ can execute Sparc32 and SPARC32PLUS binaries (Sparc64
CPU, 32 bit ABI).

‘qemu-sparc64’ can execute some Sparc64 (Sparc64 CPU, 64 bit ABI) and
SPARC32PLUS binaries (Sparc64 CPU, 32 bit ABI).

4.4 BSD User space emulator
===========================

4.4.1 BSD Status
----------------

   − target Sparc64 on Sparc64: Some trivial programs work.

4.4.2 Quick Start
-----------------

In order to launch a BSD process, QEMU needs the process executable
itself and all the target dynamic libraries used by it.

   • On Sparc64, you can just try to launch any process by using the
     native libraries:

          qemu-sparc64 /bin/ls

4.4.3 Command line options
--------------------------

     qemu-sparc64 [-h] [-d] [-L PATH] [-s SIZE] [-bsd TYPE] PROGRAM [ARGUMENTS...]

‘-h’
     Print the help
‘-L path’
     Set the library root path (default=/)
‘-s size’
     Set the stack size in bytes (default=524288)
‘-ignore-environment’
     Start with an empty environment.  Without this option, the initial
     environment is a copy of the caller’s environment.
‘-E VAR=VALUE’
     Set environment VAR to VALUE.
‘-U VAR’
     Remove VAR from the environment.
‘-bsd type’
     Set the type of the emulated BSD Operating system.  Valid values
     are FreeBSD, NetBSD and OpenBSD (default).

Debug options:

‘-d item1,...’
     Activate logging of the specified items (use ’-d help’ for a list
     of log items)
‘-p pagesize’
     Act as if the host page size was ’pagesize’ bytes
‘-singlestep’
     Run the emulation in single step mode.

Appendix A Implementation notes
*******************************

A.1 CPU emulation
=================

A.1.1 x86 and x86-64 emulation
------------------------------

QEMU x86 target features:

   • The virtual x86 CPU supports 16 bit and 32 bit addressing with
     segmentation.  LDT/GDT and IDT are emulated.  VM86 mode is also
     supported to run DOSEMU. There is some support for MMX/3DNow!, SSE,
     SSE2, SSE3, SSSE3, and SSE4 as well as x86-64 SVM.

   • Support of host page sizes bigger than 4KB in user mode emulation.

   • QEMU can emulate itself on x86.

   • An extensive Linux x86 CPU test program is included
     ‘tests/test-i386’.  It can be used to test other x86 virtual CPUs.

Current QEMU limitations:

   • Limited x86-64 support.

   • IPC syscalls are missing.

   • The x86 segment limits and access rights are not tested at every
     memory access (yet).  Hopefully, very few OSes seem to rely on that
     for normal use.

A.1.2 ARM emulation
-------------------

   • Full ARM 7 user emulation.

   • NWFPE FPU support included in user Linux emulation.

   • Can run most ARM Linux binaries.

A.1.3 MIPS emulation
--------------------

   • The system emulation allows full MIPS32/MIPS64 Release 2 emulation,
     including privileged instructions, FPU and MMU, in both little and
     big endian modes.

   • The Linux userland emulation can run many 32 bit MIPS Linux
     binaries.

Current QEMU limitations:

   • Self-modifying code is not always handled correctly.

   • 64 bit userland emulation is not implemented.

   • The system emulation is not complete enough to run real firmware.

   • The watchpoint debug facility is not implemented.

A.1.4 PowerPC emulation
-----------------------

   • Full PowerPC 32 bit emulation, including privileged instructions,
     FPU and MMU.

   • Can run most PowerPC Linux binaries.

A.1.5 Sparc32 and Sparc64 emulation
-----------------------------------

   • Full SPARC V8 emulation, including privileged instructions, FPU and
     MMU. SPARC V9 emulation includes most privileged and VIS
     instructions, FPU and I/D MMU. Alignment is fully enforced.

   • Can run most 32-bit SPARC Linux binaries, SPARC32PLUS Linux
     binaries and some 64-bit SPARC Linux binaries.

Current QEMU limitations:

   • IPC syscalls are missing.

   • Floating point exception support is buggy.

   • Atomic instructions are not correctly implemented.

   • There are still some problems with Sparc64 emulators.

A.1.6 Xtensa emulation
----------------------

   • Core Xtensa ISA emulation, including most options: code density,
     loop, extended L32R, 16- and 32-bit multiplication, 32-bit
     division, MAC16, miscellaneous operations, boolean, FP coprocessor,
     coprocessor context, debug, multiprocessor synchronization,
     conditional store, exceptions, relocatable vectors, unaligned
     exception, interrupts (including high priority and timer), hardware
     alignment, region protection, region translation, MMU, windowed
     registers, thread pointer, processor ID.

   • Not implemented options: data/instruction cache (including cache
     prefetch and locking), XLMI, processor interface.  Also options not
     covered by the core ISA (e.g.  FLIX, wide branches) are not
     implemented.

   • Can run most Xtensa Linux binaries.

   • New core configuration that requires no additional instructions may
     be created from overlay with minimal amount of hand-written code.

A.2 Translator Internals
========================

QEMU is a dynamic translator.  When it first encounters a piece of code,
it converts it to the host instruction set.  Usually dynamic translators
are very complicated and highly CPU dependent.  QEMU uses some tricks
which make it relatively easily portable and simple while achieving good
performances.

QEMU’s dynamic translation backend is called TCG, for "Tiny Code
Generator".  For more information, please take a look at ‘tcg/README’.

Some notable features of QEMU’s dynamic translator are:

*CPU state optimisations:*
     The target CPUs have many internal states which change the way it
     evaluates instructions.  In order to achieve a good speed, the
     translation phase considers that some state information of the
     virtual CPU cannot change in it.  The state is recorded in the
     Translation Block (TB). If the state changes (e.g.  privilege
     level), a new TB will be generated and the previous TB won’t be
     used anymore until the state matches the state recorded in the
     previous TB. The same idea can be applied to other aspects of the
     CPU state.  For example, on x86, if the SS, DS and ES segments have
     a zero base, then the translator does not even generate an addition
     for the segment base.

*Direct block chaining:*
     After each translated basic block is executed, QEMU uses the
     simulated Program Counter (PC) and other cpu state information
     (such as the CS segment base value) to find the next basic block.

     In order to accelerate the most common cases where the new
     simulated PC is known, QEMU can patch a basic block so that it
     jumps directly to the next one.

     The most portable code uses an indirect jump.  An indirect jump
     makes it easier to make the jump target modification atomic.  On
     some host architectures (such as x86 or PowerPC), the ‘JUMP’ opcode
     is directly patched so that the block chaining has no overhead.

*Self-modifying code and translated code invalidation:*
     Self-modifying code is a special challenge in x86 emulation because
     no instruction cache invalidation is signaled by the application
     when code is modified.

     User-mode emulation marks a host page as write-protected (if it is
     not already read-only) every time translated code is generated for
     a basic block.  Then, if a write access is done to the page, Linux
     raises a SEGV signal.  QEMU then invalidates all the translated
     code in the page and enables write accesses to the page.  For
     system emulation, write protection is achieved through the software
     MMU.

     Correct translated code invalidation is done efficiently by
     maintaining a linked list of every translated block contained in a
     given page.  Other linked lists are also maintained to undo direct
     block chaining.

     On RISC targets, correctly written software uses memory barriers
     and cache flushes, so some of the protection above would not be
     necessary.  However, QEMU still requires that the generated code
     always matches the target instructions in memory in order to handle
     exceptions correctly.

*Exception support:*
     longjmp() is used when an exception such as division by zero is
     encountered.

     The host SIGSEGV and SIGBUS signal handlers are used to get invalid
     memory accesses.  QEMU keeps a map from host program counter to
     target program counter, and looks up where the exception happened
     based on the host program counter at the exception point.

     On some targets, some bits of the virtual CPU’s state are not
     flushed to the memory until the end of the translation block.  This
     is done for internal emulation state that is rarely accessed
     directly by the program and/or changes very often throughout the
     execution of a translation block—this includes condition codes on
     x86, delay slots on SPARC, conditional execution on ARM, and so on.
     This state is stored for each target instruction, and looked up on
     exceptions.

*MMU emulation:*
     For system emulation QEMU uses a software MMU. In that mode, the
     MMU virtual to physical address translation is done at every memory
     access.

     QEMU uses an address translation cache (TLB) to speed up the
     translation.  In order to avoid flushing the translated code each
     time the MMU mappings change, all caches in QEMU are physically
     indexed.  This means that each basic block is indexed with its
     physical address.

     In order to avoid invalidating the basic block chain when MMU
     mappings change, chaining is only performed when the destination of
     the jump shares a page with the basic block that is performing the
     jump.

     The MMU can also distinguish RAM and ROM memory areas from MMIO
     memory areas.  Access is faster for RAM and ROM because the
     translation cache also hosts the offset between guest address and
     host memory.  Accessing MMIO memory areas instead calls out to C
     code for device emulation.  Finally, the MMU helps tracking dirty
     pages and pages pointed to by translation blocks.

A.3 QEMU compared to other emulators
====================================

Like bochs [1], QEMU emulates an x86 CPU. But QEMU is much faster than
bochs as it uses dynamic compilation.  Bochs is closely tied to x86 PC
emulation while QEMU can emulate several processors.

Like Valgrind [2], QEMU does user space emulation and dynamic
translation.  Valgrind is mainly a memory debugger while QEMU has no
support for it (QEMU could be used to detect out of bound memory
accesses as Valgrind, but it has no support to track uninitialised data
as Valgrind does).  The Valgrind dynamic translator generates better
code than QEMU (in particular it does register allocation) but it is
closely tied to an x86 host and target and has no support for precise
exceptions and system emulation.

EM86 [3] is the closest project to user space QEMU (and QEMU still uses
some of its code, in particular the ELF file loader).  EM86 was limited
to an alpha host and used a proprietary and slow interpreter (the
interpreter part of the FX!32 Digital Win32 code translator [4]).

TWIN from Willows Software was a Windows API emulator like Wine.  It is
less accurate than Wine but includes a protected mode x86 interpreter to
launch x86 Windows executables.  Such an approach has greater potential
because most of the Windows API is executed natively but it is far more
difficult to develop because all the data structures and function
parameters exchanged between the API and the x86 code must be converted.

User mode Linux [5] was the only solution before QEMU to launch a Linux
kernel as a process while not needing any host kernel patches.  However,
user mode Linux requires heavy kernel patches while QEMU accepts
unpatched Linux kernels.  The price to pay is that QEMU is slower.

The Plex86 [6] PC virtualizer is done in the same spirit as the now
obsolete qemu-fast system emulator.  It requires a patched Linux kernel
to work (you cannot launch the same kernel on your PC), but the patches
are really small.  As it is a PC virtualizer (no emulation is done
except for some privileged instructions), it has the potential of being
faster than QEMU. The downside is that a complicated (and potentially
unsafe) host kernel patch is needed.

The commercial PC Virtualizers (VMWare [7], VirtualPC [8]) are faster
than QEMU (without virtualization), but they all need specific,
proprietary and potentially unsafe host drivers.  Moreover, they are
unable to provide cycle exact simulation as an emulator can.

VirtualBox [9], Xen [10] and KVM [11] are based on QEMU. QEMU-SystemC
[12] uses QEMU to simulate a system where some hardware devices are
developed in SystemC.

A.4 Bibliography
================

[1]
     <http://bochs.sourceforge.net/>, the Bochs IA-32 Emulator Project,
     by Kevin Lawton et al.

[2]
     <http://www.valgrind.org/>, Valgrind, an open-source memory
     debugger for GNU/Linux.

[3]
     <http://ftp.dreamtime.org/pub/linux/Linux-Alpha/em86/v0.2/docs/em86.html>,
     the EM86 x86 emulator on Alpha-Linux.

[4]
     <http://www.usenix.org/publications/library/proceedings/usenix-nt97/full_papers/chernoff/chernoff.pdf>,
     DIGITAL FX!32: Running 32-Bit x86 Applications on Alpha NT, by
     Anton Chernoff and Ray Hookway.

[5]
     <http://user-mode-linux.sourceforge.net/>, The User-mode Linux
     Kernel.

[6]
     <http://www.plex86.org/>, The new Plex86 project.

[7]
     <http://www.vmware.com/>, The VMWare PC virtualizer.

[8]
     <https://www.microsoft.com/download/details.aspx?id=3702>, The
     VirtualPC PC virtualizer.

[9]
     <http://virtualbox.org/>, The VirtualBox PC virtualizer.

[10]
     <http://www.xen.org/>, The Xen hypervisor.

[11]
     <http://www.linux-kvm.org/>, Kernel Based Virtual Machine (KVM).

[12]
     <http://www.greensocs.com/projects/QEMUSystemC>, QEMU-SystemC, a
     hardware co-simulator.

Appendix B License
******************

QEMU is a trademark of Fabrice Bellard.

QEMU is released under the GNU General Public License (TODO: add link).
Parts of QEMU have specific licenses, see file LICENSE.

TODO (refer to file LICENSE, include it, include the GPL?)

Appendix C Index
****************

C.1 Concept Index
=================

This is the main index.  Should we combine all keywords in one index?
TODO

* Menu:

* operating modes:                       intro_features.     (line  138)
* QEMU monitor:                          pcsys_monitor.      (line 3115)
* quick start:                           pcsys_quickstart.   (line  239)
* system emulation:                      intro_features.     (line  140)
* system emulation (ARM):                ARM System emulator.
                                                             (line 5983)
* system emulation (ColdFire):           ColdFire System emulator.
                                                             (line 6140)
* system emulation (Cris):               Cris System emulator.
                                                             (line 6168)
* system emulation (M68K):               ColdFire System emulator.
                                                             (line 6140)
* system emulation (Microblaze):         Microblaze System emulator.
                                                             (line 6173)
* system emulation (MIPS):               MIPS System emulator.
                                                             (line 5928)
* system emulation (PC):                 QEMU PC System emulator.
                                                             (line  191)
* system emulation (PowerPC):            PowerPC System emulator.
                                                             (line 5771)
* system emulation (SH4):                SH4 System emulator.
                                                             (line 6178)
* system emulation (Sparc32):            Sparc32 System emulator.
                                                             (line 5824)
* system emulation (Sparc64):            Sparc64 System emulator.
                                                             (line 5889)
* system emulation (Xtensa):             Xtensa System emulator.
                                                             (line 6183)
* user mode (Alpha):                     Other binaries.     (line 6373)
* user mode (ARM):                       Other binaries.     (line 6375)
* user mode (ARM) <1>:                   Other binaries.     (line 6377)
* user mode (ColdFire):                  Other binaries.     (line 6381)
* user mode (Cris):                      Other binaries.     (line 6387)
* user mode (i386):                      Other binaries.     (line 6389)
* user mode (M68K):                      Other binaries.     (line 6381)
* user mode (Microblaze):                Other binaries.     (line 6391)
* user mode (MIPS):                      Other binaries.     (line 6393)
* user mode (NiosII):                    Other binaries.     (line 6395)
* user mode (PowerPC):                   Other binaries.     (line 6397)
* user mode (SH4):                       Other binaries.     (line 6399)
* user mode (SPARC):                     Other binaries.     (line 6401)
* user mode emulation:                   intro_features.     (line  145)

C.2 Function Index
==================

This index could be used for command line options and monitor functions.

* Menu:

* --trace:                               qemu_img_invocation.
                                                             (line 3757)
* --trace <1>:                           qemu_nbd_invocation.
                                                             (line 4351)
* -accel:                                sec_invocation.     (line  303)
* -acpitable:                            sec_invocation.     (line 1300)
* -add-fd:                               sec_invocation.     (line  351)
* -alt-grab:                             sec_invocation.     (line  922)
* -append:                               sec_invocation.     (line 2299)
* -audio-help:                           sec_invocation.     (line  462)
* -balloon:                              sec_invocation.     (line  480)
* -bios:                                 sec_invocation.     (line 2519)
* -boot:                                 sec_invocation.     (line  388)
* -bt:                                   sec_invocation.     (line 2190)
* -cdrom:                                sec_invocation.     (line  561)
* -chardev:                              sec_invocation.     (line 1739)
* -chroot:                               sec_invocation.     (line 2695)
* -cpu:                                  sec_invocation.     (line  300)
* -ctrl-grab:                            sec_invocation.     (line  926)
* -curses:                               sec_invocation.     (line  912)
* -d:                                    sec_invocation.     (line 2501)
* -D:                                    sec_invocation.     (line 2504)
* -daemonize:                            sec_invocation.     (line 2545)
* -debugcon:                             sec_invocation.     (line 2476)
* -device:                               sec_invocation.     (line  485)
* -dfilter:                              sec_invocation.     (line 2506)
* -display:                              sec_invocation.     (line  876)
* -drive:                                sec_invocation.     (line  565)
* -dtb:                                  sec_invocation.     (line 2310)
* -dump-vmstate:                         sec_invocation.     (line 2769)
* -echr:                                 sec_invocation.     (line 2649)
* -enable-fips:                          sec_invocation.     (line 2765)
* -enable-hax:                           sec_invocation.     (line 2524)
* -enable-kvm:                           sec_invocation.     (line 2521)
* -fda:                                  sec_invocation.     (line  554)
* -fdb:                                  sec_invocation.     (line  554)
* -fsdev:                                sec_invocation.     (line  724)
* -full-screen:                          sec_invocation.     (line 1070)
* -fw_cfg:                               sec_invocation.     (line 2317)
* -g:                                    sec_invocation.     (line 1072)
* -gdb:                                  sec_invocation.     (line 2492)
* -global:                               sec_invocation.     (line  375)
* -h:                                    sec_invocation.     (line  257)
* -hda:                                  sec_invocation.     (line  559)
* -hdachs:                               sec_invocation.     (line  718)
* -hdb:                                  sec_invocation.     (line  559)
* -hdc:                                  sec_invocation.     (line  559)
* -hdd:                                  sec_invocation.     (line  559)
* -icount:                               sec_invocation.     (line 2574)
* -incoming:                             sec_invocation.     (line 2670)
* -initrd:                               sec_invocation.     (line 2301)
* -k:                                    sec_invocation.     (line  449)
* -kernel:                               sec_invocation.     (line 2296)
* -L:                                    sec_invocation.     (line 2515)
* -loadvm:                               sec_invocation.     (line 2543)
* -m:                                    sec_invocation.     (line  429)
* -machine:                              sec_invocation.     (line  261)
* -mem-path:                             sec_invocation.     (line  445)
* -mem-prealloc:                         sec_invocation.     (line  447)
* -mon:                                  sec_invocation.     (line 2474)
* -monitor:                              sec_invocation.     (line 2465)
* -msg:                                  sec_invocation.     (line 2767)
* -mtdblock:                             sec_invocation.     (line  707)
* -name:                                 sec_invocation.     (line  541)
* -net:                                  sec_invocation.     (line 1334)
* -netdev:                               sec_invocation.     (line 1350)
* -no-acpi:                              sec_invocation.     (line 1294)
* -no-fd-bootchk:                        sec_invocation.     (line 1291)
* -no-frame:                             sec_invocation.     (line  918)
* -no-hpet:                              sec_invocation.     (line 1298)
* -no-quit:                              sec_invocation.     (line  930)
* -no-reboot:                            sec_invocation.     (line 2537)
* -no-shutdown:                          sec_invocation.     (line 2539)
* -no-user-config:                       sec_invocation.     (line 2737)
* -nodefaults:                           sec_invocation.     (line 2690)
* -nodefconfig:                          sec_invocation.     (line 2733)
* -nographic:                            sec_invocation.     (line  902)
* -numa:                                 sec_invocation.     (line  325)
* -object:                               sec_invocation.     (line 2776)
* -old-param (ARM):                      sec_invocation.     (line 2719)
* -only-migratable:                      sec_invocation.     (line 2687)
* -option-rom:                           sec_invocation.     (line 2551)
* -parallel:                             sec_invocation.     (line 2455)
* -pflash:                               sec_invocation.     (line  711)
* -pidfile:                              sec_invocation.     (line 2482)
* -portrait:                             sec_invocation.     (line 1031)
* -prom-env:                             sec_invocation.     (line 2701)
* -qmp:                                  sec_invocation.     (line 2470)
* -qmp-pretty:                           sec_invocation.     (line 2472)
* -readconfig:                           sec_invocation.     (line 2724)
* -realtime:                             sec_invocation.     (line 2489)
* -rotate:                               sec_invocation.     (line 1033)
* -rtc:                                  sec_invocation.     (line 2555)
* -runas:                                sec_invocation.     (line 2698)
* -S:                                    sec_invocation.     (line 2487)
* -s:                                    sec_invocation.     (line 2498)
* -sandbox:                              sec_invocation.     (line 2721)
* -sd:                                   sec_invocation.     (line  709)
* -sdl:                                  sec_invocation.     (line  932)
* -semihosting:                          sec_invocation.     (line 2703)
* -semihosting-config:                   sec_invocation.     (line 2705)
* -serial:                               sec_invocation.     (line 2334)
* -set:                                  sec_invocation.     (line  372)
* -show-cursor:                          sec_invocation.     (line 2665)
* -singlestep:                           sec_invocation.     (line 2485)
* -smbios:                               sec_invocation.     (line 1310)
* -smp:                                  sec_invocation.     (line  315)
* -snapshot:                             sec_invocation.     (line  713)
* -soundhw:                              sec_invocation.     (line  465)
* -spice:                                sec_invocation.     (line  934)
* -tb-size:                              sec_invocation.     (line 2667)
* -tpmdev:                               sec_invocation.     (line 2241)
* -trace:                                sec_invocation.     (line 2741)
* -usb:                                  sec_invocation.     (line  831)
* -usbdevice:                            sec_invocation.     (line  834)
* -uuid:                                 sec_invocation.     (line  547)
* -version:                              sec_invocation.     (line  259)
* -vga:                                  sec_invocation.     (line 1035)
* -virtfs:                               sec_invocation.     (line  779)
* -virtfs_synth:                         sec_invocation.     (line  825)
* -virtioconsole:                        sec_invocation.     (line 2659)
* -vnc:                                  sec_invocation.     (line 1074)
* -watchdog:                             sec_invocation.     (line 2611)
* -watchdog-action:                      sec_invocation.     (line 2630)
* -win2k-hack:                           sec_invocation.     (line 1287)
* -writeconfig:                          sec_invocation.     (line 2728)
* -xen-attach:                           sec_invocation.     (line 2534)
* -xen-create:                           sec_invocation.     (line 2531)
* -xen-domid:                            sec_invocation.     (line 2529)
* acl_add:                               pcsys_monitor.      (line 3465)
* acl_policy:                            pcsys_monitor.      (line 3461)
* acl_remove:                            pcsys_monitor.      (line 3473)
* acl_reset:                             pcsys_monitor.      (line 3475)
* acl_show:                              pcsys_monitor.      (line 3456)
* balloon:                               pcsys_monitor.      (line 3450)
* balloon <1>:                           pcsys_monitor.      (line 3623)
* block:                                 pcsys_monitor.      (line 3553)
* block-jobs:                            pcsys_monitor.      (line 3557)
* blockstats:                            pcsys_monitor.      (line 3555)
* block_job_cancel:                      pcsys_monitor.      (line 3154)
* block_job_complete:                    pcsys_monitor.      (line 3156)
* block_job_pause:                       pcsys_monitor.      (line 3160)
* block_job_resume:                      pcsys_monitor.      (line 3162)
* block_job_set_speed:                   pcsys_monitor.      (line 3152)
* block_passwd:                          pcsys_monitor.      (line 3499)
* block_resize:                          pcsys_monitor.      (line 3144)
* block_set_io_throttle:                 pcsys_monitor.      (line 3501)
* block_stream:                          pcsys_monitor.      (line 3150)
* boot_set:                              pcsys_monitor.      (line 3350)
* capture:                               pcsys_monitor.      (line 3595)
* change:                                pcsys_monitor.      (line 3174)
* chardev:                               pcsys_monitor.      (line 3551)
* chardev-add:                           pcsys_monitor.      (line 3528)
* chardev-remove:                        pcsys_monitor.      (line 3532)
* client_migrate_info:                   pcsys_monitor.      (line 3399)
* closefd:                               pcsys_monitor.      (line 3495)
* commit:                                pcsys_monitor.      (line 3134)
* cont:                                  pcsys_monitor.      (line 3240)
* cpu:                                   pcsys_monitor.      (line 3324)
* cpu-add:                               pcsys_monitor.      (line 3538)
* cpus:                                  pcsys_monitor.      (line 3565)
* cpustats:                              pcsys_monitor.      (line 3611)
* delvm:                                 pcsys_monitor.      (line 3233)
* device_add:                            pcsys_monitor.      (line 3320)
* device_del:                            pcsys_monitor.      (line 3322)
* drive_add:                             pcsys_monitor.      (line 3429)
* drive_backup:                          pcsys_monitor.      (line 3426)
* drive_del:                             pcsys_monitor.      (line 3166)
* drive_mirror:                          pcsys_monitor.      (line 3423)
* dump:                                  pcsys_monitor.      (line 3653)
* dump-guest-memory:                     pcsys_monitor.      (line 3405)
* dump-skeys:                            pcsys_monitor.      (line 3415)
* eject:                                 pcsys_monitor.      (line 3164)
* expire_password:                       pcsys_monitor.      (line 3511)
* gdbserver:                             pcsys_monitor.      (line 3244)
* getfd:                                 pcsys_monitor.      (line 3491)
* help:                                  pcsys_monitor.      (line 3132)
* history:                               pcsys_monitor.      (line 3567)
* hostfwd_add:                           pcsys_monitor.      (line 3445)
* hostfwd_remove:                        pcsys_monitor.      (line 3448)
* host_net_add:                          pcsys_monitor.      (line 3433)
* host_net_remove:                       pcsys_monitor.      (line 3435)
* hotpluggable-cpus:                     pcsys_monitor.      (line 3655)
* i:                                     pcsys_monitor.      (line 3294)
* info:                                  pcsys_monitor.      (line 3545)
* ioapic:                                pcsys_monitor.      (line 3563)
* iothreads:                             pcsys_monitor.      (line 3641)
* irq:                                   pcsys_monitor.      (line 3569)
* jit:                                   pcsys_monitor.      (line 3581)
* kvm:                                   pcsys_monitor.      (line 3585)
* lapic:                                 pcsys_monitor.      (line 3561)
* loadvm:                                pcsys_monitor.      (line 3230)
* log:                                   pcsys_monitor.      (line 3223)
* logfile:                               pcsys_monitor.      (line 3216)
* mce (x86):                             pcsys_monitor.      (line 3489)
* mem:                                   pcsys_monitor.      (line 3577)
* memdev:                                pcsys_monitor.      (line 3637)
* memory-devices:                        pcsys_monitor.      (line 3639)
* memsave:                               pcsys_monitor.      (line 3346)
* mice:                                  pcsys_monitor.      (line 3601)
* migrate:                               pcsys_monitor.      (line 3373)
* migrate <1>:                           pcsys_monitor.      (line 3615)
* migrate_cache_size:                    pcsys_monitor.      (line 3621)
* migrate_cancel:                        pcsys_monitor.      (line 3377)
* migrate_capabilities:                  pcsys_monitor.      (line 3617)
* migrate_incoming:                      pcsys_monitor.      (line 3380)
* migrate_parameters:                    pcsys_monitor.      (line 3619)
* migrate_set_cache_size:                pcsys_monitor.      (line 3384)
* migrate_set_capability:                pcsys_monitor.      (line 3390)
* migrate_set_downtime:                  pcsys_monitor.      (line 3388)
* migrate_set_parameter:                 pcsys_monitor.      (line 3392)
* migrate_set_speed:                     pcsys_monitor.      (line 3386)
* migrate_start_postcopy:                pcsys_monitor.      (line 3394)
* mouse_button:                          pcsys_monitor.      (line 3329)
* mouse_move:                            pcsys_monitor.      (line 3326)
* mouse_set:                             pcsys_monitor.      (line 3331)
* mtree:                                 pcsys_monitor.      (line 3579)
* name:                                  pcsys_monitor.      (line 3607)
* nbd_server_add:                        pcsys_monitor.      (line 3483)
* nbd_server_start:                      pcsys_monitor.      (line 3478)
* nbd_server_stop:                       pcsys_monitor.      (line 3487)
* netdev_add:                            pcsys_monitor.      (line 3437)
* netdev_del:                            pcsys_monitor.      (line 3439)
* network:                               pcsys_monitor.      (line 3549)
* nmi:                                   pcsys_monitor.      (line 3358)
* numa:                                  pcsys_monitor.      (line 3587)
* o:                                     pcsys_monitor.      (line 3296)
* object_add:                            pcsys_monitor.      (line 3441)
* object_del:                            pcsys_monitor.      (line 3443)
* ocker-ports:                           pcsys_monitor.      (line 3645)
* opcount:                               pcsys_monitor.      (line 3583)
* pci:                                   pcsys_monitor.      (line 3573)
* pcie_aer_inject_error:                 pcsys_monitor.      (line 3431)
* pic:                                   pcsys_monitor.      (line 3571)
* pmemsave:                              pcsys_monitor.      (line 3348)
* print:                                 pcsys_monitor.      (line 3292)
* profile:                               pcsys_monitor.      (line 3593)
* qdm:                                   pcsys_monitor.      (line 3627)
* qemu-io:                               pcsys_monitor.      (line 3535)
* qom-tree:                              pcsys_monitor.      (line 3629)
* qtree:                                 pcsys_monitor.      (line 3625)
* quit:                                  pcsys_monitor.      (line 3142)
* registers:                             pcsys_monitor.      (line 3559)
* ringbuf_read:                          pcsys_monitor.      (line 3365)
* ringbuf_write:                         pcsys_monitor.      (line 3361)
* rocker:                                pcsys_monitor.      (line 3643)
* rocker-of-dpa-flows:                   pcsys_monitor.      (line 3647)
* rocker-of-dpa-groups:                  pcsys_monitor.      (line 3649)
* roms:                                  pcsys_monitor.      (line 3631)
* savevm:                                pcsys_monitor.      (line 3225)
* screendump:                            pcsys_monitor.      (line 3214)
* sendkey:                               pcsys_monitor.      (line 3298)
* set_link:                              pcsys_monitor.      (line 3452)
* set_password:                          pcsys_monitor.      (line 3504)
* singlestep:                            pcsys_monitor.      (line 3235)
* skeys:                                 pcsys_monitor.      (line 3651)
* snapshots:                             pcsys_monitor.      (line 3597)
* snapshot_blkdev:                       pcsys_monitor.      (line 3417)
* snapshot_blkdev_internal:              pcsys_monitor.      (line 3419)
* snapshot_delete_blkdev_internal:       pcsys_monitor.      (line 3421)
* spice:                                 pcsys_monitor.      (line 3605)
* status:                                pcsys_monitor.      (line 3599)
* stop:                                  pcsys_monitor.      (line 3238)
* stopcapture:                           pcsys_monitor.      (line 3343)
* sum:                                   pcsys_monitor.      (line 3311)
* system_powerdown:                      pcsys_monitor.      (line 3309)
* system_reset:                          pcsys_monitor.      (line 3307)
* system_wakeup:                         pcsys_monitor.      (line 3242)
* tlb:                                   pcsys_monitor.      (line 3575)
* tpm:                                   pcsys_monitor.      (line 3635)
* trace-event:                           pcsys_monitor.      (line 3218)
* trace-events:                          pcsys_monitor.      (line 3633)
* trace-file:                            pcsys_monitor.      (line 3220)
* usb:                                   pcsys_monitor.      (line 3589)
* usbhost:                               pcsys_monitor.      (line 3591)
* usb_add:                               pcsys_monitor.      (line 3313)
* usb_del:                               pcsys_monitor.      (line 3316)
* usernet:                               pcsys_monitor.      (line 3613)
* uuid:                                  pcsys_monitor.      (line 3609)
* version:                               pcsys_monitor.      (line 3547)
* vm-generation-id:                      pcsys_monitor.      (line 3657)
* vnc:                                   pcsys_monitor.      (line 3603)
* watchdog_action:                       pcsys_monitor.      (line 3454)
* wavcapture:                            pcsys_monitor.      (line 3335)
* x:                                     pcsys_monitor.      (line 3246)
* xp:                                    pcsys_monitor.      (line 3248)
* x_colo_lost_heartbeat:                 pcsys_monitor.      (line 3397)

C.3 Keystroke Index
===================

This is a list of all keystrokes which have a special function in system
emulation.

* Menu:

* Ctrl-a b:                              mux_keys.           (line 3105)
* Ctrl-a c:                              mux_keys.           (line 3107)
* Ctrl-a Ctrl-a:                         mux_keys.           (line 3110)
* Ctrl-a h:                              mux_keys.           (line 3097)
* Ctrl-a s:                              mux_keys.           (line 3101)
* Ctrl-a t:                              mux_keys.           (line 3103)
* Ctrl-a x:                              mux_keys.           (line 3099)
* Ctrl-Alt:                              pcsys_keys.         (line 3082)
* Ctrl-Alt-+:                            pcsys_keys.         (line 3064)
* Ctrl-Alt--:                            pcsys_keys.         (line 3067)
* Ctrl-Alt-f:                            pcsys_keys.         (line 3061)
* Ctrl-Alt-n:                            pcsys_keys.         (line 3073)
* Ctrl-Alt-u:                            pcsys_keys.         (line 3070)
* Ctrl-Down:                             pcsys_keys.         (line 3084)
* Ctrl-PageDown:                         pcsys_keys.         (line 3084)
* Ctrl-PageUp:                           pcsys_keys.         (line 3084)
* Ctrl-Up:                               pcsys_keys.         (line 3084)

C.4 Program Index
=================

C.5 Data Type Index
===================

This index could be used for qdev device names and options.

C.6 Variable Index
==================

