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15 KiB
ReStructuredText
397 lines
15 KiB
ReStructuredText
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.. _pcsys_005fusb:
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USB emulation
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-------------
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QEMU can emulate a PCI UHCI, OHCI, EHCI or XHCI USB controller. You can
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plug virtual USB devices or real host USB devices (only works with
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certain host operating systems). QEMU will automatically create and
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connect virtual USB hubs as necessary to connect multiple USB devices.
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USB controllers
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~~~~~~~~~~~~~~~
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XHCI controller support
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^^^^^^^^^^^^^^^^^^^^^^^
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QEMU has XHCI host adapter support. The XHCI hardware design is much
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more virtualization-friendly when compared to EHCI and UHCI, thus XHCI
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emulation uses less resources (especially CPU). So if your guest
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supports XHCI (which should be the case for any operating system
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released around 2010 or later) we recommend using it:
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qemu -device qemu-xhci
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XHCI supports USB 1.1, USB 2.0 and USB 3.0 devices, so this is the
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only controller you need. With only a single USB controller (and
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therefore only a single USB bus) present in the system there is no
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need to use the bus= parameter when adding USB devices.
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EHCI controller support
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^^^^^^^^^^^^^^^^^^^^^^^
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The QEMU EHCI Adapter supports USB 2.0 devices. It can be used either
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standalone or with companion controllers (UHCI, OHCI) for USB 1.1
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devices. The companion controller setup is more convenient to use
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because it provides a single USB bus supporting both USB 2.0 and USB
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1.1 devices. See next section for details.
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When running EHCI in standalone mode you can add UHCI or OHCI
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controllers for USB 1.1 devices too. Each controller creates its own
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bus though, so there are two completely separate USB buses: One USB
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1.1 bus driven by the UHCI controller and one USB 2.0 bus driven by
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the EHCI controller. Devices must be attached to the correct
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controller manually.
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The easiest way to add a UHCI controller to a ``pc`` machine is the
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``-usb`` switch. QEMU will create the UHCI controller as function of
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the PIIX3 chipset. The USB 1.1 bus will carry the name ``usb-bus.0``.
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You can use the standard ``-device`` switch to add a EHCI controller to
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your virtual machine. It is strongly recommended to specify an ID for
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the controller so the USB 2.0 bus gets an individual name, for example
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``-device usb-ehci,id=ehci``. This will give you a USB 2.0 bus named
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``ehci.0``.
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When adding USB devices using the ``-device`` switch you can specify the
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bus they should be attached to. Here is a complete example:
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.. parsed-literal::
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|qemu_system| -M pc ${otheroptions} \\
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-drive if=none,id=usbstick,format=raw,file=/path/to/image \\
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-usb \\
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-device usb-ehci,id=ehci \\
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-device usb-tablet,bus=usb-bus.0 \\
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-device usb-storage,bus=ehci.0,drive=usbstick
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This attaches a USB tablet to the UHCI adapter and a USB mass storage
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device to the EHCI adapter.
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Companion controller support
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The UHCI and OHCI controllers can attach to a USB bus created by EHCI
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as companion controllers. This is done by specifying the ``masterbus``
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and ``firstport`` properties. ``masterbus`` specifies the bus name the
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controller should attach to. ``firstport`` specifies the first port the
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controller should attach to, which is needed as usually one EHCI
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controller with six ports has three UHCI companion controllers with
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two ports each.
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There is a config file in docs which will do all this for
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you, which you can use like this:
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.. parsed-literal::
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|qemu_system| -readconfig docs/config/ich9-ehci-uhci.cfg
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Then use ``bus=ehci.0`` to assign your USB devices to that bus.
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Using the ``-usb`` switch for ``q35`` machines will create a similar
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USB controller configuration.
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.. _Connecting USB devices:
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Connecting USB devices
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~~~~~~~~~~~~~~~~~~~~~~
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USB devices can be connected with the ``-device usb-...`` command line
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option or the ``device_add`` monitor command. Available devices are:
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``usb-mouse``
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Virtual Mouse. This will override the PS/2 mouse emulation when
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activated.
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``usb-tablet``
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Pointer device that uses absolute coordinates (like a touchscreen).
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This means QEMU is able to report the mouse position without having
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to grab the mouse. Also overrides the PS/2 mouse emulation when
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activated.
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``usb-storage,drive=drive_id``
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Mass storage device backed by drive_id (see the :ref:`disk images`
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chapter in the System Emulation Users Guide). This is the classic
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bulk-only transport protocol used by 99% of USB sticks. This
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example shows it connected to an XHCI USB controller and with
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a drive backed by a raw format disk image:
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.. parsed-literal::
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|qemu_system| [...] \\
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-drive if=none,id=stick,format=raw,file=/path/to/file.img \\
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-device nec-usb-xhci,id=xhci \\
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-device usb-storage,bus=xhci.0,drive=stick
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``usb-uas``
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USB attached SCSI device. This does not create a SCSI disk, so
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you need to explicitly create a ``scsi-hd`` or ``scsi-cd`` device
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on the command line, as well as using the ``-drive`` option to
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specify what those disks are backed by. One ``usb-uas`` device can
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handle multiple logical units (disks). This example creates three
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logical units: two disks and one cdrom drive:
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.. parsed-literal::
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|qemu_system| [...] \\
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-drive if=none,id=uas-disk1,format=raw,file=/path/to/file1.img \\
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-drive if=none,id=uas-disk2,format=raw,file=/path/to/file2.img \\
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-drive if=none,id=uas-cdrom,media=cdrom,format=raw,file=/path/to/image.iso \\
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-device nec-usb-xhci,id=xhci \\
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-device usb-uas,id=uas,bus=xhci.0 \\
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-device scsi-hd,bus=uas.0,scsi-id=0,lun=0,drive=uas-disk1 \\
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-device scsi-hd,bus=uas.0,scsi-id=0,lun=1,drive=uas-disk2 \\
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-device scsi-cd,bus=uas.0,scsi-id=0,lun=5,drive=uas-cdrom
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``usb-bot``
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Bulk-only transport storage device. This presents the guest with the
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same USB bulk-only transport protocol interface as ``usb-storage``, but
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the QEMU command line option works like ``usb-uas`` and does not
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automatically create SCSI disks for you. ``usb-bot`` supports up to
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16 LUNs. Unlike ``usb-uas``, the LUN numbers must be continuous,
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i.e. for three devices you must use 0+1+2. The 0+1+5 numbering from the
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``usb-uas`` example above won't work with ``usb-bot``.
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``usb-mtp,rootdir=dir``
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Media transfer protocol device, using dir as root of the file tree
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that is presented to the guest.
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``usb-host,hostbus=bus,hostaddr=addr``
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Pass through the host device identified by bus and addr
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``usb-host,vendorid=vendor,productid=product``
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Pass through the host device identified by vendor and product ID
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``usb-wacom-tablet``
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Virtual Wacom PenPartner tablet. This device is similar to the
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``tablet`` above but it can be used with the tslib library because in
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addition to touch coordinates it reports touch pressure.
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``usb-kbd``
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Standard USB keyboard. Will override the PS/2 keyboard (if present).
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``usb-serial,chardev=id``
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Serial converter. This emulates an FTDI FT232BM chip connected to
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host character device id.
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``usb-braille,chardev=id``
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Braille device. This will use BrlAPI to display the braille output on
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a real or fake device referenced by id.
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``usb-net[,netdev=id]``
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Network adapter that supports CDC ethernet and RNDIS protocols. id
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specifies a netdev defined with ``-netdev …,id=id``. For instance,
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user-mode networking can be used with
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.. parsed-literal::
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|qemu_system| [...] -netdev user,id=net0 -device usb-net,netdev=net0
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``usb-ccid``
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Smartcard reader device
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``usb-audio``
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USB audio device
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``u2f-{emulated,passthru}``
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Universal Second Factor device
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``canokey``
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An Open-source Secure Key implementing FIDO2, OpenPGP, PIV and more.
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For more information, see :ref:`canokey`.
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Physical port addressing
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^^^^^^^^^^^^^^^^^^^^^^^^
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For all the above USB devices, by default QEMU will plug the device
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into the next available port on the specified USB bus, or onto
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some available USB bus if you didn't specify one explicitly.
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If you need to, you can also specify the physical port where
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the device will show up in the guest. This can be done using the
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``port`` property. UHCI has two root ports (1,2). EHCI has six root
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ports (1-6), and the emulated (1.1) USB hub has eight ports.
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Plugging a tablet into UHCI port 1 works like this::
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-device usb-tablet,bus=usb-bus.0,port=1
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Plugging a hub into UHCI port 2 works like this::
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-device usb-hub,bus=usb-bus.0,port=2
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Plugging a virtual USB stick into port 4 of the hub just plugged works
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this way::
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-device usb-storage,bus=usb-bus.0,port=2.4,drive=...
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In the monitor, the ``device_add` command also accepts a ``port``
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property specification. If you want to unplug devices too you should
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specify some unique id which you can use to refer to the device.
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You can then use ``device_del`` to unplug the device later.
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For example::
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(qemu) device_add usb-tablet,bus=usb-bus.0,port=1,id=my-tablet
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(qemu) device_del my-tablet
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Hotplugging USB storage
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~~~~~~~~~~~~~~~~~~~~~~~
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The ``usb-bot`` and ``usb-uas`` devices can be hotplugged. In the hotplug
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case they are added with ``attached = false`` so the guest will not see
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the device until the ``attached`` property is explicitly set to true.
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That allows you to attach one or more scsi devices before making the
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device visible to the guest. The workflow looks like this:
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#. ``device-add usb-bot,id=foo``
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#. ``device-add scsi-{hd,cd},bus=foo.0,lun=0``
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#. optionally add more devices (luns 1 ... 15)
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#. ``scripts/qmp/qom-set foo.attached = true``
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.. _host_005fusb_005fdevices:
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Using host USB devices on a Linux host
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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WARNING: this is an experimental feature. QEMU will slow down when using
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it. USB devices requiring real time streaming (i.e. USB Video Cameras)
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are not supported yet.
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1. If you use an early Linux 2.4 kernel, verify that no Linux driver is
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actually using the USB device. A simple way to do that is simply to
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disable the corresponding kernel module by renaming it from
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``mydriver.o`` to ``mydriver.o.disabled``.
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2. Verify that ``/proc/bus/usb`` is working (most Linux distributions
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should enable it by default). You should see something like that:
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::
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ls /proc/bus/usb
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001 devices drivers
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3. Since only root can access to the USB devices directly, you can
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either launch QEMU as root or change the permissions of the USB
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devices you want to use. For testing, the following suffices:
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::
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chown -R myuid /proc/bus/usb
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4. Launch QEMU and do in the monitor:
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::
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info usbhost
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Device 1.2, speed 480 Mb/s
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Class 00: USB device 1234:5678, USB DISK
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You should see the list of the devices you can use (Never try to use
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hubs, it won't work).
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5. Add the device in QEMU by using:
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::
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device_add usb-host,vendorid=0x1234,productid=0x5678
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Normally the guest OS should report that a new USB device is plugged.
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You can use the option ``-device usb-host,...`` to do the same.
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6. Now you can try to use the host USB device in QEMU.
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When relaunching QEMU, you may have to unplug and plug again the USB
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device to make it work again (this is a bug).
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``usb-host`` properties for specifying the host device
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The example above uses the ``vendorid`` and ``productid`` to
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specify which host device to pass through, but this is not
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the only way to specify the host device. ``usb-host`` supports
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the following properties:
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``hostbus=<nr>``
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Specifies the bus number the device must be attached to
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``hostaddr=<nr>``
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Specifies the device address the device got assigned by the guest os
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``hostport=<str>``
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Specifies the physical port the device is attached to
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``vendorid=<hexnr>``
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Specifies the vendor ID of the device
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``productid=<hexnr>``
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Specifies the product ID of the device.
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In theory you can combine all these properties as you like. In
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practice only a few combinations are useful:
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- ``vendorid`` and ``productid`` -- match for a specific device, pass it to
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the guest when it shows up somewhere in the host.
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- ``hostbus`` and ``hostport`` -- match for a specific physical port in the
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host, any device which is plugged in there gets passed to the
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guest.
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- ``hostbus`` and ``hostaddr`` -- most useful for ad-hoc pass through as the
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hostaddr isn't stable. The next time you plug the device into the host it
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will get a new hostaddr.
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Note that on the host USB 1.1 devices are handled by UHCI/OHCI and USB
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2.0 by EHCI. That means different USB devices plugged into the very
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same physical port on the host may show up on different host buses
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depending on the speed. Supposing that devices plugged into a given
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physical port appear as bus 1 + port 1 for 2.0 devices and bus 3 + port 1
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for 1.1 devices, you can pass through any device plugged into that port
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and also assign it to the correct USB bus in QEMU like this:
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.. parsed-literal::
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|qemu_system| -M pc [...] \\
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-usb \\
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-device usb-ehci,id=ehci \\
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-device usb-host,bus=usb-bus.0,hostbus=3,hostport=1 \\
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-device usb-host,bus=ehci.0,hostbus=1,hostport=1
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``usb-host`` properties for reset behavior
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The ``guest-reset`` and ``guest-reset-all`` properties control
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whenever the guest is allowed to reset the physical usb device on the
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host. There are three cases:
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``guest-reset=false``
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The guest is not allowed to reset the (physical) usb device.
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``guest-reset=true,guest-resets-all=false``
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The guest is allowed to reset the device when it is not yet
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initialized (aka no usb bus address assigned). Usually this results
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in one guest reset being allowed. This is the default behavior.
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``guest-reset=true,guest-resets-all=true``
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The guest is allowed to reset the device as it pleases.
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The reason for this existing are broken usb devices. In theory one
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should be able to reset (and re-initialize) usb devices at any time.
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In practice that may result in shitty usb device firmware crashing and
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the device not responding any more until you power-cycle (aka un-plug
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and re-plug) it.
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What works best pretty much depends on the behavior of the specific
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usb device at hand, so it's a trial-and-error game. If the default
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doesn't work, try another option and see whenever the situation
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improves.
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record usb transfers
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^^^^^^^^^^^^^^^^^^^^
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All usb devices have support for recording the usb traffic. This can
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be enabled using the ``pcap=<file>`` property, for example:
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``-device usb-mouse,pcap=mouse.pcap``
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The pcap files are compatible with the linux kernels usbmon. Many
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tools, including ``wireshark``, can decode and inspect these trace
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files.
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