xref: /openbmc/qemu/docs/system/i386/xen.rst (revision 6e782ffd)
1Xen HVM guest support
2=====================
3
4
5Description
6-----------
7
8KVM has support for hosting Xen guests, intercepting Xen hypercalls and event
9channel (Xen PV interrupt) delivery. This allows guests which expect to be
10run under Xen to be hosted in QEMU under Linux/KVM instead.
11
12Using the split irqchip is mandatory for Xen support.
13
14Setup
15-----
16
17Xen mode is enabled by setting the ``xen-version`` property of the KVM
18accelerator, for example for Xen 4.17:
19
20.. parsed-literal::
21
22  |qemu_system| --accel kvm,xen-version=0x40011,kernel-irqchip=split
23
24Additionally, virtual APIC support can be advertised to the guest through the
25``xen-vapic`` CPU flag:
26
27.. parsed-literal::
28
29  |qemu_system| --accel kvm,xen-version=0x40011,kernel-irqchip=split --cpu host,+xen-vapic
30
31When Xen support is enabled, QEMU changes hypervisor identification (CPUID
320x40000000..0x4000000A) to Xen. The KVM identification and features are not
33advertised to a Xen guest. If Hyper-V is also enabled, the Xen identification
34moves to leaves 0x40000100..0x4000010A.
35
36Properties
37----------
38
39The following properties exist on the KVM accelerator object:
40
41``xen-version``
42  This property contains the Xen version in ``XENVER_version`` form, with the
43  major version in the top 16 bits and the minor version in the low 16 bits.
44  Setting this property enables the Xen guest support. If Xen version 4.5 or
45  greater is specified, the HVM leaf in Xen CPUID is populated. Xen version
46  4.6 enables the vCPU ID in CPUID, and version 4.17 advertises vCPU upcall
47  vector support to the guest.
48
49``xen-evtchn-max-pirq``
50  Xen PIRQs represent an emulated physical interrupt, either GSI or MSI, which
51  can be routed to an event channel instead of to the emulated I/O or local
52  APIC. By default, QEMU permits only 256 PIRQs because this allows maximum
53  compatibility with 32-bit MSI where the higher bits of the PIRQ# would need
54  to be in the upper 64 bits of the MSI message. For guests with large numbers
55  of PCI devices (and none which are limited to 32-bit addressing) it may be
56  desirable to increase this value.
57
58``xen-gnttab-max-frames``
59  Xen grant tables are the means by which a Xen guest grants access to its
60  memory for PV back ends (disk, network, etc.). Since QEMU only supports v1
61  grant tables which are 8 bytes in size, each page (each frame) of the grant
62  table can reference 512 pages of guest memory. The default number of frames
63  is 64, allowing for 32768 pages of guest memory to be accessed by PV backends
64  through simultaneous grants. For guests with large numbers of PV devices and
65  high throughput, it may be desirable to increase this value.
66
67Xen paravirtual devices
68-----------------------
69
70The Xen PCI platform device is enabled automatically for a Xen guest. This
71allows a guest to unplug all emulated devices, in order to use paravirtual
72block and network drivers instead.
73
74Those paravirtual Xen block, network (and console) devices can be created
75through the command line, and/or hot-plugged.
76
77To provide a Xen console device, define a character device and then a device
78of type ``xen-console`` to connect to it. For the Xen console equivalent of
79the handy ``-serial mon:stdio`` option, for example:
80
81.. parsed-literal::
82   -chardev stdio,mux=on,id=char0,signal=off -mon char0 \\
83   -device xen-console,chardev=char0
84
85The Xen network device is ``xen-net-device``, which becomes the default NIC
86model for emulated Xen guests, meaning that just the default NIC provided
87by QEMU should automatically work and present a Xen network device to the
88guest.
89
90Disks can be configured with '``-drive file=${GUEST_IMAGE},if=xen``' and will
91appear to the guest as ``xvda`` onwards.
92
93Under Xen, the boot disk is typically available both via IDE emulation, and
94as a PV block device. Guest bootloaders typically use IDE to load the guest
95kernel, which then unplugs the IDE and continues with the Xen PV block device.
96
97This configuration can be achieved as follows:
98
99.. parsed-literal::
100
101  |qemu_system| --accel kvm,xen-version=0x40011,kernel-irqchip=split \\
102       -drive file=${GUEST_IMAGE},if=xen \\
103       -drive file=${GUEST_IMAGE},file.locking=off,if=ide
104
105VirtIO devices can also be used; Linux guests may need to be dissuaded from
106umplugging them by adding '``xen_emul_unplug=never``' on their command line.
107
108Booting Xen PV guests
109---------------------
110
111Booting PV guest kernels is possible by using the Xen PV shim (a version of Xen
112itself, designed to run inside a Xen HVM guest and provide memory management
113services for one guest alone).
114
115The Xen binary is provided as the ``-kernel`` and the guest kernel itself (or
116PV Grub image) as the ``-initrd`` image, which actually just means the first
117multiboot "module". For example:
118
119.. parsed-literal::
120
121  |qemu_system| --accel kvm,xen-version=0x40011,kernel-irqchip=split \\
122       -chardev stdio,id=char0 -device xen-console,chardev=char0 \\
123       -display none  -m 1G  -kernel xen -initrd bzImage \\
124       -append "pv-shim console=xen,pv -- console=hvc0 root=/dev/xvda1" \\
125       -drive file=${GUEST_IMAGE},if=xen
126
127The Xen image must be built with the ``CONFIG_XEN_GUEST`` and ``CONFIG_PV_SHIM``
128options, and as of Xen 4.17, Xen's PV shim mode does not support using a serial
129port; it must have a Xen console or it will panic.
130
131The example above provides the guest kernel command line after a separator
132(" ``--`` ") on the Xen command line, and does not provide the guest kernel
133with an actual initramfs, which would need to listed as a second multiboot
134module. For more complicated alternatives, see the command line
135documentation for the ``-initrd`` option.
136
137Host OS requirements
138--------------------
139
140The minimal Xen support in the KVM accelerator requires the host to be running
141Linux v5.12 or newer. Later versions add optimisations: Linux v5.17 added
142acceleration of interrupt delivery via the Xen PIRQ mechanism, and Linux v5.19
143accelerated Xen PV timers and inter-processor interrupts (IPIs).
144