1 menu "Xen driver support"
5 bool "Xen memory balloon driver"
8 The balloon driver allows the Xen domain to request more memory from
9 the system to expand the domain's memory allocation, or alternatively
10 return unneeded memory to the system.
12 config XEN_SELFBALLOONING
13 bool "Dynamically self-balloon kernel memory to target"
14 depends on XEN && XEN_BALLOON && CLEANCACHE && SWAP && XEN_TMEM
17 Self-ballooning dynamically balloons available kernel memory driven
18 by the current usage of anonymous memory ("committed AS") and
19 controlled by various sysfs-settable parameters. Configuring
20 FRONTSWAP is highly recommended; if it is not configured, self-
21 ballooning is disabled by default. If FRONTSWAP is configured,
22 frontswap-selfshrinking is enabled by default but can be disabled
23 with the 'tmem.selfshrink=0' kernel boot parameter; and self-ballooning
24 is enabled by default but can be disabled with the 'tmem.selfballooning=0'
25 kernel boot parameter. Note that systems without a sufficiently
26 large swap device should not enable self-ballooning.
28 config XEN_BALLOON_MEMORY_HOTPLUG
29 bool "Memory hotplug support for Xen balloon driver"
31 depends on XEN_BALLOON && MEMORY_HOTPLUG
33 Memory hotplug support for Xen balloon driver allows expanding memory
34 available for the system above limit declared at system startup.
35 It is very useful on critical systems which require long
36 run without rebooting.
38 Memory could be hotplugged in following steps:
40 1) target domain: ensure that memory auto online policy is in
41 effect by checking /sys/devices/system/memory/auto_online_blocks
42 file (should be 'online').
44 2) control domain: xl mem-max <target-domain> <maxmem>
45 where <maxmem> is >= requested memory size,
47 3) control domain: xl mem-set <target-domain> <memory>
48 where <memory> is requested memory size; alternatively memory
49 could be added by writing proper value to
50 /sys/devices/system/xen_memory/xen_memory0/target or
51 /sys/devices/system/xen_memory/xen_memory0/target_kb on the
54 Alternatively, if memory auto onlining was not requested at step 1
55 the newly added memory can be manually onlined in the target domain
56 by doing the following:
58 for i in /sys/devices/system/memory/memory*/state; do \
59 [ "`cat "$i"`" = offline ] && echo online > "$i"; done
61 or by adding the following line to udev rules:
63 SUBSYSTEM=="memory", ACTION=="add", RUN+="/bin/sh -c '[ -f /sys$devpath/state ] && echo online > /sys$devpath/state'"
65 config XEN_BALLOON_MEMORY_HOTPLUG_LIMIT
66 int "Hotplugged memory limit (in GiB) for a PV guest"
70 depends on XEN_HAVE_PVMMU
71 depends on XEN_BALLOON_MEMORY_HOTPLUG
73 Maxmium amount of memory (in GiB) that a PV guest can be
74 expanded to when using memory hotplug.
76 A PV guest can have more memory than this limit if is
77 started with a larger maximum.
79 This value is used to allocate enough space in internal
80 tables needed for physical memory administration.
82 config XEN_SCRUB_PAGES
83 bool "Scrub pages before returning them to system"
84 depends on XEN_BALLOON
87 Scrub pages before returning them to the system for reuse by
88 other domains. This makes sure that any confidential data
89 is not accidentally visible to other domains. Is it more
90 secure, but slightly less efficient.
94 tristate "Xen /dev/xen/evtchn device"
97 The evtchn driver allows a userspace process to trigger event
98 channels and to receive notification of an event channel
100 If in doubt, say yes.
103 bool "Backend driver support"
107 Support for backend device drivers that provide I/O services
108 to other virtual machines.
111 tristate "Xen filesystem"
115 The xen filesystem provides a way for domains to share
116 information with each other and with the hypervisor.
117 For example, by reading and writing the "xenbus" file, guests
118 may pass arbitrary information to the initial domain.
119 If in doubt, say yes.
121 config XEN_COMPAT_XENFS
122 bool "Create compatibility mount point /proc/xen"
126 The old xenstore userspace tools expect to find "xenbus"
127 under /proc/xen, but "xenbus" is now found at the root of the
128 xenfs filesystem. Selecting this causes the kernel to create
129 the compatibility mount point /proc/xen if it is running on
131 If in doubt, say yes.
133 config XEN_SYS_HYPERVISOR
134 bool "Create xen entries under /sys/hypervisor"
136 select SYS_HYPERVISOR
139 Create entries under /sys/hypervisor describing the Xen
140 hypervisor environment. When running native or in another
141 virtual environment, /sys/hypervisor will still be present,
142 but will have no xen contents.
144 config XEN_XENBUS_FRONTEND
148 tristate "userspace grant access device driver"
153 Allows userspace processes to use grants.
155 config XEN_GRANT_DEV_ALLOC
156 tristate "User-space grant reference allocator driver"
160 Allows userspace processes to create pages with access granted
161 to other domains. This can be used to implement frontend drivers
162 or as part of an inter-domain shared memory channel.
170 depends on !ARM && !ARM64
171 default m if (CLEANCACHE || FRONTSWAP)
173 Shim to interface in-kernel Transcendent Memory hooks
174 (e.g. cleancache and frontswap) to Xen tmem hypercalls.
176 config XEN_PCIDEV_BACKEND
177 tristate "Xen PCI-device backend driver"
178 depends on PCI && X86 && XEN
179 depends on XEN_BACKEND
182 The PCI device backend driver allows the kernel to export arbitrary
183 PCI devices to other guests. If you select this to be a module, you
184 will need to make sure no other driver has bound to the device(s)
185 you want to make visible to other guests.
187 The parameter "passthrough" allows you specify how you want the PCI
188 devices to appear in the guest. You can choose the default (0) where
189 PCI topology starts at 00.00.0, or (1) for passthrough if you want
190 the PCI devices topology appear the same as in the host.
192 The "hide" parameter (only applicable if backend driver is compiled
193 into the kernel) allows you to bind the PCI devices to this module
194 from the default device drivers. The argument is the list of PCI BDFs:
195 xen-pciback.hide=(03:00.0)(04:00.0)
199 config XEN_PVCALLS_FRONTEND
200 tristate "XEN PV Calls frontend driver"
201 depends on INET && XEN
203 select XEN_XENBUS_FRONTEND
205 Experimental frontend for the Xen PV Calls protocol
206 (https://xenbits.xen.org/docs/unstable/misc/pvcalls.html). It
207 sends a small set of POSIX calls to the backend, which
210 config XEN_PVCALLS_BACKEND
211 bool "XEN PV Calls backend driver"
212 depends on INET && XEN && XEN_BACKEND
215 Experimental backend for the Xen PV Calls protocol
216 (https://xenbits.xen.org/docs/unstable/misc/pvcalls.html). It
217 allows PV Calls frontends to send POSIX calls to the backend,
218 which implements them.
222 config XEN_SCSI_BACKEND
223 tristate "XEN SCSI backend driver"
224 depends on XEN && XEN_BACKEND && TARGET_CORE
226 The SCSI backend driver allows the kernel to export its SCSI Devices
227 to other guests via a high-performance shared-memory interface.
228 Only needed for systems running as XEN driver domains (e.g. Dom0) and
229 if guests need generic access to SCSI devices.
237 bool "Xen stub drivers"
238 depends on XEN && X86_64 && BROKEN
241 Allow kernel to install stub drivers, to reserve space for Xen drivers,
242 i.e. memory hotplug and cpu hotplug, and to block native drivers loaded,
243 so that real Xen drivers can be modular.
245 To enable Xen features like cpu and memory hotplug, select Y here.
247 config XEN_ACPI_HOTPLUG_MEMORY
248 tristate "Xen ACPI memory hotplug"
249 depends on XEN_DOM0 && XEN_STUB && ACPI
252 This is Xen ACPI memory hotplug.
254 Currently Xen only support ACPI memory hot-add. If you want
255 to hot-add memory at runtime (the hot-added memory cannot be
256 removed until machine stop), select Y/M here, otherwise select N.
258 config XEN_ACPI_HOTPLUG_CPU
259 tristate "Xen ACPI cpu hotplug"
260 depends on XEN_DOM0 && XEN_STUB && ACPI
261 select ACPI_CONTAINER
264 Xen ACPI cpu enumerating and hotplugging
266 For hotplugging, currently Xen only support ACPI cpu hotadd.
267 If you want to hotadd cpu at runtime (the hotadded cpu cannot
268 be removed until machine stop), select Y/M here.
270 config XEN_ACPI_PROCESSOR
271 tristate "Xen ACPI processor"
272 depends on XEN && XEN_DOM0 && X86 && ACPI_PROCESSOR && CPU_FREQ
275 This ACPI processor uploads Power Management information to the Xen
278 To do that the driver parses the Power Management data and uploads
279 said information to the Xen hypervisor. Then the Xen hypervisor can
280 select the proper Cx and Pxx states. It also registers itself as the
281 SMM so that other drivers (such as ACPI cpufreq scaling driver) will
284 To compile this driver as a module, choose M here: the module will be
285 called xen_acpi_processor If you do not know what to choose, select
286 M here. If the CPUFREQ drivers are built in, select Y here.
289 bool "Xen platform mcelog"
290 depends on XEN_DOM0 && X86_64 && X86_MCE
293 Allow kernel fetching MCE error from Xen platform and
294 converting it into Linux mcelog format for mcelog tools
296 config XEN_HAVE_PVMMU
301 depends on (ARM || ARM64 || X86_64) && EFI
303 config XEN_AUTO_XLATE
305 depends on ARM || ARM64 || XEN_PVHVM
307 Support for auto-translated physmap guests.
311 depends on X86 && ACPI
315 depends on X86 && XEN_DOM0 && XENFS
316 default y if KALLSYMS
318 Exports hypervisor symbols (along with their types and addresses) via
319 /proc/xen/xensyms file, similar to /proc/kallsyms