Annotation of wikisrc/ports/xen/howto.mdwn, revision 1.205
1.203 gdt 1: [[!meta title="Xen Status and HowTo"]]
1.144 maxv 2:
1.157 maxv 3: Xen is a Type 1 hypervisor which supports running multiple guest operating
4: systems on a single physical machine. One uses the Xen kernel to control the
5: CPU, memory and console, a dom0 operating system which mediates access to
6: other hardware (e.g., disks, network, USB), and one or more domU operating
7: systems which operate in an unprivileged virtualized environment. IO requests
8: from the domU systems are forwarded by the Xen hypervisor to the dom0 to be
9: fulfilled.
1.12 gdt 10:
1.203 gdt 11: This document provides status on what Xen things work on NetBSD
12: (upstream documentation might say something works if it works on some
13: particular Linux system).
14:
15: This document is also a HOWTO that presumes a basic familiarity with
16: the Xen system architecture, with installing NetBSD on amd64 hardware,
17: and with installing software from pkgsrc. See also the [Xen
1.182 gdt 18: website](http://www.xenproject.org/).
19:
1.203 gdt 20: If this document says that something works, and you find that it does
21: not, it is best to ask on port-xen and if you are correct to file a
22: PR.
1.201 gdt 23:
1.182 gdt 24: [[!toc]]
25:
1.183 gdt 26: # Overview
1.182 gdt 27:
28: The basic concept of Xen is that the hypervisor (xenkernel) runs on
29: the hardware, and runs a privileged domain ("dom0") that can access
1.204 gdt 30: disks/networking/etc. One then runs additional unprivileged domains
1.182 gdt 31: (each a "domU"), presumably to do something useful.
32:
33: This HOWTO addresses how to run a NetBSD dom0 (and hence also build
34: xen itself). It also addresses how to run domUs in that environment,
35: and how to deal with having a domU in a Xen environment run by someone
36: else and/or not running NetBSD.
37:
1.186 gdt 38: There are many choices one can make; the HOWTO recommends the standard
39: approach and limits discussion of alternatives in many cases.
40:
1.182 gdt 41: ## Guest Styles
42:
1.205 ! gdt 43: Xen supports different styles of guests. See
! 44: https://wiki.xenproject.org/wiki/Virtualization_Spectrum for a
! 45: discussion.
! 46:
! 47: This table shows the styles, and if a NetBSD dom0 can run in that
! 48: style, if a NetBSD dom0 can sypport that style of guest in a domU, and
! 49: if NetBSD as a domU can support that style.
1.149 maxv 50:
51: [[!table data="""
1.205 ! gdt 52: Style of guest |dom0 can be? |dom0 can support? |domU can be?
! 53: PV |yes |yes |yes
! 54: HVM |N/A |yes |yes
! 55: PVHVM |N/A |yes |current only
! 56: PVH |not yet |current only |current only
1.149 maxv 57: """]]
58:
1.205 ! gdt 59: In PV (paravirtualized) mode, the guest OS does not attempt to access
1.149 maxv 60: hardware directly, but instead makes hypercalls to the hypervisor; PV
1.205 ! gdt 61: guests must be specifically coded for Xen. See
! 62: [PV](https://wiki.xen.org/wiki/Paravirtualization_(PV\)).
1.170 gdt 63:
1.205 ! gdt 64: In HVM (Hardware Virtual Machine) mode, no guest modification is
! 65: required. However, hardware support is required, such as VT-x on
! 66: Intel CPUs and SVM on AMD CPUs to assist with the processor emulation.
! 67: The dom0 runs qemu to emulate hardware other than the processor. It
! 68: is therefore non-sensical to have an HVM dom0, because there is no
! 69: underlying system to provide emulation.
1.170 gdt 70:
1.205 ! gdt 71: In PVHVM mode, the guest runs as HVM, but additionally uses PV
1.199 gdt 72: drivers for efficiency. Therefore it is non-sensical for to have a
73: PVHVM dom0. See [PV on HVM](https://wiki.xen.org/wiki/PV_on_HVM).
1.170 gdt 74:
1.180 gdt 75: There have been two PVH modes: original PVH and PVHv2. Original PVH
1.203 gdt 76: was based on PV mode and is no longer relevant at all. Therefore
1.205 ! gdt 77: PVHv2 is written as PVH, here and elsewhere. PVH is basically
! 78: lightweight HVM with PV drivers. A critical feature of it is that
! 79: qemu is not needed; the hypervisor can do the emulation that is
! 80: required. Thus, a dom0 can be PVH. The source code uses PVH and
! 81: config files use pvh, but NB that this refers to PVHv2. See
1.203 gdt 82: [PVH(v2)](https://wiki.xenproject.org/wiki/PVH_(v2\)_Domu).
1.180 gdt 83:
1.205 ! gdt 84: At system boot, the dom0 kernel is loaded as a module with Xen as the
! 85: kernel. The dom0 can start one or more domUs. (Booting is explained
! 86: in detail in the dom0 section.)
1.12 gdt 87:
1.182 gdt 88: ## CPU Architecture
89:
90: Xen runs on x86_64 hardware (the NetBSD amd64 port).
91:
92: There is a concept of Xen running on ARM, but there are no reports of this working with NetBSD.
93:
94: The dom0 system should be amd64. (Instructions for i386PAE dom0 have been removed from the HOWTO.)
1.1 mspo 95:
1.204 gdt 96: The domU can be i386 PAE or amd64.
97: i386 PAE at one point was considered as [faster](https://lists.xen.org/archives/html/xen-devel/2012-07/msg00085.html) than amd64.
98: However, as of 2021 it is normal to use amd64 as the domU architecture, and use of i386 is dwindling.
1.150 maxv 99:
1.182 gdt 100: ## Xen Versions
1.15 gdt 101:
1.111 wiz 102: In NetBSD, Xen is provided in pkgsrc, via matching pairs of packages
1.15 gdt 103: xenkernel and xentools. We will refer only to the kernel versions,
104: but note that both packages must be installed together and must have
105: matching versions.
106:
1.145 maxv 107: Versions available in pkgsrc:
1.85 gdt 108:
1.145 maxv 109: [[!table data="""
1.184 gdt 110: Xen Version |Package Name |Xen CPU Support |EOL'ed By Upstream
111: 4.11 |xenkernel411 |x86_64 |No
112: 4.13 |xenkernel413 |x86_64 |No
1.145 maxv 113: """]]
1.113 gdt 114:
1.96 gdt 115: See also the [Xen Security Advisory page](http://xenbits.xen.org/xsa/).
116:
1.204 gdt 117: Older Xen had a python-based management tool called xm; this has been
118: replaced by xl.
1.166 gdt 119:
1.183 gdt 120: ## NetBSD versions
121:
122: Xen has been supported in NetBSD for a long time, at least since 2005.
123: Initially Xen was PV only.
124:
1.204 gdt 125: NetBSD Xen has always supported PV, in both dom0 and domU; for a long
126: time this was the only way. NetBSD >=8 as a dom0 supports HVM mode in
1.205 ! gdt 127: domUs.
1.203 gdt 128:
129: Support for PVHVM and PVH is available only in NetBSD-current; this is
130: currently somewhat experimental, although PVHVM appears reasonably
131: solid.
132:
133: NetBSD up to and including NetBSD 9 as a dom0 cannot safely run SMP.
134: Even if one added "options MULTIPROCESSOR" and configured multiple
135: vcpus, the kernel is likely to crash because of drivers without
136: adequate locking.
137:
138: NetBSD-current supports SMP in dom0, and XEN3_DOM0 includes "options
139: MULTIPROCESSOR".
140:
141: NetBSD (since NetBSD 6), when run as a domU, can run SMP, using
142: multiple CPUs if provided. The XEN3_DOMU kernel is built
143: with "options MULITPROCESSOR".
1.185 gdt 144:
1.191 gdt 145: Note that while Xen 4.13 is current, the kernel support is still
146: called XEN3, because the hypercall interface has not changed
147: significantly.
1.185 gdt 148:
1.187 gdt 149: # Creating a NetBSD dom0
1.15 gdt 150:
1.191 gdt 151: In order to install a NetBSD as a dom0, one first installs a normal
152: NetBSD system, and then pivot the install to a dom0 install by
153: changing the kernel and boot configuration.
1.15 gdt 154:
1.142 gdt 155: In 2018-05, trouble booting a dom0 was reported with 256M of RAM: with
156: 512M it worked reliably. This does not make sense, but if you see
157: "not ELF" after Xen boots, try increasing dom0 RAM.
158:
1.181 gdt 159: ## Installation of NetBSD
1.13 gdt 160:
1.191 gdt 161: [Install NetBSD/amd64](/guide/inst/) just as you would if you were not
162: using Xen. Therefore, use the most recent release, or a build from
163: the most recent stable branch. Alternatively, use -current, being
164: mindful of all the usual caveats of lower stability of current, and
1.205 ! gdt 165: likely a bit more so. Think about how you will provide storage for
! 166: disk images.
1.1 mspo 167:
1.181 gdt 168: ## Installation of Xen
1.1 mspo 169:
1.191 gdt 170: ### Building Xen
171:
1.205 ! gdt 172: Use the most recent version of Xen in pkgsrc, unless the DESCR says
! 173: that it is not suitable. Therefore, choose 4.13. In the dom0,
! 174: install xenkernel413 and xentools413 from pkgsrc.
1.155 maxv 175:
1.186 gdt 176: Once this is done, copy the Xen kernel from where pkgsrc puts it to
177: where the boot process will be able to find it:
1.155 maxv 178:
179: [[!template id=programlisting text="""
1.186 gdt 180: # cp -p /usr/pkg/xen413-kernel/xen.gz /
1.155 maxv 181: """]]
182:
1.191 gdt 183: Then, place a NetBSD XEN3_DOM0 kernel in the `/` directory. Such
184: kernel can either be taken from a local release build.sh run, compiled
185: manually, or downloaded from the NetBSD FTP, for example at:
1.159 maxv 186:
187: [[!template id=programlisting text="""
1.186 gdt 188: ftp.netbsd.org/pub/NetBSD/NetBSD-9.1/amd64/binary/kernel/netbsd-XEN3_DOM0.gz
1.159 maxv 189: """]]
1.20 gdt 190:
1.191 gdt 191: ### Configuring booting
192:
1.198 gdt 193: Read boot.cfg(8) carefully. Add lines to /boot.cfg to boot Xen,
194: adjusting for your root filesystem:
1.20 gdt 195:
1.157 maxv 196: [[!template id=filecontent name="/boot.cfg" text="""
1.198 gdt 197: menu=Xen:load /netbsd-XEN3_DOM0.gz root=wd0a console=pc;multiboot /xen.gz dom0_mem=512M
198: menu=Xen single user:load /netbsd-XEN3_DOM0.gz root=wd0a console=pc -s;multiboot /xen.gz dom0_mem=512M
1.152 maxv 199: """]]
1.20 gdt 200:
1.159 maxv 201: This specifies that the dom0 should have 512MB of ram, leaving the rest
1.187 gdt 202: to be allocated for domUs.
203:
1.191 gdt 204: NB: This says add, not replace, so that you will be able to more
205: easily boot a NetBSD kernel without Xen. Once Xen boots ok, you may
206: want to set it as default. It is highly likely that you will have
207: trouble at some point, and keeping an up-to-date GENERIC for use in
208: fixing problems is the standard prudent approach.
209:
1.194 gdt 210: \todo Explain why rndseed is not set with Xen as part of the dom0
211: subconfiguration.
212:
1.198 gdt 213: Note that you are likely to have to set root= because the boot device
214: from /boot is not passed via Xen to the dom0 kernel. With one disk,
215: it will work, but e.g. plugging in USB disk to a machine with root on
216: wd0a causes boot to fail.
217:
1.195 gdt 218: Beware that userconf statements must be attached to the dom0 load, and
219: may not be at top-level, because then they would try to configure the
1.205 ! gdt 220: hypervisor, if there is a way to pass them via multiboot. It appears
1.195 gdt 221: that adding `userconf=pckbc` to `/boot.cfg` causes Xen to crash very
222: early with a heap overflow.
223:
1.191 gdt 224: ### Console selection
225:
226: See boot_console(8). Understand that you should start from a place of
227: having console setup correct for booting GENERIC before trying to
228: configure Xen.
229:
1.193 gdt 230: Generally for GENERIC, one sets the console in bootxx_ffsv1 or
231: equivalent, and this is passed on to /boot (where one typically does
232: not set the console). This configuration of bootxx_ffsv1 should also
233: be in place for Xen systems, to allow seeing messages from /boot and
234: use of a keyboard to select a line from the menu. And, one should
235: have a working boot path to GENERIC for rescue situations.
236:
237: With GENERIC, the boot options are passed on to /netbsd, but there is
238: currently no mechanism to pass these via multiboot to the hypervisor.
239: Thus, in addition to configuring the console in the boot blocks, one
240: must also configure it for Xen.
241:
242: By default, the hypervisor (Xen itself) will use some sort of vga
243: device as the console, much like GENERIC uses by default. The vga
244: console is relinquished at the conclusion of hypervisor boot, before
1.194 gdt 245: the dom0 is started. Xen when using a vga console does not process
246: console input.
1.77 gdt 247:
1.193 gdt 248: The hypervisor can be configured to use a serial port console, e.g.
1.157 maxv 249: [[!template id=filecontent name="/boot.cfg" text="""
1.202 gson 250: menu=Xen:load /netbsd-XEN3_DOM0.gz console=com0;multiboot /xen.gz dom0_mem=512M console=com1 com1=9600,8n1
1.152 maxv 251: """]]
1.194 gdt 252: This example uses the first serial port (Xen counts from 1; this is
1.193 gdt 253: what NetBSD would call com0), and sets speed and parity. (The dom0 is
254: then configured to use the same serial port in this example.)
255:
1.194 gdt 256: With the hypervisor configured for a serial console, it can get input,
257: and there is a notion of passing this input to the dom0. \todo
258: Explain why, if Xen has a serial console, the dom0 console is
259: typically also configured to open that same serial port, instead of
260: getting the passthrough input via the xen console.
261:
1.193 gdt 262: One also configures the console for the dom0. While one might expect
263: console=pc to be default, following behavior of GENERIC, a hasty read
264: of the code suggests there is no default and booting without a
265: selected console might lead to a panic. Also, there is merit in
266: explicit configuration. Therefore the standard approach is to place
267: console=pc as part of the load statement for the dom0 kernel, or
268: alternatively console=com0.
269:
270: The NetBSD dom0 kernel will attach xencons(4) (the man page does not
271: exist), but this is not used as a console. It is used to obtain the
272: messages from the hypervisor's console; run `xl dmesg` to see them.
1.191 gdt 273:
274: ### Tuning
275:
1.205 ! gdt 276: In an attempt to add performance, one can also add `dom0_max_vcpus=1
! 277: dom0_vcpus_pin`, to force only one vcpu to be provided (since NetBSD
! 278: dom0 can't use more) and to pin that vcpu to a physical CPU. Xen has
! 279: [many boot
! 280: options](http://xenbits.xenproject.org/docs/4.13-testing/misc/xen-command-line.html),
1.111 wiz 281: and other than dom0 memory and max_vcpus, they are generally not
1.93 gdt 282: necessary.
1.205 ! gdt 283:
1.191 gdt 284: \todo Revisit this advice with current.
285: \todo Explain if anyone has ever actually measured that this helps.
286:
287: ### rc.conf
1.93 gdt 288:
1.186 gdt 289: Ensure that the boot scripts installed in
290: `/usr/pkg/share/examples/rc.d` are in `/etc/rc.d`, either because you
291: have `PKG_RCD_SCRIPTS=yes`, or manually. (This is not special to Xen,
292: but a normal part of pkgsrc usage.)
1.159 maxv 293:
1.186 gdt 294: Set `xencommons=YES` in rc.conf:
1.31 gdt 295:
1.157 maxv 296: [[!template id=filecontent name="/etc/rc.conf" text="""
1.152 maxv 297: xencommons=YES
298: """]]
1.31 gdt 299:
1.187 gdt 300: \todo Recommend for/against xen-watchdog.
301:
1.191 gdt 302: ### Testing
303:
1.158 maxv 304: Now, reboot so that you are running a DOM0 kernel under Xen, rather
305: than GENERIC without Xen.
1.157 maxv 306:
1.158 maxv 307: Once the reboot is done, use `xl` to inspect Xen's boot messages,
1.157 maxv 308: available resources, and running domains. For example:
1.34 gdt 309:
1.153 maxv 310: [[!template id=programlisting text="""
311: # xl dmesg
312: ... xen's boot info ...
313: # xl info
314: ... available memory, etc ...
315: # xl list
316: Name Id Mem(MB) CPU State Time(s) Console
317: Domain-0 0 64 0 r---- 58.1
318: """]]
319:
320: Xen logs will be in /var/log/xen.
1.33 gdt 321:
1.88 gdt 322: ### Issues with xencommons
323:
1.157 maxv 324: `xencommons` starts `xenstored`, which stores data on behalf of dom0 and
1.88 gdt 325: domUs. It does not currently work to stop and start xenstored.
326: Certainly all domUs should be shutdown first, following the sort order
327: of the rc.d scripts. However, the dom0 sets up state with xenstored,
328: and is not notified when xenstored exits, leading to not recreating
329: the state when the new xenstored starts. Until there's a mechanism to
330: make this work, one should not expect to be able to restart xenstored
331: (and thus xencommons). There is currently no reason to expect that
332: this will get fixed any time soon.
1.187 gdt 333: \todo Confirm if this is still true in 2020.
1.82 gdt 334:
1.181 gdt 335: ## Xen-specific NetBSD issues
1.40 gdt 336:
337: There are (at least) two additional things different about NetBSD as a
338: dom0 kernel compared to hardware.
339:
1.191 gdt 340: One is that through NetBSD 9 the module ABI is different because some
341: of the #defines change, so there are separate sets of modules in
1.205 ! gdt 342: /stand. (Further, zfs in Xen is troubled because of differing
! 343: MAXPHYS; see the zfs howto for more.) In NetBSD-current, there is
! 344: only one set of modules.
1.40 gdt 345:
346: The other difference is that XEN3_DOM0 does not have exactly the same
1.205 ! gdt 347: options as GENERIC. While this is roughly agreed to be in large part
! 348: a bug, users should be aware of this and can simply add missing config
1.40 gdt 349: items if desired.
350:
1.187 gdt 351: Finally, there have been occasional reports of trouble with X11
1.205 ! gdt 352: servers in NetBSD as a dom0. Some hardware support is intentionally
! 353: disabled in XEN3_DOM0.
1.187 gdt 354:
355: ## Updating Xen in a dom0
356:
357: Basically, update the xenkernel and xentools packages and copy the new
358: Xen kernel into place, and reboot. This procedure should be usable to
359: update to a new Xen release, but the reader is reminded that having a
360: non-Xen boot methods was recommended earlier.
361:
1.181 gdt 362: ## Updating NetBSD in a dom0
1.15 gdt 363:
364: This is just like updating NetBSD on bare hardware, assuming the new
365: version supports the version of Xen you are running. Generally, one
366: replaces the kernel and reboots, and then overlays userland binaries
1.157 maxv 367: and adjusts `/etc`.
1.15 gdt 368:
1.191 gdt 369: Note that one should update both the non-Xen kernel typically used for
370: rescue purposes, as well as the DOM0 kernel used with Xen.
1.15 gdt 371:
1.187 gdt 372: ## anita (for testing NetBSD)
373:
1.205 ! gdt 374: With a NetBSD dom0, even without any domUs, one can run anita (see
! 375: pkgsrc/misc/py-anita) to test NetBSD releases, by doing (as root,
! 376: because anita must create a domU):
1.187 gdt 377:
378: [[!template id=programlisting text="""
379: anita --vmm=xl test file:///usr/obj/i386/
380: """]]
381:
382: # Unprivileged domains (domU)
1.28 gdt 383:
384: This section describes general concepts about domUs. It does not
1.33 gdt 385: address specific domU operating systems or how to install them. The
1.157 maxv 386: config files for domUs are typically in `/usr/pkg/etc/xen`, and are
1.60 wiki 387: typically named so that the file name, domU name and the domU's host
1.33 gdt 388: name match.
389:
1.111 wiz 390: The domU is provided with CPU and memory by Xen, configured by the
1.33 gdt 391: dom0. The domU is provided with disk and network by the dom0,
392: mediated by Xen, and configured in the dom0.
393:
394: Entropy in domUs can be an issue; physical disks and network are on
395: the dom0. NetBSD's /dev/random system works, but is often challenged.
396:
1.181 gdt 397: ## Config files
1.48 gdt 398:
1.200 gdt 399: See /usr/pkg/share/examples/xen/xlexample* for a very small number of
400: examples for running GNU/Linux.
1.48 gdt 401:
1.205 ! gdt 402: The following is an example minimal domain configuration file. The
! 403: domU serves as a network file server.
1.157 maxv 404:
405: [[!template id=filecontent name="/usr/pkg/etc/xen/foo" text="""
406: name = "domU-id"
407: kernel = "/netbsd-XEN3PAE_DOMU-i386-foo.gz"
408: memory = 1024
409: vif = [ 'mac=aa:00:00:d1:00:09,bridge=bridge0' ]
410: disk = [ 'file:/n0/xen/foo-wd0,0x0,w',
411: 'file:/n0/xen/foo-wd1,0x1,w' ]
412: """]]
1.48 gdt 413:
1.157 maxv 414: The domain will have name given in the `name` setting. The kernel has the
1.48 gdt 415: host/domU name in it, so that on the dom0 one can update the various
1.157 maxv 416: domUs independently. The `vif` line causes an interface to be provided,
1.48 gdt 417: with a specific mac address (do not reuse MAC addresses!), in bridge
418: mode. Two disks are provided, and they are both writable; the bits
419: are stored in files and Xen attaches them to a vnd(4) device in the
1.111 wiz 420: dom0 on domain creation. The system treats xbd0 as the boot device
1.48 gdt 421: without needing explicit configuration.
422:
1.205 ! gdt 423: There is not a type line; that implicitly defines a pv domU.
! 424: Otherwise, one sets type to the lower-case version of the domU type in
! 425: the table above; see later sections.
1.187 gdt 426:
1.163 gson 427: By convention, domain config files are kept in `/usr/pkg/etc/xen`. Note
1.157 maxv 428: that "xl create" takes the name of a config file, while other commands
429: take the name of a domain.
430:
431: Examples of commands:
1.48 gdt 432:
1.157 maxv 433: [[!template id=programlisting text="""
1.163 gson 434: xl create /usr/pkg/etc/xen/foo
435: xl console domU-id
436: xl create -c /usr/pkg/etc/xen/foo
437: xl shutdown domU-id
1.157 maxv 438: xl list
439: """]]
440:
441: Typing `^]` will exit the console session. Shutting down a domain is
1.48 gdt 442: equivalent to pushing the power button; a NetBSD domU will receive a
443: power-press event and do a clean shutdown. Shutting down the dom0
444: will trigger controlled shutdowns of all configured domUs.
445:
1.181 gdt 446: ## CPU and memory
1.33 gdt 447:
1.205 ! gdt 448: A domain is provided with some number of vcpus; any domain can have up
! 449: to the number of CPUs seen by the hypervisor. For a domU, it is
! 450: controlled from the config file by the "vcpus = N" directive. It is
! 451: normal to overcommit vcpus; a 4-core machine machine might well provide 4
! 452: vcpus to each domU. One might also configure fewer vcpus for a domU.
1.48 gdt 453:
454: A domain is provided with memory; this is controlled in the config
455: file by "memory = N" (in megabytes). In the straightforward case, the
456: sum of the the memory allocated to the dom0 and all domUs must be less
1.33 gdt 457: than the available memory.
458:
1.197 gdt 459: ## Balloon driver
460:
461: Xen provides a `balloon` driver, which can be used to let domains use
462: more memory temporarily.
463:
464: \todo Explain how to set up a aystem to use the balloon scheme in a
465: useful manner.
1.28 gdt 466:
1.181 gdt 467: ## Virtual disks
1.28 gdt 468:
1.158 maxv 469: In domU config files, the disks are defined as a sequence of 3-tuples:
470:
471: * The first element is "method:/path/to/disk". Common methods are
1.162 gutterid 472: "file:" for a file-backed vnd, and "phy:" for something that is already
473: a device, such as an LVM logical volume.
1.158 maxv 474:
475: * The second element is an artifact of how virtual disks are passed to
476: Linux, and a source of confusion with NetBSD Xen usage. Linux domUs
477: are given a device name to associate with the disk, and values like
478: "hda1" or "sda1" are common. In a NetBSD domU, the first disk appears
479: as xbd0, the second as xbd1, and so on. However, xl demands a
480: second argument. The name given is converted to a major/minor by
481: calling stat(2) on the name in /dev and this is passed to the domU.
482: In the general case, the dom0 and domU can be different operating
483: systems, and it is an unwarranted assumption that they have consistent
484: numbering in /dev, or even that the dom0 OS has a /dev. With NetBSD
485: as both dom0 and domU, using values of 0x0 for the first disk and 0x1
486: for the second works fine and avoids this issue. For a GNU/Linux
487: guest, one can create /dev/hda1 in /dev, or to pass 0x301 for
488: /dev/hda1.
1.48 gdt 489:
1.158 maxv 490: * The third element is "w" for writable disks, and "r" for read-only
491: disks.
492:
493: Example:
494: [[!template id=filecontent name="/usr/pkg/etc/xen/foo" text="""
495: disk = [ 'file:/n0/xen/foo-wd0,0x0,w' ]
496: """]]
1.28 gdt 497:
1.127 gdt 498: Note that NetBSD by default creates only vnd[0123]. If you need more
499: than 4 total virtual disks at a time, run e.g. "./MAKEDEV vnd4" in the
500: dom0.
501:
1.187 gdt 502: ## Virtual Networking
1.28 gdt 503:
1.111 wiz 504: Xen provides virtual Ethernets, each of which connects the dom0 and a
1.46 gdt 505: domU. For each virtual network, there is an interface "xvifN.M" in
1.158 maxv 506: the dom0, and a matching interface xennetM (NetBSD name) in domU index N.
507: The interfaces behave as if there is an Ethernet with two
1.111 wiz 508: adapters connected. From this primitive, one can construct various
1.46 gdt 509: configurations. We focus on two common and useful cases for which
510: there are existing scripts: bridging and NAT.
1.28 gdt 511:
1.48 gdt 512: With bridging (in the example above), the domU perceives itself to be
513: on the same network as the dom0. For server virtualization, this is
514: usually best. Bridging is accomplished by creating a bridge(4) device
515: and adding the dom0's physical interface and the various xvifN.0
516: interfaces to the bridge. One specifies "bridge=bridge0" in the domU
517: config file. The bridge must be set up already in the dom0; an
518: example /etc/ifconfig.bridge0 is:
1.46 gdt 519:
1.157 maxv 520: [[!template id=filecontent name="/etc/ifconfig.bridge0" text="""
521: create
522: up
523: !brconfig bridge0 add wm0
524: """]]
1.28 gdt 525:
526: With NAT, the domU perceives itself to be behind a NAT running on the
527: dom0. This is often appropriate when running Xen on a workstation.
1.48 gdt 528: TODO: NAT appears to be configured by "vif = [ '' ]".
1.28 gdt 529:
1.49 gdt 530: The MAC address specified is the one used for the interface in the new
1.53 gdt 531: domain. The interface in dom0 will use this address XOR'd with
1.49 gdt 532: 00:00:00:01:00:00. Random MAC addresses are assigned if not given.
533:
1.187 gdt 534: ## Starting domains automatically
1.28 gdt 535:
1.158 maxv 536: To start domains `domU-netbsd` and `domU-linux` at boot and shut them
537: down cleanly on dom0 shutdown, add the following in rc.conf:
1.28 gdt 538:
1.158 maxv 539: [[!template id=filecontent name="/etc/rc.conf" text="""
540: xendomains="domU-netbsd domU-linux"
541: """]]
1.28 gdt 542:
1.188 gdt 543: # domU setup for specific systems
1.14 gdt 544:
545: Creating domUs is almost entirely independent of operating system. We
1.188 gdt 546: have already presented the basics of config files in the previous system.
547:
548: Of course, this section presumes that you have a working dom0.
1.14 gdt 549:
1.187 gdt 550: ## Creating a NetBSD PV domU
551:
1.49 gdt 552: See the earlier config file, and adjust memory. Decide on how much
1.162 gutterid 553: storage you will provide, and prepare it (file or LVM).
1.49 gdt 554:
1.111 wiz 555: While the kernel will be obtained from the dom0 file system, the same
1.49 gdt 556: file should be present in the domU as /netbsd so that tools like
557: savecore(8) can work. (This is helpful but not necessary.)
558:
1.188 gdt 559: The kernel must be specifically built for Xen, to use PV interfacesas
560: a domU. NetBSD release builds provide the following kernels:
1.49 gdt 561:
562: i386 XEN3PAE_DOMU
1.95 gdt 563: amd64 XEN3_DOMU
1.5 mspo 564:
1.49 gdt 565: This will boot NetBSD, but this is not that useful if the disk is
1.188 gdt 566: empty. One approach is to unpack sets onto the disk outside of Xen
1.49 gdt 567: (by mounting it, just as you would prepare a physical disk for a
568: system you can't run the installer on).
569:
570: A second approach is to run an INSTALL kernel, which has a miniroot
571: and can load sets from the network. To do this, copy the INSTALL
572: kernel to / and change the kernel line in the config file to:
1.5 mspo 573:
1.49 gdt 574: kernel = "/home/bouyer/netbsd-INSTALL_XEN3_DOMU"
1.5 mspo 575:
1.163 gson 576: Then, start the domain as "xl create -c configfile".
1.1 mspo 577:
1.49 gdt 578: Alternatively, if you want to install NetBSD/Xen with a CDROM image, the following
579: line should be used in the config file.
1.1 mspo 580:
1.3 mspo 581: disk = [ 'phy:/dev/wd0e,0x1,w', 'phy:/dev/cd0a,0x2,r' ]
1.1 mspo 582:
583: After booting the domain, the option to install via CDROM may be
1.49 gdt 584: selected. The CDROM device should be changed to `xbd1d`.
1.1 mspo 585:
1.188 gdt 586: Once done installing, "halt -p" the new domain (don't reboot or halt:
1.49 gdt 587: it would reload the INSTALL_XEN3_DOMU kernel even if you changed the
588: config file), switch the config file back to the XEN3_DOMU kernel,
589: and start the new domain again. Now it should be able to use "root on
1.188 gdt 590: xbd0a" and you should have a functional NetBSD domU.
1.1 mspo 591:
1.49 gdt 592: TODO: check if this is still accurate.
1.1 mspo 593: When the new domain is booting you'll see some warnings about *wscons*
594: and the pseudo-terminals. These can be fixed by editing the files
1.5 mspo 595: `/etc/ttys` and `/etc/wscons.conf`. You must disable all terminals in
596: `/etc/ttys`, except *console*, like this:
1.1 mspo 597:
1.3 mspo 598: console "/usr/libexec/getty Pc" vt100 on secure
599: ttyE0 "/usr/libexec/getty Pc" vt220 off secure
600: ttyE1 "/usr/libexec/getty Pc" vt220 off secure
601: ttyE2 "/usr/libexec/getty Pc" vt220 off secure
602: ttyE3 "/usr/libexec/getty Pc" vt220 off secure
1.1 mspo 603:
1.5 mspo 604: Finally, all screens must be commented out from `/etc/wscons.conf`.
1.1 mspo 605:
1.192 gdt 606: One should also run `powerd` in a domU, but this should not need
607: configuring. With powerd, the domain will run a controlled shutdown
608: if `xl shutdown -R` or `xl shutdown -H` is used on the dom0, via
609: receiving a synthetic `power button pressed` signal. In 9 and
610: current, `powerd` is run by default under Xen kernels (or if ACPI is
611: present), and it can be added to rc.conf if not.
1.1 mspo 612:
1.92 gdt 613: It is not strictly necessary to have a kernel (as /netbsd) in the domU
1.111 wiz 614: file system. However, various programs (e.g. netstat) will use that
1.92 gdt 615: kernel to look up symbols to read from kernel virtual memory. If
616: /netbsd is not the running kernel, those lookups will fail. (This is
617: not really a Xen-specific issue, but because the domU kernel is
618: obtained from the dom0, it is far more likely to be out of sync or
619: missing with Xen.)
620:
1.187 gdt 621: Note that NetBSD by default creates only xbd[0123]. If you need more
622: virtual disks in a domU, run e.g. "./MAKEDEV xbd4" in the domU.
623:
1.196 gdt 624: ## Creating a Linux PV domU
1.1 mspo 625:
626: Creating unprivileged Linux domains isn't much different from
627: unprivileged NetBSD domains, but there are some details to know.
628:
629: First, the second parameter passed to the disk declaration (the '0x1' in
630: the example below)
631:
1.3 mspo 632: disk = [ 'phy:/dev/wd0e,0x1,w' ]
1.1 mspo 633:
634: does matter to Linux. It wants a Linux device number here (e.g. 0x300
1.49 gdt 635: for hda). Linux builds device numbers as: (major \<\< 8 + minor).
636: So, hda1 which has major 3 and minor 1 on a Linux system will have
637: device number 0x301. Alternatively, devices names can be used (hda,
638: hdb, ...) as xentools has a table to map these names to devices
639: numbers. To export a partition to a Linux guest we can use:
1.1 mspo 640:
1.49 gdt 641: disk = [ 'phy:/dev/wd0e,0x300,w' ]
642: root = "/dev/hda1 ro"
1.1 mspo 643:
644: and it will appear as /dev/hda on the Linux system, and be used as root
645: partition.
646:
1.49 gdt 647: To install the Linux system on the partition to be exported to the
648: guest domain, the following method can be used: install
649: sysutils/e2fsprogs from pkgsrc. Use mke2fs to format the partition
650: that will be the root partition of your Linux domain, and mount it.
651: Then copy the files from a working Linux system, make adjustments in
652: `/etc` (fstab, network config). It should also be possible to extract
653: binary packages such as .rpm or .deb directly to the mounted partition
654: using the appropriate tool, possibly running under NetBSD's Linux
1.111 wiz 655: emulation. Once the file system has been populated, umount it. If
656: desirable, the file system can be converted to ext3 using tune2fs -j.
1.49 gdt 657: It should now be possible to boot the Linux guest domain, using one of
658: the vmlinuz-\*-xenU kernels available in the Xen binary distribution.
1.1 mspo 659:
1.111 wiz 660: To get the Linux console right, you need to add:
1.1 mspo 661:
1.3 mspo 662: extra = "xencons=tty1"
1.1 mspo 663:
1.111 wiz 664: to your configuration since not all Linux distributions auto-attach a
1.1 mspo 665: tty to the xen console.
666:
1.180 gdt 667: ## Creating a NetBSD HVM domU
668:
1.196 gdt 669: Use type='hvm', probably. Use a GENERIC kernel within the disk image.
1.180 gdt 670:
671: ## Creating a NetBSD PVH domU
672:
1.196 gdt 673: This only works with a current kernel in the domU.
1.180 gdt 674:
1.196 gdt 675: Use type='pvh'. Probably, use a GENERIC kernel within the disk image,
676: which in current has PV support.
677:
678: \todo Verify.
679:
680: \todo Verify if one can have current PVH domU on a 9 dom0.
1.180 gdt 681:
1.187 gdt 682: ## Creating a Solaris domU
1.1 mspo 683:
1.50 gdt 684: See possibly outdated
685: [Solaris domU instructions](/ports/xen/howto-solaris/).
1.5 mspo 686:
1.187 gdt 687: ## PCI passthrough: Using PCI devices in guest domains
1.1 mspo 688:
1.180 gdt 689: NB: PCI passthrough only works on some Xen versions and as of 2020 it
1.196 gdt 690: is not clear that it works on any version in pkgsrc. \todo Reports
1.180 gdt 691: confirming or denying this notion should be sent to port-xen@.
692:
1.53 gdt 693: The dom0 can give other domains access to selected PCI
1.52 gdt 694: devices. This can allow, for example, a non-privileged domain to have
695: access to a physical network interface or disk controller. However,
696: keep in mind that giving a domain access to a PCI device most likely
697: will give the domain read/write access to the whole physical memory,
698: as PCs don't have an IOMMU to restrict memory access to DMA-capable
1.53 gdt 699: device. Also, it's not possible to export ISA devices to non-dom0
1.52 gdt 700: domains, which means that the primary VGA adapter can't be exported.
701: A guest domain trying to access the VGA registers will panic.
702:
1.53 gdt 703: If the dom0 is NetBSD, it has to be running Xen 3.1, as support has
1.52 gdt 704: not been ported to later versions at this time.
705:
706: For a PCI device to be exported to a domU, is has to be attached to
707: the "pciback" driver in dom0. Devices passed to the dom0 via the
708: pciback.hide boot parameter will attach to "pciback" instead of the
709: usual driver. The list of devices is specified as "(bus:dev.func)",
1.5 mspo 710: where bus and dev are 2-digit hexadecimal numbers, and func a
711: single-digit number:
1.1 mspo 712:
1.52 gdt 713: pciback.hide=(00:0a.0)(00:06.0)
1.1 mspo 714:
1.52 gdt 715: pciback devices should show up in the dom0's boot messages, and the
1.5 mspo 716: devices should be listed in the `/kern/xen/pci` directory.
1.1 mspo 717:
1.52 gdt 718: PCI devices to be exported to a domU are listed in the "pci" array of
719: the domU's config file, with the format "0000:bus:dev.func".
1.1 mspo 720:
1.52 gdt 721: pci = [ '0000:00:06.0', '0000:00:0a.0' ]
1.1 mspo 722:
1.52 gdt 723: In the domU an "xpci" device will show up, to which one or more pci
1.111 wiz 724: buses will attach. Then the PCI drivers will attach to PCI buses as
1.52 gdt 725: usual. Note that the default NetBSD DOMU kernels do not have "xpci"
726: or any PCI drivers built in by default; you have to build your own
727: kernel to use PCI devices in a domU. Here's a kernel config example;
728: note that only the "xpci" lines are unusual.
729:
730: include "arch/i386/conf/XEN3_DOMU"
731:
1.111 wiz 732: # Add support for PCI buses to the XEN3_DOMU kernel
1.52 gdt 733: xpci* at xenbus ?
734: pci* at xpci ?
735:
736: # PCI USB controllers
737: uhci* at pci? dev ? function ? # Universal Host Controller (Intel)
738:
739: # USB bus support
740: usb* at uhci?
741:
742: # USB Hubs
743: uhub* at usb?
744: uhub* at uhub? port ? configuration ? interface ?
745:
746: # USB Mass Storage
747: umass* at uhub? port ? configuration ? interface ?
748: wd* at umass?
749: # SCSI controllers
750: ahc* at pci? dev ? function ? # Adaptec [23]94x, aic78x0 SCSI
751:
752: # SCSI bus support (for both ahc and umass)
753: scsibus* at scsi?
754:
755: # SCSI devices
756: sd* at scsibus? target ? lun ? # SCSI disk drives
757: cd* at scsibus? target ? lun ? # SCSI CD-ROM drives
1.1 mspo 758:
759:
1.189 gdt 760: # Miscellaneous Information
1.173 gdt 761:
1.189 gdt 762: ## Nesting under Linux KVM
763:
1.205 ! gdt 764: It is possible to run Xen and a NetBSD dom0 under Linux KVM. One
1.189 gdt 765: can enable virtio in the dom0 for greater speed.
766:
1.205 ! gdt 767: ## Nesting under qemu
! 768:
! 769: It is possible to run Xen and a NetBSD dom0 under qemu on NetBSD, and
! 770: also with nvmm.
! 771: \todo Check this.
! 772:
1.189 gdt 773: ## Other nesting
774:
775: In theory, any full emulation should be able to run Xen and a NetBSD
776: dom0. The HOWTO does not currently have information about Xen XVM
1.205 ! gdt 777: mode, Virtualbox, etc.
1.189 gdt 778:
779: ## NetBSD 5 as domU
1.173 gdt 780:
1.176 gdt 781: [NetBSD 5 is known to panic.](http://mail-index.netbsd.org/port-xen/2018/04/17/msg009181.html)
1.175 gdt 782: (However, NetBSD 5 systems should be updated to a supported version.)
1.173 gdt 783:
784: # NetBSD as a domU in a VPS
1.28 gdt 785:
786: The bulk of the HOWTO is about using NetBSD as a dom0 on your own
787: hardware. This section explains how to deal with Xen in a domU as a
788: virtual private server where you do not control or have access to the
1.70 gdt 789: dom0. This is not intended to be an exhaustive list of VPS providers;
790: only a few are mentioned that specifically support NetBSD.
1.28 gdt 791:
1.52 gdt 792: VPS operators provide varying degrees of access and mechanisms for
793: configuration. The big issue is usually how one controls which kernel
1.111 wiz 794: is booted, because the kernel is nominally in the dom0 file system (to
795: which VPS users do not normally have access). A second issue is how
1.70 gdt 796: to install NetBSD.
1.52 gdt 797: A VPS user may want to compile a kernel for security updates, to run
798: npf, run IPsec, or any other reason why someone would want to change
799: their kernel.
800:
1.111 wiz 801: One approach is to have an administrative interface to upload a kernel,
1.68 gdt 802: or to select from a prepopulated list. Other approaches are pygrub
1.59 gdt 803: (deprecated) and pvgrub, which are ways to have a bootloader obtain a
1.111 wiz 804: kernel from the domU file system. This is closer to a regular physical
1.59 gdt 805: computer, where someone who controls a machine can replace the kernel.
1.52 gdt 806:
1.74 gdt 807: A second issue is multiple CPUs. With NetBSD 6, domUs support
808: multiple vcpus, and it is typical for VPS providers to enable multiple
809: CPUs for NetBSD domUs.
810:
1.180 gdt 811: ## Complexities due to Xen changes
812:
813: Xen has many security advisories and people running Xen systems make
814: different choices.
815:
816: ### stub domains
817:
1.205 ! gdt 818: Some (Linux) dom0 systems use something called "stub domains" to
1.180 gdt 819: isolate qemu from the dom0 system, as a security and reliabilty
820: mechanism when running HVM domUs. Somehow, NetBSD's GENERIC kernel
821: ends up using PIO for disks rather than DMA. Of course, all of this
822: is emulated, but emulated PIO is unusably slow. This problem is not
823: currently understood.
824:
825: ### Grant tables
826:
827: There are multiple versions of using grant tables, and some security
1.205 ! gdt 828: advisories have suggested disabling some versions. NetBSD through 9
! 829: uses version 1 and NetBSD-current uses version 2. This can lead to
1.180 gdt 830: "NetBSD current doesn't run on hosting provider X" situations.
831:
832: \todo Explain better.
833:
1.181 gdt 834: ## Boot methods
835:
836: ### pvgrub
1.59 gdt 837:
838: pvgrub is a version of grub that uses PV operations instead of BIOS
839: calls. It is booted from the dom0 as the domU kernel, and then reads
1.111 wiz 840: /grub/menu.lst and loads a kernel from the domU file system.
1.59 gdt 841:
1.70 gdt 842: It appears that [grub's FFS
843: code](http://xenbits.xensource.com/hg/xen-unstable.hg/file/bca284f67702/tools/libfsimage/ufs/fsys_ufs.c)
844: does not support all aspects of modern FFS, but there are also reports
1.205 ! gdt 845: that FFSv2 works fine.
1.59 gdt 846:
1.181 gdt 847: ### pygrub
1.168 wiki 848:
1.205 ! gdt 849: As of 2014, pygrub seems to be of mostly historical interest. As of
! 850: 2021, the section should perhaps be outright deleted.
! 851:
1.168 wiki 852: pygrub runs in the dom0 and looks into the domU file system. This
853: implies that the domU must have a kernel in a file system in a format
854: known to pygrub.
855:
856: pygrub doesn't seem to work to load Linux images under NetBSD dom0,
1.205 ! gdt 857: and is inherently less secure than pvgrub due to running inside
! 858: dom0. For both these reasons, pygrub should not be used, and is only
! 859: still present so that historical DomU images using it still work.
! 860:
! 861: ## Specific Providers
! 862:
! 863: The intent is to list providers only if they document support for
! 864: running NetBSD, and to point to their resources briefly.
1.168 wiki 865:
1.205 ! gdt 866: ### panix.com
1.168 wiki 867:
1.205 ! gdt 868: [Panix](http://www.panix.com/) provides NetBSD as an OS option. See
! 869: https://www.panix.com/v-colo/nupgrade.html for some information.
! 870: Users can use pvgrub. Panix reports that pvgrub works with FFsv2 with
! 871: 16K/2K and 32K/4K block/frag sizes (and hence with defaults from
! 872: "newfs -O 2"). See [Panix's pvgrub
! 873: page](http://www.panix.com/v-colo/grub.html) which describes how to
! 874: boot NetBSD.
! 875:
! 876: ### prgmr.com
! 877:
! 878: [prgmr.com](http://prgmr.com/) provides released versions of
! 879: NetBSD/amd64 as installation options. Users can use pvgrub to boot
! 880: their own kernel, and a small FAT32 /boot is encouraged. See the
! 881: [prgmr.com NetBSD
! 882: HOWTO](http://wiki.prgmr.com/mediawiki/index.php/NetBSD_as_a_DomU)
! 883: (which is in need of updating).
1.181 gdt 884:
885: ### Amazon
1.59 gdt 886:
1.143 wiki 887: See the [Amazon EC2 page](/amazon_ec2/).
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