xref: /freebsd/usr.bin/mkimg/mkimg.1 (revision 0b3105a37d7adcadcb720112fed4dc4e8040be99)
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25.\" $FreeBSD$
26.\"
27.Dd August 7, 2015
28.Dt MKIMG 1
29.Os
30.Sh NAME
31.Nm mkimg
32.Nd "utility to make disk images"
33.Sh SYNOPSIS
34.Nm
35.Op Fl H Ar heads
36.Op Fl P Ar blksz
37.Op Fl S Ar secsz
38.Op Fl T Ar tracksz
39.Op Fl b Ar bootcode
40.Op Fl c Ar capacity
41.Op Fl f Ar format
42.Op Fl o Ar outfile
43.Op Fl v
44.Op Fl y
45.Op Fl s Ar scheme Op Fl p Ar partition ...
46.Nm
47.Ar --formats | --schemes | --version
48.Sh DESCRIPTION
49The
50.Nm
51utility creates a disk image from the raw partition contents specified with
52the
53.Ar partition
54argument(s) and using the partitioning scheme specified with the
55.Ar scheme
56argument.
57The disk image is written to
58.Ar stdout
59by default or the file specified with the
60.Ar outfile
61argument.
62The image file is a raw disk image by default, but the format of the
63image file can be specified with the
64.Ar format
65argument.
66.Pp
67The disk image can be made bootable by specifying the scheme-specific boot
68block contents with the
69.Ar bootcode
70argument and,
71depending on the scheme,
72with a boot partition.
73The contents of such a boot partition is provided like any other partition
74and the
75.Nm
76utility does not treat it any differently from other partitions.
77.Pp
78Some partitioning schemes need a disk geometry and for those the
79.Nm
80utility accepts the
81.Ar tracksz
82and
83.Ar heads
84arguments, specifying the number of sectors per track and the number of
85heads per cylinder (resp.)
86.Pp
87Both the logical and physical sector size can be specified and for that the
88.Nm
89utility
90accepts the
91.Ar secsz
92and
93.Ar blksz
94arguments.
95The
96.Ar secsz
97argument is used to specify the logical sector size.
98This is the sector size reported by a disk when queried for its capacity.
99Modern disks use a larger sector size internally,
100referred to as block size by the
101.Nm
102utility and this can be specified by the
103.Ar blksz
104argument.
105The
106.Nm
107utility will use the (physical) block size to determine the start of
108partitions and to round the size of the disk image.
109.Pp
110The
111.Fl c
112option can be used to specify a minimal capacity for the disk image.
113Use this option without the
114.Fl s
115and
116.Fl p
117options to create an empty disk image with the given (virtual) size.
118An empty partition table can be written to the disk when specifying a
119partitioning scheme with the
120.Fl s
121option, but without specifying any partitions.
122When the size required to for all the partitions is larger than the
123given capacity, then the disk image will be larger than the capacity
124given.
125.Pp
126The
127.Fl v
128option increases the level of output that the
129.Nm
130utility prints.
131.Pp
132The
133.Fl y
134option is used for testing purposes only and is not to be used in production.
135When present, the
136.Nm
137utility will generate predictable values for Universally Unique Identifiers
138(UUIDs) and time stamps so that consecutive runs of the
139.Nm
140utility will create images that are identical.
141.Pp
142A set of long options exist to query about the
143.Nm
144utility itself.
145Options in this set should be given by themselves because the
146.Nm
147utility exits immediately after providing the requested information.
148The version of the
149.Nm
150utility is printed when the
151.Ar --version
152option is given.
153The list of supported output formats is printed when the
154.Ar --formats
155option is given and the list of supported partitioning schemes is printed
156when the
157.Ar --schemes
158option is given.
159Both the format and scheme lists a space-separated lists for easy handling
160in scripts.
161.Pp
162For a more descriptive list of supported partitioning schemes or supported
163output format, or for a detailed description of how to specify partitions,
164run the
165.Nm
166utility without any arguments.
167This will print a usage message with all the necessary details.
168.Sh DISK FORMATS
169The
170.Nm
171utility supports a number of output file formats.
172A short description of these is given below.
173.Ss QCOW and QCOW2
174QCOW stands for "QEMU Copy On Write".
175It's a sparse file format akin to VHD and VMDK and QCOW represents the
176first version.
177QCOW2 represents version 2 of the file format.
178Version 2 is not backward compatible with version 1 and adds support for
179snapshots among other things.
180The QCOW file formats are natively supported by QEMU and Xen.
181To write QCOW, specify
182.Fl f Ar qcow
183on the command line.
184To write version 2 QCOW, specify
185.Fl f Ar qcow2
186on the command line.
187The preferred file extension is ".qcow" and ".qcow2" for QCOW and QCOW2
188(resp.), but ".qcow" is sometimes used for version 2 files as well.
189.Ss RAW file format
190This file format is a sector by sector representation of an actual disk.
191There is no extra information that describes or relates to the format
192itself. The size of the file is the size of the (virtual) disk.
193This file format is suitable for being copyied onto a disk with utilities
194like
195.Nm dd .
196To write a raw disk file, either omit the
197.Fl f
198option, or specify
199.Fl f Ar raw
200on the command line.
201The preferred file extension is one of ".img" or ".raw", but there's no
202real convention for it.
203.Ss Dynamic VHD and Fixed VHD
204Microsoft's "Virtual Hard Disk" file formats.
205The dynamic format is a sparse format akin to QCOW and VMDK.
206The fixed format is effectively a raw format with a footer appended to the
207file and as such it's often indistinguishable from the raw format.
208The fixed file format has been added to support Microsoft's Azure platform
209and due to inconsistencies in interpretation of the footer is not compatible
210with utilities like
211.Nm qemu
212when it is specifically instructed to interpreted the file as a VHD file.
213By default
214.Nm qemu
215will treat the file as a raw disk file, which mostly works fine.
216To have
217.Nm
218create a dynamic VHD file, specify
219.Fl f Ar vhd
220on the command line.
221To create a fixed VHD file for use by Azure, specify
222.Fl f Ar vhdf
223on the command line.
224The preferred file extension is ".vhd".
225.Ss VMDK
226VMware's "Virtual Machine Disk" file format.
227It's a sparse file format akin to QCOW and VHD and supported by many
228virtualization solutions.
229To create a VMDK file, specify
230.Fl f Ar vmdk
231on the command line.
232The preferred file extension is ".vmdk".
233.Pp
234Not all virtualization solutions support all file formats, but often those
235virtualization environments have utilities to convert from one format to
236another.
237Note however that conversion may require that the virtual disk size is
238changed to match the constraints of the output format and this may invalidate
239the contents of the disk image.
240For example, the GUID Partition Table (GPT) scheme has a header in the last
241sector on the disk.
242When changing the disk size, the GPT must be changed so that the last header
243is moved accordingly.
244This is typically not part of the conversion process.
245If possible, use an output format specifically for the environment in which
246the file is intended to be used.
247.Sh ENVIRONMENT
248.Bl -tag -width "TMPDIR" -compact
249.It Ev TMPDIR
250Directory to put temporary files in; default is
251.Pa /tmp .
252.El
253.Sh EXAMPLES
254To create a bootable disk image that is partitioned using the GPT scheme and
255containing a root file system that was previously created using
256.Xr makefs
257and also containing a swap partition, run the
258.Nm
259utility as follows:
260.Dl % mkimg -s gpt -b /boot/pmbr -p freebsd-boot:=/boot/gptboot \
261-p freebsd-ufs:=root-file-system.ufs -p freebsd-swap::1G \
262-o gpt.img
263.Pp
264The command line given above results in a raw image file.
265This is because no output format was given.
266To create a VMDK image for example, add the
267.Fl f Ar vmdk
268argument to the
269.Nm
270utility and name the output file accordingly.
271.Pp
272A nested partitioning scheme is created by running the
273.Nm
274utility twice.
275The output of the first will be fed as the contents of a partition to the
276second.
277This can be done using a temporary file, like so:
278.Dl % mkimg -s bsd -b /boot/boot -p freebsd-ufs:=root-file-system.ufs \
279-p freebsd-swap::1G -o /tmp/bsd.img
280.Dl % mkimg -s mbr -b /boot/mbr -p freebsd:=/tmp/bsd.img -o mbr-bsd.img
281.Pp
282Alternatively, the
283.Nm
284utility can be run in a cascaded fashion, whereby the output of the
285first is fed directly into the second.
286To do this, run the
287.Nm
288utility as follows:
289.Dl % mkimg -s mbr -b /boot/mbr -p freebsd:-'mkimg -s bsd -b /boot/boot \
290-p freebsd-ufs:=root-file-system.ufs -p freebsd-swap::1G' -o mbr-bsd.img
291.Pp
292To accommodate the need to have partitions named or numbered in a certain
293way, the
294.Nm
295utility allows for the specification of empty partitions.
296For example, to create an image that is compatible with partition layouts
297found in
298.Pa /etc/disktab ,
299the 'd' partition often needs to be skipped.
300This is accomplished by inserting an unused partition after the first 2
301partition specifications.
302It is worth noting at this time that the BSD scheme will automatically
303skip the 'c' partition by virtue of it referring to the entire disk.
304To create an image that is compatible with the qp120at disk, use the
305.Nm
306utility as follows:
307.Dl % mkimg -s bsd -b /boot/boot -p freebsd-ufs:=root-file-system.ufs \
308-p freebsd-swap::20M -p- -p- -p- -p- -p freebsd-ufs:=usr-file-system.ufs \
309-o bsd.img
310.Pp
311For partitioning schemes that feature partition labels, the
312.Nm
313utility supports assigning labels to the partitions specified.
314In the following example the file system partition is labeled as 'backup':
315.Dl % mkimg -s gpt -p freebsd-ufs/backup:=file-system.ufs -o gpt.img
316.Sh SEE ALSO
317.Xr dd 1 ,
318.Xr gpart 8 ,
319.Xr makefs 8 ,
320.Xr mdconfig 8 ,
321.Xr newfs 8
322.Sh HISTORY
323The
324.Nm
325utility first appeared in
326.Fx 10.1 .
327.Sh AUTHORS
328The
329.Nm
330utility and manpage were written by
331.An Marcel Moolenaar Aq Mt marcelm@juniper.net .
332