OPTIONS
The following options are supported:
-a file [
device]
Add
file as a block device.
If
device is not specified, an available device is picked.
If
device is specified,
lofiadm attempts to assign it to
file.
device must be available or
lofiadm will fail. The ability to specify a device is provided for use in scripts that wish to reestablish a particular set of associations.
-C {
gzip |
gzip-N |
lzma}
Compress the file with the specified compression algorithm.
The
gzip compression algorithm uses the same compression as the open-source
gzip command. You can specify the
gzip level by using the value
gzip-N where
N is 6 (fast) or 9 (best compression ratio). Currently,
gzip, without a number, is equivalent to
gzip-6 (which is also the default for the
gzip command).
lzma stands for the LZMA (Lempel-Ziv-Markov) compression algorithm.
Note that you cannot write to a compressed file, nor can you mount a compressed file read/write.
-d file |
device
Remove an association by file or device name, if the associated block device is not busy, and deallocates the block device.
-o
If the -o option is specified lofiadm will prompt for a passphrase once.
-r
If the -r option is specified before the -a option, the device will be opened read-only.
-s segment_size
The segment size to use to divide the file being compressed. segment_size can be an integer multiple of 512.
-U file
Uncompress a compressed file.
The following options are used when the file is encrypted:
-c crypto_algorithm
Select the encryption algorithm. The algorithm must be specified when encryption is enabled because the algorithm is not stored in the disk image.
If none of
-e,
-k, or
-T is specified,
lofiadm prompts for a passphrase, with a minimum length of eight characters, to be entered . The passphrase is used to derive a symmetric encryption key using PKCS#5 PBKD2.
-k raw_key_file |
wrapped_key_file
Path to raw or wrapped symmetric encryption key. If a PKCS#11 object is also given with the -T option, then the key is wrapped by that object. If -T is not specified, the key is used raw.
-T token_key
The key in a PKCS#11 token to use for the encryption or for unwrapping the key file.
If
-k is also specified,
-T identifies the unwrapping key, which must be an RSA private key.
-e
Generate an ephemeral symmetric encryption key.
EXAMPLES
Example 1 Mounting an Existing CD-ROM Image
You should ensure that Solaris understands the image before creating the
CD.
lofi allows you to mount the image and see if it works.
This example mounts an existing
CD-ROM image (
sparc.iso), of the
Red Hat 6.0 CD which was downloaded from the Internet. It was created with the
mkisofs utility from the Internet.
Use
lofiadm to attach a block device to it:
#
lofiadm -a /home/mike_s/RH6.0/sparc.iso
/dev/lofi/1
lofiadm picks the device and prints the device name to the standard output. You can run
lofiadm again by issuing the following command:
#
lofiadm
Block Device File Options
/dev/lofi/1 /home/mike_s/RH6.0/sparc.iso -
Or, you can give it one name and ask for the other, by issuing the following command:
#
lofiadm /dev/lofi/1
/home/mike_s/RH6.0/sparc.iso
Use the
mount command to mount the image:
#
mount -F hsfs -o ro /dev/lofi/1 /mnt
Check to ensure that Solaris understands the image:
#
df -k /mnt
Filesystem kbytes used avail capacity Mounted on
/dev/lofi/1 512418 512418 0 100% /mnt
#
ls /mnt
./ RedHat/ doc/ ls-lR rr_moved/
../ TRANS.TBL dosutils/ ls-lR.gz sbin@
.buildlog bin@ etc@ misc/ tmp/
COPYING boot/ images/ mnt/ usr@
README boot.cat* kernels/ modules/
RPM-PGP-KEY dev@ lib@ proc/
Solaris can mount the CD-ROM image, and understand the filenames. The image was created properly, and you can now create the
CD-ROM with confidence.
As a final step, unmount and detach the images:
#
umount /mnt
#
lofiadm -d /dev/lofi/1
#
lofiadm
Block Device File Options
Example 2 Mounting a Floppy Image
This is similar to the first example.
Using
lofi to help you mount files that contain floppy images is helpful if a floppy disk contains a file that you need, but the machine which you are on does not have a floppy drive. It is also helpful if you do not want to take the time to use the
dd command to copy the image to a floppy.
This is an example of getting to
MDB floppy for Solaris on an x86 platform:
#
lofiadm -a /export/s28/MDB_s28x_wos/latest/boot.3
/dev/lofi/1
#
mount -F pcfs /dev/lofi/1 /mnt
#
ls /mnt
./ COMMENT.BAT* RC.D/ SOLARIS.MAP*
../ IDENT* REPLACE.BAT* X/
APPEND.BAT* MAKEDIR.BAT* SOLARIS/
#
umount /mnt
#
lofiadm -d /export/s28/MDB_s28x_wos/latest/boot.3
Example 3 Making a
UFS Filesystem on a File
Making a
UFS filesystem on a file can be useful, particularly if a test suite requires a scratch filesystem. It can be painful (or annoying) to have to repartition a disk just for the test suite, but you do not have to. You can
newfs a file with
lofi
Create the file:
#
mkfile 35m /export/home/test
Attach it to a block device. You also get the character device that
newfs requires, so
newfs that:
#
lofiadm -a /export/home/test
/dev/lofi/1
#
newfs /dev/rlofi/1
newfs: construct a new file system /dev/rlofi/1: (y/n)?
y
/dev/rlofi/1: 71638 sectors in 119 cylinders of 1 tracks, 602 sectors
35.0MB in 8 cyl groups (16 c/g, 4.70MB/g, 2240 i/g)
super-block backups (for fsck -F ufs -o b=#) at:
32, 9664, 19296, 28928, 38560, 48192, 57824, 67456,
Note that
ufs might not be able to use the entire file. Mount and use the filesystem:
#
mount /dev/lofi/1 /mnt
#
df -k /mnt
Filesystem kbytes used avail capacity Mounted on
/dev/lofi/1 33455 9 30101 1% /mnt
#
ls /mnt
./ ../ lost+found/
#
umount /mnt
#
lofiadm -d /dev/lofi/1
Example 4 Creating a PC (FAT) File System on a Unix File
The following series of commands creates a
FAT file system on a Unix file. The file is associated with a block device created by
lofiadm.
#
mkfile 10M /export/test/testfs
#
lofiadm -a /export/test testfs
/dev/lofi/1
Note use of rlofi
, not lofi
, in following command.
#
mkfs -F pcfs -o nofdisk,size=20480 /dev/rlofi/1
Construct a new FAT file system on /dev/rlofi/1: (y/n)? y
#
mount -F pcfs /dev/lofi/1 /mnt
#
cd /mnt
#
df -k .
Filesystem kbytes used avail capacity Mounted on
/dev/lofi/1 10142 0 10142 0% /mnt
Example 5 Compressing an Existing CD-ROM Image
The following example illustrates compressing an existing CD-ROM image (
solaris.iso), verifying that the image is compressed, and then uncompressing it.
#
lofiadm -C gzip /export/home/solaris.iso
Use
lofiadm to attach a block device to it:
#
lofiadm -a /export/home/solaris.iso
/dev/lofi/1
Check if the mapped image is compressed:
#
lofiadm
Block Device File Options
/dev/lofi/1 /export/home/solaris.iso Compressed(gzip)
/dev/lofi/2 /export/home/regular.iso -
Unmap the compressed image and uncompress it:
#
lofiadm -d /dev/lofi/1
#
lofiadm -U /export/home/solaris.iso
Example 6 Creating an Encrypted UFS File System on a File
This example is similar to the example of making a UFS filesystem on a file, above.
Create the file:
#
mkfile 35m /export/home/test
Attach the file to a block device and specify that the file image is encrypted. As a result of this command, you obtain the character device, which is subsequently used by
newfs:
#
lofiadm -c aes-256-cbc -a /export/home/secrets
Enter passphrase:
My-M0th3r;l0v3s_m3+4lw4ys! (
not echoed)
Re-enter passphrase:
My-M0th3r;l0v3s_m3+4lw4ys! (
not echoed)
/dev/lofi/1
#
newfs /dev/rlofi/1
newfs: construct a new file system /dev/rlofi/1: (y/n)?
y
/dev/rlofi/1: 71638 sectors in 119 cylinders of 1 tracks, 602 sectors
35.0MB in 8 cyl groups (16 c/g, 4.70MB/g, 2240 i/g)
super-block backups (for fsck -F ufs -o b=#) at:
32, 9664, 19296, 28928, 38560, 48192, 57824, 67456,
The mapped file system shows that encryption is enabled:
#
lofiadm
Block Device File Options
/dev/lofi/1 /export/home/secrets Encrypted
Mount and use the filesystem:
#
mount /dev/lofi/1 /mnt
#
cp moms_secret_*_recipe /mnt
#
ls /mnt
./ moms_secret_cookie_recipe moms_secret_soup_recipe
../ moms_secret_fudge_recipe moms_secret_stuffing_recipe
lost+found/ moms_secret_meatloaf_recipe moms_secret_waffle_recipe
#
umount /mnt
#
lofiadm -d /dev/lofi/1
Subsequent attempts to map the filesystem with the wrong key or the wrong encryption algorithm will fail:
#
lofiadm -c blowfish-cbc -a /export/home/secrets
Enter passphrase:
mommy (
not echoed)
Re-enter passphrase:
mommy (
not echoed)
lofiadm: could not map file /root/lofi: Invalid argument
#
lofiadm
Block Device File Options
#
Attempts to map the filesystem without encryption will succeed, however attempts to mount and use the filesystem will fail:
#
lofiadm -a /export/home/secrets
/dev/lofi/1
#
lofiadm
Block Device File Options
/dev/lofi/1 /export/home/secrets -
#
mount /dev/lofi/1 /mnt
mount: /dev/lofi/1 is not this fstype
#
NOTES
Just as you would not directly access a disk device that has mounted file systems, you should not access a file associated with a block device except through the
lofi file driver. It might also be appropriate to ensure that the file has appropriate permissions to prevent such access.
The abilities of
lofiadm, and who can use them, are controlled by the permissions of
/dev/lofictl. Read-access allows query operations, such as listing all the associations. Write-access is required to do any state-changing operations, like adding an association. As shipped,
/dev/lofictl is owned by
root, in group
sys, and mode
0644, so all users can do query operations but only root can change anything. The administrator can give users write-access, allowing them to add or delete associations, but that is very likely a security hole and should probably only be given to a trusted group.
When mounting a filesystem image, take care to use appropriate mount options. In particular, the
nosuid mount option might be appropriate for
UFS images whose origin is unknown. Also, some options might not be useful or appropriate, like
logging or
forcedirectio for
UFS. For compatibility purposes, a raw device is also exported along with the block device. For example,
newfs(1M) requires one.
The output of
lofiadm (without arguments) might change in future releases.