Udev, by default, names network devices according to Firmware/BIOS data or physical characteristics like the bus, slot, or MAC address. The purpose of this naming convention is to ensure that network devices are named consistently and not based on the time the network card was discovered. For example, on a computer having two network cards made by Intel and Realtek, the network card manufactured by Intel may become eth0 and the Realtek card becomes eth1. In some cases, after a reboot the cards get renumbered the other way around.
In the new naming scheme, typical network device names would then be something like enp5s0 or wlp3s0. If this naming convention is not desired, the traditional naming scheme or a custom scheme can be implemented.
The traditional naming scheme using eth0, eth1, etc can be
restored by adding net.ifnames=0
on the kernel
command line. This is most appropriate for those systems that
have only one ethernet device of the same type. Laptops often
have multiple ethernet connections that are named eth0 and wlan0
and are also candidates for this method. The command line is
passed in the GRUB configuration file. See Section 8.4.4,
“Creating the GRUB Configuration File”.
The naming scheme can be customized by creating custom Udev rules. A script has been included that generates the initial rules. Generate these rules by running:
bash /lib/udev/init-net-rules.sh
Now, inspect the /etc/udev/rules.d/70-persistent-net.rules
file,
to find out which name was assigned to which network device:
cat /etc/udev/rules.d/70-persistent-net.rules
In some cases such as when MAC addresess have been assigned to a network card manually or in a virtual environment such as Qemu or Xen, the network rules file may not have been generated because addresses are not consistently assigned. In these cases, this method cannot be used.
The file begins with a comment block followed by two lines for each NIC. The first line for each NIC is a commented description showing its hardware IDs (e.g. its PCI vendor and device IDs, if it's a PCI card), along with its driver in parentheses, if the driver can be found. Neither the hardware ID nor the driver is used to determine which name to give an interface; this information is only for reference. The second line is the Udev rule that matches this NIC and actually assigns it a name.
All Udev rules are made up of several keys, separated by commas and optional whitespace. This rule's keys and an explanation of each of them are as follows:
SUBSYSTEM=="net"
- This tells
Udev to ignore devices that are not network cards.
ACTION=="add"
- This tells
Udev to ignore this rule for a uevent that isn't an add
("remove" and "change" uevents also happen, but don't need
to rename network interfaces).
DRIVERS=="?*"
- This exists so
that Udev will ignore VLAN or bridge sub-interfaces
(because these sub-interfaces do not have drivers). These
sub-interfaces are skipped because the name that would be
assigned would collide with their parent devices.
ATTR{address}
- The value of
this key is the NIC's MAC address.
ATTR{type}=="1"
- This ensures
the rule only matches the primary interface in the case of
certain wireless drivers, which create multiple virtual
interfaces. The secondary interfaces are skipped for the
same reason that VLAN and bridge sub-interfaces are
skipped: there would be a name collision otherwise.
NAME
- The value of this key
is the name that Udev will assign to this interface.
The value of NAME
is the important
part. Make sure you know which name has been assigned to each of
your network cards before proceeding, and be sure to use that
NAME
value when creating your
configuration files below.
Some software that you may want to install later (e.g., various
media players) expect the /dev/cdrom
and /dev/dvd
symlinks to exist, and
to point to a CD-ROM or DVD-ROM device. Also, it may be convenient
to put references to those symlinks into /etc/fstab
. Udev comes with a script that will
generate rules files to create these symlinks for you, depending on
the capabilities of each device, but you need to decide which of
two modes of operation you wish to have the script use.
First, the script can operate in “by-path” mode (used by default for USB and FireWire devices), where the rules it creates depend on the physical path to the CD or DVD device. Second, it can operate in “by-id” mode (default for IDE and SCSI devices), where the rules it creates depend on identification strings stored in the CD or DVD device itself. The path is determined by Udev's path_id script, and the identification strings are read from the hardware by its ata_id or scsi_id programs, depending on which type of device you have.
There are advantages to each approach; the correct approach to use will depend on what kinds of device changes may happen. If you expect the physical path to the device (that is, the ports and/or slots that it plugs into) to change, for example because you plan on moving the drive to a different IDE port or a different USB connector, then you should use the “by-id” mode. On the other hand, if you expect the device's identification to change, for example because it may die, and you would replace it with a different device with the same capabilities and which is plugged into the same connectors, then you should use the “by-path” mode.
If either type of change is possible with your drive, then choose a mode based on the type of change you expect to happen more often.
External devices (for example, a USB-connected CD drive) should not use by-path persistence, because each time the device is plugged into a new external port, its physical path will change. All externally-connected devices will have this problem if you write Udev rules to recognize them by their physical path; the problem is not limited to CD and DVD drives.
If you wish to see the values that the Udev scripts will use, then
for the appropriate CD-ROM device, find the corresponding directory
under /sys
(e.g., this can be
/sys/block/hdd
) and run a command
similar to the following:
udevadm test /sys/block/hdd
Look at the lines containing the output of various *_id programs. The “by-id” mode will use the ID_SERIAL value if it exists and is not empty, otherwise it will use a combination of ID_MODEL and ID_REVISION. The “by-path” mode will use the ID_PATH value.
If the default mode is not suitable for your situation, then the
following modification can be made to the /etc/udev/rules.d/83-cdrom-symlinks.rules
file,
as follows (where mode
is
one of “by-id” or “by-path”):
sed -i -e 's/"write_cd_rules"/"write_cd_rules mode
"/' \
/etc/udev/rules.d/83-cdrom-symlinks.rules
Note that it is not necessary to create the rules files or symlinks
at this time, because you have bind-mounted the host's /dev
directory into the LFS system, and we assume
the symlinks exist on the host. The rules and symlinks will be
created the first time you boot your LFS system.
However, if you have multiple CD-ROM devices, then the symlinks
generated at that time may point to different devices than they
point to on your host, because devices are not discovered in a
predictable order. The assignments created when you first boot the
LFS system will be stable, so this is only an issue if you need the
symlinks on both systems to point to the same device. If you need
that, then inspect (and possibly edit) the generated /etc/udev/rules.d/70-persistent-cd.rules
file
after booting, to make sure the assigned symlinks match what you
need.
As explained in Section 7.3,
“Overview of Device and Module Handling”, the order
in which devices with the same function appear in /dev
is essentially random. E.g., if you have a
USB web camera and a TV tuner, sometimes /dev/video0
refers to the camera and /dev/video1
refers to the tuner, and sometimes
after a reboot the order changes to the opposite one. For all
classes of hardware except sound cards and network cards, this is
fixable by creating Udev rules for custom persistent symlinks. The
case of network cards is covered separately in Section 7.5,
“General Network Configuration”, and sound card
configuration can be found in
BLFS.
For each of your devices that is likely to have this problem (even
if the problem doesn't exist in your current Linux distribution),
find the corresponding directory under /sys/class
or /sys/block
. For video devices, this may be
/sys/class/video4linux/video
. Figure out the attributes
that identify the device uniquely (usually, vendor and product IDs
and/or serial numbers work):
X
udevadm info -a -p /sys/class/video4linux/video0
Then write rules that create the symlinks, e.g.:
cat > /etc/udev/rules.d/83-duplicate_devs.rules << "EOF"
# Persistent symlinks for webcam and tuner
KERNEL=="video*", ATTRS{idProduct}=="1910", ATTRS{idVendor}=="0d81", \
SYMLINK+="webcam"
KERNEL=="video*", ATTRS{device}=="0x036f", ATTRS{vendor}=="0x109e", \
SYMLINK+="tvtuner"
EOF
The result is that /dev/video0
and
/dev/video1
devices still refer
randomly to the tuner and the web camera (and thus should never be
used directly), but there are symlinks /dev/tvtuner
and /dev/webcam
that always point to the correct
device.