If the modules are all loaded correctly, the output of the lsmod
command should look like the following, when no cards are inserted:
Module Size Used by
ds 5640 2
i82365 15452 2
pcmcia_core 30012 3 [ds i82365]
The system log should also include output from the socket driver describing the host controller(s) found and the number of sockets detected.
The cardmgr
daemon is responsible for monitoring
PCMCIA sockets,
loading client drivers when needed, and running user-level scripts in
response to card insertions and removals. It records its actions in
the system log, but also uses beeps to signal card status changes.
The tones of the beeps indicate success or failure of particular
configuration steps. Two high beeps indicate that a card was
identified and configured successfully. A high beep followed by a low
beep indicates that a card was identified, but could not be configured
for some reason. One low beep indicates that a card could not be
identified.
The cardmgr
daemon configures cards based on a database of known
card types kept in /etc/pcmcia/config
. This file
describes the various client drivers, then describes how to identify
various cards, and which driver(s) belong with which cards. The
format of this file is described in the pcmcia(5)
man page.
Cardmgr
records device information for each socket in
/var/lib/pcmcia/stab
. Here is a sample
stab
listing:
Socket 0: Adaptec APA-1460 SlimSCSI
0 scsi aha152x_cs 0 sda 8 0
0 scsi aha152x_cs 1 scd0 11 0
Socket 1: Serial or Modem Card
1 serial serial_cs 0 ttyS1 5 65
For the lines describing devices, the first field is the socket, the
second is the device class, the third is the driver name, the fourth
is used to number multiple devices associated with the same driver,
the fifth is the device name, and the final two fields are the major
and minor device numbers for this device (if applicable). See the
stab
man page for more info.
The cardctl
command can be used to check the status of a
socket, or to see how it is configured. It can also be used to alter
the configuration status of a card. Here is an example of the
output of the ``cardctl config
'' command:
Socket 0:
not configured
Socket 1:
Vcc = 5.0, Vpp1 = 0.0, Vpp2 = 0.0
Card type is memory and I/O
IRQ 3 is dynamic shared, level mode, enabled
Speaker output is enabled
Function 0:
Config register base = 0x0800
Option = 0x63, status = 0x08
I/O window 1: 0x0280 to 0x02bf, auto sized
I/O window 2: 0x02f8 to 0x02ff, 8 bit
Or ``cardctl ident
'', to get card identification information:
Socket 0:
no product info available
Socket 1:
product info: "LINKSYS", "PCMLM336", "A", "0040052D6400"
manfid: 0x0143, 0xc0ab
function: 0 (multifunction)
The ``cardctl suspend
'' and ``cardctl resume
'' commands can
be used to shut down a card without unloading its associated drivers.
The ``cardctl reset
'' command attempts to reset and reconfigure a
card. ``cardctl insert
'' and ``cardctl eject
'' mimic the
actions performed when a card is physically inserted or ejected,
including loading or unloading drivers, and configuring or shutting
down devices.
If you are running X, the cardinfo
utility produces
a graphical display showing the current status of all PCMCIA sockets,
similar in content to ``cardctl config
''. It also provides a
graphical interface to most other cardctl
functions.
In theory, you can insert and remove PCMCIA cards at any time. However, it is a good idea not to eject a card that is currently being used by an application program. Kernels older than 1.1.77 would often lock up when serial/modem cards were ejected, but this should be fixed now.
Some card types cannot be safely hot ejected. Specifically, ATA/IDE
and SCSI interface cards are not hot-swap-safe. This is unlikely to
be fixed, because a complete solution would require significant
changes to the Linux block device model. Also, it is generally not
safe to hot eject CardBus cards of any type. This is likely to
improve gradually as hot swap bugs in the CardBus drivers are found
and fixed. For these card types (IDE, SCSI, CardBus), it is
recommended that you always use ``cardctl eject
'' before
ejecting.
Card Services can be compiled with support for APM
(Advanced Power Management) if you've configured your
kernel with APM support. The APM kernel driver is maintained by
Stephen Rothwell ([email protected]). The apmd
daemon is maintained by Avery Pennarun ([email protected]), with
more information available at
http://www.worldvisions.ca/~apenwarr/apmd/. The PCMCIA
modules will automatically be configured for APM if a compatible
version is detected on your system.
Whether or not APM is configured, you can use ``cardctl suspend
''
before suspending your laptop, and ``cardctl resume
'' after
resuming, to cleanly shut down and restart your PCMCIA cards. This
will not work with a modem that is in use, because the serial driver
isn't able to save and restore the modem operating parameters.
APM seems to be unstable on some systems. If you experience trouble with APM and PCMCIA on your system, try to narrow down the problem to one package or the other before reporting a bug.
Some drivers, notably the PCMCIA SCSI drivers, cannot recover from a
suspend/resume cycle. When using a PCMCIA SCSI card, always use
``cardctl eject
'' prior to suspending the system.
To unload the entire PCMCIA package, invoke rc.pcmcia
with:
/etc/rc.d/rc.pcmcia stop
This script will take several seconds to run, to give all client
drivers time to shut down gracefully. If a device is currently in
use, the shutdown will be incomplete, and some kernel modules may not
be unloaded. To avoid this, use ``cardctl eject
'' to shut down
all sockets before invoking rc.pcmcia
. The exit status of the
cardctl
command will indicate if any sockets could not be shut
down.
Each PCMCIA device has an associated ``class'' that describes how it
should be configured and managed. Classes are associated with device
drivers in /etc/pcmcia/config
. There are currently five IO
device classes (network, SCSI, cdrom, fixed disk, and serial) and
two memory device classes (memory and FTL). For each class,
there are two
scripts in /etc/pcmcia
: a main configuration script
(i.e., /etc/pcmcia/scsi
for SCSI devices), and an options
script (i.e., /etc/pcmcia/scsi.opts
). The main script for a
device will be invoked to configure that device when a card is
inserted, and to shut down the device when the card is removed. For
cards with several associated devices, the script will be invoked for
each device.
The config scripts start by extracting some information about a device
from the stab
file. Each script constructs a ``device address'',
that uniquely describes the device it has been asked to configure, in
the ADDRESS
shell variable. This is passed to the *.opts
script, which should return information about how a device at this
address should be configured. For some devices, the device address is
just the socket number. For others, it includes extra information
that may be useful in deciding how to configure the device. For
example, network devices pass their hardware ethernet address as part
of the device address, so the network.opts
script could use this
to select from several different configurations.
The first part of all device addresses is the current PCMCIA
``scheme''. This parameter is used to support multiple sets of device
configurations based on a single external user-specified variable.
One use of schemes would be to have a ``home'' scheme, and a ``work''
scheme, which would include different sets of network configuration
parameters. The current scheme is selected using the ``cardctl
scheme
'' command. The default if no scheme is set is ``default''.
There are a few additional shell variables that can be used in
*.opts
files in addition to ADDRESS
. The most useful are
DEVICE
, the current device name or network interface name; and
DRIVER
, the driver name, sometimes useful for distinguishing
different sorts of network devices. As the *.opts
files are just
shell scripts, it is not required that they follow the form of the
examples, which just return settings based on ADDRESS
.
As a general rule, when configuring Linux for a laptop, PCMCIA devices should only be configured from the PCMCIA device scripts. Do not try to configure a PCMCIA device the same way you would configure a permanently attached device. However, some Linux distributions provide PCMCIA packages that are hooked into those distributions' own device configuration tools. In that case, some of the following sections may not apply; ideally, this will be documented by the distribution maintainers.
Linux ethernet-type network interfaces normally have names like
eth0
, eth1
, and so on. Token-ring adapters are handled
similarly, however they are named tr0
, tr1
, and so on.
The ifconfig
command is used to
view or modify the state of a network interface. A peculiarity of
Linux is that network interfaces do not have corresponding device
files under /dev
, so do not be surprised when you do not find
them.
When an ethernet card is detected, it will be assigned the first free
interface name, which will normally be eth0
. Cardmgr
will
run the /etc/pcmcia/network
script to configure the
interface, which normally reads network settings from
/etc/pcmcia/network.opts
. The network
and
network.opts
scripts will be executed only when your ethernet
card is actually present. If your system has an automatic network
configuration facility, it may or may not be PCMCIA-aware. Consult
the documentation of your Linux distribution and the
Notes about specific Linux distributions to determine if PCMCIA network devices should be
configured with the automatic tools, or by editing network.opts
.
The device address passed to network.opts
consists of four
comma-separated fields: the scheme, the socket number, the device
instance, and the card's hardware ethernet address. The device
instance is used to
number devices for cards that have several network interfaces, so it
will usually be 0. If you have several network cards used for
different purposes, one option would be to configure the cards based
on socket position, as in:
case "$ADDRESS" in
*,0,*,*)
# definitions for network card in socket 0
;;
*,1,*,*)
# definitions for network card in socket 1
;;
esac
Alternatively, they could be configured using their hardware addresses, as in:
case "$ADDRESS" in
*,*,*,00:80:C8:76:00:B1)
# definitions for a D-Link card
;;
*,*,*,08:00:5A:44:80:01)
# definitions for an IBM card
esac
The following parameters can be defined in network.opts
:
IF_PORT
Specifies the ethernet transceiver type, for certain 16-bit cards that
do not autodetect. See ``man ifport
'' for more information.
BOOTP
A boolean (y/n) value: indicates if the host's IP address and routing
information should be obtained using the BOOTP protocol, with
bootpc
or pump
.
DHCP
A boolean (y/n) value: indicates if the host's IP address and routing
information should be obtained from a DHCP server. The network script
first looks for dhcpcd
, then dhclient
, then pump
.
DHCP_HOSTNAME
Specifies a hostname to be passed to dhcpcd
or pump
, for
inclusion in DHCP messages.
IPADDR
The IP address for this interface.
NETMASK
, BROADCAST
, NETWORK
Basic network parameters: see the networking HOWTO for more information.
GATEWAY
The IP address of a gateway for this host's subnet. Packets with destinations outside this subnet will be routed to this gateway.
DOMAIN
The local network domain name for this host, to be used in creating
/etc/resolv.conf
.
SEARCH
A search list for host name lookup, to be added to
/etc/resolv.conf
. DOMAIN
and SEARCH
are mutually
exclusive: see ``man resolver
'' for more information.
DNS_1
, DNS_2
, DNS_3
Host names or IP addresses for nameservers for this interface, to be
added to /etc/resolv.conf
MOUNTS
A space-separated list of NFS mount points to be mounted for this interface.
IPX_FRAME
, IPX_NETNUM
For IPX networks: the frame type and network number, passed to the
ipx_interface
command.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
set, then ``cardctl eject
'' will shut down a device even if
there are open connections. If NO_FUSER
is set, then the script
will not check for busy NFS mounts or kill processes using those mounts.
For example:
case "$ADDRESS" in
*,*,*,*)
IF_PORT="10base2"
BOOTP="n"
IPADDR="10.0.0.1"
NETMASK="255.255.255.0"
NETWORK="10.0.0.0"
BROADCAST="10.0.0.255"
GATEWAY="10.0.0.1"
DOMAIN="domain.org"
DNS_1="dns1.domain.org"
;;
esac
To automatically mount and unmount NFS filesystems, first add all
these filesystems to /etc/fstab
, but include noauto
in the mount options. In network.opts
, list the filesystem
mount points in the MOUNTS
variable. It is especially
important to use either cardctl
or cardinfo
to shut down a
network card when NFS mounts are active. It is not possible to
cleanly unmount NFS filesystems if a network card is simply ejected
without warning.
In addition to the usual network configuration parameters, the
network.opts
script can specify extra actions to be taken after
an interface is configured, or before an interface is shut down. If
network.opts
defines a shell function called start_fn
, it
will be invoked by the network script after the interface is
configured, and the interface name will be passed to the function as its
first (and only) argument. Similarly, if it is defined, stop_fn
will be invoked before shutting down an interface.
The transceiver type for some cards can be selected using the
IF_PORT
setting. This can either be a numeric value, or a
keyword identifying the transceiver type. All the network drivers
default to either autodetect the interface if possible, or 10baseT
otherwise. The ifport
command can be used to check or set the
current transceiver type. For example:
# ifport eth0 10base2
#
# ifport eth0
eth0 2 (10base2)
The current (3.0.10 or later) 3c589 driver should quickly autodetect transceiver changes at any time. Earlier releases of the 3c589 driver had a somewhat slow and flaky transceiver autodetection algorithm. For these releases, the appropriate network cable should be connected to the card when the card is configured, or you can force autodetection with:
ifconfig eth0 down up
mem_speed=#
option to the pcnet_cs
module.
An example of how to do this is given in the standard config.opts
file. Try speeds of up to 1000 (in nanoseconds).io_speed=#
option when the pcmcia_core
module is loaded.
Edit CORE_OPTS
in the startup script to set this option.ifconfig
reports the hardware
address as all 0's, this is likely to be due to a memory window
configuration problem.pcnet_cs
, 3c574_cs
, smc91c92_cs
, or xirc2ps_cs
driver) will never achieve full 100baseT throughput. Only CardBus
network adapters can fully exploit 100baseT data rates.[email protected]
) has put together a wireless HOWTO at
http://www.hpl.hp.com/personal/Jean_Tourrilhes/Linux/.
test_network
script in
the debug-tools
subdirectory of the PCMCIA source tree will spot
some common problems.cardmgr
identifies the card correctly and starts
up one of the network drivers. If it doesn't, your card might still
be usable if it is compatible with a supported card. This will be
most easily done if the card claims to be ``NE2000 compatible''.cardmgr
, but still doesn't work, there
might be an interrupt or port conflict with another device. Find out
what resources the card is using (from the system log),
and try excluding these in /etc/pcmcia/config.opts
to force
the card to use something different./etc/pcmcia/network.opts
is incorrect. This exact message is
an absolutely foolproof indication of a routing error. On the other
hand, mis-configured cards will usually fail silently./etc/pcmcia/network.opts
, start by
trying to ping other systems on the same subnet using their IP
addresses. Then try to ping your gateway, and then machines on other
subnets. Ping machines by name only after trying these simpler tests./etc/pcmcia/network.opts
script.
Make sure your drop cable, ``T'' jack, terminator, etc are working.
Linux serial devices are accessed via the /dev/ttyS*
and
/dev/cua*
special device files. In pre-2.2 kernels, the
ttyS*
devices were for incoming connections, such as directly
connected terminals, and the cua*
devices were for outgoing
connections, such as modems. Use of cua*
devices is deprecated
in current kernels, and ttyS*
can be used for all applications.
The configuration of a serial device can be examined and modified with
the setserial
command.
When a serial or modem card is detected, it will be assigned to the
first available serial device slot. This will usually be
/dev/ttyS1
(cua1
) or /dev/ttyS2
(cua2
),
depending on the number of built-in serial ports. The ttyS*
device is the one reported in stab
. The default
serial device option script, /etc/pcmcia/serial.opts
, will
link the device file to /dev/modem
as a convenience. For
pre-2.2 kernels, the link is made to the cua*
device.
Do not try to use /etc/rc.d/rc.serial
to configure a PCMCIA
modem. This script should only be used to configure non-removable
devices. Modify /etc/pcmcia/serial.opts
if you want to do
anything special to set up your modem. Also, do not try to change the
IO port and interrupt settings of a serial device using
setserial
. This would tell the serial driver to look for the
device in a different place, but would not change how the card's
hardware is actually configured. The serial configuration script
allows you to specify other setserial
options, as well as whether
a line should be added to /etc/inittab
for this port.
The device address passed to serial.opts
has three
comma-separated fields: the first is the scheme, the second is the
socket number, and the third is the device instance. The device
instance may take several values for cards that support multiple
serial ports, but for single-port cards, it will always be 0. If you
commonly use more than one modem, you may want to specify different
settings based on socket position, as in:
case "$ADDRESS" in
*,0,*)
# Options for modem in socket 0
LINK=/dev/modem0
;;
*,1,*)
# Options for modem in socket 1
LINK=/dev/modem1
;;
esac
If a PCMCIA modem is already configured when Linux boots, it may be
incorrectly identified as an ordinary built-in serial port. This is
harmless, however, when the PCMCIA drivers take control of the modem,
it will be assigned a different device slot. It is best to either
parse stab
or use /dev/modem
, rather than
expecting a PCMCIA modem to always have the same device assignment.
If you configure your kernel to load the basic Linux serial port
driver as a module, you must edit /etc/pcmcia/config
to
indicate that this module must be loaded. Edit the serial device
entry to read:
device "serial_cs"
class "serial" module "misc/serial", "serial_cs"
The following parameters can be defined in serial.opts
:
LINK
Specifies a path for a symbolic link to be created to the ``callout''
device (e.g., /dev/cua*
for pre-2.2, or /dev/ttyS*
for 2.2 kernels).
SERIAL_OPTS
Specifies options to be passed to the setserial
command.
INITTAB
If specified, this will be used to construct an inittab
entry for
the device.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
true, then ``cardctl eject
'' will shut down a device even if it
is busy. If NO_FUSER
is true, then the script will not try to
kill processes using an ejected device.
For example:
case "$ADDRESS" in
*,*,*,*)
LINK="/dev/modem"
SERIAL_OPTS=""
INITTAB="/sbin/getty"
SERIAL_OPTS="baud_base 460800"
in
/etc/pcmcia/serial.opts
.
test_modem
script in the
debug-tools
subdirectory of the PCMCIA source tree will spot some
common problems. cardmgr
identifies the card correctly and starts up the
serial_cs
driver. If it doesn't, you may need to add a new entry to
your /etc/pcmcia/config
file so that it will be identified properly.
See the
Configuring unrecognized cards
section for details./etc/pcmcia/config.opts
and exclude the port range that was allocated for the modem. setserial
to
change the irq to 0, and see if the modem works. This causes the
serial driver to use a slower polled mode instead of using interrupts.
If this seems to fix the problem, it is likely that some other device
in your system is using the interrupt selected by serial_cs. You
should add a line to /etc/pcmcia/config.opts
to exclude this
interrupt./etc/pcmcia/config
to indicate that the
serial
module should be loaded before serial_cs
.
The Linux parallel port driver is layered so that several high-level
device types can share use of the same low level port driver. Printer
devices are accessed via the /dev/lp*
special device files.
The configuration of a printer device can be examined and modified with
the tunelp
command.
The parport_cs
module depends on the parport
and
parport_pc
drivers, which may be either compiled into the kernel
or compiled as modules. The layered driver structure means that any
top-level parallel drivers (such as the plip driver, the printer
driver, etc) must be compiled as modules. These drivers only
recognize parallel port devices at module startup time, so they need
to be loaded after any PC Card parallel devices are configured.
The device address passed to parport.opts
has three
comma-separated fields: the first is the scheme, the second is the
socket number, and the third is the device instance. The device
instance may take several values for cards that support multiple
parallel ports, but for single-port cards, it will always be 0. If
you commonly use more than one such card, you may want to specify
different settings based on socket position, as in:
case "$ADDRESS" in
*,0,*)
# Options for card in socket 0
LINK=/dev/printer0
;;
*,1,*)
# Options for card in socket 1
LINK=/dev/printer1
;;
esac
If you configure your kernel to load the basic Linux parallel port
driver as a module, you must edit /etc/pcmcia/config
to
indicate that the appropriate modules must be loaded. Edit the
parallel device entry to read:
device "parport_cs"
class "parport" module "misc/parport", "misc/parport_pc", "parport_cs"
The following parameters can be defined in parport.opts
:
LINK
Specifies a path for a symbolic link to be created to the printer port.
LP_OPTS
Specifies options to be passed to the tunelp
command.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
true, then ``cardctl eject
'' will shut down a device even if it
is busy. If NO_FUSER
is true, then the script will not try to
kill processes using an ejected device.
For example:
case "$ADDRESS" in
*,*,*,*)
LINK="/dev/printer"
LP_OPTS=""
tunelp
to
change the irq to 0, and see if things improve. This switches the
driver to polling mode. If this seems to fix the problem, it is
likely that some other device in your system is using the interrupt
selected by parport_cs. You should add a line to
/etc/pcmcia/config.opts
to exclude this interrupt.parport_cs
module
cannot be loaded, it means that your kernel does not have parallel
device support. If you have compiled the parallel driver as a module,
you may need to modify /etc/pcmcia/config
to indicate that the
parport
and parport_pc
modules should be loaded before
parport_cs
.
All the currently supported PCMCIA SCSI cards are work-alikes of one
of the following ISA bus cards: the Qlogic, the Adaptec AHA-152X, or
the Future Domain TMC-16x0. The PCMCIA drivers are built by linking
some PCMCIA-specific code (in qlogic_cs.c
, aha152x_cs.c
, or
fdomain_cs.c
) with the normal Linux SCSI driver, pulled from the
Linux kernel source tree. The Adaptec APA1480 CardBus driver is based
on the kernel aic7xxx PCI driver. Due to limitations in the Linux
SCSI driver model, only one removable card per driver is supported.
When a new SCSI host adapter is detected, the SCSI drivers will probe
for devices. Check the system log to make sure your devices are
detected properly. New SCSI devices will be assigned to the first
available SCSI device files. The first SCSI disk will be
/dev/sda
, the first SCSI tape will be /dev/st0
, and
the first CD-ROM will be /dev/scd0
.
A list of SCSI devices connected to this host adapter will be shown in
stab
, and the SCSI configuration script,
/etc/pcmcia/scsi
, will be called once for each attached
device, to either configure or shut down that device. The default
script does not take any actions to configure SCSI devices, but will
properly unmount filesystems on SCSI devices when a card is removed.
The device addresses passed to scsi.opts
are complicated, because
of the variety of things that can be attached to a SCSI adapter.
Addresses consist of either six or seven comma-separated fields: the
current scheme, the
device type, the socket number, the SCSI channel, ID, and logical unit
number, and optionally, the partition number. The device type will be
``sd'' for disks, ``st'' for tapes, ``sr'' for CD-ROM devices, and
``sg'' for generic SCSI devices. For most setups, the SCSI channel
and logical unit number will be 0. For disk devices with several
partitions, scsi.opts
will first be called for the whole device,
with a five-field address. The script should set the PARTS
variable to a list of partitions. Then, scsi.opts
will be called
for each partition, with the longer seven-field addresses.
If your kernel does not have a top-level driver (disk, tape, etc) for
a particular SCSI device, then the device will not be configured by
the PCMCIA drivers. As a side effect, the device's name in
stab
will be something like ``sd#nnnn'' where ``nnnn''
is a four-digit hex number. This happens when cardmgr
is unable
to translate a SCSI device ID into a corresponding Linux device name.
It is possible to modularize the top-level SCSI drivers so that they
are loaded on demand. To do so, you need to edit
/etc/pcmcia/config
to tell cardmgr
which extra modules
need to be loaded when your adapter is configured. For example:
device "aha152x_cs"
class "scsi" module "scsi/scsi_mod", "scsi/sd_mod", "aha152x_cs"
would say to load the core SCSI module and the top-level disk driver module before loading the regular PCMCIA driver module. The PCMCIA Configure script will not automatically detect modularized SCSI modules, so you will need use the manual configure option to enable SCSI support.
Always turn on SCSI devices before powering up your laptop, or before
inserting the adapter card, so that the SCSI bus is properly
terminated when the adapter is configured. Also be very careful about
ejecting a SCSI adapter. Be sure that all associated SCSI devices are
unmounted and closed before ejecting the card. The best way to ensure
this is to use either cardctl
or cardinfo
to request card
removal before physically ejecting the card. For now, all SCSI
devices should be powered up before plugging in a SCSI adapter, and
should stay connected until after you unplug the adapter and/or power
down your laptop.
There is a potential complication when using these cards that does not arise with ordinary ISA bus adapters. The SCSI bus carries a ``termination power'' signal that is necessary for proper operation of ordinary passive SCSI terminators. PCMCIA SCSI adapters do not supply termination power, so if it is required, an external device must supply it. Some external SCSI devices may be configured to supply termination power. Others, such as the Zip Drive and the Syquest EZ-Drive, use active terminators that do not depend on it. In some cases, it may be necessary to use a special terminator block such as the APS SCSI Sentry 2, which has an external power supply. When configuring your SCSI device chain, be aware of whether or not any of your devices require or can provide termination power.
The following parameters can be defined in scsi.opts
:
LINK
Specifies a path for a symbolic link to be created to this device.
DO_FSTAB
A boolean (y/n) setting: specifies if an entry should be added to
/etc/fstab
for this device.
DO_FSCK
A boolean (y/n) setting: specifies if the filesystem should be checked
before being mounted, with ``fsck -Ta
''.
DO_MOUNT
A boolean (y/n) setting: specifies if this device should be automatically mounted at card insertion time.
FSTYPE
, OPTS
, MOUNTPT
The filesystem type, mount options, and mount point to be used for the fstab entry and/or mounting the device.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
true, then ``cardctl eject
'' will shut down a device even if it
is busy. If NO_FUSER
is true, then the script will not try to
kill processes using an ejected device.
For example, here is a script for configuring a disk device at SCSI ID 3, with two partitions, and a CD-ROM at SCSI ID 6:
case "$ADDRESS" in
*,sd,*,0,3,0)
# This device has two partitions...
PARTS="1 2"
;;
*,sd,*,0,3,0,1)
# Options for partition 1:
# update /etc/fstab, and mount an ext2 fs on /usr1
DO_FSTAB="y" ; DO_FSCK="y" ; DO_MOUNT="y"
FSTYPE="ext2"
OPTS=""
MOUNTPT="/usr1"
;;
*,sd,*,0,3,0,2)
# Options for partition 2:
# update /etc/fstab, and mount an MS-DOS fs on /usr2
DO_FSTAB="y" ; DO_FSCK="y" ; DO_MOUNT="y"
FSTYPE="msdos"
OPTS=""
MOUNTPT="/usr2"
;;
*,sr,*,0,6,0)
# Options for CD-ROM at SCSI ID 6
PARTS=""
DO_FSTAB="y" ; DO_FSCK="n" ; DO_MOUNT="y"
FSTYPE="iso9660"
OPTS="ro"
MOUNTPT="/cdrom"
;;
esac
/etc/pcmcia/config.opts
to
guarantee that such a large window can be found.
aha152x_cs
driver (used by Adaptec, New Media, and
a few others), it seems that SCSI disconnect/reconnect support is a
frequent source of trouble with tape drives. To disable this ``feature,''
add the following to /etc/pcmcia/config.opts
:
module "aha152x_cs" opts "reconnect=0"
aha152x_cs
driver, certain devices seem to require
a longer startup delay, controlled via the reset_delay
module
parameter. The Yamaha 4416S CDR drive is one such device. The result
is the device is identified successfully, then hangs the system. In
such cases, try:
module "aha152x_cs" opts "reset_delay=500"
CONFIG_SCSI_MULTI_LUN
option.CONFIG_SCSI
is
``m''), you may need to modify /etc/pcmcia/config
to load the
SCSI modules before the appropriate *_cs
driver is loaded.
The memory_cs
driver handles all types of memory cards, as well
as providing direct access to the PCMCIA memory address space for
cards that have other functions. When loaded, it creates a
combination of character and block devices. See the man page for the
module for a complete description of the device naming scheme. Block
devices are used for disk-like access (creating and mounting
filesystems, etc). The character devices are for "raw" unbuffered
reads and writes at arbitrary locations.
The device address passed to memory.opts
consists of two fields:
the scheme, and the socket number. The options are applied to the
first common memory partition on the corresponding memory card.
Some flash memory cards, and most simple static RAM cards, lack a
``Card Information Structure'' (CIS), which is the system PCMCIA cards
use to identify themselves. Normally, cardmgr
will assume that
any card that lacks a CIS is a simple memory card, and load the
memory_cs
driver. Thus, a common side effect of a general card
identification problem is that other types of cards may be misdetected
as memory cards.
There is another issue to consider when handling memory cards that do
not have CIS information. At startup time, the PCMCIA package tries
to use the first detected card to determine what memory regions are
usable for PCMCIA. The memory scan can be fooled if that card is a
simple memory card. If you plan to use memory cards often, it is best
to limit the memory windows in /etc/pcmcia/config.opts
to
known-good regions.
The memory_cs
driver uses a heuristic to guess the capacity of
these cards. The heuristic does not work for write protected cards,
and may make mistakes in some other cases as well. If a card is
misdetected, its size should then be explicitly specified when using
commands such as dd
or mkfs
. The memory_cs
module also
has a parameter for overriding the size detection. See the man page.
The following parameters can be specified in memory.opts
:
DO_FSTAB
A boolean (y/n) setting: specifies if an entry should be added to
/etc/fstab
for this device.
DO_FSCK
A boolean (y/n) setting: specifies if the filesystem should be checked
before being mounted, with ``fsck -Ta
''.
DO_MOUNT
A boolean (y/n) setting: specifies if this device should be automatically mounted at card insertion time.
FSTYPE
, OPTS
, MOUNTPT
The filesystem type, mount options, and mount point to be used for the fstab entry and/or mounting the device.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
true, then ``cardctl eject
'' will shut down a device even if it
is busy. If NO_FUSER
is true, then the script will not try to
kill processes using an ejected device.
Here is an example of a script that will automatically mount memory cards based on which socket they are inserted into:
case "$ADDRESS" in
*,0,0)
# Mount filesystem, but don't update /etc/fstab
DO_FSTAB="n" ; DO_FSCK="y" ; DO_MOUNT="y"
FSTYPE="ext2" ; OPTS=""
MOUNTPT="/mem0"
;;
*,1,0)
# Mount filesystem, but don't update /etc/fstab
DO_FSTAB="n" ; DO_FSCK="y" ; DO_MOUNT="y"
FSTYPE="ext2" ; OPTS=""
MOUNTPT="/mem1"
;;
esac
The following information applies only to so-called ``linear flash'' memory cards. Many flash cards, including all SmartMedia and CompactFlash cards, actually include circuitry to emulate an IDE disk device. Those cards are thus handled as IDE devices, not memory cards.
There are two major formats for flash memory cards: the FTL or ``flash translation layer'' style, and the Microsoft Flash File System. The FTL format is generally more flexible because it allows any ordinary high-level filesystem (ext2, ms-dos, etc) to be used on a flash card as if it were an ordinary disk device. The FFS is a completely different filesystem type. Linux cannot currently handle cards formated with FFS.
To use a flash memory card as an ordinary disk-like block device,
first create an FTL partition on the device with the
ftl_format
command. This layer hides the
device-specific details of flash memory programming and make the card
look like a simple block device. For example:
ftl_format -i /dev/mem0c0c
Note that this command accesses the card through the ``raw'' memory
card interface. Once formatted, the card can be accessed as an
ordinary block device via the ftl_cs
driver. For example:
mke2fs /dev/ftl0c0
mount -t ext2 /dev/ftl0c0 /mnt
Device naming for FTL devices is tricky. Minor device numbers have three parts: the card number, the region number on that card, and optionally, the partition within that region. A region can either be treated as a single block device with no partition table (like a floppy), or it can be partitioned like a hard disk device. The ``ftl0c0'' device is card 0, common memory region 0, the entire region. The ``ftl0c0p1'' through ``ftl0c0p4'' devices are primary partitions 1 through 4 if the region has been partitioned.
Configuration options for FTL partitions can be given in
ftl.opts
, which is similar in structure to memory.opts
.
The device address passed to ftl.opts
consists of three or four
fields: the scheme, the socket number, the region number, and
optionally, the partition number. Most flash cards have just one
flash memory region, so the region number will generally always be
zero.
Intel Series 100 flash cards use the first 128K flash block to store
the cards' configuration information. To prevent accidental erasure
of this information, ftl_format
will automatically detect this
and skip the first block when creating an FTL partition.
ATA/IDE drive support is based on the regular kernel IDE driver. This
includes SmartMedia and CompactFlash devices: these flash memory cards
are set up so that they emulate an IDE interface. The PCMCIA-specific
part of the driver is ide_cs
. Be sure to use cardctl
or
cardinfo
to shut down an ATA/IDE card before ejecting it, as the
driver has not been made ``hot-swap-proof''.
The device addresses passed to ide.opts
consist of either three
or four fields: the current scheme, the socket number, the drive's
serial number, and an optional partition number. The ide_info
command can be used to obtain an IDE device's serial number. As with
SCSI devices, ide.opts
is first called for the entire device. If
ide.opts
returns a list of partitions in the PARTS
variable, the script will then be called for each partition.
The following parameters can be specified in ide.opts
:
DO_FSTAB
A boolean (y/n) setting: specifies if an entry should be added to
/etc/fstab
for this device.
DO_FSCK
A boolean (y/n) setting: specifies if the filesystem should be checked
before being mounted, with ``fsck -Ta
''.
DO_MOUNT
A boolean (y/n) setting: specifies if this device should be automatically mounted at card insertion time.
FSTYPE
, OPTS
, MOUNTPT
The filesystem type, mount options, and mount point to be used for the fstab entry and/or mounting the device.
NO_CHECK
, NO_FUSER
Boolean (y/n) settings for card eject policy. If NO_CHECK
is
true, then ``cardctl eject
'' will shut down a device even if it
is busy. If NO_FUSER
is true, then the script will not try to
kill processes using an ejected device.
Here is an example ide.opts
file to mount the first partition
of any ATA/IDE card on /mnt
.
case "$ADDRESS" in
*,*,*,1)
DO_FSTAB="y" ; DO_FSCK="y" ; DO_MOUNT="y"
FSTYPE="msdos"
OPTS=""
MOUNTPT="/mnt"
;;
*,*,*)
PARTS="1"
;;
esac
INVALID GEOMETRY: 0 PHYSICAL HEADS?
''. To
fix, try excluding the selected IO port range in
/etc/pcmcia/config.opts
.unreset_delay
and/or unreset_limit
parameters for
the pcmcia_core
module to give a drive more time to spin up; see
the pcmcia_core
man page for parameter details. For example:
CORE_OPTS="unreset_delay=400"
CONFIG_BLK_DEV_IDECD
enabled. This will normally be the case for
standard kernels, however it is something to be aware of if you
compile a custom kernel./dev/hde1
, not /dev/hde
).
A single interrupt can be shared by several drivers, such as the serial driver and an ethernet driver: in fact, the PCMCIA specification requires all card functions to share the same interrupt. Normally, all card functions are available without having to swap drivers. Any remotely recent Linux kernel (i.e., 1.3.72 or later) supports this kind of interrupt sharing.
Simultaneous use of two card functions is ``tricky'' and various
hardware vendors have implemented interrupt sharing in their own
incompatible (and sometimes proprietary) ways. The drivers for some
cards (Ositech Jack of Diamonds, 3Com 3c562 and related cards, Linksys
cards) properly support simultaneous access, but others (older
Megahertz cards in particular) do not. If you have trouble using a
card with both functions active, try using each function in isolation.
That may require explicitly doing an ``ifconfig down
'' to shut
down a network interface and use a modem on the same card.
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