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Linux and parallel port IDE devices
PARIDE v1.03 (c) 1997-8 Grant Guenther <grant@torque.net>
1. Introduction
Owing to the simplicity and near universality of the parallel port interface
to personal computers, many external devices such as portable hard-disk,
CD-ROM, LS-120 and tape drives use the parallel port to connect to their
host computer. While some devices (notably scanners) use ad-hoc methods
to pass commands and data through the parallel port interface, most
external devices are actually identical to an internal model, but with
a parallel-port adapter chip added in. Some of the original parallel port
adapters were little more than mechanisms for multiplexing a SCSI bus.
(The Iomega PPA-3 adapter used in the ZIP drives is an example of this
approach). Most current designs, however, take a different approach.
The adapter chip reproduces a small ISA or IDE bus in the external device
and the communication protocol provides operations for reading and writing
device registers, as well as data block transfer functions. Sometimes,
the device being addressed via the parallel cable is a standard SCSI
controller like an NCR 5380. The "ditto" family of external tape
drives use the ISA replicator to interface a floppy disk controller,
which is then connected to a floppy-tape mechanism. The vast majority
of external parallel port devices, however, are now based on standard
IDE type devices, which require no intermediate controller. If one
were to open up a parallel port CD-ROM drive, for instance, one would
find a standard ATAPI CD-ROM drive, a power supply, and a single adapter
that interconnected a standard PC parallel port cable and a standard
IDE cable. It is usually possible to exchange the CD-ROM device with
any other device using the IDE interface.
The document describes the support in Linux for parallel port IDE
devices. It does not cover parallel port SCSI devices, "ditto" tape
drives or scanners. Many different devices are supported by the
parallel port IDE subsystem, including:
MicroSolutions backpack CD-ROM
MicroSolutions backpack PD/CD
MicroSolutions backpack hard-drives
MicroSolutions backpack 8000t tape drive
SyQuest EZ-135, EZ-230 & SparQ drives
Avatar Shark
Imation Superdisk LS-120
Maxell Superdisk LS-120
FreeCom Power CD
Hewlett-Packard 5GB and 8GB tape drives
Hewlett-Packard 7100 and 7200 CD-RW drives
as well as most of the clone and no-name products on the market.
To support such a wide range of devices, PARIDE, the parallel port IDE
subsystem, is actually structured in three parts. There is a base
paride module which provides a registry and some common methods for
accessing the parallel ports. The second component is a set of
high-level drivers for each of the different types of supported devices:
pd IDE disk
pcd ATAPI CD-ROM
pf ATAPI disk
pt ATAPI tape
pg ATAPI generic
(Currently, the pg driver is only used with CD-R drives).
The high-level drivers function according to the relevant standards.
The third component of PARIDE is a set of low-level protocol drivers
for each of the parallel port IDE adapter chips. Thanks to the interest
and encouragement of Linux users from many parts of the world,
support is available for almost all known adapter protocols:
aten ATEN EH-100 (HK)
bpck Microsolutions backpack (US)
comm DataStor (old-type) "commuter" adapter (TW)
dstr DataStor EP-2000 (TW)
epat Shuttle EPAT (UK)
epia Shuttle EPIA (UK)
fit2 FIT TD-2000 (US)
fit3 FIT TD-3000 (US)
friq Freecom IQ cable (DE)
frpw Freecom Power (DE)
kbic KingByte KBIC-951A and KBIC-971A (TW)
ktti KT Technology PHd adapter (SG)
on20 OnSpec 90c20 (US)
on26 OnSpec 90c26 (US)
2. Using the PARIDE subsystem
While configuring the Linux kernel, you may choose either to build
the PARIDE drivers into your kernel, or to build them as modules.
In either case, you will need to select "Parallel port IDE device support"
as well as at least one of the high-level drivers and at least one
of the parallel port communication protocols. If you do not know
what kind of parallel port adapter is used in your drive, you could
begin by checking the file names and any text files on your DOS
installation floppy. Alternatively, you can look at the markings on
the adapter chip itself. That's usually sufficient to identify the
correct device.
You can actually select all the protocol modules, and allow the PARIDE
subsystem to try them all for you.
For the "brand-name" products listed above, here are the protocol
and high-level drivers that you would use:
Manufacturer Model Driver Protocol
MicroSolutions CD-ROM pcd bpck
MicroSolutions PD drive pf bpck
MicroSolutions hard-drive pd bpck
MicroSolutions 8000t tape pt bpck
SyQuest EZ, SparQ pd epat
Imation Superdisk pf epat
Maxell Superdisk pf friq
Avatar Shark pd epat
FreeCom CD-ROM pcd frpw
Hewlett-Packard 5GB Tape pt epat
Hewlett-Packard 7200e (CD) pcd epat
Hewlett-Packard 7200e (CD-R) pg epat
2.1 Configuring built-in drivers
We recommend that you get to know how the drivers work and how to
configure them as loadable modules, before attempting to compile a
kernel with the drivers built-in.
If you built all of your PARIDE support directly into your kernel,
and you have just a single parallel port IDE device, your kernel should
locate it automatically for you. If you have more than one device,
you may need to give some command line options to your bootloader
(eg: LILO), how to do that is beyond the scope of this document.
The high-level drivers accept a number of command line parameters, all
of which are documented in the source files in linux/drivers/block/paride.
By default, each driver will automatically try all parallel ports it
can find, and all protocol types that have been installed, until it finds
a parallel port IDE adapter. Once it finds one, the probe stops. So,
if you have more than one device, you will need to tell the drivers
how to identify them. This requires specifying the port address, the
protocol identification number and, for some devices, the drive's
chain ID. While your system is booting, a number of messages are
displayed on the console. Like all such messages, they can be
reviewed with the 'dmesg' command. Among those messages will be
some lines like:
paride: bpck registered as protocol 0
paride: epat registered as protocol 1
The numbers will always be the same until you build a new kernel with
different protocol selections. You should note these numbers as you
will need them to identify the devices.
If you happen to be using a MicroSolutions backpack device, you will
also need to know the unit ID number for each drive. This is usually
the last two digits of the drive's serial number (but read MicroSolutions'
documentation about this).
As an example, let's assume that you have a MicroSolutions PD/CD drive
with unit ID number 36 connected to the parallel port at 0x378, a SyQuest
EZ-135 connected to the chained port on the PD/CD drive and also an
Imation Superdisk connected to port 0x278. You could give the following
options on your boot command:
pd.drive0=0x378,1 pf.drive0=0x278,1 pf.drive1=0x378,0,36
In the last option, pf.drive1 configures device /dev/pf1, the 0x378
is the parallel port base address, the 0 is the protocol registration
number and 36 is the chain ID.
Please note: while PARIDE will work both with and without the
PARPORT parallel port sharing system that is included by the
"Parallel port support" option, PARPORT must be included and enabled
if you want to use chains of devices on the same parallel port.
2.2 Loading and configuring PARIDE as modules
It is much faster and simpler to get to understand the PARIDE drivers
if you use them as loadable kernel modules.
Note 1: using these drivers with the "kerneld" automatic module loading
system is not recommended for beginners, and is not documented here.
Note 2: if you build PARPORT support as a loadable module, PARIDE must
also be built as loadable modules, and PARPORT must be loaded before the
PARIDE modules.
To use PARIDE, you must begin by
insmod paride
this loads a base module which provides a registry for the protocols,
among other tasks.
Then, load as many of the protocol modules as you think you might need.
As you load each module, it will register the protocols that it supports,
and print a log message to your kernel log file and your console. For
example:
# insmod epat
paride: epat registered as protocol 0
# insmod kbic
paride: k951 registered as protocol 1
paride: k971 registered as protocol 2
Finally, you can load high-level drivers for each kind of device that
you have connected. By default, each driver will autoprobe for a single
device, but you can support up to four similar devices by giving their
individual co-ordinates when you load the driver.
For example, if you had two no-name CD-ROM drives both using the
KingByte KBIC-951A adapter, one on port 0x378 and the other on 0x3bc
you could give the following command:
# insmod pcd drive0=0x378,1 drive1=0x3bc,1
For most adapters, giving a port address and protocol number is sufficient,
but check the source files in linux/drivers/block/paride for more
information. (Hopefully someone will write some man pages one day !).
As another example, here's what happens when PARPORT is installed, and
a SyQuest EZ-135 is attached to port 0x378:
# insmod paride
paride: version 1.0 installed
# insmod epat
paride: epat registered as protocol 0
# insmod pd
pd: pd version 1.0, major 45, cluster 64, nice 0
pda: Sharing parport1 at 0x378
pda: epat 1.0, Shuttle EPAT chip c3 at 0x378, mode 5 (EPP-32), delay 1
pda: SyQuest EZ135A, 262144 blocks [128M], (512/16/32), removable media
pda: pda1
Note that the last line is the output from the generic partition table
scanner - in this case it reports that it has found a disk with one partition.
2.3 Using a PARIDE device
Once the drivers have been loaded, you can access PARIDE devices in the
same way as their traditional counterparts. You will probably need to
create the device "special files". Here is a simple script that you can
cut to a file and execute:
#!/bin/bash
#
# mkd -- a script to create the device special files for the PARIDE subsystem
#
function mkdev {
mknod $1 $2 $3 $4 ; chmod 0660 $1 ; chown root:disk $1
}
#
function pd {
D=$( printf \\$( printf "x%03x" $[ $1 + 97 ] ) )
mkdev pd$D b 45 $[ $1 * 16 ]
for P in 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
do mkdev pd$D$P b 45 $[ $1 * 16 + $P ]
done
}
#
cd /dev
#
for u in 0 1 2 3 ; do pd $u ; done
for u in 0 1 2 3 ; do mkdev pcd$u b 46 $u ; done
for u in 0 1 2 3 ; do mkdev pf$u b 47 $u ; done
for u in 0 1 2 3 ; do mkdev pt$u c 96 $u ; done
for u in 0 1 2 3 ; do mkdev npt$u c 96 $[ $u + 128 ] ; done
for u in 0 1 2 3 ; do mkdev pg$u c 97 $u ; done
#
# end of mkd
With the device files and drivers in place, you can access PARIDE devices
like any other Linux device. For example, to mount a CD-ROM in pcd0, use:
mount /dev/pcd0 /cdrom
If you have a fresh Avatar Shark cartridge, and the drive is pda, you
might do something like:
fdisk /dev/pda -- make a new partition table with
partition 1 of type 83
mke2fs /dev/pda1 -- to build the file system
mkdir /shark -- make a place to mount the disk
mount /dev/pda1 /shark
Devices like the Imation superdisk work in the same way, except that
they do not have a partition table. For example to make a 120MB
floppy that you could share with a DOS system:
mkdosfs /dev/pf0
mount /dev/pf0 /mnt
2.4 The pf driver
The pf driver is intended for use with parallel port ATAPI disk
devices. The most common devices in this category are PD drives
and LS-120 drives. Traditionally, media for these devices are not
partitioned. Consequently, the pf driver does not support partitioned
media. This may be changed in a future version of the driver.
2.5 Using the pt driver
The pt driver for parallel port ATAPI tape drives is a minimal driver.
It does not yet support many of the standard tape ioctl operations.
For best performance, a block size of 32KB should be used. You will
probably want to set the parallel port delay to 0, if you can.
2.6 Using the pg driver
The pg driver can be used in conjunction with the cdrecord program
to create CD-ROMs. Please get cdrecord version 1.6.1 or later
from ftp://ftp.fokus.gmd.de/pub/unix/cdrecord/ . To record CD-R media
your parallel port should ideally be set to EPP mode, and the "port delay"
should be set to 0. With those settings it is possible to record at 2x
speed without any buffer underruns. If you cannot get the driver to work
in EPP mode, try to use "bidirectional" or "PS/2" mode and 1x speeds only.
3. Troubleshooting
3.1 Use EPP mode if you can
The most common problems that people report with the PARIDE drivers
concern the parallel port CMOS settings. At this time, none of the
PARIDE protocol modules support ECP mode, or any ECP combination modes.
If you are able to do so, please set your parallel port into EPP mode
using your CMOS setup procedure.
3.2 Check the port delay
Some parallel ports cannot reliably transfer data at full speed. To
offset the errors, the PARIDE protocol modules introduce a "port
delay" between each access to the i/o ports. Each protocol sets
a default value for this delay. In most cases, the user can override
the default and set it to 0 - resulting in somewhat higher transfer
rates. In some rare cases (especially with older 486 systems) the
default delays are not long enough. if you experience corrupt data
transfers, or unexpected failures, you may wish to increase the
port delay. The delay can be programmed using the "driveN" parameters
to each of the high-level drivers. Please see the notes above, or
read the comments at the beginning of the driver source files in
linux/drivers/block/paride.
3.3 Some drives need a printer reset
There appear to be a number of "noname" external drives on the market
that do not always power up correctly. We have noticed this with some
drives based on OnSpec and older Freecom adapters. In these rare cases,
the adapter can often be reinitialised by issuing a "printer reset" on
the parallel port. As the reset operation is potentially disruptive in
multiple device environments, the PARIDE drivers will not do it
automatically. You can however, force a printer reset by doing:
insmod lp reset=1
rmmod lp
If you have one of these marginal cases, you should probably build
your paride drivers as modules, and arrange to do the printer reset
before loading the PARIDE drivers.
3.4 Use the verbose option and dmesg if you need help
While a lot of testing has gone into these drivers to make them work
as smoothly as possible, problems will arise. If you do have problems,
please check all the obvious things first: does the drive work in
DOS with the manufacturer's drivers ? If that doesn't yield any useful
clues, then please make sure that only one drive is hooked to your system,
and that either (a) PARPORT is enabled or (b) no other device driver
is using your parallel port (check in /proc/ioports). Then, load the
appropriate drivers (you can load several protocol modules if you want)
as in:
# insmod paride
# insmod epat
# insmod bpck
# insmod kbic
...
# insmod pd verbose=1
(using the correct driver for the type of device you have, of course).
The verbose=1 parameter will cause the drivers to log a trace of their
activity as they attempt to locate your drive.
Use 'dmesg' to capture a log of all the PARIDE messages (any messages
beginning with paride:, a protocol module's name or a driver's name) and
include that with your bug report. You can submit a bug report in one
of two ways. Either send it directly to the author of the PARIDE suite,
by e-mail to grant@torque.net, or join the linux-parport mailing list
and post your report there.
3.5 For more information or help
You can join the linux-parport mailing list by sending a mail message
to
linux-parport-request@torque.net
with the single word
subscribe
in the body of the mail message (not in the subject line). Please be
sure that your mail program is correctly set up when you do this, as
the list manager is a robot that will subscribe you using the reply
address in your mail headers. REMOVE any anti-spam gimmicks you may
have in your mail headers, when sending mail to the list server.
You might also find some useful information on the linux-parport
web pages (although they are not always up to date) at
http://www.torque.net/parport/