The Linux 2.4 Parallel Port Subsystem
Tim
Waugh
twaugh@redhat.com
1999-2000
Tim Waugh
Permission is granted to copy, distribute and/or modify this
document under the terms of the GNU Free Documentation License,
Version 1.1 or any later version published by the Free Software
Foundation; with no Invariant Sections, with no Front-Cover Texts,
and with no Back-Cover Texts. A copy of the license is included
in the section entitled "GNU Free Documentation License".
Design goals
The problems
The first parallel port support for Linux came with the line
printer driver, lp. The printer driver is a
character special device, and (in Linux 2.0) had support for
writing, via write, and configuration and
statistics reporting via ioctl.
The printer driver could be used on any computer that had an IBM
PC-compatible parallel port. Because some architectures have
parallel ports that aren't really the same as PC-style ports,
other variants of the printer driver were written in order to
support Amiga and Atari parallel ports.
When the Iomega Zip drive was released, and a driver written for
it, a problem became apparent. The Zip drive is a parallel port
device that provides a parallel port of its own---it is designed
to sit between a computer and an attached printer, with the
printer plugged into the Zip drive, and the Zip drive plugged into
the computer.
The problem was that, although printers and Zip drives were both
supported, for any given port only one could be used at a time.
Only one of the two drivers could be present in the kernel at
once. This was because of the fact that both drivers wanted to
drive the same hardware---the parallel port. When the printer
driver initialised, it would call the
check_region function to make sure that the
IO region associated with the parallel port was free, and then it
would call request_region to allocate it.
The Zip drive used the same mechanism. Whichever driver
initialised first would gain exclusive control of the parallel
port.
The only way around this problem at the time was to make sure that
both drivers were available as loadable kernel modules. To use
the printer, load the printer driver module; then for the Zip
drive, unload the printer driver module and load the Zip driver
module.
The net effect was that printing a document that was stored on a
Zip drive was a bit of an ordeal, at least if the Zip drive and
printer shared a parallel port. A better solution was
needed.
Zip drives are not the only devices that presented problems for
Linux. There are other devices with pass-through ports, for
example parallel port CD-ROM drives. There are also printers that
report their status textually rather than using simple error pins:
sending a command to the printer can cause it to report the number
of pages that it has ever printed, or how much free memory it has,
or whether it is running out of toner, and so on. The printer
driver didn't originally offer any facility for reading back this
information (although Carsten Gross added nibble mode readback
support for kernel 2.2).
The IEEE has issued a standards document called IEEE 1284, which
documents existing practice for parallel port communications in a
variety of modes. Those modes are: compatibility
,
reverse nibble, reverse byte, ECP and EPP. Newer devices often
use the more advanced modes of transfer (ECP and EPP). In Linux
2.0, the printer driver only supported compatibility
mode
(i.e. normal printer protocol) and reverse nibble
mode.
The solutions
The parport code in Linux 2.2 was designed to
meet these problems of architectural differences in parallel
ports, of port-sharing between devices with pass-through ports,
and of lack of support for IEEE 1284 transfer modes.
There are two layers to the parport
subsystem, only one of which deals directly with the hardware.
The other layer deals with sharing and IEEE 1284 transfer modes.
In this way, parallel support for a particular architecture comes
in the form of a module which registers itself with the generic
sharing layer.
The sharing model provided by the parport
subsystem is one of exclusive access. A device driver, such as
the printer driver, must ask the parport
layer for access to the port, and can only use the port once
access has been granted. When it has finished a
transaction
, it can tell the
parport layer that it may release the port
for other device drivers to use.
Devices with pass-through ports all manage to share a parallel
port with other devices in generally the same way. The device has
a latch for each of the pins on its pass-through port. The normal
state of affairs is pass-through mode, with the device copying the
signal lines between its host port and its pass-through port.
When the device sees a special signal from the host port, it
latches the pass-through port so that devices further downstream
don't get confused by the pass-through device's conversation with
the host parallel port: the device connected to the pass-through
port (and any devices connected in turn to it) are effectively cut
off from the computer. When the pass-through device has completed
its transaction with the computer, it enables the pass-through
port again.
This technique relies on certain special signals
being invisible to devices that aren't watching for them. This
tends to mean only changing the data signals and leaving the
control signals alone. IEEE 1284.3 documents a standard protocol
for daisy-chaining devices together with parallel ports.
Support for standard transfer modes are provided as operations
that can be performed on a port, along with operations for setting
the data lines, or the control lines, or reading the status lines.
These operations appear to the device driver as function pointers;
more later.
Standard transfer modes
The standard
transfer modes in use over the parallel
port are defined
by a document called IEEE 1284. It
really just codifies existing practice and documents protocols (and
variations on protocols) that have been in common use for quite
some time.
The original definitions of which pin did what were set out by
Centronics Data Computer Corporation, but only the printer-side
interface signals were specified.
By the early 1980s, IBM's host-side implementation had become the
most widely used. New printers emerged that claimed Centronics
compatibility, but although compatible with Centronics they
differed from one another in a number of ways.
As a result of this, when IEEE 1284 was published in 1994, all that
it could really do was document the various protocols that are used
for printers (there are about six variations on a theme).
In addition to the protocol used to talk to Centronics-compatible
printers, IEEE 1284 defined other protocols that are used for
unidirectional peripheral-to-host transfers (reverse nibble and
reverse byte) and for fast bidirectional transfers (ECP and
EPP).
Structure
Sharing core
At the core of the parport subsystem is the
sharing mechanism (see
drivers/parport/share.c). This module,
parport, is responsible for keeping track of
which ports there are in the system, which device drivers might be
interested in new ports, and whether or not each port is available
for use (or if not, which driver is currently using it).
Parports and their overrides
The generic parport sharing code doesn't
directly handle the parallel port hardware. That is done instead
by low-level
parport drivers.
The function of a low-level parport driver is
to detect parallel ports, register them with the sharing code, and
provide a list of access functions for each port.
The most basic access functions that must be provided are ones for
examining the status lines, for setting the control lines, and for
setting the data lines. There are also access functions for
setting the direction of the data lines; normally they are in the
forward
direction (that is, the computer drives
them), but some ports allow switching to reverse
mode (driven by the peripheral). There is an access function for
examining the data lines once in reverse mode.
IEEE 1284 transfer modes
Stacked on top of the sharing mechanism, but still in the
parport module, are functions for
transferring data. They are provided for the device drivers to
use, and are very much like library routines. Since these
transfer functions are provided by the generic
parport core they must use the lowest
common denominator
set of access functions: they can set
the control lines, examine the status lines, and use the data
lines. With some parallel ports the data lines can only be set
and not examined, and with other ports accessing the data register
causes control line activity; with these types of situations, the
IEEE 1284 transfer functions make a best effort attempt to do the
right thing. In some cases, it is not physically possible to use
particular IEEE 1284 transfer modes.
The low-level parport drivers also provide
IEEE 1284 transfer functions, as names in the access function
list. The low-level driver can just name the generic IEEE 1284
transfer functions for this. Some parallel ports can do IEEE 1284
transfers in hardware; for those ports, the low-level driver can
provide functions to utilise that feature.
Pardevices and parport_drivers
When a parallel port device driver (such as
lp) initialises it tells the sharing layer
about itself using parport_register_driver.
The information is put into a struct
parport_driver, which is put into a linked list. The
information in a struct parport_driver
really just amounts to some function pointers to callbacks in the
parallel port device driver.
During its initialisation, a low-level port driver tells the
sharing layer about all the ports that it has found (using
parport_register_port), and the sharing layer
creates a struct parport for each of
them. Each struct parport contains
(among other things) a pointer to a struct
parport_operations, which is a list of function
pointers for the various operations that can be performed on a
port. You can think of a struct parport
as a parallel port object
, if
object-orientated
programming is your thing. The
parport structures are chained in a
linked list, whose head is portlist (in
drivers/parport/share.c).
Once the port has been registered, the low-level port driver
announces it. The parport_announce_port
function walks down the list of parallel port device drivers
(struct parport_drivers) calling the
attach function of each (which may block).
Similarly, a low-level port driver can undo the effect of
registering a port with the
parport_unregister_port function, and device
drivers are notified using the detach
callback (which may not block).
Device drivers can undo the effect of registering themselves with
the parport_unregister_driver
function.
The IEEE 1284.3 API
The ability to daisy-chain devices is very useful, but if every
device does it in a different way it could lead to lots of
complications for device driver writers. Fortunately, the IEEE
are standardising it in IEEE 1284.3, which covers daisy-chain
devices and port multiplexors.
At the time of writing, IEEE 1284.3 has not been published, but
the draft specifies the on-the-wire protocol for daisy-chaining
and multiplexing, and also suggests a programming interface for
using it. That interface (or most of it) has been implemented in
the parport code in Linux.
At initialisation of the parallel port bus
,
daisy-chained devices are assigned addresses starting from zero.
There can only be four devices with daisy-chain addresses, plus
one device on the end that doesn't know about daisy-chaining and
thinks it's connected directly to a computer.
Another way of connecting more parallel port devices is to use a
multiplexor. The idea is to have a device that is connected
directly to a parallel port on a computer, but has a number of
parallel ports on the other side for other peripherals to connect
to (two or four ports are allowed). The multiplexor switches
control to different ports under software control---it is, in
effect, a programmable printer switch.
Combining the ability of daisy-chaining five devices together with
the ability to multiplex one parallel port between four gives the
potential to have twenty peripherals connected to the same
parallel port!
In addition, of course, a single computer can have multiple
parallel ports. So, each parallel port peripheral in the system
can be identified with three numbers, or co-ordinates: the
parallel port, the multiplexed port, and the daisy-chain
address.
Each device in the system is numbered at initialisation (by
parport_daisy_init). You can convert between
this device number and its co-ordinates with
parport_device_num and
parport_device_coords.
#include <parport.h>
int parport_device_num
int parport
int mux
int daisy
int parport_device_coords
int devnum
int *parport
int *mux
int *daisy
Any parallel port peripheral will be connected directly or
indirectly to a parallel port on the system, but it won't have a
daisy-chain address if it does not know about daisy-chaining, and
it won't be connected through a multiplexor port if there is no
multiplexor. The special co-ordinate value
-1 is used to indicate these cases.
Two functions are provided for finding devices based on their IEEE
1284 Device ID: parport_find_device and
parport_find_class.
#include <parport.h>
int parport_find_device
const char *mfg
const char *mdl
int from
int parport_find_class
parport_device_class cls
int from
These functions take a device number (in addition to some other
things), and return another device number. They walk through the
list of detected devices until they find one that matches the
requirements, and then return that device number (or
-1 if there are no more such devices). They
start their search at the device after the one in the list with
the number given (at from+1, in other
words).
Device driver's view
This section is written from the point of view of the device driver
programmer, who might be writing a driver for a printer or a
scanner or else anything that plugs into the parallel port. It
explains how to use the parport interface to
find parallel ports, use them, and share them with other device
drivers.
We'll start out with a description of the various functions that
can be called, and then look at a reasonably simple example of
their use: the printer driver.
The interactions between the device driver and the
parport layer are as follows. First, the
device driver registers its existence with
parport, in order to get told about any
parallel ports that have been (or will be) detected. When it gets
told about a parallel port, it then tells
parport that it wants to drive a device on
that port. Thereafter it can claim exclusive access to the port in
order to talk to its device.
So, the first thing for the device driver to do is tell
parport that it wants to know what parallel
ports are on the system. To do this, it uses the
parport_register_driver function:
#include <parport.h>
struct parport_driver {
const char *name;
void (*attach) (struct parport *);
void (*detach) (struct parport *);
struct parport_driver *next;
};
int parport_register_driver
struct parport_driver *driver
In other words, the device driver passes pointers to a couple of
functions to parport, and
parport calls attach for
each port that's detected (and detach for each
port that disappears---yes, this can happen).
The next thing that happens is that the device driver tells
parport that it thinks there's a device on the
port that it can drive. This typically will happen in the driver's
attach function, and is done with
parport_register_device:
#include <parport.h>
struct pardevice *parport_register_device
struct parport *port
const char *name
int (*pf)
void *
void (*kf)
void *
void (*irq_func)
int, void *, struct pt_regs *
int flags
void *handle
The port comes from the parameter supplied
to the attach function when it is called, or
alternatively can be found from the list of detected parallel ports
directly with the (now deprecated)
parport_enumerate function. A better way of
doing this is with parport_find_number or
parport_find_base functions, which find ports
by number and by base I/O address respectively.
#include <parport.h>
struct parport *parport_find_number
int number
#include <parport.h>
struct parport *parport_find_base
unsigned long base
The next three parameters, pf,
kf, and irq_func, are
more function pointers. These callback functions get called under
various circumstances, and are always given the
handle as one of their parameters.
The preemption callback, pf, is called when
the driver has claimed access to the port but another device driver
wants access. If the driver is willing to let the port go, it
should return zero and the port will be released on its behalf.
There is no need to call parport_release. If
pf gets called at a bad time for letting the
port go, it should return non-zero and no action will be taken. It
is good manners for the driver to try to release the port at the
earliest opportunity after its preemption callback is
called.
The kick
callback, kf, is
called when the port can be claimed for exclusive access; that is,
parport_claim is guaranteed to succeed inside
the kick
callback. If the driver wants to claim the
port it should do so; otherwise, it need not take any
action.
The irq_func callback is called,
predictably, when a parallel port interrupt is generated. But it
is not the only code that hooks on the interrupt. The sequence is
this: the lowlevel driver is the one that has done
request_irq; it then does whatever
hardware-specific things it needs to do to the parallel port
hardware (for PC-style ports, there is nothing special to do); it
then tells the IEEE 1284 code about the interrupt, which may
involve reacting to an IEEE 1284 event, depending on the current
IEEE 1284 phase; and finally the irq_func
function is called.
None of the callback functions are allowed to block.
The flags are for telling
parport any requirements or hints that are
useful. The only useful value here (other than
0, which is the usual value) is
PARPORT_DEV_EXCL. The point of that flag is
to request exclusive access at all times---once a driver has
successfully called parport_register_device
with that flag, no other device drivers will be able to register
devices on that port (until the successful driver deregisters its
device, of course).
The PARPORT_DEV_EXCL flag is for preventing
port sharing, and so should only be used when sharing the port with
other device drivers is impossible and would lead to incorrect
behaviour. Use it sparingly!
Devices can also be registered by device drivers based on their
device numbers (the same device numbers as in the previous
section).
The parport_open function is similar to
parport_register_device, and
parport_close is the equivalent of
parport_unregister_device. The difference is
that parport_open takes a device number rather
than a pointer to a struct parport.
#include <parport.h>
struct pardevice *parport_open
int devnum
const char *name
int (*pf)
void *
int (*kf)
void *
int (*irqf)
int, void *, struct pt_regs *
int flags
void *handle
void parport_close
struct pardevice *dev
struct pardevice *parport_register_device
struct parport *port
const char *name
int (*pf)
void *
int (*kf)
void *
int (*irqf)
int, void *, struct pt_regs *
int flags
void *handle
void parport_unregister_device
struct pardevice *dev
The intended use of these functions is during driver initialisation
while the driver looks for devices that it supports, as
demonstrated by the following code fragment:
Once your device driver has registered its device and been handed a
pointer to a struct pardevice, the next
thing you are likely to want to do is communicate with the device
you think is there. To do that you'll need to claim access to the
port.
#include <parport.h>
int parport_claim
struct pardevice *dev
int parport_claim_or_block
struct pardevice *dev
void parport_release
struct pardevice *dev
To claim access to the port, use parport_claim
or parport_claim_or_block. The first of these
will not block, and so can be used from interrupt context. If
parport_claim succeeds it will return zero and
the port is available to use. It may fail (returning non-zero) if
the port is in use by another driver and that driver is not willing
to relinquish control of the port.
The other function, parport_claim_or_block,
will block if necessary to wait for the port to be free. If it
slept, it returns 1; if it succeeded without
needing to sleep it returns 0. If it fails it
will return a negative error code.
When you have finished communicating with the device, you can give
up access to the port so that other drivers can communicate with
their devices. The parport_release function
cannot fail, but it should not be called without the port claimed.
Similarly, you should not try to claim the port if you already have
it claimed.
You may find that although there are convenient points for your
driver to relinquish the parallel port and allow other drivers to
talk to their devices, it would be preferable to keep hold of the
port. The printer driver only needs the port when there is data to
print, for example, but a network driver (such as PLIP) could be
sent a remote packet at any time. With PLIP, it is no huge
catastrophe if a network packet is dropped, since it will likely be
sent again, so it is possible for that kind of driver to share the
port with other (pass-through) devices.
The parport_yield and
parport_yield_blocking functions are for
marking points in the driver at which other drivers may claim the
port and use their devices. Yielding the port is similar to
releasing it and reclaiming it, but is more efficient because
nothing is done if there are no other devices needing the port. In
fact, nothing is done even if there are other devices waiting but
the current device is still within its timeslice
.
The default timeslice is half a second, but it can be adjusted via
a /proc entry.
#include <parport.h>
int parport_yield
struct pardevice *dev
int parport_yield_blocking
struct pardevice *dev
The first of these, parport_yield, will not
block but as a result may fail. The return value for
parport_yield is the same as for
parport_claim. The blocking version,
parport_yield_blocking, has the same return
code as parport_claim_or_block.
Once the port has been claimed, the device driver can use the
functions in the struct parport_operations
pointer in the struct parport it has a
pointer to. For example:
ops->write_data (port, d);
]]>
Some of these operations have shortcuts
. For
instance, parport_write_data is equivalent to
the above, but may be a little bit faster (it's a macro that in
some cases can avoid needing to indirect through
port and ops).
Port drivers
To recap, then:
The device driver registers itself with parport.
A low-level driver finds a parallel port and registers it with
parport (these first two things can happen
in either order). This registration creates a struct
parport which is linked onto a list of known ports.
parport calls the
attach function of each registered device
driver, passing it the pointer to the new struct
parport.
The device driver gets a handle from
parport, for use with
parport_claim/release.
This handle takes the form of a pointer to a struct
pardevice, representing a particular device on the
parallel port, and is acquired using
parport_register_device.
The device driver claims the port using
parport_claim (or
function_claim_or_block).
Then it goes ahead and uses the port. When finished it releases
the port.
The purpose of the low-level drivers, then, is to detect parallel
ports and provide methods of accessing them (i.e. implementing the
operations in struct
parport_operations).
A more complete description of which operation is supposed to do
what is available in
Documentation/parport-lowlevel.txt.
The printer driver
The printer driver, lp is a character special
device driver and a parport client. As a
character special device driver it registers a struct
file_operations using
register_chrdev, with pointers filled in for
write, ioctl,
open and
release. As a client of
parport, it registers a struct
parport_driver using
parport_register_driver, so that
parport knows to call
lp_attach when a new parallel port is
discovered (and lp_detach when it goes
away).
The parallel port console functionality is also implemented in
drivers/char/lp.c, but that won't be covered
here (it's quite simple though).
The initialisation of the driver is quite easy to understand (see
lp_init). The lp_table is
an array of structures that contain information about a specific
device (the struct pardevice associated
with it, for example). That array is initialised to sensible
values first of all.
Next, the printer driver calls register_chrdev
passing it a pointer to lp_fops, which contains
function pointers for the printer driver's implementation of
open, write, and so on.
This part is the same as for any character special device
driver.
After successfully registering itself as a character special device
driver, the printer driver registers itself as a
parport client using
parport_register_driver. It passes a pointer
to this structure:
The lp_detach function is not very interesting
(it does nothing); the interesting bit is
lp_attach. What goes on here depends on
whether the user supplied any parameters. The possibilities are:
no parameters supplied, in which case the printer driver uses every
port that is detected; the user supplied the parameter
auto
, in which case only ports on which the device
ID string indicates a printer is present are used; or the user
supplied a list of parallel port numbers to try, in which case only
those are used.
For each port that the printer driver wants to use (see
lp_register), it calls
parport_register_device and stores the
resulting struct pardevice pointer in the
lp_table. If the user told it to do so, it then
resets the printer.
The other interesting piece of the printer driver, from the point
of view of parport, is
lp_write. In this function, the user space
process has data that it wants printed, and the printer driver
hands it off to the parport code to deal with.
The parport functions it uses that we have not
seen yet are parport_negotiate,
parport_set_timeout, and
parport_write. These functions are part of
the IEEE 1284 implementation.
The way the IEEE 1284 protocol works is that the host tells the
peripheral what transfer mode it would like to use, and the
peripheral either accepts that mode or rejects it; if the mode is
rejected, the host can try again with a different mode. This is
the negotation phase. Once the peripheral has accepted a
particular transfer mode, data transfer can begin that mode.
The particular transfer mode that the printer driver wants to use
is named in IEEE 1284 as compatibility
mode, and the
function to request a particular mode is called
parport_negotiate.
#include <parport.h>
int parport_negotiate
struct parport *port
int mode
The modes parameter is a symbolic constant
representing an IEEE 1284 mode; in this instance, it is
IEEE1284_MODE_COMPAT. (Compatibility mode is
slightly different to the other modes---rather than being
specifically requested, it is the default until another mode is
selected.)
Back to lp_write then. First, access to the
parallel port is secured with
parport_claim_or_block. At this point the
driver might sleep, waiting for another driver (perhaps a Zip drive
driver, for instance) to let the port go. Next, it goes to
compatibility mode using parport_negotiate.
The main work is done in the write-loop. In particular, the line
that hands the data over to parport reads:
The parport_write function writes data to the
peripheral using the currently selected transfer mode
(compatibility mode, in this case). It returns the number of bytes
successfully written:
#include <parport.h>
ssize_t parport_write
struct parport *port
const void *buf
size_t len
ssize_t parport_read
struct parport *port
void *buf
size_t len
(parport_read does what it sounds like, but
only works for modes in which reverse transfer is possible. Of
course, parport_write only works in modes in
which forward transfer is possible, too.)
The buf pointer should be to kernel space
memory, and obviously the len parameter
specifies the amount of data to transfer.
In fact what parport_write does is call the
appropriate block transfer function from the struct
parport_operations:
The transfer code in parport will tolerate a
data transfer stall only for so long, and this timeout can be
specified with parport_set_timeout, which
returns the previous timeout:
#include <parport.h>
long parport_set_timeout
struct pardevice *dev
long inactivity
This timeout is specific to the device, and is restored on
parport_claim.
The next function to look at is the one that allows processes to
read from /dev/lp0:
lp_read. It's short, like
lp_write.
The semantics of reading from a line printer device are as follows:
Switch to reverse nibble mode.
Try to read data from the peripheral using reverse nibble mode,
until either the user-provided buffer is full or the peripheral
indicates that there is no more data.
If there was data, stop, and return it.
Otherwise, we tried to read data and there was none. If the user
opened the device node with the O_NONBLOCK
flag, return. Otherwise wait until an interrupt occurs on the
port (or a timeout elapses).
User-level device drivers
Introduction to ppdev
The printer is accessible through /dev/lp0;
in the same way, the parallel port itself is accessible through
/dev/parport0. The difference is in the
level of control that you have over the wires in the parallel port
cable.
With the printer driver, a user-space program (such as the printer
spooler) can send bytes in printer protocol
.
Briefly, this means that for each byte, the eight data lines are
set up, then a strobe
line tells the printer to
look at the data lines, and the printer sets an
acknowledgement
line to say that it got the byte.
The printer driver also allows the user-space program to read
bytes in nibble mode
, which is a way of
transferring data from the peripheral to the computer half a byte
at a time (and so it's quite slow).
In contrast, the ppdev driver (accessed via
/dev/parport0) allows you to:
examine status lines,
set control lines,
set/examine data lines (and control the direction of the data
lines),
wait for an interrupt (triggered by one of the status lines),
find out how many new interrupts have occurred,
set up a response to an interrupt,
use IEEE 1284 negotiation (for telling peripheral which transfer
mode, to use)
transfer data using a specified IEEE 1284 mode.
User-level or kernel-level driver?
The decision of whether to choose to write a kernel-level device
driver or a user-level device driver depends on several factors.
One of the main ones from a practical point of view is speed:
kernel-level device drivers get to run faster because they are not
preemptable, unlike user-level applications.
Another factor is ease of development. It is in general easier to
write a user-level driver because (a) one wrong move does not
result in a crashed machine, (b) you have access to user libraries
(such as the C library), and (c) debugging is easier.
Programming interface
The ppdev interface is largely the same as that
of other character special devices, in that it supports
open, close,
read, write, and
ioctl. The constants for the
ioctl commands are in
include/linux/ppdev.h.
Starting and stopping: open and
close
The device node /dev/parport0 represents any
device that is connected to parport0, the
first parallel port in the system. Each time the device node is
opened, it represents (to the process doing the opening) a
different device. It can be opened more than once, but only one
instance can actually be in control of the parallel port at any
time. A process that has opened
/dev/parport0 shares the parallel port in
the same way as any other device driver. A user-land driver may
be sharing the parallel port with in-kernel device drivers as
well as other user-land drivers.
Control: ioctl
Most of the control is done, naturally enough, via the
ioctl call. Using
ioctl, the user-land driver can control both
the ppdev driver in the kernel and the
physical parallel port itself. The ioctl
call takes as parameters a file descriptor (the one returned from
opening the device node), a command, and optionally (a pointer
to) some data.
PPCLAIM
Claims access to the port. As a user-land device driver
writer, you will need to do this before you are able to
actually change the state of the parallel port in any way.
Note that some operations only affect the
ppdev driver and not the port, such as
PPSETMODE; they can be performed while
access to the port is not claimed.
PPEXCL
Instructs the kernel driver to forbid any sharing of the port
with other drivers, i.e. it requests exclusivity. The
PPEXCL command is only valid when the
port is not already claimed for use, and it may mean that the
next PPCLAIM ioctl
will fail: some other driver may already have registered
itself on that port.
Most device drivers don't need exclusive access to the port.
It's only provided in case it is really needed, for example
for devices where access to the port is required for extensive
periods of time (many seconds).
Note that the PPEXCL
ioctl doesn't actually claim the port
there and then---action is deferred until the
PPCLAIM ioctl is
performed.
PPRELEASE
Releases the port. Releasing the port undoes the effect of
claiming the port. It allows other device drivers to talk to
their devices (assuming that there are any).
PPYIELD
Yields the port to another driver. This
ioctl is a kind of short-hand for
releasing the port and immediately reclaiming it. It gives
other drivers a chance to talk to their devices, but
afterwards claims the port back. An example of using this
would be in a user-land printer driver: once a few characters
have been written we could give the port to another device
driver for a while, but if we still have characters to send to
the printer we would want the port back as soon as possible.
It is important not to claim the parallel port for too long,
as other device drivers will have no time to service their
devices. If your device does not allow for parallel port
sharing at all, it is better to claim the parallel port
exclusively (see PPEXCL).
PPNEGOT
Performs IEEE 1284 negotiation into a particular mode.
Briefly, negotiation is the method by which the host and the
peripheral decide on a protocol to use when transferring data.
An IEEE 1284 compliant device will start out in compatibility
mode, and then the host can negotiate to another mode (such as
ECP).
The ioctl parameter should be a pointer
to an int; values for this are in
incluce/linux/parport.h and include:
IEEE1284_MODE_COMPAT
IEEE1284_MODE_NIBBLE
IEEE1284_MODE_BYTE
IEEE1284_MODE_EPP
IEEE1284_MODE_ECP
The PPNEGOT ioctl
actually does two things: it performs the on-the-wire
negotiation, and it sets the behaviour of subsequent
read/write calls so
that they use that mode (but see
PPSETMODE).
PPSETMODE
Sets which IEEE 1284 protocol to use for the
read and write
calls.
The ioctl parameter should be a pointer
to an int.
PPGETMODE
Retrieves the current IEEE 1284 mode to use for
read and write.
PPGETTIME
Retrieves the time-out value. The read
and write calls will time out if the
peripheral doesn't respond quickly enough. The
PPGETTIME ioctl
retrieves the length of time that the peripheral is allowed to
have before giving up.
The ioctl parameter should be a pointer
to a struct timeval.
PPSETTIME
Sets the time-out. The ioctl parameter
should be a pointer to a struct
timeval.
PPGETMODES
Retrieves the capabilities of the hardware (i.e. the
modes field of the
parport structure).
PPSETFLAGS
Sets flags on the ppdev device which can
affect future I/O operations. Available flags are:
PP_FASTWRITE
PP_FASTREAD
PP_W91284PIC
PPWCONTROL
Sets the control lines. The ioctl
parameter is a pointer to an unsigned char, the
bitwise OR of the control line values in
include/linux/parport.h.
PPRCONTROL
Returns the last value written to the control register, in the
form of an unsigned char: each bit corresponds to
a control line (although some are unused). The
ioctl parameter should be a pointer to an
unsigned char.
This doesn't actually touch the hardware; the last value
written is remembered in software. This is because some
parallel port hardware does not offer read access to the
control register.
The control lines bits are defined in
include/linux/parport.h:
PARPORT_CONTROL_STROBE
PARPORT_CONTROL_AUTOFD
PARPORT_CONTROL_SELECT
PARPORT_CONTROL_INIT
PPFCONTROL
Frobs the control lines. Since a common operation is to
change one of the control signals while leaving the others
alone, it would be quite inefficient for the user-land driver
to have to use PPRCONTROL, make the
change, and then use PPWCONTROL. Of
course, each driver could remember what state the control
lines are supposed to be in (they are never changed by
anything else), but in order to provide
PPRCONTROL, ppdev
must remember the state of the control lines anyway.
The PPFCONTROL ioctl
is for frobbing
control lines, and is like
PPWCONTROL but acts on a restricted set
of control lines. The ioctl parameter is
a pointer to a struct
ppdev_frob_struct:
The mask and
val fields are bitwise ORs of
control line names (such as in
PPWCONTROL). The operation performed by
PPFCONTROL is:
In other words, the signals named in
mask are set to the values in
val.
PPRSTATUS
Returns an unsigned char containing bits set for
each status line that is set (for instance,
PARPORT_STATUS_BUSY). The
ioctl parameter should be a pointer to an
unsigned char.
PPDATADIR
Controls the data line drivers. Normally the computer's
parallel port will drive the data lines, but for byte-wide
transfers from the peripheral to the host it is useful to turn
off those drivers and let the peripheral drive the
signals. (If the drivers on the computer's parallel port are
left on when this happens, the port might be damaged.)
This is only needed in conjunction with
PPWDATA or
PPRDATA.
The ioctl parameter is a pointer to an
int. If the int is zero, the
drivers are turned on (forward direction); if non-zero, the
drivers are turned off (reverse direction).
PPWDATA
Sets the data lines (if in forward mode). The
ioctl parameter is a pointer to an
unsigned char.
PPRDATA
Reads the data lines (if in reverse mode). The
ioctl parameter is a pointer to an
unsigned char.
PPCLRIRQ
Clears the interrupt count. The ppdev
driver keeps a count of interrupts as they are triggered.
PPCLRIRQ stores this count in an
int, a pointer to which is passed in as the
ioctl parameter.
In addition, the interrupt count is reset to zero.
PPWCTLONIRQ
Set a trigger response. Afterwards when an interrupt is
triggered, the interrupt handler will set the control lines as
requested. The ioctl parameter is a
pointer to an unsigned char, which is interpreted
in the same way as for PPWCONTROL.
The reason for this ioctl is simply
speed. Without this ioctl, responding to
an interrupt would start in the interrupt handler, switch
context to the user-land driver via poll
or select, and then switch context back
to the kernel in order to handle
PPWCONTROL. Doing the whole lot in the
interrupt handler is a lot faster.
Transferring data: read and
write
Transferring data using read and
write is straightforward. The data is
transferring using the current IEEE 1284 mode (see the
PPSETMODE ioctl). For
modes which can only transfer data in one direction, only the
appropriate function will work, of course.
Waiting for events: poll and
select
The ppdev driver provides user-land device
drivers with the ability to wait for interrupts, and this is done
using poll (and select,
which is implemented in terms of poll).
When a user-land device driver wants to wait for an interrupt, it
sleeps with poll. When the interrupt
arrives, ppdev wakes it up (with a
read
event, although strictly speaking there is
nothing to actually read).
Examples
Presented here are two demonstrations of how to write a simple
printer driver for ppdev. Firstly we will
use the write function, and after that we
will drive the control and data lines directly.
The first thing to do is to actually open the device.
Here name should be something along the lines
of "/dev/parport0". (If you don't have any
/dev/parport files, you can make them with
mknod; they are character special device nodes
with major 99.)
In order to do anything with the port we need to claim access to
it.
Our printer driver will copy its input (from
stdin) to the printer, and it can do that it
one of two ways. The first way is to hand it all off to the
kernel driver, with the knowledge that the protocol that the
printer speaks is IEEE 1284's compatibility
mode.
0) {
int written = write_printer (fd, ptr, got);
if (written < 0) {
perror ("write");
close (fd);
return 1;
}
ptr += written;
got -= written;
}
}
]]>
The write_printer function is not pictured
above. This is because the main loop that is shown can be used
for both methods of driving the printer. Here is one
implementation of write_printer:
We hand the data to the kernel-level driver (using
write) and it handles the printer
protocol.
Now let's do it the hard way! In this particular example there is
no practical reason to do anything other than just call
write, because we know that the printer talks
an IEEE 1284 protocol. On the other hand, this particular example
does not even need a user-land driver since there is already a
kernel-level one; for the purpose of this discussion, try to
imagine that the printer speaks a protocol that is not already
implemented under Linux.
So, here is the alternative implementation of
write_printer (for brevity, error checking
has been omitted):
To show a bit more of the ppdev interface,
here is a small piece of code that is intended to mimic the
printer's side of printer protocol.
1)
fprintf (stderr, "Arghh! Missed %d interrupt%s!\n",
irqc - 1, irqc == 2 ? "s" : "");
/* Ack it. */
ioctl (fd, PPWCONTROL, &acking);
usleep (2);
ioctl (fd, PPWCONTROL, &busy);
putchar (ch);
}
]]>
And here is an example (with no error checking at all) to show how
to read data from the port, using ECP mode, with optional
negotiation to ECP mode first.
Linux parallel port driver API reference
!Fdrivers/parport/daisy.c parport_device_num
!Fdrivers/parport/daisy.c parport_device_coords
!Fdrivers/parport/daisy.c parport_find_device
!Fdrivers/parport/daisy.c parport_find_class
!Fdrivers/parport/share.c parport_register_driver
!Fdrivers/parport/share.c parport_unregister_driver
!Fdrivers/parport/share.c parport_get_port
!Fdrivers/parport/share.c parport_put_port
!Fdrivers/parport/share.c parport_find_number parport_find_base
!Fdrivers/parport/share.c parport_register_device
!Fdrivers/parport/share.c parport_unregister_device
!Fdrivers/parport/daisy.c parport_open
!Fdrivers/parport/daisy.c parport_close
!Fdrivers/parport/share.c parport_claim
!Fdrivers/parport/share.c parport_claim_or_block
!Fdrivers/parport/share.c parport_release
!Finclude/linux/parport.h parport_yield
!Finclude/linux/parport.h parport_yield_blocking
!Fdrivers/parport/ieee1284.c parport_negotiate
!Fdrivers/parport/ieee1284.c parport_write
!Fdrivers/parport/ieee1284.c parport_read
!Fdrivers/parport/ieee1284.c parport_set_timeout
The Linux 2.2 Parallel Port Subsystem
Although the interface described in this document is largely new
with the 2.4 kernel, the sharing mechanism is available in the 2.2
kernel as well. The functions available in 2.2 are:
parport_register_device
parport_unregister_device
parport_claim
parport_claim_or_block
parport_release
parport_yield
parport_yield_blocking
In addition, negotiation to reverse nibble mode is supported:
int parport_ieee1284_nibble_mode_ok
struct parport *port
unsigned char mode
The only valid values for mode are 0 (for
reverse nibble mode) and 4 (for Device ID in reverse nibble mode).
This function is obsoleted by
parport_negotiate in Linux 2.4, and has been
removed.
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Front-Cover Texts, write "no Front-Cover Texts" instead of
"Front-Cover Texts being LIST"; likewise for Back-Cover Texts.
If your document contains nontrivial examples of program code, we
recommend releasing these examples in parallel under your choice of
free software license, such as the GNU General Public License,
to permit their use in free software.