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:

	
struct ppdev_frob_struct {
        unsigned char mask;
        unsigned char val;
};
	
       

The mask and val fields are bitwise ORs of control line names (such as in PPWCONTROL). The operation performed by PPFCONTROL is:

	
	new_ctr = (old_ctr & ~mask) | val;
       

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).