xref: /freebsd/share/man/man4/ppbus.4 (revision c6063d0da8e1f8d8452b0c2ee1c7ad718c1a7052)
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25.\" $FreeBSD$
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27.Dd March 1, 1998
28.Dt PPBUS 4
29.Os
30.Sh NAME
31.Nm ppbus
32.Nd Parallel Port Bus system
33.Sh SYNOPSIS
34.Cd "device ppbus"
35.Pp
36.Cd "device vpo"
37.Pp
38.Cd "device lpt"
39.Cd "device plip"
40.Cd "device ppi"
41.Cd "device pps"
42.Cd "device lpbb"
43.Sh DESCRIPTION
44The
45.Em ppbus
46system provides a uniform, modular and architecture-independent
47system for the implementation of drivers to control various parallel devices,
48and to utilize different parallel port chipsets.
49.Sh DEVICE DRIVERS
50In order to write new drivers or port existing drivers, the ppbus system
51provides the following facilities:
52.Bl -bullet -offset indent
53.It
54architecture-independent macros or functions to access parallel ports
55.It
56mechanism to allow various devices to share the same parallel port
57.It
58a user interface named
59.Xr ppi 4
60that allows parallel port access from outside the kernel without conflicting
61with kernel-in drivers.
62.El
63.Ss Developing new drivers
64The ppbus system has been designed to support the development of standard
65and non-standard software:
66.Pp
67.Bl -column "Driver" -compact
68.It Em Driver Ta Em Description
69.It Sy vpo Ta "VPI0 parallel to Adaptec AIC-7110 SCSI controller driver" .
70It uses standard and non-standard parallel port accesses.
71.It Sy ppi Ta "Parallel port interface for general I/O"
72.It Sy pps Ta "Pulse per second Timing Interface"
73.It Sy lpbb Ta "Philips official parallel port I2C bit-banging interface"
74.El
75.Ss Porting existing drivers
76Another approach to the ppbus system is to port existing drivers.
77Various drivers have already been ported:
78.Pp
79.Bl -column "Driver" -compact
80.It Em Driver Ta Em Description
81.It Sy lpt Ta "lpt printer driver"
82.It Sy plip Ta "lp parallel network interface driver"
83.El
84.Pp
85ppbus should let you port any other software even from other operating systems
86that provide similar services.
87.Sh PARALLEL PORT CHIPSETS
88Parallel port chipset support is provided by
89.Xr ppc 4 .
90.Pp
91The ppbus system provides functions and macros to allocate a new
92parallel port bus, then initialize it and upper peripheral device drivers.
93.Pp
94ppc makes chipset detection and initialization and then calls ppbus attach
95functions to initialize the ppbus system.
96.Sh PARALLEL PORT MODEL
97The logical parallel port model chosen for the ppbus system is the PC's
98parallel port model.
99Consequently, for the i386 implementation of ppbus,
100most of the services provided by ppc are macros for inb()
101and outb() calls.
102But, for an other architecture, accesses to one of our logical
103registers (data, status, control...) may require more than one I/O access.
104.Ss Description
105The parallel port may operate in the following modes:
106.Bl -bullet -offset indent
107.It
108compatible mode, also called Centronics mode
109.It
110bidirectional 8/4-bits mode, also called NIBBLE mode
111.It
112byte mode, also called PS/2 mode
113.It
114Extended Capability Port mode, ECP
115.It
116Enhanced Parallel Port mode, EPP
117.It
118mixed ECP+EPP or ECP+PS/2 modes
119.El
120.Ss Compatible mode
121This mode defines the protocol used by most PCs to transfer data to a printer.
122In this mode, data is placed on the port's data lines, the printer status is
123checked for no errors and that it is not busy, and then a data Strobe is
124generated by the software to clock the data to the printer.
125.Pp
126Many I/O controllers have implemented a mode that uses a FIFO buffer to
127transfer data with the Compatibility mode protocol.
128This mode is referred to as
129"Fast Centronics" or "Parallel Port FIFO mode".
130.Ss Bidirectional mode
131The NIBBLE mode is the most common way to get reverse channel data from a
132printer or peripheral.
133Combined with the standard host to printer mode, it
134provides a complete bidirectional channel.
135.Pp
136In this mode, outputs are 8-bits long.
137Inputs are accomplished by reading
1384 of the 8 bits of the status register.
139.Ss Byte mode
140In this mode, the data register is used either for outputs and inputs.
141Then,
142any transfer is 8-bits long.
143.Ss Extended Capability Port mode
144The ECP protocol was proposed as an advanced mode for communication with
145printer and scanner type peripherals.
146Like the EPP protocol, ECP mode provides
147for a high performance bidirectional communication path between the host
148adapter and the peripheral.
149.Pp
150ECP protocol features include:
151.Bl -item -offset indent
152.It
153Run_Length_Encoding (RLE) data compression for host adapters
154.It
155FIFOs for both the forward and reverse channels
156.It
157DMA as well as programmed I/O for the host register interface.
158.El
159.Ss Enhanced Parallel Port mode
160The EPP protocol was originally developed as a means to provide a high
161performance parallel port link that would still be compatible with the
162standard parallel port.
163.Pp
164The EPP mode has two types of cycle: address and data.
165What makes the
166difference at hardware level is the strobe of the byte placed on the data
167lines.
168Data are strobed with nAutofeed, addresses are strobed with
169nSelectin signals.
170.Pp
171A particularity of the ISA implementation of the EPP protocol is that an
172EPP cycle fits in an ISA cycle.
173In this fashion, parallel port peripherals can
174operate at close to the same performance levels as an equivalent ISA plug-in
175card.
176.Pp
177At software level, you may implement the protocol you wish, using data and
178address cycles as you want.
179This is for the IEEE1284 compatible part.
180Then,
181peripheral vendors may implement protocol handshake with the following
182status lines: PError, nFault and Select.
183Try to know how these lines toggle
184with your peripheral, allowing the peripheral to request more data, stop the
185transfer and so on.
186.Pp
187At any time, the peripheral may interrupt the host with the nAck signal without
188disturbing the current transfer.
189.Ss Mixed modes
190Some manufacturers, like SMC, have implemented chipsets that support mixed
191modes.
192With such chipsets, mode switching is available at any time by
193accessing the extended control register.
194.Sh IEEE1284-1994 Standard
195.Ss Background
196This standard is also named "IEEE Standard Signaling Method for a
197Bidirectional Parallel Peripheral Interface for Personal Computers".
198It
199defines a signaling method for asynchronous, fully interlocked, bidirectional
200parallel communications between hosts and printers or other peripherals.
201It
202also specifies a format for a peripheral identification string and a method of
203returning this string to the host outside of the bidirectional data stream.
204.Pp
205This standard is architecture independent and only specifies dialog handshake
206at signal level.
207One should refer to architecture specific documentation in
208order to manipulate machine dependent registers, mapped memory or other
209methods to control these signals.
210.Pp
211The IEEE1284 protocol is fully oriented with all supported parallel port
212modes.
213The computer acts as master and the peripheral as slave.
214.Pp
215Any transfer is defined as a finite state automaton.
216It allows software to
217properly manage the fully interlocked scheme of the signaling method.
218The compatible mode is supported "as is" without any negotiation because it
219is compatible.
220Any other mode must be firstly negotiated by the host to check
221it is supported by the peripheral, then to enter one of the forward idle
222states.
223.Pp
224At any time, the slave may want to send data to the host.
225This is only
226possible from forward idle states (nibble, byte, ecp...).
227So, the
228host must have previously negotiated to permit the peripheral to
229request transfer.
230Interrupt lines may be dedicated to the requesting signals
231to prevent time consuming polling methods.
232.Pp
233But peripheral requests are only a hint to the master host.
234If the host
235accepts the transfer, it must firstly negotiate the reverse mode and then
236starts the transfer.
237At any time during reverse transfer, the host may
238terminate the transfer or the slave may drive wires to signal that no more
239data is available.
240.Ss Implementation
241IEEE1284 Standard support has been implemented at the top of the ppbus system
242as a set of procedures that perform high level functions like negotiation,
243termination, transfer in any mode without bothering you with low level
244characteristics of the standard.
245.Pp
246IEEE1284 interacts with the ppbus system as little as possible.
247That means
248you still have to request the ppbus when you want to access it, the negotiate
249function does not do it for you.
250And of course, release it later.
251.Sh ARCHITECTURE
252.Ss adapter, ppbus and device layers
253First, there is the
254.Em adapter
255layer, the lowest of the ppbus system.
256It provides
257chipset abstraction throw a set of low level functions that maps the logical
258model to the underlying hardware.
259.Pp
260Secondly, there is the
261.Em ppbus
262layer that provides functions to:
263.Bl -enum -offset indent
264.It
265share the parallel port bus among the daisy-chain like connected devices
266.It
267manage devices linked to ppbus
268.It
269propose an arch-independent interface to access the hardware layer.
270.El
271.Pp
272Finally, the
273.Em device
274layer gathers the parallel peripheral device drivers.
275.Ss Parallel modes management
276We have to differentiate operating modes at various ppbus system layers.
277Actually, ppbus and adapter operating modes on one hands and for each
278one, current and available modes are separated.
279.Pp
280With this level of abstraction a particular chipset may commute from any
281native mode to any other mode emulated with extended modes without
282disturbing upper layers.
283For example, most chipsets support NIBBLE mode as
284native and emulated with ECP and/or EPP.
285.Pp
286This architecture should support IEEE1284-1994 modes.
287.Sh FEATURES
288.Ss The boot process
289The boot process starts with the probe stage of the
290.Xr ppc 4
291driver during ISA bus (PC architecture) initialization.
292During attachment of
293the ppc driver, a new ppbus structure is allocated, then probe and attachment
294for this new bus node are called.
295.Pp
296ppbus attachment tries to detect any PnP parallel peripheral (according to
297.%T "Plug and Play Parallel Port Devices"
298draft from (c)1993-4 Microsoft Corporation)
299then probes and attaches known device drivers.
300.Pp
301During probe, device drivers are supposed to request the ppbus and try to
302set their operating mode.
303This mode will be saved in the context structure and
304returned each time the driver requests the ppbus.
305.Ss Bus allocation and interrupts
306ppbus allocation is mandatory not to corrupt I/O of other devices.
307Another
308usage of ppbus allocation is to reserve the port and receive incoming
309interrupts.
310.Pp
311High level interrupt handlers are connected to the ppbus system thanks to the
312newbus
313.Fn BUS_SETUP_INTR
314and
315.Fn BUS_TEARDOWN_INTR
316functions.
317But, in order to attach a handler, drivers must
318own the bus.
319Consequently, a ppbus request is mandatory in order to call the above
320functions (see existing drivers for more info).
321Note that the interrupt handler
322is automatically released when the ppbus is released.
323.Ss Microsequences
324.Em Microsequences
325is a general purpose mechanism to allow fast low-level
326manipulation of the parallel port.
327Microsequences may be used to do either
328standard (in IEEE1284 modes) or non-standard transfers.
329The philosophy of
330microsequences is to avoid the overhead of the ppbus layer and do most of
331the job at adapter level.
332.Pp
333A microsequence is an array of opcodes and parameters.
334Each opcode codes an
335operation (opcodes are described in
336.Xr microseq 9 ) .
337Standard I/O operations are implemented at ppbus level whereas basic I/O
338operations and microseq language are coded at adapter level for efficiency.
339.Pp
340As an example, the
341.Xr vpo 4
342driver uses microsequences to implement:
343.Bl -bullet -offset indent
344.It
345a modified version of the NIBBLE transfer mode
346.It
347various I/O sequences to initialize, select and allocate the peripheral
348.El
349.Sh SEE ALSO
350.Xr lpt 4 ,
351.Xr plip 4 ,
352.Xr ppc 4 ,
353.Xr ppi 4 ,
354.Xr vpo 4
355.Sh HISTORY
356The
357.Nm
358manual page first appeared in
359.Fx 3.0 .
360.Sh AUTHORS
361This
362manual page was written by
363.An Nicolas Souchu .
364