2
0
mirror of https://github.com/edk2-porting/linux-next.git synced 2024-12-27 14:43:58 +08:00
linux-next/Documentation/networking/PLIP.txt
Linus Torvalds 1da177e4c3 Linux-2.6.12-rc2
Initial git repository build. I'm not bothering with the full history,
even though we have it. We can create a separate "historical" git
archive of that later if we want to, and in the meantime it's about
3.2GB when imported into git - space that would just make the early
git days unnecessarily complicated, when we don't have a lot of good
infrastructure for it.

Let it rip!
2005-04-16 15:20:36 -07:00

216 lines
8.0 KiB
Plaintext

PLIP: The Parallel Line Internet Protocol Device
Donald Becker (becker@super.org)
I.D.A. Supercomputing Research Center, Bowie MD 20715
At some point T. Thorn will probably contribute text,
Tommy Thorn (tthorn@daimi.aau.dk)
PLIP Introduction
-----------------
This document describes the parallel port packet pusher for Net/LGX.
This device interface allows a point-to-point connection between two
parallel ports to appear as a IP network interface.
What is PLIP?
=============
PLIP is Parallel Line IP, that is, the transportation of IP packages
over a parallel port. In the case of a PC, the obvious choice is the
printer port. PLIP is a non-standard, but [can use] uses the standard
LapLink null-printer cable [can also work in turbo mode, with a PLIP
cable]. [The protocol used to pack IP packages, is a simple one
initiated by Crynwr.]
Advantages of PLIP
==================
It's cheap, it's available everywhere, and it's easy.
The PLIP cable is all that's needed to connect two Linux boxes, and it
can be built for very few bucks.
Connecting two Linux boxes takes only a second's decision and a few
minutes' work, no need to search for a [supported] netcard. This might
even be especially important in the case of notebooks, where netcards
are not easily available.
Not requiring a netcard also means that apart from connecting the
cables, everything else is software configuration [which in principle
could be made very easy.]
Disadvantages of PLIP
=====================
Doesn't work over a modem, like SLIP and PPP. Limited range, 15 m.
Can only be used to connect three (?) Linux boxes. Doesn't connect to
an existing Ethernet. Isn't standard (not even de facto standard, like
SLIP).
Performance
===========
PLIP easily outperforms Ethernet cards....(ups, I was dreaming, but
it *is* getting late. EOB)
PLIP driver details
-------------------
The Linux PLIP driver is an implementation of the original Crynwr protocol,
that uses the parallel port subsystem of the kernel in order to properly
share parallel ports between PLIP and other services.
IRQs and trigger timeouts
=========================
When a parallel port used for a PLIP driver has an IRQ configured to it, the
PLIP driver is signaled whenever data is sent to it via the cable, such that
when no data is available, the driver isn't being used.
However, on some machines it is hard, if not impossible, to configure an IRQ
to a certain parallel port, mainly because it is used by some other device.
On these machines, the PLIP driver can be used in IRQ-less mode, where
the PLIP driver would constantly poll the parallel port for data waiting,
and if such data is available, process it. This mode is less efficient than
the IRQ mode, because the driver has to check the parallel port many times
per second, even when no data at all is sent. Some rough measurements
indicate that there isn't a noticeable performance drop when using IRQ-less
mode as compared to IRQ mode as far as the data transfer speed is involved.
There is a performance drop on the machine hosting the driver.
When the PLIP driver is used in IRQ mode, the timeout used for triggering a
data transfer (the maximal time the PLIP driver would allow the other side
before announcing a timeout, when trying to handshake a transfer of some
data) is, by default, 500usec. As IRQ delivery is more or less immediate,
this timeout is quite sufficient.
When in IRQ-less mode, the PLIP driver polls the parallel port HZ times
per second (where HZ is typically 100 on most platforms, and 1024 on an
Alpha, as of this writing). Between two such polls, there are 10^6/HZ usecs.
On an i386, for example, 10^6/100 = 10000usec. It is easy to see that it is
quite possible for the trigger timeout to expire between two such polls, as
the timeout is only 500usec long. As a result, it is required to change the
trigger timeout on the *other* side of a PLIP connection, to about
10^6/HZ usecs. If both sides of a PLIP connection are used in IRQ-less mode,
this timeout is required on both sides.
It appears that in practice, the trigger timeout can be shorter than in the
above calculation. It isn't an important issue, unless the wire is faulty,
in which case a long timeout would stall the machine when, for whatever
reason, bits are dropped.
A utility that can perform this change in Linux is plipconfig, which is part
of the net-tools package (its location can be found in the
Documentation/Changes file). An example command would be
'plipconfig plipX trigger 10000', where plipX is the appropriate
PLIP device.
PLIP hardware interconnection
-----------------------------
PLIP uses several different data transfer methods. The first (and the
only one implemented in the early version of the code) uses a standard
printer "null" cable to transfer data four bits at a time using
data bit outputs connected to status bit inputs.
The second data transfer method relies on both machines having
bi-directional parallel ports, rather than output-only ``printer''
ports. This allows byte-wide transfers and avoids reconstructing
nibbles into bytes, leading to much faster transfers.
Parallel Transfer Mode 0 Cable
==============================
The cable for the first transfer mode is a standard
printer "null" cable which transfers data four bits at a time using
data bit outputs of the first port (machine T) connected to the
status bit inputs of the second port (machine R). There are five
status inputs, and they are used as four data inputs and a clock (data
strobe) input, arranged so that the data input bits appear as contiguous
bits with standard status register implementation.
A cable that implements this protocol is available commercially as a
"Null Printer" or "Turbo Laplink" cable. It can be constructed with
two DB-25 male connectors symmetrically connected as follows:
STROBE output 1*
D0->ERROR 2 - 15 15 - 2
D1->SLCT 3 - 13 13 - 3
D2->PAPOUT 4 - 12 12 - 4
D3->ACK 5 - 10 10 - 5
D4->BUSY 6 - 11 11 - 6
D5,D6,D7 are 7*, 8*, 9*
AUTOFD output 14*
INIT output 16*
SLCTIN 17 - 17
extra grounds are 18*,19*,20*,21*,22*,23*,24*
GROUND 25 - 25
* Do not connect these pins on either end
If the cable you are using has a metallic shield it should be
connected to the metallic DB-25 shell at one end only.
Parallel Transfer Mode 1
========================
The second data transfer method relies on both machines having
bi-directional parallel ports, rather than output-only ``printer''
ports. This allows byte-wide transfers, and avoids reconstructing
nibbles into bytes. This cable should not be used on unidirectional
``printer'' (as opposed to ``parallel'') ports or when the machine
isn't configured for PLIP, as it will result in output driver
conflicts and the (unlikely) possibility of damage.
The cable for this transfer mode should be constructed as follows:
STROBE->BUSY 1 - 11
D0->D0 2 - 2
D1->D1 3 - 3
D2->D2 4 - 4
D3->D3 5 - 5
D4->D4 6 - 6
D5->D5 7 - 7
D6->D6 8 - 8
D7->D7 9 - 9
INIT -> ACK 16 - 10
AUTOFD->PAPOUT 14 - 12
SLCT->SLCTIN 13 - 17
GND->ERROR 18 - 15
extra grounds are 19*,20*,21*,22*,23*,24*
GROUND 25 - 25
* Do not connect these pins on either end
Once again, if the cable you are using has a metallic shield it should
be connected to the metallic DB-25 shell at one end only.
PLIP Mode 0 transfer protocol
=============================
The PLIP driver is compatible with the "Crynwr" parallel port transfer
standard in Mode 0. That standard specifies the following protocol:
send header nibble '0x8'
count-low octet
count-high octet
... data octets
checksum octet
Each octet is sent as
<wait for rx. '0x1?'> <send 0x10+(octet&0x0F)>
<wait for rx. '0x0?'> <send 0x00+((octet>>4)&0x0F)>
To start a transfer the transmitting machine outputs a nibble 0x08.
That raises the ACK line, triggering an interrupt in the receiving
machine. The receiving machine disables interrupts and raises its own ACK
line.
Restated:
(OUT is bit 0-4, OUT.j is bit j from OUT. IN likewise)
Send_Byte:
OUT := low nibble, OUT.4 := 1
WAIT FOR IN.4 = 1
OUT := high nibble, OUT.4 := 0
WAIT FOR IN.4 = 0