README.protocol

This file is an explanation of what I've figured out about control codes
for StyleWriter printers.  If you just want to use the driver, you
don't need to read any further -- this is here purely to satisfy
curiosity about how the driver works (or fails to work, as the
case may be).

If you have specific questions you would like to see answered here in
future versions, send them to monroe@pobox.com.


All StyleWriters use a serial interface.  They have a standard RS422
DIN8 plug, which is electrically compatible with RS232 given the
right plug adapter.  At power-on, they default to communicating at
57600 baud, and later models can be put into a mode where they
externally clock the serial port at a rate close to 1 megabit.

The communication protocol with the printer uses _no_ flow control
in the traditional sense.  There is no hardware handshaking and
no XON/XOFF flow control.  The driver must be aware of the size of
the printer's buffer, and not send too much data at one time.  One
of the codes the driver can send causes the printer to return a
byte which seems to indicate how full its buffer is.  The driver
could potentially use this information to keep feeding data as
quickly as possible, but it currently just waits for the buffer to
drain completely before sending more data.

This protocol is the main reason that the driver is a standalone
program, and not simply a driver module in ghostscript.  When I
started work on the driver, I looked into making a gs driver module,
but the architecture didn't seem to support two-way communication
with the printer.  It's possible that later versions of ghostscript
have removed this limitation, but I haven't looked at it lately.

StyleWriters are rather unforgiving to experimentation.  Sending
a control code that the printer doesn't understand or a buffer of
image data that has been encoded incorrectly causes the printer to
eject the page and reset itself.  


Sending the question mark character '?' causes the printer to return
a string identifying which model it is.  The string is terminated
with a carriage return (character 0x0D).

All other control codes seem to be of one of two types.  One type
consists of four characters; three 0xFF bytes followed by a one-byte
code.  The other type consists of one- or two-byte codes that are
not preceeded by 0xFF bytes.  The first type causes the printer to
send back one byte of data, usually some sort of error code or
configuration information.  The second type causes no reply.  I
speculate that the first type could be sent in the middle of a
block of image data -- because of the data encoding used, there
should never be three 0xFF bytes in a row in the image data.

All of the definitions of control codes given here were arrived at
by deduction or simple trial and error.  This should not be taken
as definitive information.  If you find errors or omissions in this
list, or figure out anything interesting that belongs here, please
send your information to monroe@pobox.com.



Known ident strings:

"IJ10\r" = StyleWriter I
"SW\r"   = StyleWriter II
"SW3\r"  = StyleWriter 1200
"CS\r"   = Color Stylewriter 1500, 2200, 2400 or 2500

Type 1 codes (prefix these with "\xFF\xFF\xFF"):

"I" - Ejects the page and resets the printer.
"1" - Returns something about the status of the printer.
"2" - Returns error status of the printer.  The return value may actually 
	consist of bitfields.  Known return values:
	0x00 -- nothing wrong
	0x80 -- nothing wrong (possibly "bad command?)
	0x04 -- printer is out of paper

"B" - Returns the status of the printer's buffer.  The meaning of the
	return value is different on different printer models.  On the 2400,
	0xF8 means the buffer is empty, and lower values indicate more data
	in the buffer.  On the 2500, 0x80 means the buffer is empty, and lower
	values indicate more data in the buffer.  I don't know what values
	indicate a completely full buffer on either model.

"p" - Distinguishes between the printers that return 'CS'.  Known return 
	values:
	0x01 -- StyleWriter 2400
	0x02 -- StyleWriter 2200
	0x04 -- StyleWriter 1500
	0x05 -- StyleWriter 2500
	Honorable mention goes to the person who finds a printer with 0x03 as 
	its 'p' code.

"S" - Tells the printer to try again after it has reported being out of
	paper.  This code is only known to work on the 2400/2500.

"H" - Tells something about the configuration of the printer.  The return
	value may actually consist of bitfields.  Known return values:
	0x01 -- Black ink cartridge installed (in 2400/2500)
	0x81 -- Color ink cartridge installed (in 2400/2500)

"R" - Not sure, but it seems to have something to do with turning on
	high-quality printing on the 2400/2500.


Type 2 codes (sent by themselves):

"?" - Tells the printer to return its ID string.

"\x0C" - Marks the end of the data for a page.

"nuA" - Start a new page on a StyleWriter I.

"L" - Start a new page on all other StyleWriters.

The following were gleaned from the MacOS printer drivers, and are used while
setting up the printer.  I don't know exactly what some of them do.

"D" - I don't remember.

"N" - I don't remember.

"m0nZAH" - Sets up for normal-quality printing.

"m0sAB" - Sets up for high-quality printing.


Image Data
----------

Bitmap data for the printer to print is sent in encoded blocks.
Each block consists of a rectangle in printer coordinates, the
two-byte length of the data, and the encoded scanlines in top-to-bottom
order.  Printer coordinates have (0,0) at the top left of the
_printable_ area of the page.  This means that the top and left
margins must be dealt with by the driver.  Very similar formats
are used for monochrome and color data.

The overall format of a data block is as follows:

'R' for monochrome or 'c' for color
<LSB of rect.left>
<MSB of rect.left>
<LSB of rect.top>
<MSB of rect.top>
<LSB of rect.right>
<MSB of rect.right>
<LSB of rect.bottom>
<MSB of rect.bottom>
'G'
<LSB of size>
<MSB of size>
<'size' bytes of encoded data>
'\0'

Bitmap data is encoded using a modified RLE scheme with differencing
from previous lines.  The differencing algorithm is reset for each
new block of data that is sent.  For color data, the bitmap for
each plane (C,M,Y,K) is encoded separately and the encoded data
for the planes in each scanline is interleaved in CMYK order.

The encoding scheme is best described by the code in the function
encodescanline().  The code was written while figuring out the
encoding scheme by trial-and-error.  During the course of this it
was redesigned and rewritten several times, and it's not pretty,
but it works.