Unsupported devices

These devices are no longer supported and/or superceeded by newer methods. The documentation is kept here for reference. Be advised that these devices will be removed in future versions of Ghostscript.

Supported devices are descripted in Details of Ghostscript output devices.

For other information, see the Ghostscript overview. You may also be interested in how to build Ghostscript and install it, as well as the description of the driver interface.

H-P 8xx, 1100, and 1600 color inkjet printers

This section, written by Uli Wortmann, deals with the DeskJet 670, 690, 850, 855, 870, 890, 1100, and 1600.

Drivers contained in gdevcd8.c

The source module gdevcd8.c contains four generic drivers:

cdj670

HP DeskJet 670 and 690

cdj850

HP DeskJet 850, 855, 870, and 1100

cdj890

HP DeskJet 890

cdj1600

HP DeskJet 1600

Further documentation

Credits: Much of the driver is based on ideas derived from the cdj550 driver of George Cameron. The support for the hp670, hp690, hp890 and hp1600 was added by Martin Gerbershagen.

Date

Version

Comments

11.11.96

Version 1.0

25.08.97

Version 1.2

Resolved all but one of the known bugs,

introduced a couple of perfomance improvements.

Complete new color-transfer-function handling (see gamma).

01.06.98

Version 1.3

Due to the most welcome contribution of

Martin Gerbershagen, support for the

hp670, hp690 and hp890

and hp1600 has been added.

Martin has also resolved all known bugs.

Problems: Dark colors are still pale.

The hp690 is supported through the hp670 device, the hp855, hp870 and the hp1100 through the hp850 device. The driver needs no longer special switches to be invoked except -sDEVICE=cdj850, -sDEVICE=CDJ890, -sDEVICE=CDJ670, or -sDevice=CDJ1600. The following switches are supported:

-dPapertype=

0

plain paper [default]

1

bond paper

2

special paper

3

glossy film

4

transparency film

Currently the lookup tables are unsuited for printing on special

paper or transparencies. For these please revert to the gamma functions.

-dQuality=

-1

draft

0

normal [default]

1

presentation

-dRetStatus=

0

C-RET off

1

C-RET on [default]

-dMasterGamma=

3.0

[default = 1.0]

Note

To take advantage of the calibrated color-transfer functions, be sure not to have any gamma statements left! If you need to (i.e., for overhead transparencies), you still can use the gamma functions, but they will override the built-in calibration. To use gamma in the traditional way, set MasterGamma to any value greater than 1.0 and less than 10.0. To adjust individual gamma values, you have to additionally set MasterGamma to a value greater than 1.0 and less than 10.0. With the next release, gamma functions will be dropped.

When using the driver, be aware that printing at 600dpi involves processing large amounts of data (> 188MB !). Therefore the driver is not what you would expect to be a fast driver ;-) This is no problem when printing a full-sized color page (because printing itself is slow), but it’s really annoying if you print only text pages. Maybe I can optimize the code for text-only pages in a later release. Right now, it is recommended to use the highest possible optimisation level your compiler offers. For the time being, use the cdj550 device with -sBitsPerPixel=3 for fast proof prints. If you simply want to print 600dpi BW data, use the cdj550 device with -sBitsPerPixel=8 (or 1).

Since the printer itself is slow, it may help to set the process priority of the gs process to “regular” or even less. On a 486/100MHz this is still sufficient to maintain a continuous data flow. Note to OS/2 users: simply put the gs window into the background or minimize it. Also make sure that print01.sys is invoked without the /irq switch (great speed improvement under Warp4).

The printer default settings compensate for dot-gain by a calibrated color-transfer function. If this appears to be too light for your business graphs, or for overhead transparencies, feel free to set -dMasterGamma=1.7. Furthermore, you may tweak the gamma values independently by setting -dGammaValC, -dGammaValM, -dGammaValY or -dGammaValK (if not set, the values default to MasterGamma). This will only work when -dMasterGamma is set to a value greater than 1.0.

Depending on how you transfer the files, under UNIX you may need to remove the CRs of the CR-LF sequence used for end-of-line on DOS-based (MS Windows-based) systems. You can do this in unpacking the files with unzip -a hp850.zip.

To compile with gs5.x or later, simply add to your makefile:

DEVICE_DEVS4=cdj850.dev cdj670.dev cdj890.dev cdj1600.dev

H-P 812, 815, 832, 880, 882, 895, and 970 color inkjet printers

This section, written by Matthew Gelhaus, deals with the DeskJet 812, 815, 832, 880, 882, 895, and 970.

This is a modified version of the HP8xx driver written by Uli Wortmann. More information and download are available at gelhaus.net/hp880c.

Drivers contained in gdevcd8.c

The source module gdevcd8.c contains one generic driver:

cdj880

HP DeskJet 812, 815, 832, 880, 882, 895, and 970

Further documentation

Credits: This driver is based on the cdj850 driver by Uli Wortmann, and shares the same internal structure, although the PCL3+ interpretation has changed.

Date

Version

Comments

15.03.99

Version 1.3

Initial version, based on Version 1.3 of Uli Wortmann’s driver.

26.02.00

Version 1.4beta

Greatly improved color handling & dithering, but not yet complete enough to use for text.

All printers are supported through the cdj880 device. Invoke with -sDEVICE=cdj880. The following switches are supported:

-dPapertype=

0

plain paper [default]

1

bond paper

2

special paper

3

glossy film

4

transparency film

Currently the lookup tables are unsuited for printing on special

paper or transparencies. For these please revert to the gamma functions.

-dQuality=

-1

draft

0

normal [default]

1

presentation

-dMasterGamma=

3.0

[default = 1.0]

The printer default settings compensate for dot-gain by a pre-defined color-transfer function. If this appears to be too light for your business graphs, or for overhead transparencies, feel free to set -dMasterGamma=1.7. Furthermore, you may tweak the gamma values independently by setting -dGammaValC, -dGammaValM, -dGammaValY or -dGammaValK (if not set, the values default to MasterGamma). This will only work when -dMasterGamma is set to a value greater than 1.0.

To compile with gs6.x or later, simply add to your makefile:

DEVICE_DEVS4=$(DD)cdj880.dev

H-P color inkjet printers

This section, written by George Cameron, deals with the DeskJet 500C, DeskJet 550C, PaintJet, PaintJet XL, PaintJet XL300, the DEC LJ250 operating in PaintJet-compatible mode.

Drivers contained in gdevcdj.c

The source module gdevcdj.c contains six generic drivers:

cdj500

HP DeskJet 500C and 540C

cdj550

HP DeskJet 550C, 560C, 660C, 660Cse

pjxl300

HP PaintJet XL300, DeskJet 1200C, and CopyJet

pjtest

HP PaintJet

pjxltest

HP PaintJet XL

declj250

DEC LJ250

All these drivers have 8-bit (monochrome), 16-bit and 24-bit (colour) and for the DJ 550C, 32-bit (colour, CMYK mode) options in addition to standard colour and mono drivers. It is also possible to set various printer-specific parameters from the command line, for example:

gs -sDEVICE=cDeskJet -dBitsPerPixel=16 -dDepletion=1 -dShingling=2 tiger.eps

Note

The old names cdeskjet, cdjcolor and cdjmono drivers have been retained; however, their functionality duplicates that available using the drivers above (and cdeskjet is identical to cdj500). That is, we can use:

gs -sDEVICE=cdj500 -dBitsPerPixel=24   for cdjcolor, and
gs -sDEVICE=cdj500 -dBitsPerPixel=1 for cdjmono

Default paper size

If the preprocessor symbol A4 is defined, the default paper size is ISO A4; otherwise it is U.S. letter size (see about paper sizes in the usage documentation). You can specify other paper sizes on the command line, including A3 for the PaintJet XL and PaintJet XL300, as also explained in the usage documentation.

DeskJet physical limits

The DeskJet’s maximum printing width is 2400 dots, or 8 inches (20.32cm). The printer manuals say that the maximum recommended printing height on the page is 10.3 inches (26.16cm), but since this is obviously not true for A4 paper, and I have been unable to detect any problems in printing longer page lengths, this would seem to be a rather artificial restriction.

All DeskJets have 0.5 inches (1.27cm) of unprintable bottom margin, due to the mechanical arrangement used to grab the paper. Side margins are approximately 0.25 inches (0.64cm) for U.S. letter paper, and 0.15 inches (0.38cm) for A4.

Printer properties (command-line parameters)

Several printer “properties” have been implemented for these printers. Those available so far are all integer quantities, and thus may be specified, for instance, like

gs -dBitsPerPixel=32 -dShingling=1 ...

which sets the BitsPerPixel parameter to 32 and the Shingling parameter to 1.

Bits per pixel

If the preprocessor symbol BITSPERPIXEL is defined as an integer (see below for the range of allowable values), that number defines the default bits per pixel (bit depth) for the generic drivers. If the symbol is undefined, the default is 24 bits per pixel. It is, of course, still possible to specify the value from the command line as described below. Note also that the cDeskJet, cdjcolor and cdjmono drivers are unaffected by setting this symbol, as their default settings are predefined to be 1, 3 and 24 respectively.

All of the drivers in gdevcdj.c accept a command line option to set the BitsPerPixel property. This gives considerable flexibility in choosing various tradeoffs among speed, quality, colour, etc. The valid numbers are:

BITSPERPIXEL

Comments

1

A standard Ghostscript monochrome driver, using black

ink (by installing the separate mono cartridge in the

case of the DeskJet 500C, or automatically for the other printers).

3

A standard Ghostscript colour driver, using internal dithering.

This is fast to compute and to print, but the clustered

dithering can lose some detail and colour fidelity.

8

An “error-diffusion” monochrome driver which uses Floyd-Steinberg

dithering to print greyscale images.

The patterns are much more randomised than with the normal

clustered dithering, but the data files can be much larger

and somewhat slower to print.

16

A “cheaper” version of the 24-bit driver, which generates

Floyd-Steinberg colour dithered output using the minimum

memory (this may be helpful when using Ghostscript has not

been compiled using a 16-bit build environment).

The quality can be almost as good as the 24-bit version.

24

A high-quality colour driver using Floyd-Steinberg

dithering for maximum detail and colour range.

However, it is very memory-intensive, and thus can

be slow to compute. It tends to produce rather

larger raw data files, so they can also take longer to print.

32

Only for the DeskJet 550C, which uses the black cartridge

and the colour cartridge simultaneously (that is, CMYK printing).

This printer can both be faster and give higher quality than

the DeskJet 500C, because of the true black ink.

(Note that the 24-bit mode also permits CMYK printing on

this printer, and uses less memory). Any differences

between 24-bit and 32-bit should be small.

DeskJet properties

Name

Type

Comments

BlackCorrect

int

Colour correction to give better blacks when using

the DJ500C in colour mode. For example, the

default of 4 reduces the cyan component to 4/5.

Range accepted: 0 - 9 (0 = none).

Shingling

int

Interlaced, multi-pass printing:

0 = none, 1 = 50%, 2 = 25%, 2 is best and slowest.

Depletion

int

“Intelligent” dot-removal:

0 = none, 1 = 25%, 2 = 50%, 1 best for graphics?

Use 0 for transparencies.

PaintJet XL300 / PaintJet XL properties

Name

Type

Comments

PrintQuality

int

Mechanical print quality: -1 = fast, 0 = normal, 1 = presentation.

Fast mode reduces ink usage and uses single-pass operation for

some media types. Presentation uses more ink and the maximum number

of passes, giving slowest printing for highest quality.

RenderType

int

0 driver does dithering

1 snap to primaries

2 snap black to white, others to black

3 ordered dither

4 error diffusion

5 monochrome ordered dither

6 monochrome error diffusion

7 cluster ordered dither

8 monochrome cluster ordered dither

9 user-defined dither (not supported)

10 monochrome user-defined dither ns.

The PaintJet (non-XL) has no additional properties.

Gamma correction

One consequence of using Floyd-Steinberg dithering rather than Ghostscript’s default clustered ordered dither is that it is much more obvious that the ink dots are rather larger on the page than their nominal 1/180-inch or 1/300-inch size (clustering the dots tends to minimise this effect). Thus it is often the case that the printed result is rather too dark. A simple empirical correction for this may be achieved by preceding the actual PostScript file to be printed by a short file which effectively sets the gamma for the device, such as:

gs ... gamma.ps colorpic.ps -c quit

where gamma.ps is:

%!
/.fixtransfer {
  currentcolortransfer 4 {
    mark exch
    dup type dup /arraytype eq exch /packedarraytype eq or
    1 index xcheck and { /exec load } if
    0.333 /exp load
    ] cvx 4 1 roll
  } repeat setcolortransfer
} bind odef
.fixtransfer
/setpagedevice { setpagedevice .fixtransfer } bind odef

This does the gamma correction after whatever correction the device might be doing already. To do the correction before the current correction:

%!
/.fixtransfer {
  currentcolortransfer 4 {
    mark 0.333 /exp load 4 -1 roll
    dup type dup /arraytype eq exch /packedarraytype eq or
    1 index xcheck and { /exec load } if
    ] cvx 4 1 roll
  } repeat setcolortransfer
} bind odef
.fixtransfer
/setpagedevice { setpagedevice .fixtransfer } bind odef

This example sets the gamma for R, G, and B to 3, which seems to work reasonably well in practice.

HP’s resolution-enhanced mode for Inkjet printers

This feature is available on HP’s more recent inkjet printers, including the DeskJet 520 (mono), 540 (mono or colour) and 560C (mono and colour). The colour and monochrome drivers for the HP DeskJet 550c are (probably) the best you will get for use with Ghostscript, for the following reasons.

These printers do not offer true 600×300dpi resolution. Those that print in colour are strictly 300×300dpi in colour mode, while in mono mode there is a pseudo 600×300dpi mode with the restriction that you can’t print two adjacent dots. In effect what you have is 600dpi dot positioning, but on average you don’t get more dots per line. This provides the possibility, for instance, to have sharper character outlines, because you can place dots on the edges nearer to their ideal positions. This is why it is worth doing.

However, HP will not support user-level programming of this resolution-enhanced mode, one reason being that (I understand) all the dot spacing has to be done by the driver, and if you get it wrong, you can actually damage the print head.

To summarise, you may lose a smidgin of (potential) text clarity using the 550c drivers (cdj550, cdjcolor, cdjmono etc.), but other than that, they are the ones for the job.

General tips

For all the printers above, the choice of paper is critically important to the final results. The printer manuals suggest type of paper, but in general, smoother, less fibrous types give better results. In particular, the special ink-jet paper can make a big difference: colours are brighter, but most importantly, there is almost no colour bleed, even with adjacent areas of very heavy inking. Similarly the special coated transparencies also work well (and ordinary transparencies do not work at all!).

The Unix procedure unix-lpr.sh provides one example of setting up a multi-option colour PostScript lpr queue on Unix systems, and includes the ability to choose a range of different colour options and printer accounting and error logging.

Caveat emptor! It is not always easy for me to test all of these drivers, as the only colour printer I have here is the DeskJet 500C. I rely on others to test drivers for the additional machines and report their findings back to me.

Canon BJC-8200 printer

This section was contributed by the author of the uniprint configuration files for the Canon BJC-8200, Stephan C. Buchert. These files also handle the Japanese Canon F850 printer.

Warning

Usage of this program is neither supported nor endorsed by the Canon corporation. Please see the Ghostscript license regarding warranty.

Introduction

The Canon Bubble Jet printer BJC-8200 is designed for printing digital photos and halftone images. Software drivers for Windows 95-2000 and Mac are usually included and can be downloaded from the Canon web sites for the US market. If these drivers cannot be used for some reason, then at present Ghostscript is probably the alternative giving the best results.

The BJC-8200 has features not found among the specs of earlier bubble jet models (except the even more advanced BJC-8500) and is advertised to offer:

  1. Microfine droplet technology.

  2. Support for printing on a new type of paper, Photo Paper Pro.

  3. A printhead capable of printing up to 1200 DpI.

  4. Individual ink tanks for 6 colors.

  5. An internal status monitor reporting low ink back to a driver.

  6. An optional color scanner cartridge for up to 600 DpI resolution.

Access to features 5 and 6 requires use of the original Canon drivers for the foreseeable future. This README is about getting the printer features 1-3 working with Ghostscript. No (re)compilation of Ghostscript is normally required.

Ghostscript comes with a relatively highly configurable driver, called uniprint, for printers which understand raster images in various propriety formats. Most options for this driver are usually organized into files having the suffix .upp. Ghostscript versions >= 5.10 (or even earlier) include such uniprint control files for the Canon BJC-610. They work also well for some other Canon Bubble Jet models, for example for my BJC-35vII. But when using them for a BJC-8200 the result is unsatisfactory.

The uniprint control files for the BJC-8200

After some experimenting with the options for uniprint I have obtained quite satisfactory prints with my printer. This distribution includes six new uniprint control files:

  • bj8pp12f.upp

  • bj8hg12f.upp

  • bj8gc12f.upp

  • bj8oh06n.upp

  • bj8ts06n.upp

  • bj8pa06n.upp

They are included in Ghostscript >=6.21. For older versions you can put them anywhere in the Ghostscript search path (type gs -h to see the path), but should perhaps add the files to the directory with the other *.upp files. This is /usr/share/ghostscript/gs6.01/lib in my RedHat 6.1 Linux box with Aladdin Ghostscript 6.01.

Here is an explanation of my file name convention: the prefix “bj8” should perhaps be used for the Canon BJC-8200 and compatible (like the Japanese F850 and perhaps the non-Japanese BJC-8500) models. The next two letters indicate the print media:

  • pp - “Photo Paper Pro”.

  • hg - “High Gloss Photo Film”.

  • gc - “Glossy Photo Cards”.

  • oh - “OHP transparencies”.

  • ts - “T-shirt transfer”.

  • pa - “Plain Paper”.

The numbers at positions 6 and 7 indicate the resolution

  • 12 - 1200x1200 DpIxDpI.

  • 06 - 600x600 DpIxDpI.

The last letter stands for a quality factor that effects also the print speed (presumably related to the number of passes that the printhead makes).

  • f - highest quality.

  • n - normal quality.

Printing a postcard size (~10x15 cm^2) image at 1200x1200 DpI^2 takes about 3 minutes. The output of Ghostscript is then typically 4-5 MByte. The bootleneck seems to be the transfer of the raster image in run-length encoded Canon format to the printer (via the parallel port on my system) or the printer’s speed, not Ghostscript or the uniprint renderer.

Further Optimization for the Canon BJC-8200

So far I have only experimented with the printer initialization code at the beginning of each page (-dupBeginPageCommand) and the resolution (-r). Other options, particularly the transfer arrays (-dupBlackTransfer, -dupCyanTransfer, -dupMagentaTransfer, -dupYellowTransfer) and the margins (-dupMargins) were simply copied from the files for the BJC-610, but they may need to be changed for optimized performance.

Here is information useful for changing or adding uniprint control files for the BJC-8200:

In -dupBeginPageCommand=... use the line:

1b28 64 0400 04b0 04b0

for 1200x1200 resolution, and:


1b28 64 0400 0258 0258

for 600x600. The -r option in the control file must of course match this line. Other resolutions might work as well, but I didn’t try.

Crucial are the numbers in the lines like:

  1b28 63 0300 3005 04
                  ^  ^
      Plain Paper 0  4 Highest quality
 OHP transparency 2  .
 T-shirt transfer 3  .
Glossy Photo Film 5  .
 High Gloss Paper 6  0 Lowest quality
  Photo Paper Pro 9

Outlook

Presently uniprint can use the black (K), cyan (C), magenta (M), and yellow (Y) colors in the BJC-8200. The unused colors are photo (or light) cyan (c) and magenta (m). Also the Canon driver seems to use only CMYK, for example when printing on Photo Paper Pro in “Camera” or “SuperPhoto” mode. These modes supposedly produce prints of the best quality that the Canon driver can offer. Other modes of Canon driver do use up to all six color cartridges (CMYKcm). Therefore expanding uniprint’s capabilities for six colors would be interesting, but it may not increase the output quality of 6-color printers such as the BJC-8200 drastically.

More control files for uniprint could be added in order to offer more versatility for controlling the BJC-8200 within a Ghostscript installation. The number of possible combinations for media type, resolution and print quality factor is very large, many combinations would not make much sense, many might be used here and there, but relatively rarely. The user would have to remember a name for each combination that is used.

A better way would be to let the user patch optionally a user owned or system wide uniprint control file before each print via some print tool. This is similar to the approach taken by Canon with their driver for Windows. Similarly a uniprint tool could also incorporate other functions such as printing test and demo pages and the low ink warning once the protocol for this is known. Clearly it would be difficult to code such a uniprint tool for all the platforms where Ghostscript is running.

Usage on RedHat Linux

In order to install a BJC-8200 printer on a RedHat Linux system with RedHat’s printtool, you need also to insert with a text editor the contents of the file bj8.rpd into the RedHat printer database /usr/lib/rhs/rhs-printfilters/printerdb. Insert it most appropriately after the section:

StartEntry: U_CanonBJC610
.
.
.
EndEntry

< --- insert here "bj8.rpd" from this distribution:
< --- StartEntry: U_CanonBJC8200
      .
      .
      .

Note

Actually I have a F850, not a BJC-8200. That model is sold for the Japanese market only. The specs and also the external look are the same as those of the BJC-8200 models for the American and European markets. I expect that the raster image mode which is used exclusively by Ghostscript is entirely compatible for both models.

Other Canon BubbleJet (BJC) printers

This section was contributed by the author of the drivers, Yves Arrouye. The drivers handle Canon BJC-600, BJC-4xxx, BJC-70, Stylewriter 2x00, and BJC-800 printers.

History

The BJC-600 driver was written in the first place by Yoshio Kuniyoshi and later modified by Yves Arrouye. We tried to make it evolve synchronously, though Yoshio cannot be reached since a long time ago. The drivers are based on code for the HP printers by George Cameron (in fact, they are in the same file!), so he’s the first person to thank.

The 2.00 version of the drivers was a complete rewrite of the driver (arguments, optimization, colour handling, in short: everything!) by Yves Arrouye. That release was also the first one to be able to use the full width of an A3 paper size. PostScript Printer Description (PPD) files for the drivers were released with version 2.15. They are incomplete, but they can be used to drive the printers’ main features.

Configuring and building the BJC drivers

Modify values in gdevbjc.h.

Configure the drivers by modifying the default values in the file gdevbjc.h or on the compilation line. If you don’t do that, the drivers use reasonable defaults that make them work “as expected”. All default values shown here are defined in that file.

CMYK-to-RGB color conversion

By default, the drivers use the same algorithm as Ghostscript to convert CMYK colors to RGB. If you prefer to use Adobe formulas, define USE_ADOBE_CMYK_RGB when compiling. (See the top of the file gdevcdj.c to see the difference between the two.)

Vertical centering of the printable area

The drivers center the imageable area horizontally but not vertically, so that what can be printed does use the most of the output media. If you define BJC_DEFAULT_CENTEREDAREA when compiling, then the top and bottom margins will be the same, resulting in a (smaller) vertically centered imageable area also.

Page margins

If you define USE_RECOMMENDED_MARGINS, then the top and bottom margins will be the same (that is, BJC_DEFAULT_CENTEREDAREA will be defined for you) and the margins will be the 12.4mm recommended by Canon. Since margins are complicated (because one must rely on the mechanical precision of the printer), the drivers do something about the bottom margin: by default the bottom margin is 9.54mm for the BJC-600 driver and 7mm for the BJC-800. If you define USE_TIGHT_MARGINS, then the bottom margin is 7mm for both drivers (but I never managed to get my own BJC-600 to print a line on this low bound, hence the larger default). Regardless of the presence of this definition, USE_FIXED_MARGINS will not allow the BJC-800 to use the lower 7mm bottom margin, so if you have a problem with the bottom margin on a BJC-800, just define that (without defining USE_TIGHT_MARGINS, of course).

A quick way to be sure the margins you selected is to print a file whose contents are:

%!
clippath stroke showpage

If the margins are okay, you will get a rectangle visibly surrounding the printable area. If they’re not correct, one or more of the sides will be either incomplete or completely unprinted.

Makefile and compilation

Make sure the bjc600 or bjc800 devices are in DEVICE_DEVS in the makefile; that is, look in the makefile for your platform and add them if necessary – they may already be there. As of Ghostscript 5.10, for instance, one makefile has:

DEVICE_DEVS6=bj10e.dev bj200.dev bjc600.dev bjc800.dev

Use of the drivers

There are two drivers here. The bjc600 one supports the BJC-600 and BJC-4xxx (maybe the BJC-70 as well) and the bjc800 one supports the BJC-800 series. Remarks here that apply to both drivers use the name bjc.

Supported Options and Defaults

Note

“options”, “properties”, and “parameters” designate the same thing: device parameters that you can change.

Giving an option an incorrect value causes an error. Unless stated otherwise, this error will be a rangecheckerror. Options may be set from the Ghostscript command line (using the -d and -s switches or other predetermined switches if they have an effect on the driver) or using the PostScript Level 2 setpagedevice operator if Ghostscript has been compiled with the level2 or level3 device (which it should ;-)). There are no special-purpose operators such as one was able to find in Level 1 printers.

The bjc uses 24 bits per pixel by default (unless you change the value of BJC_BITSPERPIXEL), corresponding to CMYK printing. Supported modes are 1 bpp and 4 bpp (gray levels), 8 bpp, 16 bpp, 24 bpp and 32 bpp (colours). Colours are preferably stored in the CMYK model (which means, for example, that with 16 bpp there are only 16 different shades of each color) but it is possible to store them as RGB color for some depths. Some modes do Floyd-Steinberg dithering and some don’t, but use the default Ghostscript halftoning (in fact, when halftoning is used, dithering takes also place but because of the low point density it is usually not efficient, and thus invisible).

Descriptions of printing modes by bpp and Colors

bpp

Colors

Mode

32

4

CMYK colour printing, Floyd-Steinberg dithering

24

4

The same. (But each primary colour is stored on 6 bits instead of 8.)

24

3

RGB colour printing, Floyd-Steinberg dithering. This mode does not use the black

cartridge (that’s why it exists, for when you don’t want to use it ;-)).

Each primary colour is stored in 8 bits as in the 32/4 mode, but black generation

and under-color removal are done on the driver side and not by Ghostscript,

so you have no control over it. (This mode is no longer supported in this driver.)

16

4

CMYK colour printing, halftoned by Ghostscript. F-S dithering is still

visible here (but the halftone patterns are visible too!).

8

4

The same.(But each primary colour is stored in 2 bits instead of 4.)

8

3

RGB colour printing. This mode is not intended for use. What I mean is

that it should be used only if you want to use custom halftone screens

and the halftoning is broken using the 8/4 mode (some versions of

Ghostscript have this problem).

8

1

Gray-level printing, Floyd-Steinberg dithering

1

1

Gray-level printing halftoned by Ghostscript

These modes are selected using the BitsPerPixel and Colors integer options (either from the command line or in a PostScript program using setpagedevice). See below.

A note about darkness of what is printed: Canon printers do print dark, really. And the Floyd-Steinberg dithering may eventually darken your image too. So you may need to apply gamma correction by calling Ghostscript as in:

gs -sDEVICE=bjc600 gamma.ps myfile.ps

where gamma.ps changes the gamma correction (here to 3 for all colors); 0.45 gives me good results, but your mileage may vary. The bigger the value the lighter the output:

{ 0.45 exp } dup dup currenttransfer setcolortransfer

The drivers support printing at 90dpi, 180dpi and 360dpi. Horizontal and vertical resolutions must be the same or a limitcheck error will happen. A rangecheck will happen too if the resolution is not 90 ×2^N. If the driver is compiled with -DBJC_STRICT a rangecheck also happens if the resolution is not one of those supported. This is not the case, as we expect that there may be a 720dpi bjc some day.

Here are the various options supported by the bjc drivers, along with their types, supported values, effects, and usage:

BitsPerPixel (int)

Choose the depth of the page. Valid values are 1, 8, 16, 24 (the default) and 32. Note that when this is set for the first time, the Colors property is automatically adjusted unless it is also specified. The table here shows the corresponding color models and the rendering method visible: “GS” for Ghostscript halftoning and “F-S” for Floyd-Steinberg dithering. When both are present it means that the dithering of halftones is visible. Default choices are indicated by asterisk “*”.

Valid colors values for allowed BitsPerPixel values

bpp

Colors

Default

Color model

Dithering

32

4

CMYK

F-S

24

4

*

CMYK

F-S

3

RGB

F-S

16

4

CMYK

GS, F-S

8

4

*

CMYK

GS

3

RGB

GS

1

K (CMYK)

F-S

1

1

*

K (CMYK)

GS

Also note that automagical change of one parameter depending on the other one does not work in a setpagedevice call. This means that if you want to change BitsPerPixel to a value whose valid Colors values do not include the actual Colors value, you must change Colors too.

Colors (int)

Choose the number of color components from among 1, 3 and 4 (the default). This setting cannot be used in a PostScript program, only on Ghostscript’s command line. See ProcessColorModel below for what to use to change the number of colors with PostScript code. Note that setting this property does limit the choices of BitsPerPixel. As for the previous property, its first setting may induce a setting of the “other value” (BitsPerPixel here). The table here indicates valid combinations with “V”, default values with asterisk “*”.

Valid BitsPerPixel values for allowed Colors values

BitsPerPixel OK values

Colors

Type

32

24

16

8

1

4

CMYK

V

V

V

3

RGB

*

V

1

K

V

*

Also note that automagical change of one parameter depending on the other one does not work in a setpagedevice call. This means that if you want to change Colors to a value whose valid BitsPerPixel values don’t include the actual BitsPerPixel value, you must change BitsPerPixel too.

ProcessColorModel (symbol)

A symbol taken from /DeviceGray, /DeviceRGB or /DeviceCMYK which can be used to select 1, 3 or 4 colors respectively. Note that this parameter takes precedence over Colors, and that both affect the same variable of the driver. (See Colors above for values combined with BitsPerPixel.)

HWResolution (floats array)

An array of two floats giving the horizontal and vertical resolution in dots per inch from among 90, 180 and 360 (the default). Both values must be the same. On the Ghostscript command line, the resolution may be changed with the -r switch.

ManualFeed (bool)

Indicate that the sheets won’t be fed automatically by the printer, false by default. (Not meaningful on the BJC-600, I fear.)

MediaType (string)

The media to print on, chosen from among “PlainPaper”, “CoatedPaper”, “TransparencyFilm”, “Envelope”, “Card” and “Other”. Default is “PlainPaper”. For “Envelope”, “Card” or “Other” the driver puts the printer into thick mode automatically regardless of the actual media weight.

MediaWeight (int or null)

The weight of the media in grams per square meter. Null (the default) indicates that the weight is of no importance. If the specified media weight is greater than 105 (that is, the value of the compilation default BJC???_MEDIAWEIGHT_THICKLIMIT) then the printer will be set to use thick paper.

PrintQuality (string)

The quality of printing.

Value

bjc600

bjc800

Comments

Low

X

Has the effect of making only two printing passes instead of four,

so should be twice the speed; known as “CN” (Color Normal) mode

Draft

X

X

Unlights the “HQ” light on a BJC-600

Normal

X

X

Default for both drivers; lights the “HQ” light on a BJC-600

High

X

X

Means 200% black and 100% C

DitheringType (string)

Dithering algorithm from between “Floyd-Steinberg” and “None”. “None” is the default for 1/1 print mode, “Floyd-Steinberg” for other modes. At the moment this parameter is read-only, though no error is generated if one tries to change it. This parameter is not of much value at the moment and is here mainly to reserve the name for future addition of dithering algorithms.

PrintColors (int)

Mask for printing color. If 0, use black for any color; otherwise the value must be the sum of any of 1 (cyan), 2 (magenta), 4 (yellow) and 8 (black), indicating which colors will be used for printing. When printing colour, only colours specified will be printed (this means that some planes will be missing if a color’s value above is omitted). When printing grays, black is used if it is present in the PrintColors; otherwise, the image is printed by superimposing each requested color.

MonochromePrint (bool)

For bjc600 only, false by default. Substitute black for Cyan, Magenta and Yellow when printing – useful, for example, to get some monochrome output of a dithered printing This is a hardware mechanism as opposed to the previous software one. I think that using this or setting PrintColors to 0 will give the same results.

Note

The MediaType and ThickMedia options will be replaced by the use of the device InputAttributes and OutputAttributes as soon as possible. Please note too that the print mode may be reset at the start of printing, not at the end. This is the expected behaviour. If you need to reset the printer to its default state, simply print a file that does just a showpage.

Device information

Here is other information published by the driver that you will find in the deviceinfo dictionary.

OutputFaceUp (bool)

This has the boolean value true, indicating that the sheets are stacked face up.

Version (float)

In the form M.mmpp, where M is the major version, mm the bjc driver’s minor version, and pp the specific driver minor version (that is, M.mm will always be the same for the bjc600 and bjc800 drivers).

VersionString (string)

A string showing the driver version and other indications. At the moment, things like “a” or “b” may follow the version to indicate alpha or beta versions. The date of the last change to this version is given in the form MM/DD/YY (no, it won’t adapt to your locale).

Hardware margins

The BJC printers have top and bottom hardware margins of 3mm and 7.1mm respectively (Canon says 7mm, but this is unusable because of the rounding of paper sizes to PostScript points). The left margin is 3.4mm for A4 and smaller paper sizes, 6.4mm for U.S. paper sizes, envelopes and cards. It is 4.0mm for A3 paper on the BJC-800.

The maximum printing width of a BJC-600 printer is 203mm. The maximum printing width of a BJC-800 printer is 289mm on A3 paper, 203mm on U.S. letter and ISO A4 paper.

PostScript printer description (PPD) files

The files CBJC600.PPD and CBJC800.PPD (whose long names are, respectively, Canon_BubbleJetColor_600.ppd and Canon_BubbleJetColor_800.ppd) are PPD files to drive the features of the bjc600 and bjc800 drivers. They can be used, for example, on NextStep systems (presumably on OpenStep systems too) and on Unix systems with Adobe’s TranScript and pslpr (not tested). The files are not complete at the moment. Please note that NextStep’s printing interface does not correctly enforce constraints specified in these files (in UIConstraints descriptions): you must force yourself to use valid combinations of options.

Customizing the PPD files

By default the PPD files are set for U.S. letter size paper, and they use a normalized transfer function. If you choose to use A4 printing by default, you must replace “Letter” with “A4” in these (noncontiguous) lines:

[...]
*DefaultPageSize: Letter
[...]
*DefaultRegion: Letter
[...]
*DefaultImageableArea: Letter
[...]

Some versions of Ghostscript have problems with normalized colors, which makes them add magenta in gray levels. If you experience this problem, in the PPD file replace the line:

*DefaultTransfer: Normalized

with the alternate line:

*DefaultTransfer: Null

The “thick media” option is implemented by choosing a value of 120 or 80 (for thick and thin media respectively) for the MediaWeight feature of the drivers. If you ever change the threshold for thick media in the driver code, you may need to change the values in the PPD files too.

All customization should be done using the “*Include:” feature of PPD files so that your local changes will be retained if you update the PPD files.

How to report problems

Yves Arrouye no longer maintains this driver, and will not answer questions about it. If you are posting a question about it in a public form, please be as descriptive as possible, and please send information that can be used to reproduce the problem. Don’t forget to say which driver you use, and in what version. Version information can be found in the source code of the driver or by issuing the following command in a shell:

echo "currentpagedevice /VersionString get ==" | gs -q -sDEVICE=bjc600 -

Acknowledgements

I am particularly grateful to Yoshio Kuniyoshi without whom I’d never make these drivers, and also to L. Peter Deutsch, who answered all my (often silly) questions about Ghostscript’s driver interface.

Thanks also to the people who volunteered to beta-test the v2.x BJC drivers: David Gaudine, Robert M. Kenney, James McPherson and Ian Thurlbeck (listed alphabetically) were particularly helpful by discovering bugs and helping find out exact paper margins on printers I don’t have access to.

And many thanks to Klaus-Gunther Hess for looking at the dithering code and devising a good CMYK dithering algorithm for the Epson Stylus Color, which I then adapted to the code of these drivers.

Epson Stylus color printer (see also uniprint)

This section was contributed by Gunther Hess, who also wrote uniprint, a later set of drivers. You should probably see the section on uniprint for whether it might be better for your uses than this driver.

Usage

This driver is selected with -sDEVICE=stcolor, producing output for an Epson Stylus Color at 360dpi resolution by default. But it can do much more with this printer, and with significantly better quality, than with the default mode; and it can also produce code for monochrome versions of the printer. This can be achieved via either command-line options or Ghostscript input. For convenience a PostScript file is supplied for use as an initial input file. Try the following command:

gs -sDEVICE=stcolor -r{Xdpi}x{Ydpi} stcolor.ps {YourFile.ps}

where {Xdpi} is one of 180, 360, or 720 and {Ydpi} is one of 90, 180, 360, or 720. The result should be significantly better. You may use stcolor.ps with other devices too, but I do not recommend this, since it does nothing then. stcolor.ps should be available with binary distributions and should reside in the same directory as other Ghostscript initialization files or in the same directory as the files to be printed. Thus if Ghostscript is part of your printer-spooler, you can insert:

(stcolor.ps) findlibfile { pop run } if pop

in files you want to use the improved algorithms. You may want to adapt stcolor.ps file to your specific needs. The methods and options for this are described here, but this description is restricted to Ghostscript options, while their manipulation at the PostScript level is documented in the material on the relationship of Ghostscript and PostScript and in stcolor.ps.

Options

Now to explain the options (as written on my UNIX system). The order is somehow related to their use during the printing process:

-dUnidirectional

Force unidirectional printing, recommended for transparencies

-dMicroweave

Enable the printer’s “microweave” feature; see “What is weaving?” below.

-dnoWeave

Disable any Weaving (overrides -dMicroweave)

-dSoftweave

Enable the driver’s internal weaving. Note that Softweave works only with the original Stylus Color and the PRO-Series.

-sDithering= {name}

Select another dithering algorithm (name) from among:

Dithering name

Comments

gscmyk

fast color output, CMYK process color model (default)

gsmono

fast monochrome output

gsrgb

fast color output, RGB process color model

fsmono

Floyd-Steinberg, monochrome

fsrgb

Floyd-Steinberg, RGB process color model (almost identical to

the cdj550/bjc algorithm)

fsx4

Floyd-Steinberg, CMYK process color model (shares code with fsmono and

fsrgb, but is algorithmically really bad)

fscmyk

Floyd-Steinberg, CMYK process color model and proper modifications for CMYK

hscmyk

modified Floyd-Steinberg with CMYK model (“hs” stands for “hess” not

for “high speed”, but the major difference from fscmyk is speed)

fs2

algorithm by Steven Singer (RGB) should be identical to escp2cfs2.

-dBitsPerPixel={1...32}

number of bits used for pixel storage; the larger the value, the better the quality – at least in theory. In fsrgb one can gain some speed by restricting to 24 bits rather than the default 30.

-dFlag0

causes some algorithms to select a uniform initialisation rather than a set of random values. May yield a sharper image impression at the cost of dithering artifacts. (Applies to hscmyk and all fs modes, except for fs2, which always uses a constant initialization.)

-dFlag1 ... -dFlag4

Available for future algorithms.

-dColorAdjustMatrix='{three, nine, or sixteen floating-point values}'

This is a matrix to adjust the colors. Values should be between -1.0 and 1.0, and the number of values depends on the color model the selected algorithm uses. In RGB and CMYK modes a matrix with 1.0 on the diagonal produces no transformation. This feature is really required, but I could not identify a similar feature at the language level, so I implemented it, but I don’t know reasonable values yet.

-dCtransfer='{float float ...}' or -dMtransfer=..., -dY..., -dK... or -dRtransfer='{float float ...}' or -dG..., -dB... or -dKtransfer='{float float ...}'

Which you use depends on the algorithm, which may be either either CMYK, RGB or monochrome. The values are arrays of floats in the range from 0 to 1.0, representing the visible color intensity for the device. One may achieve similar effects with setcolortransfer at the language level, but this takes more time and the underlying code for the driver-specific parameters is still required. The size of the arrays is arbitrary and the defaults are “{0.0 1.0}”, which is a linear characteristic. Most of the code in stcolor.ps are better transfer arrays.

-dKcoding='{float...}' , -dC..., -dM... etc.

Arrays between 0.0 and 1.0, controlling the internal coding of the color values. Clever use of these arrays may yield further enhancements, but I have no experience yet. (To be discontinued with version 2.x.)

-sModel=st800

Causes output to be suitable for the monochrome Stylus 800 (no weaving, no color).

-sOutputCode= {name}

Can be either “plain”, “runlength” or “deltarow” and changes the ESC/P2 coding technique used by the driver. The default is to use runlength encoding. “plain” selects uncompressed encoding and generates enormous amounts of data.

-descp_Band= 1/8/15/24

Number of nozzles of scanlines used in printing, Useful only with -dnoWeave. Larger Values yield smaller code, but this doesn’t increase the printing speed.

-descp_Width= N

Number of pixels Printed in each scan Line. (Useful only when tuning margins; see below)

-descp_Height= pixels

Length of the entire page in pixels. (Parameter of “ESC(C” in default initialization.)

-descp_Top= scan lines

Top margin in scan lines. (First parameter of “ESC(c” in default initialization.)

-descp_Bottom= scan lines

Bottom margin in scan lines. (Second parameter of “ESC(c” in default initialization.)

-sescp_Init= “string”

Override for the initialization sequence. (Must set graphics mode 1 and units.)

-sescp_Release= “string”

Overrides the release sequence, “ESC @ FF” by default.

ESC/P2 allows any resolutions to be valid in theory, but only -r360x360 (the default) and -r720x720 (not on STC-IIs ? and st800) are known to work with most printers.

Valid option combinations – Stylus I & Pro-Series only

Resolution

escp_Band

Weave usable

escp_Band & number of passes

180x90

15

noWeave

180x180

1, 8, 24

noWeave, Microweave

15/2 SoftWeave

180x360

15/4 SoftWeave

180x720

15/8 SoftWeave

360x90

15

noWeave

360x180

1, 8, 24

noWeave, Microweave

15/2 SoftWeave

360x360

1, 8, 24

noWeave, Microweave

15/4 SoftWeave

360x720

15/8 SoftWeave

720x90

15

noWeave

720x180

15/2 SoftWeave

720x360

15/4 SoftWeave

720x720 1 noWeave, Microweave

1

noWeave, Microweave

15/8 SoftWeave

Warning

Beware: there are only few validity checks for parameters. A good example is escp_Band: if you set this, the driver uses your value even if the value is not supported by the printer. You asked for it and you got it!

Application note and FAQ

Quite a bunch of parameters. Hopefully you never need any of them, besides feeding stcolor.ps to Ghostscript in front of your input.

After answering some questions over fifty times I prepared a FAQ. Here is version 1.3 of the FAQ, as of stcolor version 1.20 (for Ghostscript 3.50).

Support for A3 paper

Yes, this driver supports the A3-size printer: merely set the required pagesize and margins. A simple way to do this is to specify the command-line switch -sPAPERSIZE=a3 or include the procedure call a3 in the PostScript prolog section. To optimize the printable area or set the proper margins, see the next paragraph.

Margins, PageSize

I refuse to add code to stcolor that tries to guess the proper margins or page size, because I found that such guessing is usually wrong and needs correction in either the source or the parameters. You can modify stcolor.ps to do that, however. After the line:

mark % prepare stack for "putdeviceprops"

insert these lines, which define page size and margins in points:

/.HWMargins [9.0 39.96 12.6 9.0]     % Left, bottom, right, top (1/72")
/PageSize   [597.6 842.4]            % Paper, including margins (1/72")
/Margins [ % neg. Offset to Left/Top in Pixels
   4 index 0 get STCold /HWResolution get 0 get mul 72 div neg
   5 index 3 get STCold /HWResolution get 1 get mul 72 div neg
]

Feel free to change the values of .HWMargins and PageSize to match your needs; the values given are the defaults when the driver is compiled with “-DA4”. This option or its omission may cause trouble: the Stylus Color can print up to exactly 8 inches (2880 pixels) at 360dpi. The remaining paper is the margin, where the left margin varies only slightly with the paper size, while the right margin is significantly increased for wider paper, such as U.S. letter size.

Note

If you are using an ISO paper size with a version of stcolor after 1.20 and compiled without “-DA4”, then the default margin is too large, and you need to add the proper “.HWMargins” to the command line or to stcolor.ps.

Stylus Color II / IIs and 1500

First the good news: the driver can print on the Stylus Color II. Now the bad news:

  • According to Epson support the driver “abuses” the color capabilities. (See “Future Plans” for details).

  • You need some parameters on the command line (or in stcolor.ps).

  • I doubted that it would be usable with the Stylus Color IIs, but it is usable and suffers from mixing problems!

To make things work, you MUST disable the driver’s internal weaving (Softweave), in one of these two ways:

gs -dMicroweave ...
gs -dnoWeave -descp_Band=1 ...

Version 1.90, current as of Ghostscript 5.10, fixes this bug by new default behaviour. I experienced significantly increased printing speed with the second variant on the old Stylus Color, when printing mostly monochrome data.

Recommendations

The next section is a contribution from Jason Patterson who evaluated a previous version (1.17). Ghostscript was invoked as follows:

gs -sDEVICE=stcolor -r720x720 -sDithering=... -sOutputFile=escp.out stcolor.ps whatsoever.ps

where “...” is the name of the desired algorithm. stcolor.ps was omitted for the gs-algorithms (gsmono, gsrgb and gscmyk), for which it is useless and would not allow the selection of “gscmyk”.

Color dithering experiments with gdevstc 1.21

Here are data about the EPSON Stylus Color driver’s different dithering methods, based on a little experiment using four good quality scanned images of quite varied nature, to begin with, a summary of the results of the four experiments. Sanity note: the results here are from only four images and a total of 24 printouts (eight on 720dpi paper, sixteen on plain paper). Your results will almost certainly vary, and your standards might not be the same as mine, so use these results only as a guide, not as a formal evaluation.

Quality of output by method

gsmono

Pretty much what you’d expect from a mono ordered pattern. Looks like what a lot of mono laser printers produce.

fsmono

Excellent for monochrome.

gscmyk

Not very good, but expected from an ordered pattern.

gsrgb

A little better than gscmyk. More consistent looking.

fs2

Good, but not quite as good as fsrgb. Gets the brightness wrong: too light at 720dpi, too dark at 360dpi.

fsrgb

Very good, but a little too dark and has a slight blue tint.

hscmyk

Excellent. Slightly better than fsrgb and fs2. Better than fscmyk on some images, almost the same on most.

fscmyk

Best. Very, very slightly better than hscmyk. On some images nearly as good as the EPSON demos done with the MS Windows driver.

Overall visual quality (1-10), best to worst

0 1 2 3 4 5 6 7 8 9 10

Monochrome

fsmono

******************

gsmono

**********

Colour

fscmyk

*******************

hscmyk

*******************

fsrgb

******************

fs2

*****************

gsrgb

**********

gscmyk

*********

Color transformation

In the initial version of the driver distributed with Ghostscript 3.33, the parameter SpotSize was the only way to manipulate the colors at the driver level. According to the parameters enumerated above, this has changed significantly with version 1.16 and above as a result an ongoing discussion about dithering algorithms and “false color” on the Epson Stylus Color. This initiated the transformation of the stcolor driver into a framework for different dithering algorithms, providing a generalized interface to the internal Ghostscript color models and the other data structures related to Ghostscript drivers.

The main thing such a framework should be able to do is to deliver the values the dithering algorithm needs; and since this directly influences the optical image impression, this transformation should be adjustable without the need for recompilation and relinking.

Due to the limitations on raster storage, information is lost in the first transformation step, except for the 16-bit monochrome mode. So any color adjustment should take place before this step and this is where the optional ColorAdjustMatrix works.

The first transformation step, called “coding”, is controlled by the ?coding arrays. The decoding process expands the range of values expontentially to a larger range than that provided by the initial Ghostscript color model, and is therefore a reasonable place to make device- or algorithm-specific adjustments. This is where the ?transfer arrays are used. Array access might be not the fastest method, but its generality is superior, so this step is always based upon internally algorithm-specific array access. If 8 bits are stored per color component and if the algorithm uses bytes too, the second transformation is included within the first, which saves significant computation time when printing the data.

ColorAdjustMatrix

The driver supports different values for ProcessColorModel, which raises the need for different color adjustments. Here “CAM” stands for “ColorAdjustMatrix”.

DeviceGray (three floats)
if ((r == g) && (g == b))
   K' = 1.0 - R;
else
   K' = 1.0 - CAM[0] * R + CAM[1] * G + CAM[2] * B;

According to the documentation on drivers, the latter (the “else” clause) should never happen.

DeviceRGB (nine floats)
if((r == g) && (g == b))
   R' = B' = G' = R;
else
   R' = CAM[0]*R + CAM[1]*G + CAM[2]*B;
   G' = CAM[3]*R + CAM[4]*G + CAM[5]*B;
   B' = CAM[6]*R + CAM[7]*G + CAM[8]*B;

The printer always uses four inks, so a special treatment of black is provided. Algorithms may take special action if R, G, and B are all equal.

DeviceCMYK (sixteen floats)
if((c == m) && (m == y))
   K' = max(C,K);
   C' = M' = Y' = 0;
else
   K  = min(C,M,Y);
   if((K > 0) && ColorAdjustMatrix_present) { => UCR
      C -= K;
      M -= K;
      Y -= K;
   }

   C' = CAM[ 0]*C + CAM[ 1]*M + CAM[ 2]*Y + CAM[ 3]*K;
   M' = CAM[ 4]*C + CAM[ 5]*M + CAM[ 6]*Y + CAM[ 7]*K;
   Y' = CAM[ 8]*C + CAM[ 9]*M + CAM[10]*Y + CAM[11]*K;
   K' = CAM[12]*C + CAM[13]*M + CAM[14]*Y + CAM[15]*K;

Again we have a special black treatment. “max(C,K)” was introduced because of a slight misbehaviour of Ghostscript, which delivers black under certain circumstances as (1,1,1,0). Normally, when no special black separation and undercolor removal procedures are defined at the PostScript level, either (C,M,Y,0) or (0,0,0,K) values are mapped. This would make the extended ColorAdjustMatrix quite tedious, and so during mapping, black separation is done for (C,M,Y,0) requests; and if there is a ColorAdjustMatrix, undercolor removal is used too. In other words the default matrix is:

1

0

0

1

0

1

0

1

0

0

1

1

0

0

0

1

and it is applied to CMYK values with separated and removed black. Raising the CMY coefficients while lowering the K coefficients reduces black and intensifies color. But be careful, because even small deviations from the default cause drastic changes.

If no ColorAdjustMatrix is set, the matrix computations are skipped. Thus the transformation reduces to range inversion in monochrome mode and black separation in CMYK mode.

RGB / CMYK coding and transfer, and BitsPerPixel

These two (groups of) parameters are arrays of floating-point numbers in the range 0.0 to 1.0. They control the truncation to the desired number of bits stored in raster memory (BitsPerPixel) and the ink density. The “truncation” may become a nonlinear function if any of the ?coding arrays is set. Assume the following Ghostscript invocation:

gs -sDEVICE=stcolor -sDithering=fscmyk -dBitsPerPixel=16 \
     -dKcoding='{ 0.0 0.09 0.9 1.0 }' \
     -dMcoding='{ 0.0 0.09 0.9 1.0 }' \
   -dKtransfer='{ 0.0 0.09 0.9 1.0 }' \
   -dYtransfer='{ 0.0 0.09 0.9 1.0 }'

We may have either or both of ?coding and ?transfer, giving four possible combinations. (These four combinations appear in the given example.) The resulting mapping appears in the following tables, where except for the internal Indices (4 components × 4 bits = 16 BitsPerPixel), all values are normalized to the range 0 to 1. The actual range is 0 to 65535 for the Ghostscript color and 0 to 16777215 for the ink values delivered to the fscmyk algorithm. Sorry for the bunch of numbers following, but you may try this example in conjunction with stcinfo.ps, which should give you a graphical printout of the following numbers when you issue a showpage command.

Cyan Magenta
CI/15 gs_color_values CI Ink gs_color_values CI Ink
0.000 0.000 - 0.062 0 0.000 -0.123 - 0.123 0 0.000
0.067 0.063 - 0.125 1 0.067 0.123 - 0.299 1 0.247
0.133 0.125 - 0.187 2 0.133 0.299 - 0.365 2 0.351
0.200 0.188 - 0.250 3 0.200 0.365 - 0.392 3 0.379
0.267 0.250 - 0.312 4 0.267 0.392 - 0.420 4 0.406
0.333 0.313 - 0.375 5 0.333 0.420 - 0.447 5 0.433
0.400 0.375 - 0.437 6 0.400 0.447 - 0.475 6 0.461
0.467 0.438 - 0.500 7 0.467 0.475 - 0.502 7 0.488
0.533 0.500 - 0.562 8 0.533 0.502 - 0.529 8 0.516
0.600 0.563 - 0.625 9 0.600 0.529 - 0.557 9 0.543
0.667 0.625 - 0.687 10 0.667 0.557 - 0.584 10 0.571
0.733 0.688 - 0.750 11 0.733 0.584 - 0.612 11 0.598
0.800 0.750 - 0.812 12 0.800 0.612 - 0.639 12 0.626
0.867 0.813 - 0.875 13 0.867 0.639 - 0.715 13 0.653
0.933 0.875 - 0.937 14 0.933 0.715 - 0.889 14 0.778
1.000 0.938 - 1.000 15 1.000 0.889 - 1.111 15 1.000

The difference between cyan and magenta is the presence of a coding array. The coding process must map a range of color values to each of the sixteen component indices. If no coding array is given, this is accomplished by dividing by 4096, equivalent to a right shift by 12 bits. The final ink density resides in the given interval and moves from the left to the right side from 0 to 15. For magenta there is a coding array and the ink value matches the center of the intervals. But the distribution of the mapped intervals follows the given coding array and is nonlinear in the linear color space of Ghostscript.

Now let us take a look at the case with transfer arrays:

Yellow Black
CI/15 gs_color_values CI Ink gs_color_values CI Ink
0.000 0.000 - 0.062 0 0.000 -0.123 - 0.123 0 0.000
0.067 0.063 - 0.125 1 0.018 0.123 - 0.299 1 0.067
0.13 0.125 - 0.187 2 0.036 0.299 - 0.365 2 0.133
0.200 0.188 - 0.250 3 0.054 0.365 - 0.392 3 0.200
0.267 0.250 - 0.312 4 0.072 0.392 - 0.420 4 0.267
0.333 0.313 - 0.375 5 0.090 0.420 - 0.447 5 0.333
0.400 0.375 - 0.437 6 0.252 0.447 - 0.475 6 0.400
0.467 0.438 - 0.500 7 0.414 0.475 - 0.502 7 0.467
0.533 0.500 - 0.562 8 0.576 0.502 - 0.529 8 0.533
0.600 0.563 - 0.625 9 0.738 0.529 - 0.557 9 0.600
0.667 0.625 - 0.687 10 0.900 0.557 - 0.584 10 0.667
0.733 0.688 - 0.750 11 0.920 0.584 - 0.612 11 0.733
0.800 0.750 - 0.812 12 0.940 0.612 - 0.639 12 0.800
0.867 0.813 - 0.875 13 0.960 0.639 - 0.715 13 0.867
0.933 0.875 - 0.937 14 0.980 0.715 - 0.889 14 0.933
1.000 0.938 - 1.000 15 1.000 0.889 - 1.111 15 1.000

Yellow uses a transfer array. There is no linear correspondence between the color and the ink values: this correspondence is defined through the given array. In other words, the transfer arrays define a nonlinear ink characteristic, which is exactly the same functionality that PostScript’s “(color)transfer” function provides.

While for yellow the intervals match the intervals used with cyan, for black the intervals match the magenta intervals. But watch the correspondence between the CI/15 values and the ink density for black: this is a linear distribution in the ink domain.

Not a bad idea, I think. Consider the fs2 algorithm: it uses values in the range 0 to 255. If any transfer array were alone, some of the 256 possible values would never be used and others would be used for adjacent intervals several times. Establishing an identical coding array solves this problem, so the full potential of the algorithm is used.

Another useful feature of the coding arrays is that they are internally normalized to the range 0-1. In 720x720dpi mode the transfer arrays in stcolor.ps limit the dot density to about 50%, so these arrays end at 0.5 (and begin at 0.5 for RGB). Because of automatic normalization, these arrays can also be used as coding arrays. But of course in the fs2 case mentioned above, values from 0 to 127 will never be delivered to the algorithm, while values 128-255 are delivered for adjacent intervals.

To clarify the intended use of the three parameters (parameter groups), keep this in mind:

  • ColorAdjustMatrix is never used when transferring gray values. This restricts it to what the name says: adjustment of colors, that is, correction for miscolored ink. Do not use it for saturation or brightness control.

  • ?transfer arrays control the values delivered to the driver, which in turn controls the ink quantity. Use these arrays to control saturation and brightness. In general these arrays are identical for all inks. If they differ they provide a simpler scheme for color correction, which is not necessarily faster than the ColorAdjustMatrix.

  • ?coding arrays control the color value intervals mapped to the internal color indices.

What is weaving?

The Epson Stylus Color has a head assembly that contains two physically identifiable heads, one for black and one for cyan, magenta, and yellow (CMY). This makes four “logical” heads, one for each color component. Each of these four heads has several jets at some vertical (Y) distance from one another, so several horizontal lines can be printed of a given color during one pass of the heads. From experience I think there are fifteen jets per color, spaced at 1/90in.

So the question arises of how to print at a Y resolution of 360dpi with 90dpi jets. Simply by division one gets 360dpi/90dpi = 4, which tells us that 4 passes of the head assembly are needed to achieve a Y resolution of 360dpi.

Weaving is the method of how the fifteen jets are used to print adjacent horizontal rows separated here by 1/360 inch:

Print-head jets used with and without weaving
Weaving noWeave
Pass 1 2 3 4 1 2 3 4
Row
0 jet 0 -- -- -- jet 0 -- -- --
1 -- jet 1 -- -- -- jet 0 -- --
2 -- -- jet 2 -- -- -- jet 0 --
3 -- -- -- jet 3 -- -- -- jet 0
4 jet 1 -- -- -- jet 1 -- -- --
5 -- jet 2 -- -- -- jet 1 -- --
6 -- -- jet 3 -- -- -- jet 1 --
...

Now let’s assume that the dot diameter is different for each individual jet, but the average among the jets matches the desired resolution. With weaving, adjacent rows are printed by different jets, thus some averaging takes place. Without weaving, adjacent rows are printed by the same jet and this makes the dot diameter deviations visible as 1/90in stripes on the paper.

Bugs and pitfalls

  • The given ?coding and ?transfer arrays should be strictly monotonic.

  • It is impossible to change WHITE: that’s your paper. Thus RGB transfer should end at 1.0 and CMYK transfer should start at 0.0.

  • Usually 8 bits per component yields fastest operation.

  • The ColorAdjustMatrix is not used in the reverse transformation used when Ghostscript does the dithering (gs* modes). Expect funny results.

  • If BitsPerPixel is less than 6, the entire coding and transfer process does not work. This is always true for the gs* modes and becomes true for the other modes if BitsPerPixel is forced to low values.

  • 720×720dpi printing should never select the gs* modes and should always use stcolor.ps. (I prefer 360×720.)

Tests

This section gives an overview of performance in terms of processing and printing times, from tests run after version 1.13. Printing was done offline (simply copying a processed file to the printer) to measure real printing speed without regard to speed of processing on the host, since at high resolutions, processing time is the same order of magnitude and thus may become the limiting factor.

The various OutputCodes

I ran several files though Ghostscript and recorded the size of the resulting print code, the processing time, and the printing time, at least for some of the files, always using these options:

gs -sDEVICE=stcolor -sPAPERSIZE=a4 stcolor.ps - < file.ps

(Actually “-sPAPERSIZE=a4” is in my gs_init.ps since I’m a germ.)

deltarow” is the new encoding principle (”ESC . 3 10 10 1”) with Microweave on. It is activated with “-sOutputCode=deltarow”.

Softweave” actually means that nothing else was used: it is the default, and implies that odd v=40/h=10/m=15 mode (”ESC . 1 40 10 15”).

Microweave” means “-dMicroweave”, equivalent to “ESC . 1 10 10 1”, with full skip optimization and microweave activated.

Finally I wanted to see the plain Kathy Ireland, and used “-sOutputCode=plain”, which just replaces runlength encoding (RLE) by no encoding, thus using “ESC . 0 40 10 15”. [So sorry ;-) Kathy was still dressed in blue in front of the blue sea on a blue air cushion – nice to see but hard to dither.]

So here are the results.

File sizes and printing speeds with various weaving methods
  golfer.ps colorcir.ps drawing.ps brief.ps
deltarow 572751/48.180u 643374/41.690u 90142/46.180u/1:50 178563/49.350u/2:22
Softweave 559593/46.810u 669966/44.960u 296168/48.160u/1:30 269808/43.320u/1:55
Microweave 590999/56.060u 754276/42.890u 338885/47.060u/1:50 282314/44.690u/2:22

Kathy Ireland
kathy.ps
deltarow 3975334/111.940u/5:35
Softweave 3897112/101.940u/3:10
Microweave 4062829/100.990u/3:15
plain/soft 5072255/104.390u/3:05

It may be that I’ve not chosen the optimal deltarow code, but even if it saves at lot of bytes, printing-speed is not increased.

At least the printer prefers plain Kathy. In other words, sending 1 Megabyte or 20% more data has no impact on printing speed. drawing.ps is an exception to this rule: plain prints slower than RLE.

“Unclever” coding – especially with deltarow – can significantly slow down printing. But even if very significant advantages in the size of the code are achieved, deltarow is not competitive. colorcir.ps shows savings with deltarow, but printing is a mess.

Printing time related to other options (*Full page halftone images printed, unless otherwise noted.)
dpi Print mode Size KB Time Comments
180x180 mono -/uni 358 1:15  
  -/bi 358 0:45  
  micro/bi 205 0:45 Not Weaving
  soft/bi 179 1:25  
color -/bi 641 2:45  
  soft/bi 556 1:32  
360x360 mono -/uni 269 0:50 Monochrome text
  -/bi 269 0:35 Monochrome text
  micro/bi 269 2:25 Monochrome text
  soft/uni 250 3:15 Monochrome text
  soft/bi 250 1:55 Monochrome text
color -/bi 346 1:00 Sparse-color page, visible displacements
  micro/bi 346 1:50 Sparse-color page, looks buggy – printer?
  soft/bi 294 1:30 Sparse-color page, O.K.
  -/bi 2218 2:45 Visible stripes
  micro/bi 5171 3:17  
  soft/bi 3675 3:05  
360x720 mono soft/bi 2761 5:40  
color soft/bi 7789 6:15 Just a small difference!
720x360 color soft/bi 7182 5:40  
720x720 color micro/bi 14748 30:26 Actually beyond printer's capabilities
  soft/bi 14407 11:08  

Acknowledgments

This driver was copied from gdevcdj.c (Ghostscript 3.12), which was contributed by George Cameron, Koert Zeilstra, and Eckhard Rueggeberg. Some of the ESC/P2 code was drawn from Richard Brown’s gdevescp.c. The POSIX interrupt code (compilation option -DSTC_SIGNAL) is from Frederic Loyer. Several improvements are based on discussions with Brian Converse, Bill Davidson, Gero Guenther, Jason Patterson, ? Rueschstroer, and Steven Singer.

While I wish to thank everyone mentioned above, they are by no means responsible for bugs in the stcolor driver – just for the features.

uniprint, a flexible unified printer driver

uniprint is a unified parametric driver by Gunther Hess for several kinds of printers and devices, including:

  • Any Epson Stylus Color, Stylus, or Stylus Pro.

  • HP PCL/RTL.

  • Canon BubbleJet Color 610.

  • NEC P2X.

  • Sun raster file format.

This driver is intended to become a unified printer driver. If you consider it ugly, please send me your suggestions for improvements. The driver will be updated with them. Thus the full explanation of the driver’s name is: Ugly- -> Updated- -> Unified Printer Driver

But you probably want to know something about the functionality. At the time of this writing uniprint drives:

  • NEC Pinwriter P2X (24-pin monochrome impact printer, ESC/P style).

  • Several Epson Stylus Color models (ESC/P2 style).

  • HP-DeskJet 550c (basic HP-RTL).

  • Canon BJC 610.

It can be configured for various other printers without recompilation and offers uncompressed (ugly) Sun rasterfiles as another format, but this format is intended for testing purposes rather than real use. The usage of this driver is quite simple. The typical command line looks like this:

gs @{MODEL}.upp -sOutputFile={printable file} MyFile.ps -c quit

For example, from my Linux box:

gs @stc.upp -sOutputFile=/dev/lp1 tiger.eps -c quit
Unified Printer Parameter files distributed with Ghostscript
Canon BJC 610 (color, rendered)
bjc610a0.upp 360×360dpi plain paper, high speed
bjc610a1.upp 360×360dpi plain paper
bjc610a2.upp 360×360dpi coated paper
bjc610a3.upp 360×360dpi transparency film
bjc610a4.upp 360×360dpi back print film
bjc610a5.upp 360×360dpi fabric sheet
bjc610a6.upp 360×360dpi glossy paper
bjc610a7.upp 360×360dpi high gloss film
bjc610a8.upp 360×360dpi high resolution paper
bjc610b1.upp 720×720dpi plain paper
bjc610b2.upp 720×720dpi coated paper
bjc610b3.upp 720×720dpi transparency film
bjc610b4.upp 720×720dpi back print film
bjc610b6.upp 720×720dpi glossy paper
bjc610b7.upp 720×720dpi high-gloss paper
bjc610b8.upp 720×720dpi high resolution paper
HP Ink-Printers
cdj550.upp 300×300dpi 32-bit CMYK
cdj690.upp 300×300dpi Normal mode
cdj690ec.upp 300×300dpi Economy mode
dnj750c.upp 300×300dpi Color – also good for 450C
dnj750m.upp 600×600dpi Monochrome
NEC P2X
necp2x.upp 360×360dpi 8-bit (Floyd-Steinberg)
Any Epson Stylus Color
stcany.upp 360×360dpi 4-bit, PostScript halftoning
stcany_h.upp 720×720dpi 4-bit, PostScript halftoning
Original Epson Stylus and Stylus Pro Color
stc.upp 360×360dpi 32-bit CMYK, 15-pin
stc_l.upp 360×360dpi 4-bit, PostScript halftoning, weaved noWeave
stc_h.upp 720×720dpi 32-bit CMYK, 15-pin Weave
Epson Stylus Color II
stc2.upp 360×360dpi 32-bit CMYK, 20-pin, Epson Stylus Color II(s)
stc2_h.upp 720×720dpi 32-bit CMYK, 20-pin, Epson Stylus Color II
stc2s_h.upp 720×720dpi 32-bit CMYK, 20-pin, Epson Stylus Color IIs
Epson Stylus Color 200
stc200.upp 360×720dpi Plain Paper
Epson Stylus Color 300
stc300.upp 360×360dpi 32-bit CMYK, plain paper
stc300bl.upp 180×180dpi black only, plain paper
stc300bm.upp 360×360dpi black only, plain paper
Epson Stylus Color 500 (good transfer curves for plain paper)
stc500p.upp 360×360dpi 32-bit CMYK, noWeave, plain paper
stc500ph.upp 720×720dpi 32-bit CMYK, noWeave, plain paper
Epson Stylus Color 600, 32/90-inch weaving
stc600pl.upp 360×360dpi 32-bit CMYK, 32-pin, plain paper
stc600p.upp 720×720dpi 32-bit CMYK, 32-pin, plain paper
stc600ih.upp 1440×720dpi 32-bit CMYK, 30-pin, inkjet paper
Epson Stylus Color 640
stc640p.upp 720×720dpi plain paper?
st640p.upp 720×720dpi CMYK, plain paper
st640pg.upp 720×720dpi grayscale, plain paper
st640pl.upp 360×360dpi CMYK, plain paper
st640plg.upp 360×360dpi grayscale, plain paper
st640ih.upp 1440×720dpi CMYK, inkjet paper
st640ihg.upp 1440×720dpi grayscale, inkjet paper
Epson Stylus Color 800, 64/180-inch weaving
stc800pl.upp 360×360dpi 32-bit CMYK, 64-pin, plain paper
stc800p.upp 720×720dpi 32-bit CMYK, 64-pin, plain paper
stc800ih.upp 1440×720dpi 32-bit CMYK, 62-pin, inkjet paper
stc1520.upp 1440×720dpi 32-bit CMYK, 62-pin, inkjet paper
Sun raster file
ras1.upp 1-bit monochrome (Ghostscript)
ras3.upp 3-bit RGB (Ghostscript)
ras4.upp 4-bit CMYK (Ghostscript)
ras8m.upp 8-bit grayscale (Floyd-Steinberg)
ras24.upp 24-bit RGB (Floyd-Steinberg)
ras32.upp 32-bit CMYK (CMYK-Floyd-Steinberg)

Thanks to Danilo Beuche, Guido Classen, Mark Goldberg and Hans-Heinrich Viehmann for providing the files for the stc200, hp690, stc500 and the stc640. Thanks to Michael Lossin for the newer st640 parameter sets.

Note

  • Changing the resolution with Ghostscript’s -r switch is usually not possible.

  • For Epson Stylus Color models not listed above, the two stc500 variants are likely to work in addition to stcany, but their gamma correction might be wrong.

The state of this driver

The coding of uniprint was triggered by the requirements of the various Stylus Color models and some personal needs for HP and NEC drivers. Thus the Epson models are well represented among the distributed parameter files. When this driver entered the beta test phase, three other drivers appeared on the scene that could be at least partially integrated into uniprint: cdj850 by Uli Wortmann, hpdj by Martin Lottermoser, and bjc610 by Helmut Riegler.

Uli addresses features of the more recent DeskJet models that will not be available in uniprint soon. Martin taught me a lesson on HP-PCL3 headers that will be available in uniprint soon. Helmut in turn followed an almost similar idea, but targetted primarily for printing on Canon printers from the pbmplus library. Starting with version 1.68 of uniprint, BJC support is available. Work on the hpdj integration will start after the update of my website.

Notes on uniprint’s background

uniprint is actually an update of stcolor, but much more versatile than its predecessor; stcolor, in its turn, started as a clone of the color DeskJet family of drivers (cdj*). Finally, cdj* can be considered an addition of features to the simpler monochrome drivers of Ghostscript. This addition of features is useful to get an idea of the functionality of uniprint:

Monochrome to advanced color (cdj*)

This adds color mapping and rendering functions to the driver. Error diffusion is especially important for the quality of printing.

HP color to Epson Color (stcolor)

The Epson Stylus Color offered two features simultaneously: it could produce 720×720dpi output and it could soak the paper. In other words, it required more color management features inside the driver. This is still the major conceptual difference in the data generation for HP and Epson printers.

Weaving techniques (stcolor)

Besides the internal color management, the Stylus Color did not provide enough buffer space to operate the printer fast at 720×720dpi. The use of weaving could yield triple the print speed. Weaving, also called interleaving, is present in some monochrome drivers too. The new thing in stcolor was the combination with error diffusion. Unfortunately the weaving was somehow hard-coded, as the problems with the newer members of the Stylus Color family of printers demonstrated.

Generalized output format and weaving (uniprint)

The features mentioned above yield about 90% of stcolor’s source code; only 10% is related to the formatting of the output. The idea to make the output format switchable came up soon after completing stcolor, but its final design was triggered by the (personal) necessity to drive a NEC P2X and a Designjet 750c.

Thus uniprint accumulates almost any features that can be found among the other printer drivers, which clearly has some disadvantage in processing speed – true in particular of version 1.75, since it was targetted for functionality, and several speed-gaining features were (knowingly) omitted.

To summarize and to introduce the terms used in the description of the parameters, the features of uniprint that can be parameterized are:

  • Color mapping.

  • Color rendering (error diffusion or Floyd-Steinberg).

  • Output format, including weaving.

Godzilla’s guide to the creation of Unified Printer Parameter (.upp) files

Here is one of the distributed parameter files (stc_l.upp) with some added comments. Also see the section that describes all uniprint’s parameters in brief.

-supModel="Epson Stylus Color I (and PRO Series), 360x360DpI, noWeave"
-sDEVICE=uniprint                    -- Select the driver
-dNOPAUSE                            -- Useful with printers
-dSAFER                              -- Provides some security
-dupColorModel=/DeviceCMYK           -- Selects the color mapping
-dupRendering=/ErrorDiffusion        -- Selects the color rendering
-dupOutputFormat=/EscP2              -- Selects the output format
-r360x360                            -- Adjusts the resolution
-dupMargins="{ 9.0 39.96 9.0 9.0}"   -- Establishes (L/B/R/T margins in points)
-dupComponentBits="{1 1 1 1}"        -- Map: bits per component (default: 8)
-dupWeaveYPasses=4                   -- Weave: Y-passes (default: 1)
-dupOutputPins=15                    -- Format/weave: scans per Command
-dupBeginPageCommand="<              -- Goes to the printer
  1b40   1b40                        -- ESC '@' ESC '@'    -> dual reset
  1b2847 0100 01                     -- ESC '(' 'G' 1 0 1  -> graphics
  1b2869 0100 00                     -- ESC '(' 'i' 1 0 1  -> no HW weave
  1b2855 0100 0A                     -- ESC '(' 'U' 1 0 10 -> 360dpi
  1b5500                             -- ESC 'U'  0         -> bidir print
  1b2843 0200 0000                   -- ESC '(' 'C' 2 0 xx -> page length
  1b2863 0400 0000 0000              -- ESC '(' 'c' 4 0 xxxx -> margins
>"                                   -- as it is, unless:
-dupAdjustPageLengthCommand          -- Adjust page length in BOP requested
-dupAdjustTopMarginCommand           -- Adjust top margin in BOP
-dupAdjustBottomMarginCommand        -- Adjust bottom margin in BOP
-dupEndPageCommand="(\033@\014)"     -- Last (but one) data to the printer
-dupAbortCommand="(\033@\15\12\12\12\12    Printout-Aborted\15\014)"

That’s short, and if one removes upWeaveYPasses and upOutputPins it becomes shorter, almost stcany.upp. This miniature size is because I am most familiar with ESC/P2, and was able to add defaults for the omitted parameters. Now a few notes about the parameters used in this example:

  • upModel is a string serving as a comment (and nothing else).

  • DEVICE, NOPAUSE, SAFER are well-known Ghostscript parameters described in the usage documentation.

  • upColorModel is one of the major uniprint parameters: it selects the color mapping and in turn the PostScript color model. It supports the devices /DeviceGray, /DeviceRGBW, /DeviceRGB, /DeviceCMYK, and /DeviceCMYKgenerate.

  • upRendering selects the (color) rendering, supporting the values /ErrorDiffusion and /FSCMYK32. /ErrorDiffusion is similar to fsmono, fsrgb and fsx4 of stcolor, while /FSCMYK32 is (almost) identical to fscmyk and hscmyk, but is restricted to 32-bit data and should be used in conjunction with /DeviceCMYKgenerate.

  • upOutputFormat selects the output method, supporting the values /SunRaster, /Epson, /EscP2, /EscP2XY, and /Pcl.

    /SunRaster

    creates Sun raster files and requires no other parameters

    /Epson

    is used for the elderly ESC/P format (used by many printers)

    /EscP2

    is used by more recent Epson printers (no X weaving supported)

    /EscP2XY

    supports X-Weaving, used with 1440dpi printers and in stc2s_h

    /Pcl

    HP PCL/RTL-style output formatter without weaving

  • -r360x360 is Ghostscript’s standard resolution switch.

  • upMargins="{ 9.0 39.96 9.0 9.0}" has function similar to the Ghostscript parameter .HWMargins: it sets the left, bottom, right, and top margins in points. uniprint provides this parameter to enable automatic left-right exchange if upYFlip is active.

  • upComponentBits is an array of integers that selects the bits stored in raster memory, by default 8 bits per component. In this example, 1 bit is selected for each component, thus turning down the Floyd-Steinberg algorithm (but still carrying out the time-consuming computation). The related parameter upComponentShift controls positioning the components within raster memory. Each of the numbers given corresponds to a component which depends on the selected upColorModel:

    /DeviceGray

    /DeviceRGBW

    /DeviceRGB

    /DeviceCMYK

    /DeviceCMYKgenerate

    0

    White

    White

    Red

    Black

    Black

    1

    Red

    Green

    Cyan

    Cyan

    2

    Green

    Blue

    Magenta

    Magenta

    3

    Blue

    Yellow

    Yellow

    This order may not be suitable for some printers, so another parameter upOutputComponentOrder, also an array of integers, selects the output order using the numbers on the left.

    One group of very important parameters not used in the example above deserves to be mentioned here: the transfer arrays, named up{color}Transfer, where {color} is one of the names in the table above. These are arrays of floats in the range 0.0 - 1.0 representing the color transfer functions. They are used during mapping and rendering. In the simplest case, these arrays ensure an equidistant distribution of the stored values within the device space (which means a nonlinear mapping from Ghostscript’s point of view). If the given array does not cover the entire range from 0 to 1, which applies for the Stylus Color family at high resolution for some media, only the relevant part gets mapped to raster memory (meaning that is’s fully utilized) and the rendering takes care of the “overhang” (in this case the post-diffusion of 1-bit components makes sense).

    Finally an important note on the transfer arrays: for monochrome devices the stored component is White, which is the way PostScript defines these devices, but most printers require Black. Thus one has to provide a falling upWhiteTransfer for such printers.

  • upWeaveYPasses is an integer that gives the number of print head passes required to achieve the requested Ydpi. This makes sense only if upOutputPins is set to something greater than 1. Thus multiple pins or nozzles are transferred with a single command, and of course such a command must be supported by the device.

If no other weave parameters are given, uniprint computes several defaults which together do no weaving. The /Epson and /EscP2XY formats take care of upWeaveXPasses too.

  • upBeginPageCommand represents the data transferred to the printer whenever a new page begins. Before that, upBeginJobCommand is written to the device only once per output file. (Intended for the HP PJL sequences).

  • upAdjustBottomMarginCommand, upAdjustMediaSize, upAdjustPageLengthCommand, upAdjustPageWidthCommand, upAdjustResolutionCommand, and upAdjustTopMarginCommand.

    Normally uniprint does not change the upBeginPageCommand, nor does it provide a default. However, if the above boolean values are set, the corresponding values are changed (provided that the code of the formatters supports this change and the commands to be adjusted are included in the BOP string).

  • upEndPageCommand is the fixed termination sequence for each page, and of course there is an upEndJobCommand too.

  • upAbortCommand is written if uniprint’s interrupt detection is enabled and a signal is caught. It replaces upEndPageCommand and upEndJobCommand, thus allowing the indication of an aborted job. (Ghostscript gets an error return from uniprint in this case, and abandons further processing).

For the ESC/P(2) formats all commands represent binary data, while for the PCL/RTL formatter some of them are formats for fprintf. These strings must explicitly have a trailing "\0'.

I should write more, but the only recommendation is to take a look at the various parameter files. Here are a few more hints.

  • If the Driver rejects a configuration, nothing happens until showpage; then an error is raised and a message with CALL-REJECTED upd_print_page... is printed on stderr.

  • uniprint has lots of messages that can be activated by setting bits in the preprocessor macro UPD_MESSAGES. I usually use the compile-time option -DUPD_MESSAGES=0x17 for configuration development. (For the semantics, check the UPD_M_ macros in the source).

  • A program "uninfo.ps" distributed with Ghostscript displays interactively in alphabetical order the contents of the current pagedevice dictionary. This includes any parameters generated or changed by uniprint.

All parameters in brief

This table gives a brief explanation of every parameter known to uniprint, listing them in alphabetical order. “[ ]” denotes that a parameter is an array, and “(RO)” that it is read-only.

All uniprint parameters
Parameter Type Use
upAbortCommand String End of page and file on interrupt
upAdjustBottomMarginCommand Bool Manipulate bottom margin in upBeginPageCommand
upAdjustMediaSizeCommand Bool Manipulate Mediasize [intended]
upAdjustPageLengthCommand Bool Manipulate page length in upBeginPageCommand
upAdjustPageWidthCommand Bool Manipulate page width in upBeginPageCommand
upAdjustResolutionCommand Bool Manipulate resolution
upAdjustTopMarginCommand Bool Manipulate top margin in upBeginPageCommand
upBeginJobCommand String Begin each output file
upBeginPageCommand String Begin each page
upBlackTransfer Float[ ] Black transfer (CMYK only!)
upBlueTransfer Float[ ] Blue transfer
upColorInfo Int[ ] struct gx_device_color_info
upColorModel Name Select color mapping
upColorModelInitialized Bool (RO) Color mapping OK
upComponentBits Int[ ] Bits stored per component
upComponentShift Int[ ] Positioning within gx_color_index
upCyanTransfer Float[ ] Cyan transfer
upEndJobCommand String End each file unless upAbortCommand
upEndPageCommand String End each page unless upAbortCommand
upErrorDetected Bool (RO) Severe (VM) error, not fully operational
upFSFixedDirection Bool Inhbits direction toggling in rendering
upFSProcessWhiteSpace Bool Causes white-space rendering
upFSReverseDirection Bool Run rendering in reverse (if fixed)
upFSZeroInit Bool Non-random rendering initialization
upFormatXabsolute Bool Write absolute X coordinates
upFormatYabsolute Bool Write absolute Y coordinates
upGreenTransfer Float[ ] Green transfer
upMagentaTransfer Float[ ] Magenta transfer
upMargins Float[ ] L/B/R/T margins in points
upModel String Comment string, holds some info
upOutputAborted Bool (RO) Caught an interrupt
upOutputBuffers Int Number of rendering buffers (2^N)
upOutputComponentOrder Int[ ] Order of components when printing
upOutputComponents Int Number of written components, not fully operational
upOutputFormat Name Select output format
upOutputFormatInitialized Bool (RO) Format data OK
upOutputHeight Int Output height in pixels
upOutputPins Int Number of pins / nozzles per command
upOutputWidth Int Output width in pixels
upOutputXOffset Int Offset in pixels, if upFormatXabsolute
upOutputXStep Int Divisor or multiplier for X coords
upOutputYOffset Int Offset in pixels, if upFormatYabsolute
upOutputYStep Int Divisor or multiplier for Y coords
upRasterBufferInitialized Bool (RO) GS buffer OK
upRedTransfer Float[ ] Red transfer
upRendering Name Select rendering algorithm
upRenderingInitialized Bool (RO) Rendering parameters OK
upSelectComponentCommands String[ ] Establish color (output order!)
upSetLineFeedCommand String Adjust linefeed (Epson only)
upVersion String (RO) Source code version
upWeaveFinalPins Int[ ] Number of bottom pins on EOP passes
upWeaveFinalScan Int Begin EOP passes (Y-coord)
upWeaveFinalXStarts Int[ ] X-pass indices for EOP passes
upWeaveFinalYFeeds Int[ ] Y increments for EOP passes
upWeaveInitialPins Int[ ] Number of top pins on BOP passes
upWeaveInitialScan Int End BOP passes (Y coord)
upWeaveInitialXStarts Int[ ] X-pass indices for BOP passes
upWeaveInitialYFeeds int[ ] Y increments for BOP passes
upWeavePasses Int XPasses × YPasses
upWeaveXPasses Int Number of X passes
upWeaveXStarts Int[ ] X-pass indices for normal passes
upWeaveYFeeds Int[ ] Y increments for normal passes
upWeaveYOffset Int Number of blank or incomplete scans at BOP
upWeaveYPasses Int Number of X passes
upWhiteTransfer Float[ ] White transfer (monochrome devices!)
upWriteComponentCommands String[ ] Commands to write each component
upWroteData Bool (RO) Something (BeginJob) written to output
upXMoveCommand String X positioning command
upXStepCommand String Single step to the right
upYFlip Bool Flips output along the Y axis
upYMoveCommand String Y positioning command
upYStepCommand String Single step down
upYellowTransfer Float[ ] Yellow transfer

uniprint’s Roll of Honor

I should mention all of the people who were involved in stcolor’s evolution, but I’ve decided to start from scratch here for uniprint:

John P. Beale

for testing the stc600 modes

Bill Davidson

who triggered some weaving research and tested stc2s_h

L. Peter Deutsch

who triggered ease of configuration

Mark Goldberg

who prepared the stc500 transfers

Scott F. Johnston and Scott J. Kramer

for testing the stc800 modes

Martin Lottermoser

for his great commented H-P DeskJet driver

Helmut Riegler

for the BJC extension

Hans-Gerd Straeter

for some measured transfer curves and more

Uli Wortmann

for discussions and his cdj850 driver

My family

for tolerating my printer-driver hacking

Gunther Hess Duesseldorfer Landstr. 16b, D-47249 Duisburg ,Germany, +49 203 376273 telephone (MET evening hours)

Uniprint weaving parameters HowTo

This section was contributed by Glenn Ramsey.

I wrote this because the documentation was very brief and I really struggled with it for a while, but it is very simple once you understand what is going on.

This only describes how to work out the Y parameters, I haven’t looked at the X parameters yet.

  1. Determine the nozzle geometry (upOutputPins) You need to know how many nozzles the printer has and the spacing between them. Usually you can find this out from the printer manual, or the printer supplier, but you may have to dissect a couple of printer output files produced with the driver supplied with the printer. There is a utility called escp2ras* that will help with that. Sometimes the term pin is used instead of nozzle but they mean the same thing.

    The number of nozzles will be the value assigned to the upOutputPins parameter.

    Actually you don’t have to print with all the pins available but for the purpose of demonstration I’ll assume that we are using them all.

  2. Determine how many passes are required (upWeaveYPasses).

  3. The number of passes required is going to depend on the required resolution and the nozzle spacing.

    passes = resolution * nozzle spacing
    

    This will be the value assigned to the upWeaveYPasses parameter.

    For example if the desired resolution is 360 dpi and the nozzles are spaced at 1/90in then 360 * 1/90 = 4 passes are required. For 720 dpi 8 passes would be required. The printer would, of course, have to be capable of moving the paper in increments of either 360 or 720 dpi too.

  4. Determine the normal Y feed increment (upWeaveYFeeds)

    You need to work out how much to feed the paper so that when the paper has moved by one head length in however many passes you have then each row space on the paper has been passed over by at least one nozzle. There will be one feed value for each pass and the feed values must comply with the following rules:

    sum of feeds = passes * nozzles
    feed%passes != 0 (feed is not exactly divisible by passes)
    sum of (nozzles - feed) = 0
    

    For example if passes=4 and nozzles=15, then sum of feeds=60. The feed values could be 1,1,1,57 or 15,15,15,15 or 14,15,18,13.

    These values will be assigned to the upWeaveYFeeds parameter.

    You would need to experiment to see what combination looks best on the printer.

    I found it convenient to draw several lines of nozzles and then move them around to see how the different combinations would fill the paper. A computer drawing tool makes this easier than pencil and paper (I used Dia, a GNOME app). The number of nozzles would probably be be a good place to start.

    Remember that if the number of passes is more than 1 then the feed increment will be less than the nozzle spacing and passes × feed increment size must equal the physical distance between each nozzle.

  5. Determine the beginning of page pins (upWeaveInitialPins).

    These values will be assigned to the upWeaveInitialPins parameter and are the numbers of nozzles to operate in each of the initial passes at the top of a page. The nozzles that the values refer to are the topmost nozzles on the head, nearest the top margin. If the image doesn’t start at the top margin then uniprint doesn’t use these feeds.

    I don’t know a mathematical relation for this except that at least one of the values must be the number of nozzles, but I’m sure that there must be one. I used a graphical method, the description that follows refers to the ascii diagram in below.

    Draw a line of nozzles for each pass arranged as they would be using the normal Y feed increment determined in step 3. In the diagram below this would be passes 5-8.

    Draw a line of nozzles that would print just before the first normal pass. The feed increment for this pass will be close to and most likely 1 or 2 units less than the feed increment of the last normal pass. In the example below this line is pass 4 and the feed increment is 13 whereas the normal feed increment is 15.

    Draw each pass before that with a small feed increment so that if all of the nozzles appearing above the first nozzle of the first normal pass operate then all of the spaces will be filled. This feed increment is usually 1 except in cases where some jiggery pokery is going on to make the printer print at an apparent higher resolution than the nozzle diameter.

    Now select the nozzles that will operate in each of theses initial passes so that the paper is filled. In each pass the nozzles must be adjacent to each other and at least one of the passes will have all the nozzles operating. I suspect that for each combination of normal Y feed increments there will only be one set of valid beginning of page increments.

Example: stc.upp from Aladdin Ghostscript 6.01

15 nozzles spaced at 1/90 in, 360 dpi requires 4 passes.

-dupWeaveYPasses=4
-dupOutputPins=15
-dupWeaveYFeeds="{15 15 15 15}"
-dupWeaveInitialYFeeds="{1 1 1 13}"
-dupWeaveInitialPins="{ 4 15 11 7}"

The following diagram shows which nozzles operate during each pass.

Passes 1-4 are beginning of page passes and passes 5-8 are normal passes.

x=nozzle operates, o=nozzle not used in this pass

  1 2 3 4 5 6 7 8 - pass no


0 x
1   x
2     x
3       x
4 x
5   x
6     x
7       x
8 x
9   x
0     x
1       x
2 x
3   x
4     x
5       x
6 o       x
7   x
8     x
9       x
0 o       x
1   x
2     x
3       x
4 o       x
5   x
6     x
7       x
8 o       x
9   x
0     x
1       o   x
2 o       x
3   x
4     x
5       o   x
6 o       x
7   x
8     x
9       o   x
0 o       x
1   x
2     x
3       o   x
4 o       x
5   x
6     o       x
7       o   x
8 o       x
9   x
0     o       x
1       o   x
2 o       x
3   x
4     o       x
5       o   x
6 o       x
7   x
8     o       x
9       o   x
0         x
1               x
2             x
3           x
4         x
5               x
6             x
7           x
8         x
9               x
0             x
1           x
2         x
3               x
4             x
5           x
6
7               x
8             x
9           x
0
1               x
2             x
3           x
4
5               x
6             x
7           x
8
9               x
0             x
1
2
3               x
4             x
5
6
7               x
8             x
9
0
1               x
2             x
3
4
5               x
6
7
8
9               x
0
1
2
3               x
4
5
6
7               x

These parameters would also work:

-dupWeaveYPasses=4
-dupOutputPins=15
-dupWeaveYFeeds="{14 15 18 13}"
-dupWeaveInitialYFeeds="{1 1 1 13}"
-dupWeaveInitialPins="{ 4 11 7 15}"

Extension to uniprint for the Epson Stylus Color 300

This section was contributed by Glenn Ramsey.

The Epson Stylus Color 300 uses a different command set to other Epson Stylus Color printers that use the ESC/P2 language. As far as I can tell its commands are a subset of ESC/P2. In ESC/P2 the colour to be printed is selected by a ‘set colour’ command and then the data sent is only printed in that colour until the colour is changed with another ‘set colour’ command. The Stylus Color 300 lacks this functionality. The data sent to the printer maps directly to the ink nozzles and colour of an output scan line in the printed output is determined by the position of the scan line within the data. This means that the driver must know how the nozzles are arranged and must format the output accordingly. The extension adds a format that I have called EscNozzleMap and adds some additional parameters to uniprint.

  • upOutputFormatselects the output method, and should be set to the value /EscNozzleMap to select this format.

    /EscNozzleMap

    produces output for the Epson Stylus Color 300

    uniprint parameters for the EscNozzleMap format
    Parameter Type Use
    upNozzleMapRowsPerPass Int output rows to generate for each pass of the head
    upNozzleMapPatternRepeat Int no. of rows that correspond to the repeat pattern of the nozzles
    upNozzleMapRowMask Int[] mask indicating the colour of the nozzles
    upNozzleMapMaskScanOffset Int[] mask indicating the physical position of the nozzles

A more detailed description of the new parameters

upNozzleMapRowsPerPass

The number of rows of data that are required to address all nozzles for a single pass of the head. There will always be this number of rows of output data generated. I’d expect it to be the same as the total number of nozzles but it wouldn’t break the formatter if it wasn’t. So if you wanted to print with only the 10th nozzle then row 10 would contain data corresponding to the bit pattern and all of the others would be padded with zeros.

upNozzleMapPatternRepeat

The number of nozzles in each repeated group on the printing head. This parameter must correspond with the length of the upNozzleMapRowMask array.

upNozzleMapRowMask

An array of integers that defines the colour of the nozzles on the head and whether the nozzles will be used to print. The array index defines the row index for the nozzle in the output data and the value defines the colour of the nozzle. The mapping of colours to values is defined in the table below.

header-rows: 1

colour mask value

K

1

C

2

M

3

Y

4

no data

0

A value of 0 means that the nozzle is not used and the row in the output data will be padded with zeros.

upNozzleMapMaskScanOffset

An array of integers that defines the physical position of the nozzles relative to the first nozzle in the repeated group. The relative distance is measured in printed line widths and will be different for different printing resolutions. This parameter is used because the physical spacing of the nozzles may not correspond to their mapping in the output data. For example the ESC300 has nozzles physically arranged something like this:

                                       
                                        etc ...

There is a one nozzle width space between the last two nozzles in each group. In the output data the data for the last nozzle in the group would be in row 5 (numbering starts at 0) but the nozzle is physically positioned at 6 spaces from the first nozzle.

Example 1 - Epson Stylus Color 300 - 360 dpi colour

-dupWeaveYPasses=6
-dupOutputPins=11
-dupWeaveYFeeds="{ 11 11 11 11 11 11 }"
-dupWeaveInitialYFeeds="{ 1 1 1 1 1 7 }"
-dupWeaveInitialPins="{ 2 11 9 7 5 3 }"
-dupNozzleMapRowsPerPass=64
-dupNozzleMapPatternRepeat=6
-dupNozzleMapRowMask="{ 2 4 1 3 0 0 }"
-dupNozzleMapMaskScanOffset="{ 0 1 2 3 0 0 }"

The weaving parameters are the same as for any other uniprint driver but they must be consistent with the nozzle map parameters. In this printer the coloured nozzles are spaced at 1/60” so 6 passes are required for 360 dpi resolution.

In the example there are 64 rows of data required for each head pass. Each row must be completely filled with data for each pass so if certain nozzles do not print in the pass then the rows for those nozzles will be padded with zeroes.

The row mask translates to “C Y K M 0 0” so in the output data rows 0,7,13,… will contain data for cyan, rows 1,8,14,… will contain data for yellow, etc. Rows 4,10,16,… and 5, 11,15,… will always be padded with zeroes. The upNozzleMapPatternRepeat parameter defines the length of the mask.

The row mask is repeated for each group of upNozzleMapPatternRepeat rows in the output data. In this case there are 64 rows so there will be 10 groups of “C Y K M 0 0” followed by “C Y K M” which is equivalent to 11 output pins.

The upNozzleMaskScanOffset array indicates how the data from the scan buffer is mapped to the output data. The data is presented to the formatter as a buffer of four colour scanlines. The index of the scanline being printed, lets call it y, always corresponds, in this example, to the physical position of the cyan nozzle but since the nozzles are not on the same horizontal line then the other colours for the current pass must come from other scanlines in the scan buffer. The example is { 0 1 2 3 0 0 }, this means that when printing a 4 colour image the magenta data would come from scanline y+3, the black from scanline y+2, etc. It would have been possible in this case to use the array index instead of the upNozzleMaskScanOffset parameter however the parameter is necessary to be able to use the full capability of the printer in black only mode.

Example 2 - Epson Stylus Color 300 - 180 dpi black only

-dupMargins="{ 9.0 39.96 9.0 9.0}"
-dupWeaveYPasses=1
-dupOutputPins=31
-dupNozzleMapRowsPerPass=64
-dupNozzleMapPatternRepeat=6
-dupNozzleMapRowMask="{ 0 0 1 0 1 1}"
-dupNozzleMapMaskScanOffset="{ 0 0 0 0 1 2 }"

In this example there is no weaving.

The ESC300 has black nozzles evenly physically arranged as K K K but the data must be sent to the printer as 00K0KK. This is handled by the upNozzleMapRowMask and upNozzleMaskScanOffset arrays. The upNozzleMapRowMask array is { 0 0 1 0 1 1} which translates to { 0 0 K 0 K K } so rows 0, 1 and 3 will always contain zeros and the other rows will contain data.

The upNozzleMaskScanOffset array in this case is { 0 0 0 0 1 2 } so if the data for the 1st nozzle comes from row y in the scan buffer then the data for the 2nd and 3rd nozzles will come from rows y+1 and y+2.

Example 3 - Epson Stylus Color 300 - 360 dpi black only

-dupWeaveYPasses=2
-dupOutputPins=31
-dupWeaveYFeeds="{31 31}"
-dupWeaveInitialYFeeds="{1 31}"
-dupWeaveInitialPins="{16 31}"
-dupNozzleMapRowsPerPass=64
-dupNozzleMapPatternRepeat=6
-dupNozzleMapRowMask="{ 0 0 1 0 1 1}"
-dupNozzleMapMaskScanOffset="{ 0 0 0 0 2 4 }"

In this example 2 weave passes are required to achieve the desired resolution.

The upNozzleMaskScanOffset array in this case is { 0 0 0 0 2 4 } because there are two weave passes so if the data for the first nozzle comes from row y in the scan buffer then the data for the 2nd and 3rd nozzles must come from rows y+(1*2) and y+(2*2).

Glenn Ramsey

glennr at users.sourceforge.net

February 2001


This software is provided AS-IS with no warranty, either express or implied. This software is distributed under license and may not be copied, modified or distributed except as expressly authorized under the terms of that license. Refer to licensing information at https://www.artifex.com or contact Artifex Software, Inc., 1305 Grant Avenue - Suite 200, Novato, CA 94945, U.S.A., +1(415)492-9861, for further information.