/* Copyright (C) 1990, 1992, 1993 Aladdin Enterprises. All rights reserved. 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 the license contained in the file LICENSE in this distribution. For more information about licensing, please refer to http://www.ghostscript.com/licensing/. For information on commercial licensing, go to http://www.artifex.com/licensing/ or contact Artifex Software, Inc., 101 Lucas Valley Road #110, San Rafael, CA 94903, U.S.A., +1(415)492-9861. */ /* $Id$*/ /* * StarJet SJ48 printer driver. * * --- derived from gdevbj10.c 1993-10-07 * by Mats kerblom (f86ma@dd.chalmers.se). */ #include "gdevprn.h" /* * The only available resolutions (in the program) are (180,360)x(180,360). * * Used control codes: * @ Printer reset * J Make a n/180 inch linefeed * \ Move the print position (a+256b)/180 inch to the right * *... Print graphics; m=39: 180*180 dpi * m=40: 360*180 dpi * m=71: 180*360 dpi * m=72: 360*360 dpi * a+256b columns is printed. */ /* The device descriptor */ private dev_proc_print_page(sj48_print_page); gx_device_printer far_data gs_sj48_device = prn_device(prn_std_procs, "sj48", 80, /* width_10ths, 8" */ 105, /* height_10ths, 10.5" */ 360, /* x_dpi */ 360, /* y_dpi */ 0,0,0,0, /* margins */ 1, sj48_print_page); /* This comes from the bj10/bj200 source. I don't know how it applies * for a StarJet. --- Mats kerblom. * * * The following is taken from the BJ200 Programmer's manual. The top * margin is 3mm (0.12"), and the bottom margin is 6.4mm (0.25"). The * left and right margin depend on the type of paper -- US letter or * A4 -- but ultimately rest on a print width of 203.2mm (8"). For letter * paper, the left margin (and hence the right) is 6.4mm (0.25"), while * for A4 paper, both are 3.4mm (0.13"). * * The bottom margin requires a bit of care. The image is printed * as strips, each about 3.4mm wide. We can only attain the bottom * margin if the final strip coincides with it. Note that each strip * is generated using only 48 of the available 64 jets, and the absence * of those bottom 16 jets makes our bottom margin, in effect, about * 1.1mm (0.04") larger. * * The bj200 behaves, in effect, as though the origin were at the first * printable position, rather than the top left corner of the page, so * we add a translation to the initial matrix to compensate for this. * * Except for the details of getting the margins correct, the bj200 is * no different from the bj10e, and uses the same routine to print each * page. * */ /* Send the page to the printer. */ private int sj48_print_page(gx_device_printer *pdev, FILE *prn_stream) { int line_size = gx_device_raster((gx_device *)pdev, 0); int xres = pdev->x_pixels_per_inch; int yres = pdev->y_pixels_per_inch; int mode = (yres == 180 ? (xres == 180 ? 39 : 40) : (xres == 180 ? 71 : 72)); int bytes_per_column = (yres == 180) ? 3 : 6; int bits_per_column = bytes_per_column * 8; int skip_unit = bytes_per_column * (xres == 180 ? 1 : 2); /* Skips in step of 1/180" */ byte *in = (byte *)gs_malloc(8, line_size, "sj48_print_page(in)"); byte *out = (byte *)gs_malloc(bits_per_column, line_size, "sj48_print_page(out)"); int lnum = 0; int skip = 0; int skips; int code = 0; int last_row = dev_print_scan_lines(pdev); int limit = last_row - bits_per_column; if ( in == 0 || out == 0 ) { code = gs_error_VMerror; gs_note_error(code); goto fin; } /* Abort if the requested resolution is unsupported. */ if ((xres !=180 && xres != 360) || (yres !=180 && yres != 360)) { code = gs_error_rangecheck; gs_note_error(code); goto fin; } /* Initialize the printer. */ fwrite("\033@\000\000", 1, 4, prn_stream); /* , <0>, <0>. */ /* Transfer pixels to printer. The last row we can print is defined by "last_row". Only the bottom of the print head can print at the bottom margin, and so we align the final printing pass. The print head is kept from moving below "limit", which is exactly one pass above the bottom margin. Once it reaches this limit, we make our final printing pass of a full "bits_per_column" rows. */ while ( lnum < last_row ) { byte *in_data; byte *in_end = in + line_size; byte *out_beg = out; byte *out_end = out + bytes_per_column * pdev->width; byte *outl = out; int count, bnum; /* Copy 1 scan line and test for all zero. */ code = gdev_prn_get_bits(pdev, lnum, in, &in_data); if ( code < 0 ) goto xit; /* The mem... or str... functions should be faster than */ /* the following code, but all systems seem to implement */ /* them so badly that this code is faster. */ { register const long *zip = (const long *)in_data; register int zcnt = line_size; register const byte *zipb; for ( ; zcnt >= 4 * sizeof(long); zip += 4, zcnt -= 4 * sizeof(long) ) { if ( zip[0] | zip[1] | zip[2] | zip[3] ) goto notz; } zipb = (const byte *)zip; while ( --zcnt >= 0 ) { if ( *zipb++ ) goto notz; } /* Line is all zero, skip */ lnum++; skip++; continue; notz: ; } /* Vertical tab to the appropriate position. Note here that we make sure we don't move below limit. */ if ( lnum > limit ) { skip -= (limit - lnum); lnum = limit; } /* The SJ48 can only skip in steps of 1/180" */ if (yres == 180) { skips = skip; } else { if (skip & 1) { skip--; /* Makes skip even. */ lnum--; } skips = skip/2; } while ( skips > 255 ) { fputs("\033J\377", prn_stream); skips -= 255; } if ( skips ) fprintf(prn_stream, "\033J%c", skips); /* If we've printed as far as "limit", then reset "limit" to "last_row" for the final printing pass. */ if ( lnum == limit ) limit = last_row; skip = 0; /* Transpose in blocks of 8 scan lines. */ for ( bnum = 0; bnum < bits_per_column; bnum += 8 ) { int lcnt = min(8, limit - lnum); byte *inp = in; byte *outp = outl; lcnt = gdev_prn_copy_scan_lines(pdev, lnum, in, lcnt * line_size); if ( lcnt < 0 ) { code = lcnt; goto xit; } if ( lcnt < 8 ) memset(in + lcnt * line_size, 0, (8 - lcnt) * line_size); for ( ; inp < in_end; inp++, outp += bits_per_column ) { gdev_prn_transpose_8x8(inp, line_size, outp, bytes_per_column); } outl++; lnum += lcnt; skip += lcnt; } /* Send the bits to the printer. We alternate horizontal skips with the data. The horizontal skips are in units of 1/180 inches, so we look at the data in groups of 1 or 2 columns depending on resolution (controlled by skip_unit). */ outl = out; do { int count; int n; byte *out_ptr; /* First look for blank groups of columns. */ while(outl < out_end) { n = count = min(out_end - outl, skip_unit); out_ptr = outl; while ( --count >= 0 ) { if ( *out_ptr++ ) break; } if ( count >= 0 ) break; else outl = out_ptr; } if (outl >= out_end) break; if (outl > out_beg) { count = (outl - out_beg) / skip_unit; fprintf(prn_stream, "\033\\%c%c", count & 0xff, count >> 8); } /* Next look for non-blank groups of columns. */ out_beg = outl; outl += n; while(outl < out_end) { n = count = min(out_end - outl, skip_unit); out_ptr = outl; while ( --count >= 0 ) { if ( *out_ptr++ ) break; } if ( count < 0 ) break; else outl += n; } count = outl - out_beg; { /* What to transmit is the number of columns in the row. Compare this with the |*-command wich expects the total number of bytes in the graphic row! */ int count1 = count/bytes_per_column; fprintf(prn_stream, "\033*%c%c%c", mode, count1 & 0xff, count1 >> 8); } fwrite(out_beg, 1, count, prn_stream); out_beg = outl; outl += n; } while ( out_beg < out_end ); fputc('\r', prn_stream); skip = bits_per_column; /* only moves to the beginning of the row. */ } /* Eject the page */ xit: fputc(014, prn_stream); /* form feed */ fflush(prn_stream); fin: if ( out != 0 ) gs_free((char *)out, bits_per_column, line_size, "sj48_print_page(out)"); if ( in != 0 ) gs_free((char *)in, 8, line_size, "sj48_print_page(in)"); return code; }