/* GENERAL This program converts pbm (B/W) images and 1-bit-per-pixel cmyk images (both produced by ghostscript) to Software Imaging K.K. SLX-stream format. With this utility, you can print to some Lexmark printers, such as these: - Lexmark C500 B/W and Color AUTHORS This program began life as"foo2zjs' and was converted to drive Lexmark C500 printers. You can contact the current author at mailto:rick.richardson@comcast.net LICENSE This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. If you want to use this program under different license conditions, then contact the author for an arrangement. It is possible that certain products which can be built using the jbig software module might form inventions protected by patent rights in some countries (e.g., by patents about arithmetic coding algorithms owned by IBM and AT&T in the USA). Provision of this software by the author does NOT include any licenses for any patents. In those countries where a patent license is required for certain applications of this software module, you will have to obtain such a license yourself. */ static char Version[] = "$Id: foo2slx.c,v 1.20 2007/12/13 15:30:50 rick Exp $"; #include #include #include #include #include #include #include "jbig.h" #include "slx.h" /* * Command line options */ int Debug = 0; int ResX = 1200; int ResY = 600; int Bpp = 1; int PaperCode = DMPAPER_LETTER; int PageWidth = 1200 * 8.5; int PageHeight = 600 * 11; int UpperLeftX = 0; int UpperLeftY = 0; int LowerRightX = 0; int LowerRightY = 0; int Copies = 1; int Duplex = DMDUPLEX_OFF; int SourceCode = DMBIN_AUTO; int MediaCode = DMMEDIA_STANDARD; char *Username = NULL; char *Filename = NULL; int Mode = 0; #define MODE_MONO 1 #define MODE_COLOR 2 int Model = 0; #define MODEL_2300DL 0 #define MODEL_HP1020 1 #define MODEL_LAST 1 int Color2Mono = 0; int BlackClears = 0; int AllIsBlack = 0; int OutputStartPlane = 1; int ExtraPad = 0; int LogicalOffsetX = 0; int LogicalOffsetY = 0; #define LOGICAL_CLIP_X 2 #define LOGICAL_CLIP_Y 1 int LogicalClip = LOGICAL_CLIP_X | LOGICAL_CLIP_Y; int SaveToner = 0; int PageNum = 0; int RealWidth; int EconoMode = 0; int IsCUPS = 0; FILE *EvenPages = NULL; typedef struct { off_t b, e; } SEEKREC; SEEKREC SeekRec[2000]; int SeekIndex = 0; off_t SeekMedia; long JbgOptions[5] = { /* Order */ // JBG_ILEAVE | JBG_SMID, 0, /* Options */ // JBG_DELAY_AT | JBG_LRLTWO | JBG_TPDON | JBG_TPBON | JBG_DPON, JBG_DELAY_AT | JBG_TPBON, /* L0 */ 128, /* MX */ 0, //16, /* MY */ 0 }; void usage(void) { fprintf(stderr, "Usage:\n" " foo2slx [options] slx-file\n" "\n" " Convert Ghostscript pbmraw format to a monochrome SLX stream,\n" " for driving the Lexmark C500 network color laser printer\n" " and other SLX-based and Lexmark black and white printers.\n" "\n" " gs -q -dBATCH -dSAFER -dQUIET -dNOPAUSE \\ \n" " -sPAPERSIZE=letter -r1200x600 -sDEVICE=pbmraw \\ \n" " -sOutputFile=- - < testpage.ps \\ \n" " | foo2slx -r1200x600 -g10200x6600 -p1 >testpage.zm\n" "\n" " foo2slx [options] slx-file\n" " foo2slx [options] slx-file\n" "\n" " Convert Ghostscript bitcmyk or pksmraw format to a color SLX stream,\n" " for driving the Lexmark C500 network color laser printer.\n" " N.B. Color correction is expected to be performed by ghostscript.\n" "\n" " gs -q -dBATCH -dSAFER -dQUIET -dNOPAUSE \\ \n" " -sPAPERSIZE=letter -g10200x6600 -r1200x600 -sDEVICE=bitcmyk \\ \n" " -sOutputFile=- - < testpage.ps \\ \n" " | foo2slx -r1200x600 -g10200x6600 -p1 >testpage.zc\n" "\n" "Normal Options:\n" "-c Force color mode if autodetect doesn't work\n" // "-d duplex Duplex code to send to printer [%d]\n" // " 1=off, 2=longedge, 3=shortedge\n" // " 4=manual longedge, 5=manual shortedge\n" "-g x Set page dimensions in pixels [%dx%d]\n" "-m media Media code to send to printer [%d]\n" " 0=plain, 1=transparency, 2=labels, 3=thick1, 4=envelope1\n" " 5=thin, 6=thick2, 7=envelope2, 8=middle, 9=special\n" "-p paper Paper code to send to printer [%d]\n" " 2=a4, 4=b5, 5=b5iso, 6=letter, 8=executive, 9=legal,\n" " 10=env#10, 11=envDL\n" "-n copies Number of copies [%d]\n" "-r x Set device resolution in pixels/inch [%dx%d]\n" "-s source Source code to send to printer [%d]\n" " 1=upper 2=lower 4=manual 7=auto\n" " Code numbers may vary with printer model\n" // "-t Draft mode. Every other pixel is white.\n" // "-J filename Filename string to send to printer [%s]\n" // "-U username Username string to send to printer [%s]\n" "\n" "Printer Tweaking Options:\n" "-u x Set offset of upper left printable in pixels [%dx%d]\n" "-l x Set offset of lower right printable in pixels [%dx%d]\n" "-L mask Send logical clipping values from -u/-l in ZjStream [%d]\n" " 0=no, 1=Y, 2=X, 3=XY\n" "-A AllIsBlack: convert C=1,M=1,Y=1 to just K=1\n" "-B BlackClears: K=1 forces C,M,Y to 0\n" " -A, -B work with bitcmyk input only\n" // "-P Do not output START_PLANE codes. May be needed by some\n" // " some black and white only printers.\n" // "-X padlen Add extra zero padding to the end of BID segments [%d]\n" // "-z model Model: 0=2300DL 1=hp1020 [%d]\n" "\n" "Debugging Options:\n" "-S plane Output just a single color plane from a color print [all]\n" " 1=Cyan, 2=Magenta, 3=Yellow, 4=Black\n" "-D lvl Set Debug level [%d]\n" "-V Version %s\n" // , Duplex , PageWidth , PageHeight , MediaCode , PaperCode , Copies , ResX , ResY , SourceCode // , Filename ? Filename : "" // , Username ? Username : "" , UpperLeftX , UpperLeftY , LowerRightX , LowerRightY , LogicalClip // , ExtraPad // , Model , Debug , Version ); exit(1); } /* * Mirror1: bits 01234567 become 76543210 */ unsigned char Mirror1[256] = { 0,128, 64,192, 32,160, 96,224, 16,144, 80,208, 48,176,112,240, 8,136, 72,200, 40,168,104,232, 24,152, 88,216, 56,184,120,248, 4,132, 68,196, 36,164,100,228, 20,148, 84,212, 52,180,116,244, 12,140, 76,204, 44,172,108,236, 28,156, 92,220, 60,188,124,252, 2,130, 66,194, 34,162, 98,226, 18,146, 82,210, 50,178,114,242, 10,138, 74,202, 42,170,106,234, 26,154, 90,218, 58,186,122,250, 6,134, 70,198, 38,166,102,230, 22,150, 86,214, 54,182,118,246, 14,142, 78,206, 46,174,110,238, 30,158, 94,222, 62,190,126,254, 1,129, 65,193, 33,161, 97,225, 17,145, 81,209, 49,177,113,241, 9,137, 73,201, 41,169,105,233, 25,153, 89,217, 57,185,121,249, 5,133, 69,197, 37,165,101,229, 21,149, 85,213, 53,181,117,245, 13,141, 77,205, 45,173,109,237, 29,157, 93,221, 61,189,125,253, 3,131, 67,195, 35,163, 99,227, 19,147, 83,211, 51,179,115,243, 11,139, 75,203, 43,171,107,235, 27,155, 91,219, 59,187,123,251, 7,135, 71,199, 39,167,103,231, 23,151, 87,215, 55,183,119,247, 15,143, 79,207, 47,175,111,239, 31,159, 95,223, 63,191,127,255, }; /* * Mirror2: bits 01234567 become 67452301 */ unsigned char Mirror2[256] = { 0, 64,128,192, 16, 80,144,208, 32, 96,160,224, 48,112,176,240, 4, 68,132,196, 20, 84,148,212, 36,100,164,228, 52,116,180,244, 8, 72,136,200, 24, 88,152,216, 40,104,168,232, 56,120,184,248, 12, 76,140,204, 28, 92,156,220, 44,108,172,236, 60,124,188,252, 1, 65,129,193, 17, 81,145,209, 33, 97,161,225, 49,113,177,241, 5, 69,133,197, 21, 85,149,213, 37,101,165,229, 53,117,181,245, 9, 73,137,201, 25, 89,153,217, 41,105,169,233, 57,121,185,249, 13, 77,141,205, 29, 93,157,221, 45,109,173,237, 61,125,189,253, 2, 66,130,194, 18, 82,146,210, 34, 98,162,226, 50,114,178,242, 6, 70,134,198, 22, 86,150,214, 38,102,166,230, 54,118,182,246, 10, 74,138,202, 26, 90,154,218, 42,106,170,234, 58,122,186,250, 14, 78,142,206, 30, 94,158,222, 46,110,174,238, 62,126,190,254, 3, 67,131,195, 19, 83,147,211, 35, 99,163,227, 51,115,179,243, 7, 71,135,199, 23, 87,151,215, 39,103,167,231, 55,119,183,247, 11, 75,139,203, 27, 91,155,219, 43,107,171,235, 59,123,187,251, 15, 79,143,207, 31, 95,159,223, 47,111,175,239, 63,127,191,255, }; /* * Mirror4: bits 01234567 become 45670123 */ unsigned char Mirror4[256] = { 0, 16, 32, 48, 64, 80, 96,112,128,144,160,176,192,208,224,240, 1, 17, 33, 49, 65, 81, 97,113,129,145,161,177,193,209,225,241, 2, 18, 34, 50, 66, 82, 98,114,130,146,162,178,194,210,226,242, 3, 19, 35, 51, 67, 83, 99,115,131,147,163,179,195,211,227,243, 4, 20, 36, 52, 68, 84,100,116,132,148,164,180,196,212,228,244, 5, 21, 37, 53, 69, 85,101,117,133,149,165,181,197,213,229,245, 6, 22, 38, 54, 70, 86,102,118,134,150,166,182,198,214,230,246, 7, 23, 39, 55, 71, 87,103,119,135,151,167,183,199,215,231,247, 8, 24, 40, 56, 72, 88,104,120,136,152,168,184,200,216,232,248, 9, 25, 41, 57, 73, 89,105,121,137,153,169,185,201,217,233,249, 10, 26, 42, 58, 74, 90,106,122,138,154,170,186,202,218,234,250, 11, 27, 43, 59, 75, 91,107,123,139,155,171,187,203,219,235,251, 12, 28, 44, 60, 76, 92,108,124,140,156,172,188,204,220,236,252, 13, 29, 45, 61, 77, 93,109,125,141,157,173,189,205,221,237,253, 14, 30, 46, 62, 78, 94,110,126,142,158,174,190,206,222,238,254, 15, 31, 47, 63, 79, 95,111,127,143,159,175,191,207,223,239,255, }; void rotate_bytes_180(unsigned char *sp, unsigned char *ep, unsigned char *mirror) { unsigned char tmp; while (sp < ep) { tmp = mirror[*sp]; *sp = mirror[*ep]; *ep = tmp; ++sp; --ep; } if (sp == ep) *sp = mirror[*sp]; } void debug(int level, char *fmt, ...) { va_list ap; if (Debug < level) return; setvbuf(stderr, (char *) NULL, _IOLBF, BUFSIZ); va_start(ap, fmt); vfprintf(stderr, fmt, ap); va_end(ap); } void error(int fatal, char *fmt, ...) { va_list ap; va_start(ap, fmt); vfprintf(stderr, fmt, ap); va_end(ap); if (fatal) exit(fatal); } static void chunk_write_rsvd(unsigned long type, unsigned int rsvd, unsigned long items, unsigned long size, FILE *fp) { SL_HEADER chunk; chunk.type = be32(type); chunk.items = be32(items); chunk.size = be32(sizeof(SL_HEADER) + size); chunk.reserved = be16(rsvd); chunk.signature = 0xa5a5; fwrite(&chunk, 1, sizeof(SL_HEADER), fp); } static void chunk_write(unsigned long type, unsigned long items, unsigned long size, FILE *fp) { chunk_write_rsvd(type, 0, items, size, fp); } static void item_uint32_write(unsigned short item, unsigned long value, FILE *fp) { SL_ITEM_UINT32 item_uint32; item_uint32.header.size = be32(sizeof(SL_ITEM_UINT32)); item_uint32.header.item = be16(item); item_uint32.header.type = SLIT_UINT32; item_uint32.header.param = 0; item_uint32.value = be32(value); fwrite(&item_uint32, 1, sizeof(SL_ITEM_UINT32), fp); } static void item_int32_write_pad(unsigned short item, long value, int pad, FILE *fp) { SL_ITEM_INT32 item_int32; item_int32.header.size = be32(sizeof(SL_ITEM_INT32) + pad); item_int32.header.item = be16(item); item_int32.header.type = SLIT_INT32; item_int32.header.param = 0; item_int32.value = be32(value); fwrite(&item_int32, 1, sizeof(SL_ITEM_INT32), fp); while (pad--) fputc(0, fp); } int item_str_write(unsigned short item, char *str, FILE *fp) { int lenpadded; SL_ITEM_HEADER hdr; lenpadded = 4 * ((strlen(str)+1 + 3) / 4); hdr.size = be32(sizeof(hdr) + lenpadded); hdr.item = be16(item); hdr.type = SLIT_STRING; hdr.param = 0; if (fp) { fwrite(&hdr, sizeof(hdr), 1, fp); fwrite(str, lenpadded, 1, fp); } return (sizeof(hdr) + lenpadded); } /* * A linked list of compressed data */ typedef struct _BIE_CHAIN{ unsigned char *data; size_t len; struct _BIE_CHAIN *next; } BIE_CHAIN; void free_chain(BIE_CHAIN *chain) { BIE_CHAIN *next; next = chain; while ((chain = next)) { next = chain->next; if (chain->data) free(chain->data); free(chain); } } int write_plane(int planeNum, BIE_CHAIN **root, FILE *fp) { BIE_CHAIN *current = *root; BIE_CHAIN *next; int i, len, pad_len; #define PADTO 4 debug(3, "Write Plane %d\n", planeNum); /* error handling */ if (!current) error(1,"There is no JBIG!\n"); if (!current->next) error(1,"There is no or wrong JBIG header!\n"); if (current->len != 20) error(1,"wrong BIH length\n"); if (planeNum) { // chunk_write(SLT_START_PLANE, 1, 1*sizeof(SL_ITEM_UINT32), fp); // item_uint32_write(SLI_PLANE, planeNum, fp); } for (current = *root; current && current->len; current = current->next) { if (current == *root) { chunk_write(SLT_JBIG_BIH, 0, current->len, fp); fwrite(current->data, 1, current->len, fp); } else { len = current->len; next = current->next; if (!next || !next->len) pad_len = ExtraPad + PADTO * ((len+PADTO-1)/PADTO) - len; else pad_len = 0; chunk_write(SLT_JBIG_BID, 0, len + pad_len, fp); fwrite(current->data, 1, len, fp); for (i = 0; i < pad_len; i++ ) putc(0, fp); } } free_chain(*root); chunk_write(SLT_END_JBIG, 0, 0, fp); // if (planeNum) // chunk_write(SLT_END_PLANE, 0, 0, fp); return 0; } void start_page(BIE_CHAIN **root, int nbie, FILE *ofp) { BIE_CHAIN *current = *root; unsigned long w, h; static int pageno = 0; int nitems; int customx = 0, customy = 0; /* error handling */ if (!current) error(1, "There is no JBIG!\n"); if (!current->next) error(1, "There is no or wrong JBIG header!\n"); if (current->len != 20 ) error(1,"wrong BIH length\n"); /* startpage, jbig_bih, jbig_bid, jbig_end, endpage */ w = (((long) current->data[ 4] << 24) | ((long) current->data[ 5] << 16) | ((long) current->data[ 6] << 8) | (long) current->data[ 7]); h = (((long) current->data[ 8] << 24) | ((long) current->data[ 9] << 16) | ((long) current->data[10] << 8) | (long) current->data[11]); debug(9, "start_page: w x h = %d x %d\n", w, h); nitems = 14; if (LogicalOffsetX != 0) ++nitems; if (LogicalOffsetY != 0) ++nitems; if (PaperCode == 255) { customx = PageWidth; customy = PageHeight; } chunk_write(SLT_START_PAGE, nitems, nitems * sizeof(SL_ITEM_UINT32), ofp); item_uint32_write(SLI_DMPAPER, PaperCode, ofp); item_uint32_write(SLI_CUSTOM_X, customx, ofp); item_uint32_write(SLI_CUSTOM_Y, customy, ofp); item_uint32_write(SLI_DMCOPIES, Copies, ofp); item_uint32_write(SLI_DMDEFAULTSOURCE, SourceCode, ofp); item_uint32_write(SLI_DMMEDIATYPE, MediaCode, ofp); if ((PageNum & 1) == 0 && EvenPages) SeekMedia = ftell(EvenPages) - 4; item_uint32_write(SLI_NBIE, (nbie==4) ? 14 : 0, ofp); item_uint32_write(SLI_RESOLUTION_X, ResX, ofp); item_uint32_write(SLI_RESOLUTION_Y, ResY, ofp); if (LogicalOffsetX != 0) item_uint32_write(SLI_OFFSET_X, LogicalOffsetX, ofp); if (LogicalOffsetY != 0) item_uint32_write(SLI_OFFSET_Y, LogicalOffsetY, ofp); item_uint32_write(SLI_RASTER_X, RealWidth, ofp); item_uint32_write(SLI_RASTER_Y, h, ofp); item_uint32_write(SLI_VIDEO_X, RealWidth / Bpp,ofp); item_uint32_write(SLI_VIDEO_Y, h, ofp); item_uint32_write(0x10f, 1, ofp); ++pageno; if (IsCUPS) fprintf(stderr, "PAGE: %d %d\n", pageno, Copies); } void end_page(FILE *ofp) { chunk_write(SLT_END_PAGE, 0, 0, ofp); } int write_page(BIE_CHAIN **root, BIE_CHAIN **root2, BIE_CHAIN **root3, BIE_CHAIN **root4, FILE *ofp) { int nbie = root2 ? 4 : 1; start_page(root, nbie, ofp); if (root4) write_plane(4, root4, ofp); if (root) { if (OutputStartPlane) write_plane(nbie == 1 ? 4 : 1, root, ofp); else write_plane(nbie == 1 ? 0 : 1, root, ofp); } if (root2) write_plane(2, root2, ofp); if (root3) write_plane(3, root3, ofp); end_page(ofp); return 0; } /* * This creates a linked list of compressed data. The first item * in the list is the BIH and is always 20 bytes in size. Each following * item is 65536 bytes in length. The last item length is whatever remains. */ void output_jbig(unsigned char *start, size_t len, void *cbarg) { BIE_CHAIN *current, **root = (BIE_CHAIN **) cbarg; int size = 20000000; if ( (*root) == NULL) { (*root) = malloc(sizeof(BIE_CHAIN)); if (!(*root)) error(1, "Can't allocate space for chain\n"); (*root)->data = NULL; (*root)->next = NULL; (*root)->len = 0; size = 20; if (len != 20) error(1, "First chunk must be BIH and 20 bytes long\n"); } current = *root; while (current->next) current = current->next; while (len > 0) { int amt, left; if (!current->data) { current->data = malloc(size); if (!current->data) error(1, "Can't allocate space for compressed data\n"); } left = size - current->len; amt = (len > left) ? left : len; memcpy(current->data + current->len, start, amt); current->len += amt; len -= amt; start += amt; if (current->len == size) { current->next = malloc(sizeof(BIE_CHAIN)); if (!current->next) error(1, "Can't allocate space for chain\n"); current = current->next; current->data = NULL; current->next = NULL; current->len = 0; } } } void start_doc(FILE *fp) { char header[4] = "\245SLX"; // Big-endian data int nitems; int size; int pad1 = 12; fwrite(header, 1, sizeof(header), fp); nitems = 12; size = nitems * sizeof(SL_ITEM_UINT32) + pad1; chunk_write(SLT_START_DOC, nitems, size, fp); item_uint32_write(SLI_PAGECOUNT, -1, fp); item_uint32_write(SLI_DMDUPLEX, 0, fp); item_uint32_write(SLI_DMCOLLATE, 0, fp); item_int32_write_pad(0x03, 0, pad1, fp); item_int32_write_pad(0x04, 0, 0, fp); item_uint32_write(0x05, 0, fp); item_uint32_write(0x06, 0, fp); item_uint32_write(0x07, 1, fp); item_uint32_write(0x08, 0, fp); item_uint32_write(0x09, 0, fp); item_uint32_write(SLI_COUNT, 1, fp); item_uint32_write(0x0e, 0, fp); } void end_doc(FILE *fp) { int nitems; nitems = 0; chunk_write(SLT_END_DOC , nitems, nitems * sizeof(SL_ITEM_UINT32), fp); // item_uint32_write(0x8112, 1, fp); } void load_tray2(FILE *fp) { int nitems; nitems = 0; chunk_write(SLT_2600N_PAUSE, nitems, nitems * sizeof(SL_ITEM_UINT32), fp); } static int AnyColor; void cmyk_planes(unsigned char *plane[4], unsigned char *raw, int w, int h) { int rawbpl = (w+1) / 2; int bpl = (w + 7) / 8; int i; int x, y; unsigned char byte; unsigned char mask[8] = { 128, 64, 32, 16, 8, 4, 2, 1 }; int aib = AllIsBlack; int bc = BlackClears; AnyColor = 0; for (i = 0; i < 4; ++i) memset(plane[i], 0, bpl * h); // // Unpack the combined plane into individual color planes // // TODO: this can be speeded up using a 256 or 65536 entry lookup table // for (y = 0; y < h; ++y) { for (x = 0; x < w; ++x) { byte = raw[y*rawbpl + x/2]; if (aib && (byte & 0xE0) == 0xE0) { plane[3][y*bpl + x/8] |= mask[x&7]; } else if (byte & 0x10) { plane[3][y*bpl + x/8] |= mask[x&7]; if (!bc) { if (byte & 0x80) plane[0][y*bpl + x/8] |= mask[x&7]; if (byte & 0x40) plane[1][y*bpl + x/8] |= mask[x&7]; if (byte & 0x20) plane[2][y*bpl + x/8] |= mask[x&7]; if (byte & 0xE0) AnyColor |= byte; } } else { if (byte & 0x80) plane[0][y*bpl + x/8] |= mask[x&7]; if (byte & 0x40) plane[1][y*bpl + x/8] |= mask[x&7]; if (byte & 0x20) plane[2][y*bpl + x/8] |= mask[x&7]; if (byte & 0xE0) AnyColor |= byte; } ++x; if (aib && (byte & 0x0E) == 0x0E) { plane[3][y*bpl + x/8] |= mask[x&7]; } else if (byte & 0x1) { plane[3][y*bpl + x/8] |= mask[x&7]; if (!bc) { if (byte & 0x8) plane[0][y*bpl + x/8] |= mask[x&7]; if (byte & 0x4) plane[1][y*bpl + x/8] |= mask[x&7]; if (byte & 0x2) plane[2][y*bpl + x/8] |= mask[x&7]; if (byte & 0xE) AnyColor |= byte; } } else { if (byte & 0x8) plane[0][y*bpl + x/8] |= mask[x&7]; if (byte & 0x4) plane[1][y*bpl + x/8] |= mask[x&7]; if (byte & 0x2) plane[2][y*bpl + x/8] |= mask[x&7]; if (byte & 0xE) AnyColor |= byte; } } } debug(2, "BlackClears = %d; AnyColor = %s %s %s\n", BlackClears, (AnyColor & 0x88) ? "Cyan" : "", (AnyColor & 0x44) ? "Magenta" : "", (AnyColor & 0x22) ? "Yellow" : "" ); } int cmyk_page(unsigned char *raw, int w, int h, FILE *ofp) { BIE_CHAIN *chain[4]; int i; int bpl = (w + 7) / 8; unsigned char *plane[4], *bitmaps[4][1]; struct jbg_enc_state se[4]; RealWidth = w; for (i = 0; i < 4; ++i) { plane[i] = malloc(bpl * h); if (!plane[i]) error(3, "Cannot allocate space for bit plane\n"); chain[i] = NULL; } cmyk_planes(plane, raw, w, h); for (i = 0; i < 4; ++i) { if (Debug >= 9) { FILE *dfp; char fname[256]; sprintf(fname, "xxxplane%d", i); dfp = fopen(fname, "w"); if (dfp) { fwrite(plane[i], bpl*h, 1, dfp); fclose(dfp); } } *bitmaps[i] = plane[i]; jbg_enc_init(&se[i], w, h, 1, bitmaps[i], output_jbig, &chain[i]); jbg_enc_options(&se[i], JbgOptions[0], JbgOptions[1], JbgOptions[2], JbgOptions[3], JbgOptions[4]); jbg_enc_out(&se[i]); jbg_enc_free(&se[i]); } if (Color2Mono) write_page(&chain[Color2Mono-1], NULL, NULL, NULL, ofp); else if (AnyColor) write_page(&chain[0], &chain[1], &chain[2], &chain[3], ofp); else write_page(&chain[3], NULL, NULL, NULL, ofp); for (i = 0; i < 4; ++i) free(plane[i]); return 0; } int pksm_page(unsigned char *plane[4], int w, int h, FILE *ofp) { BIE_CHAIN *chain[4]; int i; unsigned char *bitmaps[4][1]; struct jbg_enc_state se[4]; RealWidth = w; for (i = 0; i < 4; ++i) chain[i] = NULL; for (i = 0; i < 4; ++i) { *bitmaps[i] = plane[i]; jbg_enc_init(&se[i], w, h, 1, bitmaps[i], output_jbig, &chain[i]); jbg_enc_options(&se[i], JbgOptions[0], JbgOptions[1], JbgOptions[2], JbgOptions[3], JbgOptions[4]); jbg_enc_out(&se[i]); jbg_enc_free(&se[i]); } if (Color2Mono) write_page(&chain[Color2Mono-1], NULL, NULL, NULL, ofp); else if (AnyColor) write_page(&chain[0], &chain[1], &chain[2], &chain[3], ofp); else write_page(&chain[3], NULL, NULL, NULL, ofp); return 0; } int pbm_page(unsigned char *buf, int w, int h, FILE *ofp) { BIE_CHAIN *chain = NULL; unsigned char *bitmaps[1]; struct jbg_enc_state se; RealWidth = w; if (Model == MODEL_HP1020) w = (w + 127) & ~127; if (SaveToner) { int x, y; int bpl, bpl16; bpl = (w + 7) / 8; if (Model == MODEL_2300DL) bpl16 = bpl; else bpl16 = (bpl + 15) & ~15; for (y = 0; y < h; y += 2) for (x = 0; x < bpl16; ++x) buf[y*bpl16 + x] &= 0x55; for (y = 1; y < h; y += 2) for (x = 0; x < bpl16; ++x) buf[y*bpl16 + x] &= 0xaa; } *bitmaps = buf; debug(9, "w x h = %d x %d\n", w, h); jbg_enc_init(&se, w, h, 1, bitmaps, output_jbig, &chain); jbg_enc_options(&se, JbgOptions[0], JbgOptions[1], JbgOptions[2], JbgOptions[3], JbgOptions[4]); jbg_enc_out(&se); jbg_enc_free(&se); write_page(&chain, NULL, NULL, NULL, ofp); return 0; } int read_and_clip_image(unsigned char *buf, int rawBpl, int rightBpl, int pixelsPerByte, int bpl, int h, int bpl16, FILE *ifp) { unsigned char *rowbuf, *rowp; int y; int rc; rowbuf = malloc(rawBpl); if (!rowbuf) error(1, "Can't allocate row buffer\n"); // Clip top rows if (UpperLeftY) { for (y = 0; y < UpperLeftY; ++y) { rc = fread(rowbuf, rawBpl, 1, ifp); if (rc == 0) goto eof; if (rc != 1) error(1, "Premature EOF(1) on input at y=%d\n", y); } } // Copy the rows that we want to image rowp = buf; for (y = 0; y < h; ++y, rowp += bpl16) { // Clip left pixel *bytes* if (UpperLeftX) { rc = fread(rowbuf, UpperLeftX / pixelsPerByte, 1, ifp); if (rc == 0 && y == 0 && !UpperLeftY) goto eof; if (rc != 1) error(1, "Premature EOF(2) on input at y=%d\n", y); } if (bpl != bpl16) memset(rowp, 0, bpl16); rc = fread(rowp, bpl, 1, ifp); if (rc == 0 && y == 0 && !UpperLeftY && !UpperLeftX) goto eof; if (rc != 1) error(1, "Premature EOF(3) on input at y=%d\n", y); // Clip right pixels if (rightBpl != bpl) { rc = fread(rowbuf, rightBpl - bpl, 1, ifp); if (rc != 1) error(1, "Premature EOF(4) on input at y=%d\n", y); } } // Clip bottom rows if (LowerRightY) { for (y = 0; y < LowerRightY; ++y) { rc = fread(rowbuf, rawBpl, 1, ifp); if (rc != 1) error(1, "Premature EOF(5) on input at y=%d\n", y); } } free(rowbuf); return (0); eof: free(rowbuf); return (EOF); } int cmyk_pages(FILE *ifp, FILE *ofp) { unsigned char *buf; int rawW, rawH, rawBpl; int rightBpl; int w, h, bpl; int rc; // // Save the original Upper Right clip values as the logical offset, // because we may adjust them slightly below, in the interest of speed. // if (LogicalClip & LOGICAL_CLIP_X) LogicalOffsetX = UpperLeftX; if (LogicalClip & LOGICAL_CLIP_Y) LogicalOffsetY = UpperLeftY; rawW = PageWidth; rawH = PageHeight; rawBpl = (PageWidth + 1) / 2; // We only clip multiples of 2 pixels off the leading edge, and // add any remainder to the amount we clip from the right edge. // Its fast, and good enough for government work. LowerRightX += UpperLeftX & 1; UpperLeftX &= ~1; w = rawW - UpperLeftX - LowerRightX; h = rawH - UpperLeftY - LowerRightY; bpl = (w + 1) / 2; rightBpl = (rawW - UpperLeftX + 1) / 2; buf = malloc(bpl * h); if (!buf) error(1, "Unable to allocate page buffer of %d x %d = %d bytes\n", rawW, rawH, rawBpl * rawH); for (;;) { rc = read_and_clip_image(buf, rawBpl, rightBpl, 2, bpl, h, bpl, ifp); if (rc == EOF) goto done; ++PageNum; if (Duplex == DMDUPLEX_LONGEDGE && (PageNum & 1) == 0) rotate_bytes_180(buf, buf + bpl * h - 1, Mirror4); if (Duplex == DMDUPLEX_MANUALLONG && (PageNum & 1) == 0) rotate_bytes_180(buf, buf + bpl * h - 1, Mirror4); if ((PageNum & 1) == 0 && EvenPages) { SeekRec[SeekIndex].b = ftell(EvenPages); cmyk_page(buf, w, h, EvenPages); SeekRec[SeekIndex].e = ftell(EvenPages); debug(1, "CMYK Page: %d %ld %ld\n", PageNum, SeekRec[SeekIndex].b, SeekRec[SeekIndex].e); SeekIndex++; } else cmyk_page(buf, w, h, ofp); } done: free(buf); return 0; } static unsigned long getint(FILE *fp) { int c; unsigned long i; while ((c = getc(fp)) != EOF && !isdigit(c)) if (c == '#') while ((c = getc(fp)) != EOF && !(c == 13 || c == 10)) ; if (c != EOF) { ungetc(c, fp); fscanf(fp, "%lu", &i); } return i; } static void skip_to_nl(FILE *fp) { for (;;) { int c; c = getc(fp); if (c == EOF) error(1, "Premature EOF on input stream\n"); if (c == '\n') return; } } int pbm_header(FILE *ifp, int *p4eatenp, int *wp, int *hp) { int c1, c2; if (*p4eatenp) *p4eatenp = 0; // P4 already eaten in main else { c1 = getc(ifp); if (c1 == EOF) return 0; c2 = getc(ifp); if (c1 != 'P' || c2 != '4') error(1, "Not a pbmraw data stream\n"); } skip_to_nl(ifp); *wp = getint(ifp); *hp = getint(ifp); skip_to_nl(ifp); return 1; } int pksm_pages(FILE *ifp, FILE *ofp) { unsigned char *plane[4]; int rawW, rawH, rawBpl; int saveW = 0, saveH = 0; int rightBpl; int w, h, bpl; int i; int rc; int p4eaten = 1; // // Save the original Upper Right clip values as the logical offset, // because we may adjust them slightly below, in the interest of speed. // if (LogicalClip & LOGICAL_CLIP_X) LogicalOffsetX = UpperLeftX; if (LogicalClip & LOGICAL_CLIP_Y) LogicalOffsetY = UpperLeftY; for (;;) { ++PageNum; AnyColor = 0; for (i = 0; i < 4; ++i) { if (pbm_header(ifp, &p4eaten, &rawW, &rawH) == 0) { if (i == 0) goto eof; else error(1, "Premature EOF(pksm) on page %d hdr, plane %d\n", PageNum, i); } if (i == 0) { saveW = rawW; saveH = rawH; } if (saveW != rawW) error(1, "Image width changed from %d to %d on plane %d\n", saveW, rawW, i); if (saveH != rawH) error(1, "Image height changed from %d to %d on plane %d\n", saveH, rawH, i); rawBpl = (rawW + 7) / 8; // We only clip multiples of 8 pixels off the leading edge, and // add any remainder to the amount we clip from the right edge. // Its fast, and good enough for government work. LowerRightX += UpperLeftX & 7; UpperLeftX &= ~7; w = rawW - UpperLeftX - LowerRightX; h = rawH - UpperLeftY - LowerRightY; bpl = (w + 7) / 8; rightBpl = (rawW - UpperLeftX + 7) / 8; plane[i] = malloc(bpl * h); if (!plane[i]) error(1, "Can't allocate plane buffer\n"); rc = read_and_clip_image(plane[i], rawBpl, rightBpl, 8, bpl, h, bpl, ifp); if (rc == EOF) error(1, "Premature EOF(pksm) on page %d data, plane %d\n", PageNum, i); if (Debug >= 9) { FILE *dfp; char fname[256]; sprintf(fname, "xxxplane%d", i); dfp = fopen(fname, "w"); if (dfp) { fwrite(plane[i], bpl*h, 1, dfp); fclose(dfp); } } // See if we can optimize this to be a monochrome page if (!AnyColor && i != 3) { unsigned char *p, *e; for (p = plane[i], e = p + bpl*h; p < e; ++p) if (*p) { AnyColor |= 1< '9')) ++p; str = p; if (str[0] == 0) return -3; *yp = strtoul(str, &p, 10); if (str == p) return -4; return (0); } void do_one(FILE *in) { int mode; if (Mode == MODE_COLOR) { mode = getc(in); if (mode != 'P') { ungetc(mode, in); cmyk_pages(in, stdout); } else { mode = getc(in); if (mode == '4') pksm_pages(in, stdout); else error(1, "Not a pksmraw file!\n"); } } else { mode = getc(in); if (mode != 'P') error(1, "Not a pbm file!\n"); mode = getc(in); if (mode == '4') pbm_pages(in, stdout); else error(1, "Not a pbmraw file!\n"); } } int main(int argc, char *argv[]) { int c; int i, j; while ( (c = getopt(argc, argv, "cd:g:n:m:p:r:s:tu:l:z:L:ABPJ:S:U:X:D:V?h")) != EOF) switch (c) { case 'c': Mode = MODE_COLOR; break; case 'S': Color2Mono = atoi(optarg); Mode = MODE_COLOR; if (Color2Mono < 0 || Color2Mono > 4) error(1, "Illegal value '%s' for -C\n", optarg); break; case 'd': Duplex = atoi(optarg); break; case 'g': if (parse_xy(optarg, &PageWidth, &PageHeight)) error(1, "Illegal format '%s' for -g\n", optarg); if (PageWidth < 0 || PageWidth > 1000000) error(1, "Illegal X value '%s' for -g\n", optarg); if (PageHeight < 0 || PageHeight > 1000000) error(1, "Illegal Y value '%s' for -g\n", optarg); break; case 'm': MediaCode = atoi(optarg); break; case 'n': Copies = atoi(optarg); break; case 'p': PaperCode = atoi(optarg); break; case 'r': if (parse_xy(optarg, &ResX, &ResY)) error(1, "Illegal format '%s' for -r\n", optarg); break; case 's': SourceCode = atoi(optarg); break; case 't': SaveToner = 1; break; case 'u': if (strcmp(optarg, "0") == 0) break; if (parse_xy(optarg, &UpperLeftX, &UpperLeftY)) error(1, "Illegal format '%s' for -u\n", optarg); break; case 'l': if (strcmp(optarg, "0") == 0) break; if (parse_xy(optarg, &LowerRightX, &LowerRightY)) error(1, "Illegal format '%s' for -l\n", optarg); break; case 'z': Model = atoi(optarg); if (Model < 0 || Model > MODEL_LAST) error(1, "Illegal value '%s' for -z\n", optarg); break; case 'L': LogicalClip = atoi(optarg); if (LogicalClip < 0 || LogicalClip > 3) error(1, "Illegal value '%s' for -L\n", optarg); break; case 'A': AllIsBlack = !AllIsBlack; break; case 'B': BlackClears = !BlackClears; break; case 'P': OutputStartPlane = !OutputStartPlane; break; case 'J': if (optarg[0]) Filename = optarg; break; case 'U': if (optarg[0]) Username = optarg; break; case 'X': ExtraPad = atoi(optarg); break; case 'D': Debug = atoi(optarg); break; case 'V': printf("%s\n", Version); exit(0); default: usage(); exit(1); } if (UpperLeftX < 0 || UpperLeftX >= PageWidth) error(1, "Illegal X value '%d' for -u\n", UpperLeftX); if (UpperLeftY < 0 || UpperLeftY >= PageHeight) error(1, "Illegal Y value '%d' for -u\n", UpperLeftY); if (LowerRightX < 0 || LowerRightX >= PageWidth) error(1, "Illegal X value '%d' for -l\n", LowerRightX); if (LowerRightY < 0 || LowerRightY >= PageHeight) error(1, "Illegal Y value '%d' for -l\n", LowerRightY); argc -= optind; argv += optind; if (getenv("DEVICE_URI")) IsCUPS = 1; if (Model == MODEL_HP1020) { Bpp = ResX / 600; ResX = 600; if (SaveToner) { SaveToner = 0; EconoMode = 1; } } switch (Duplex) { case DMDUPLEX_MANUALLONG: case DMDUPLEX_MANUALSHORT: EvenPages = tmpfile(); break; } start_doc(stdout); if (argc == 0) { do_one(stdin); } else { for (i = 0; i < argc; ++i) { FILE *ifp; ifp = fopen(argv[i], "r"); if (!ifp) error(1, "Can't open '%s' for reading\n", argv[i]); do_one(ifp); fclose(ifp); } } /* * Do manual duplex */ if (EvenPages) { DWORD media; // Handle odd page count if ( (PageNum & 1) == 1) { SeekRec[SeekIndex].b = ftell(EvenPages); blank_page(EvenPages); SeekRec[SeekIndex].e = ftell(EvenPages); debug(1, "Blank Page: %d %ld %ld\n", PageNum, SeekRec[SeekIndex].b, SeekRec[SeekIndex].e); SeekIndex++; } /* * Manual Pause */ if (Model == MODEL_HP1020) load_tray2(stdout); fseek(EvenPages, SeekMedia, 0L); media = be32(DMMEDIA_LETTERHEAD); fwrite(&media, 1, sizeof(DWORD), EvenPages); // Write even pages in reverse order for (i = SeekIndex-1; i >= 0; --i) { debug(1, "EvenPage: %d %ld %ld\n", i, SeekRec[i].b, SeekRec[i].e); fseek(EvenPages, SeekRec[i].b, 0L); for (j = 0; j < (SeekRec[i].e - SeekRec[i].b); ++j) putc(getc(EvenPages), stdout); } fclose(EvenPages); } end_doc(stdout); exit(0); }