/* ultra.c - Ultracode libzint - the open source barcode library Copyright (C) 2020-2022 Robin Stuart Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of the project nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* This version was developed using AIMD/TSC15032-43 v0.99c Edit 60, dated 4th Nov 2015 */ #ifdef _MSC_VER #include #endif #include #include "common.h" #define ULT_EIGHTBIT_MODE 10 #define ULT_ASCII_MODE 20 #define ULT_C43_MODE 30 #define ULT_PREDICT_WINDOW 12 #define ULT_GFMUL(i, j) ((((i) == 0)||((j) == 0)) ? 0 : gfPwr[(gfLog[i] + gfLog[j])]) static const char ult_fragment[27][13] = {"http://", "https://", "http://www.", "https://www.", "ftp://", "www.", ".com", ".edu", ".gov", ".int", ".mil", ".net", ".org", ".mobi", ".coop", ".biz", ".info", "mailto:", "tel:", ".cgi", ".asp", ".aspx", ".php", ".htm", ".html", ".shtml", "file:"}; static const char ult_c43_set1[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789 .,%"; static const char ult_c43_set2[] = "abcdefghijklmnopqrstuvwxyz:/?#[]@=_~!.,-"; static const char ult_c43_set3[] = "{}`()\"+'<>|$;&\\^*"; static const char ult_digit[] = "0123456789,/"; static const char ult_colour[] = "0CBMRYGKW"; // Max size and min cols adjusted to BWIPP values as updated 2021-07-14 // https://github.com/bwipp/postscriptbarcode/commit/4255810845fa8d45c6192dd30aee1fdad1aaf0cc static const int ult_maxsize[] = {37, 84, 161, 282}; static const int ult_mincols[] = {5, 13, 22, 29}; static const int ult_kec[] = {0, 1, 2, 4, 6, 8}; // Value K(EC) from Table 12 /* Taken from BWIPP - change in DCCU/DCCL tiles for revision 2 2021-09-28 */ static const unsigned short ult_dccu[2][32] = { { // Revision 1 051363, 051563, 051653, 053153, 053163, 053513, 053563, 053613, // 0-7 053653, 056153, 056163, 056313, 056353, 056363, 056513, 056563, // 8-15 051316, 051356, 051536, 051616, 053156, 053516, 053536, 053616, // 16-23 053636, 053656, 056136, 056156, 056316, 056356, 056516, 056536 // 24-31 }, { // Revision 2 (inversion of DCCL Revision 1) 015316, 016316, 013516, 016516, 013616, 015616, 013136, 015136, // 0-7 016136, 013536, 016536, 013636, 013156, 016156, 015356, 013656, // 8-15 015313, 016313, 013513, 016513, 013613, 015613, 013153, 015153, // 16-23 016153, 016353, 013653, 015653, 013163, 015163, 015363, 013563 // 24-31 }, }; static const unsigned short ult_dccl[2][32] = { { // Revision 1 061351, 061361, 061531, 061561, 061631, 061651, 063131, 063151, // 0-7 063161, 063531, 063561, 063631, 065131, 065161, 065351, 065631, // 8-15 031351, 031361, 031531, 031561, 031631, 031651, 035131, 035151, // 16-23 035161, 035361, 035631, 035651, 036131, 036151, 036351, 036531 // 24-31 }, { // Revision 2 (inversion of DCCU Revision 1) 036315, 036515, 035615, 035135, 036135, 031535, 036535, 031635, // 0-7 035635, 035165, 036165, 031365, 035365, 036365, 031565, 036565, // 8-15 061315, 065315, 063515, 061615, 065135, 061535, 063535, 061635, // 16-23 063635, 065635, 063165, 065165, 061365, 065365, 061565, 063565 // 24-31 }, }; static const int ult_tiles[] = { 013135, 013136, 013153, 013156, 013163, 013165, 013513, 013515, 013516, 013531, // 0-9 013535, 013536, 013561, 013563, 013565, 013613, 013615, 013616, 013631, 013635, // 10-19 013636, 013651, 013653, 013656, 015135, 015136, 015153, 015163, 015165, 015313, // 20-29 015315, 015316, 015351, 015353, 015356, 015361, 015363, 015365, 015613, 015615, // 30-39 015616, 015631, 015635, 015636, 015651, 015653, 015656, 016135, 016136, 016153, // 40-49 016156, 016165, 016313, 016315, 016316, 016351, 016353, 016356, 016361, 016363, // 50-59 016365, 016513, 016515, 016516, 016531, 016535, 016536, 016561, 016563, 016565, // 60-69 031315, 031316, 031351, 031356, 031361, 031365, 031513, 031515, 031516, 031531, // 70-79 031535, 031536, 031561, 031563, 031565, 031613, 031615, 031631, 031635, 031636, // 80-89 031651, 031653, 031656, 035131, 035135, 035136, 035151, 035153, 035156, 035161, // 90-99 035163, 035165, 035315, 035316, 035351, 035356, 035361, 035365, 035613, 035615, // 100-109 035616, 035631, 035635, 035636, 035651, 035653, 035656, 036131, 036135, 036136, // 110-119 036151, 036153, 036156, 036163, 036165, 036315, 036316, 036351, 036356, 036361, // 120-129 036365, 036513, 036515, 036516, 036531, 036535, 036536, 036561, 036563, 036565, // 130-139 051313, 051315, 051316, 051351, 051353, 051356, 051361, 051363, 051365, 051513, // 140-149 051516, 051531, 051536, 051561, 051563, 051613, 051615, 051616, 051631, 051635, // 150-159 051636, 051651, 051653, 051656, 053131, 053135, 053136, 053151, 053153, 053156, // 160-169 053161, 053163, 053165, 053513, 053516, 053531, 053536, 053561, 053563, 053613, // 170-179 053615, 053616, 053631, 053635, 053636, 053651, 053653, 053656, 056131, 056135, // 180-189 056136, 056151, 056153, 056156, 056161, 056163, 056165, 056313, 056315, 056316, // 190-199 056351, 056353, 056356, 056361, 056363, 056365, 056513, 056516, 056531, 056536, // 200-209 056561, 056563, 061313, 061315, 061316, 061351, 061353, 061356, 061361, 061363, // 210-219 061365, 061513, 061515, 061516, 061531, 061535, 061536, 061561, 061563, 061565, // 220-229 061615, 061631, 061635, 061651, 061653, 063131, 063135, 063136, 063151, 063153, // 230-239 063156, 063161, 063163, 063165, 063513, 063515, 063516, 063531, 063535, 063536, // 240-249 063561, 063563, 063565, 063613, 063615, 063631, 063635, 063651, 063653, 065131, // 250-259 065135, 065136, 065151, 065153, 065156, 065161, 065163, 065165, 065313, 065315, // 260-269 065316, 065351, 065353, 065356, 065361, 065363, 065365, 065613, 065615, 065631, // 270-279 065635, 065651, 065653, 056565, 051515 // 280-284 }; /* The following adapted from ECC283.C "RSEC codeword generator" * from Annex B of Ultracode draft * originally written by Ted Williams of Symbol Vision Corp. * Dated 2001-03-09 * Corrected thanks to input from Terry Burton */ /* * NOTE: Included here is an attempt to allow code compression within Ultracode. Unfortunately * the copy of the standard this was written from was an early draft which includes self * contradictions, so this is a "best guess" implementation. Because it is not guaranteed * to be correct this compression is not applied by default. To enable compression set * * symbol->option_3 = ULTRA_COMPRESSION; * * Code compression should be enabled by default when it has been implemented according to * a more reliable version of the specification. */ /* Generate divisor polynomial gQ(x) for GF283() given the required ECC size, 3 to 101 */ static void ult_genPoly(const short EccSize, unsigned short gPoly[], const unsigned short gfPwr[], const unsigned short gfLog[]) { int i, j; gPoly[0] = 1; for (i = 1; i < (EccSize + 1); i++) gPoly[i] = 0; for (i = 0; i < EccSize; i++) { for (j = i; j >= 0; j--) gPoly[j + 1] = (gPoly[j] + ULT_GFMUL(gPoly[j + 1], gfPwr[i + 1])) % 283; gPoly[0] = ULT_GFMUL(gPoly[0], gfPwr[i + 1]); } for (i = EccSize - 1; i >= 0; i -= 2) gPoly[i] = 283 - gPoly[i]; /* gPoly[i] is > 0 so modulo operation not needed */ } /* Generate the log and antilog tables for GF283() multiplication & division */ static void ult_initLogTables(unsigned short gfPwr[], unsigned short gfLog[]) { int i, j; for (j = 0; j < 283; j++) gfLog[j] = 0; i = 1; for (j = 0; j < 282; j++) { /* j + 282 indices save doing the modulo operation in ULT_GFMUL */ gfPwr[j + 282] = gfPwr[j] = (short) i; gfLog[i] = (short) j; i = (i * 3) % 283; } } static void ult_gf283(const short DataSize, const short EccSize, int Message[]) { /* Input is complete message codewords in array Message[282] * DataSize is number of message codewords * EccSize is number of Reed-Solomon GF(283) check codewords to generate * * Upon exit, Message[282] contains complete 282 codeword Symbol Message * including leading zeroes corresponding to each truncated codeword */ unsigned short gPoly[283], gfPwr[(282 * 2)], gfLog[283]; int i, j, n; unsigned short t; /* first build the log & antilog tables used in multiplication & division */ ult_initLogTables(gfPwr, gfLog); /* then generate the division polynomial of length EccSize */ ult_genPoly(EccSize, gPoly, gfPwr, gfLog); /* zero all EccSize codeword values */ for (j = 281; (j > (281 - EccSize)); j--) Message[j] = 0; /* shift message codewords to the right, leave space for ECC checkwords */ for (i = DataSize - 1; (i >= 0); j--, i--) Message[j] = Message[i]; /* add zeroes to pad left end Message[] for truncated codewords */ j++; for (i = 0; i < j; i++) Message[i] = 0; /* generate (EccSize) Reed-Solomon checkwords */ for (n = j; n < (j + DataSize); n++) { t = (Message[j + DataSize] + Message[n]) % 283; for (i = 0; i < (EccSize - 1); i++) { Message[j + DataSize + i] = (Message[j + DataSize + i + 1] + 283 - ULT_GFMUL(t, gPoly[EccSize - 1 - i])) % 283; } Message[j + DataSize + EccSize - 1] = (283 - ULT_GFMUL(t, gPoly[0])) % 283; } for (i = j + DataSize; i < (j + DataSize + EccSize); i++) Message[i] = (283 - Message[i]) % 283; } /* End of Ted Williams code */ static int ult_find_fragment(const unsigned char source[], const int length, const int position) { int retval = -1; int j, k, latch, fraglen; for (j = 0; j < 27; j++) { latch = 0; fraglen = (int) strlen(ult_fragment[j]); if ((position + fraglen) <= length) { latch = 1; for (k = 0; k < fraglen; k++) { if (source[position + k] != ult_fragment[j][k]) { latch = 0; break; } } } if (latch) { retval = j; } } return retval; } /* Encode characters in 8-bit mode */ static float ult_look_ahead_eightbit(const unsigned char source[], const int length, const int in_locn, const int current_mode, const int end_char, int cw[], int *cw_len, const int gs1) { int codeword_count = 0; int i; int letters_encoded = 0; if (current_mode != ULT_EIGHTBIT_MODE) { cw[codeword_count] = 282; // Unlatch codeword_count += 1; } i = in_locn; while ((i < length) && (i < end_char)) { if ((source[i] == '[') && gs1) { cw[codeword_count] = 268; // FNC1 } else { cw[codeword_count] = source[i]; } i++; codeword_count++; } letters_encoded = i - in_locn; *cw_len = codeword_count; if (codeword_count == 0) { return 0.0f; } return (float) letters_encoded / (float) codeword_count; } /* Encode character in the ASCII mode/submode (including numeric compression) */ static float ult_look_ahead_ascii(unsigned char source[], const int length, const int in_locn, const int current_mode, const int symbol_mode, const int end_char, int cw[], int *cw_len, int *encoded, const int gs1) { int codeword_count = 0; int i; int first_digit, second_digit, done; int letters_encoded = 0; if (current_mode == ULT_EIGHTBIT_MODE) { cw[codeword_count] = 267; // Latch ASCII Submode codeword_count++; } if (current_mode == ULT_C43_MODE) { cw[codeword_count] = 282; // Unlatch codeword_count++; if (symbol_mode == ULT_EIGHTBIT_MODE) { cw[codeword_count] = 267; // Latch ASCII Submode codeword_count++; } } i = in_locn; do { /* Check for double digits */ done = 0; if (i + 1 < length) { first_digit = posn(ult_digit, source[i]); second_digit = posn(ult_digit, source[i + 1]); if ((first_digit != -1) && (second_digit != -1)) { /* Double digit can be encoded */ if ((first_digit >= 0) && (first_digit <= 9) && (second_digit >= 0) && (second_digit <= 9)) { /* Double digit numerics */ cw[codeword_count] = (10 * first_digit) + second_digit + 128; codeword_count++; i += 2; done = 1; } else if ((first_digit >= 0) && (first_digit <= 9) && (second_digit == 10)) { /* Single digit followed by selected decimal point character */ cw[codeword_count] = first_digit + 228; codeword_count++; i += 2; done = 1; } else if ((first_digit == 10) && (second_digit >= 0) && (second_digit <= 9)) { /* Selected decimal point character followed by single digit */ cw[codeword_count] = second_digit + 238; codeword_count++; i += 2; done = 1; } else if ((first_digit >= 0) && (first_digit <= 9) && (second_digit == 11)) { /* Single digit or decimal point followed by field deliminator */ cw[codeword_count] = first_digit + 248; codeword_count++; i += 2; done = 1; } else if ((first_digit == 11) && (second_digit >= 0) && (second_digit <= 9)) { /* Field deliminator followed by single digit or decimal point */ cw[codeword_count] = second_digit + 259; codeword_count++; i += 2; done = 1; } } } if (!done && source[i] < 0x80) { if ((source[i] == '[') && gs1) { cw[codeword_count] = 272; // FNC1 } else { cw[codeword_count] = source[i]; } codeword_count++; i++; } } while ((i < length) && (i < end_char) && (source[i] < 0x80)); letters_encoded = i - in_locn; if (encoded != NULL) { *encoded = letters_encoded; } *cw_len = codeword_count; if (codeword_count == 0) { return 0.0f; } return (float) letters_encoded / (float) codeword_count; } /* Returns true if should latch to subset other than given `subset` */ static int ult_c43_should_latch_other(const unsigned char source[], const int length, const int locn, const int subset, const int gs1) { int i, fraglen, predict_window; int cnt, alt_cnt, fragno; const char *const set = subset == 1 ? ult_c43_set1 : ult_c43_set2; const char *const alt_set = subset == 2 ? ult_c43_set1 : ult_c43_set2; if (locn + 3 > length) { return 0; } predict_window = locn + 3; for (i = locn, cnt = 0, alt_cnt = 0; i < predict_window; i++) { if (source[i] <= 0x1F || source[i] >= 0x7F || (gs1 && source[i] == '[')) { break; } fragno = ult_find_fragment(source, length, i); if (fragno != -1 && fragno != 26) { fraglen = (int) strlen(ult_fragment[fragno]); predict_window += fraglen; if (predict_window > length) { predict_window = length; } i += fraglen - 1; } else { if (posn(set, source[i]) != -1) { cnt++; } if (posn(alt_set, source[i]) != -1) { alt_cnt++; } } } return alt_cnt > cnt; } static int ult_get_subset(const unsigned char source[], const int length, const int in_locn, const int current_subset) { int fragno; int subset = 0; fragno = ult_find_fragment(source, length, in_locn); if ((fragno != -1) && (fragno != 26)) { subset = 3; } else if (current_subset == 2) { if (posn(ult_c43_set2, source[in_locn]) != -1) { subset = 2; } else if (posn(ult_c43_set1, source[in_locn]) != -1) { subset = 1; } } else { if (posn(ult_c43_set1, source[in_locn]) != -1) { subset = 1; } else if (posn(ult_c43_set2, source[in_locn]) != -1) { subset = 2; } } if (subset == 0) { if (posn(ult_c43_set3, source[in_locn]) != -1) { subset = 3; } } return subset; } /* Encode characters in the C43 compaction submode */ static float ult_look_ahead_c43(const unsigned char source[], const int length, const int in_locn, const int current_mode, const int end_char, int subset, int cw[], int *cw_len, int *encoded, const int gs1, const int debug_print) { int codeword_count = 0; int subcodeword_count = 0; int i; int fragno; int sublocn = in_locn; int new_subset; int unshift_set; int base43_value; int letters_encoded = 0; int pad; #ifndef _MSC_VER int subcw[(length + 3) * 2]; #else int *subcw = (int *) _alloca((length + 3) * 2 * sizeof(int)); #endif /* _MSC_VER */ if (current_mode == ULT_EIGHTBIT_MODE) { /* Check for permissable URL C43 macro sequences, otherwise encode directly */ fragno = ult_find_fragment(source, length, sublocn); if ((fragno == 2) || (fragno == 3)) { // http://www. > http:// // https://www. > https:// fragno -= 2; } switch (fragno) { case 17: // mailto: cw[codeword_count] = 276; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; case 18: // tel: cw[codeword_count] = 277; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; case 26: // file: cw[codeword_count] = 278; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; case 0: // http:// cw[codeword_count] = 279; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; case 1: // https:// cw[codeword_count] = 280; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; case 4: // ftp:// cw[codeword_count] = 281; sublocn += (int) strlen(ult_fragment[fragno]); codeword_count++; break; default: if (subset == 1) { cw[codeword_count] = 260; // C43 Compaction Submode C1 codeword_count++; } else if ((subset == 2) || (subset == 3)) { cw[codeword_count] = 266; // C43 Compaction Submode C2 codeword_count++; } break; } } else if (current_mode == ULT_ASCII_MODE) { if (subset == 1) { cw[codeword_count] = 278; // C43 Compaction Submode C1 codeword_count++; } else if ((subset == 2) || (subset == 3)) { cw[codeword_count] = 280; // C43 Compaction Submode C2 codeword_count++; } } unshift_set = subset; while ((sublocn < length) && (sublocn < end_char)) { /* Check for FNC1 */ if (gs1 && source[sublocn] == '[') { break; } new_subset = ult_get_subset(source, length, sublocn, subset); if (new_subset == 0) { break; } if ((new_subset != subset) && ((new_subset == 1) || (new_subset == 2))) { if (ult_c43_should_latch_other(source, length, sublocn, subset, gs1)) { subcw[subcodeword_count] = 42; // Latch to other C43 set subcodeword_count++; unshift_set = new_subset; } else { subcw[subcodeword_count] = 40; // Shift to other C43 set for 1 char subcodeword_count++; subcw[subcodeword_count] = posn(new_subset == 1 ? ult_c43_set1 : ult_c43_set2, source[sublocn]); subcodeword_count++; sublocn++; continue; } } subset = new_subset; if (subset == 1) { subcw[subcodeword_count] = posn(ult_c43_set1, source[sublocn]); subcodeword_count++; sublocn++; } else if (subset == 2) { subcw[subcodeword_count] = posn(ult_c43_set2, source[sublocn]); subcodeword_count++; sublocn++; } else if (subset == 3) { subcw[subcodeword_count] = 41; // Shift to set 3 subcodeword_count++; fragno = ult_find_fragment(source, length, sublocn); if (fragno != -1 && fragno != 26) { if (fragno <= 18) { subcw[subcodeword_count] = fragno; // C43 Set 3 codewords 0 to 18 subcodeword_count++; sublocn += (int) strlen(ult_fragment[fragno]); } else { subcw[subcodeword_count] = fragno + 17; // C43 Set 3 codewords 36 to 42 subcodeword_count++; sublocn += (int) strlen(ult_fragment[fragno]); } } else { subcw[subcodeword_count] = posn(ult_c43_set3, source[sublocn]) + 19; // C43 Set 3 codewords 19 to 35 subcodeword_count++; sublocn++; } subset = unshift_set; } } pad = 3 - (subcodeword_count % 3); if (pad == 3) { pad = 0; } for (i = 0; i < pad; i++) { subcw[subcodeword_count] = 42; // Latch to other C43 set used as pad subcodeword_count++; } if (debug_print) { printf("C43 codewords %.*s: (%d)", length, source + in_locn, subcodeword_count); for (i = 0; i < subcodeword_count; i++) printf( " %d", subcw[i]); printf("\n"); } letters_encoded = sublocn - in_locn; if (encoded != NULL) { *encoded = letters_encoded; } for (i = 0; i < subcodeword_count; i += 3) { base43_value = (43 * 43 * subcw[i]) + (43 * subcw[i + 1]) + subcw[i + 2]; cw[codeword_count] = base43_value / 282; codeword_count++; cw[codeword_count] = base43_value % 282; codeword_count++; } *cw_len = codeword_count; if (codeword_count == 0) { return 0.0f; } return (float) letters_encoded / (float) codeword_count; } /* Produces a set of codewords which are "somewhat" optimised - this could be improved on */ static int ult_generate_codewords(struct zint_symbol *symbol, const unsigned char source[], const int length, const int eci, const int gs1, const int symbol_mode, int *p_current_mode, int codewords[], int codeword_count) { int i; int crop_length; int input_locn = 0; int current_mode; int subset; float eightbit_score; float ascii_score; float c43_score; int end_char; int block_length; int fragment_length; int ascii_encoded, c43_encoded; const int debug_print = (symbol->debug & ZINT_DEBUG_PRINT); #ifndef _MSC_VER unsigned char crop_source[length + 1]; char mode[length + 1]; int cw_fragment[length * 2 + 1]; #else unsigned char *crop_source = (unsigned char *) _alloca(length + 1); char *mode = (char *) _alloca(length + 1); int *cw_fragment = (int *) _alloca((length * 2 + 1) * sizeof(int)); #endif /* _MSC_VER */ /* Check for 06 Macro Sequence and crop accordingly */ if (length >= 9 && source[0] == '[' && source[1] == ')' && source[2] == '>' && source[3] == '\x1e' && source[4] == '0' && source[5] == '6' && source[6] == '\x1d' && source[length - 2] == '\x1e' && source[length - 1] == '\x04') { if (symbol_mode == ULT_EIGHTBIT_MODE) { codewords[codeword_count] = 271; // 06 Macro } else { codewords[codeword_count] = 273; // 06 Macro } codeword_count++; for (i = 7; i < (length - 2); i++) { crop_source[i - 7] = source[i]; } crop_length = length - 9; crop_source[crop_length] = '\0'; } else { /* Make a cropped version of input data - removes http:// and https:// if needed */ for (i = input_locn; i < length; i++) { crop_source[i - input_locn] = source[i]; } crop_length = length - input_locn; crop_source[crop_length] = '\0'; } /* Attempt encoding in all three modes to see which offers best compaction and store results */ if (symbol->option_3 == ULTRA_COMPRESSION || gs1) { current_mode = symbol_mode; input_locn = 0; do { end_char = input_locn + ULT_PREDICT_WINDOW; eightbit_score = ult_look_ahead_eightbit(crop_source, crop_length, input_locn, current_mode, end_char, cw_fragment, &fragment_length, gs1); ascii_score = ult_look_ahead_ascii(crop_source, crop_length, input_locn, current_mode, symbol_mode, end_char, cw_fragment, &fragment_length, &ascii_encoded, gs1); subset = ult_c43_should_latch_other(crop_source, crop_length, input_locn, 1 /*subset*/, gs1) ? 2 : 1; c43_score = ult_look_ahead_c43(crop_source, crop_length, input_locn, current_mode, end_char, subset, cw_fragment, &fragment_length, &c43_encoded, gs1, 0 /*debug_print*/); mode[input_locn] = 'a'; current_mode = ULT_ASCII_MODE; if ((c43_score > ascii_score) && (c43_score > eightbit_score)) { mode[input_locn] = 'c'; current_mode = ULT_C43_MODE; } else if ((eightbit_score > ascii_score) && (eightbit_score > c43_score)) { mode[input_locn] = '8'; current_mode = ULT_EIGHTBIT_MODE; } if (mode[input_locn] == 'a') { for (i = 0; i < ascii_encoded; i++) { mode[input_locn + i] = 'a'; } input_locn += ascii_encoded; } else if (mode[input_locn] == 'c') { for (i = 0; i < c43_encoded; i++) { mode[input_locn + i] = 'c'; } input_locn += c43_encoded; } else { input_locn++; } } while (input_locn < crop_length); } else { // Force eight-bit mode for (input_locn = 0; input_locn < crop_length; input_locn++) { mode[input_locn] = '8'; } } mode[crop_length] = '\0'; if (debug_print) { printf("Mode (%d): %s\n", (int) strlen(mode), mode); } if (symbol_mode == ULT_EIGHTBIT_MODE && *p_current_mode != ULT_EIGHTBIT_MODE) { codewords[codeword_count++] = 282; // Unlatch to 8-bit mode } if (eci) { if (eci < 899) { codewords[codeword_count++] = 272; codewords[codeword_count++] = eci / 256; codewords[codeword_count++] = eci % 256; } else if (eci < 10000) { codewords[codeword_count++] = 274; codewords[codeword_count++] = eci / 100 + 128; codewords[codeword_count++] = eci % 100 + 128; } else { codewords[codeword_count++] = 275; codewords[codeword_count++] = eci / 10000 + 128; codewords[codeword_count++] = (eci % 10000) / 100 + 128; codewords[codeword_count++] = eci % 100 + 128; } } /* Use results from test to perform actual mode switching */ current_mode = symbol_mode; input_locn = 0; do { fragment_length = 0; block_length = 0; while (input_locn + block_length < crop_length && mode[input_locn + block_length] == mode[input_locn]) { block_length++; } switch (mode[input_locn]) { case 'a': ult_look_ahead_ascii(crop_source, crop_length, input_locn, current_mode, symbol_mode, input_locn + block_length, cw_fragment, &fragment_length, NULL, gs1); current_mode = ULT_ASCII_MODE; break; case 'c': subset = ult_c43_should_latch_other(crop_source, crop_length, input_locn, 1 /*subset*/, gs1) ? 2 : 1; ult_look_ahead_c43(crop_source, crop_length, input_locn, current_mode, input_locn + block_length, subset, cw_fragment, &fragment_length, NULL, gs1, debug_print); /* Substitute temporary latch if possible */ if (current_mode == ULT_EIGHTBIT_MODE && cw_fragment[0] == 260 && fragment_length >= 5 && fragment_length <= 11) { cw_fragment[0] = 256 + (fragment_length - 5) / 2; /* Temporary latch to submode 1 from Table 11 */ } else if (current_mode == ULT_EIGHTBIT_MODE && cw_fragment[0] == 266 && fragment_length >= 5 && fragment_length <= 11) { cw_fragment[0] = 262 + (fragment_length - 5) / 2; /* Temporary latch to submode 2 from Table 11 */ } else if (current_mode == ULT_ASCII_MODE && cw_fragment[0] == 278 && fragment_length >= 5 && fragment_length <= 11) { cw_fragment[0] = 274 + (fragment_length - 5) / 2; /* Temporary latch to submode 1 from Table 9 */ } else { current_mode = ULT_C43_MODE; } break; case '8': ult_look_ahead_eightbit(crop_source, crop_length, input_locn, current_mode, input_locn + block_length, cw_fragment, &fragment_length, gs1); current_mode = ULT_EIGHTBIT_MODE; break; } for (i = 0; i < fragment_length; i++) { codewords[codeword_count + i] = cw_fragment[i]; } codeword_count += fragment_length; input_locn += block_length; } while (input_locn < crop_length); *p_current_mode = current_mode; return codeword_count; } /* Call `ult_generate_codewords()` for each segment, dealing with symbol mode and start codeword beforehand */ static int ult_generate_codewords_segs(struct zint_symbol *symbol, struct zint_seg segs[], const int seg_count, int codewords[]) { int i; int codeword_count = 0; int symbol_mode; int current_mode; int have_eci = 0; const unsigned char *source = segs[0].source; int length = segs[0].length; const int eci = segs[0].eci; const int gs1 = (symbol->input_mode & 0x07) == GS1_MODE; for (i = 0; i < seg_count; i++) { if (segs[i].eci) { have_eci = 1; break; } } if (have_eci || (symbol->option_3 != ULTRA_COMPRESSION && !gs1)) { // Force eight-bit mode by default as other modes are poorly documented symbol_mode = ULT_EIGHTBIT_MODE; } else { // Decide start character codeword (from Table 5) symbol_mode = ULT_ASCII_MODE; for (i = 0; i < length; i++) { if (source[i] >= 0x80) { symbol_mode = ULT_EIGHTBIT_MODE; break; } } } if (symbol->output_options & READER_INIT) { /* Reader Initialisation mode */ codeword_count = 2; if (symbol_mode == ULT_ASCII_MODE) { codewords[0] = 272; // 7-bit ASCII mode codewords[1] = 271; // FNC3 } else { codewords[0] = 257; // 8859-1 codewords[1] = 269; // FNC3 } } else { /* Calculate start character codeword */ codeword_count = 1; if (symbol_mode == ULT_ASCII_MODE) { if (gs1) { codewords[0] = 273; } else { codewords[0] = 272; } } else { if ((eci >= 3) && (eci <= 18) && (eci != 14)) { // ECI indicates use of character set within ISO/IEC 8859 codewords[0] = 257 + (eci - 3); if (codewords[0] > 267) { // Avoids ECI 14 for non-existant ISO/IEC 8859-12 codewords[0]--; } } else if ((eci > 18) && (eci <= 898)) { // ECI indicates use of character set outside ISO/IEC 8859 codewords[0] = 275 + (eci / 256); codewords[1] = eci % 256; codeword_count = 2; } else if (eci == 899) { // Non-language byte data codewords[0] = 280; } else if ((eci > 899) && (eci <= 9999)) { // ECI beyond 899 needs to use fixed length encodable ECI invocation (section 7.6.2) // Encode as 3 codewords codewords[0] = 257; // ISO/IEC 8859-1 used to enter 8-bit mode codewords[1] = 274; // Encode ECI as 3 codewords codewords[2] = (eci / 100) + 128; codewords[3] = (eci % 100) + 128; codeword_count = 4; } else if (eci >= 10000) { // Encode as 4 codewords codewords[0] = 257; // ISO/IEC 8859-1 used to enter 8-bit mode codewords[1] = 275; // Encode ECI as 4 codewords codewords[2] = (eci / 10000) + 128; codewords[3] = ((eci % 10000) / 100) + 128; codewords[4] = (eci % 100) + 128; codeword_count = 5; } else { codewords[0] = 257; // Default is assumed to be ISO/IEC 8859-1 (ECI 3) } } if ((codewords[0] == 257) || (codewords[0] == 272)) { int fragno = ult_find_fragment(source, length, 0); // Check for http:// at start of input if ((fragno == 0) || (fragno == 2)) { codewords[0] = 281; source += 7; length -= 7; symbol_mode = ULT_EIGHTBIT_MODE; // Check for https:// at start of input } else if ((fragno == 1) || (fragno == 3)) { codewords[0] = 282; source += 8; length -= 8; symbol_mode = ULT_EIGHTBIT_MODE; } } } current_mode = symbol_mode; codeword_count = ult_generate_codewords(symbol, source, length, 0 /*eci*/, gs1, symbol_mode, ¤t_mode, codewords, codeword_count); for (i = 1; i < seg_count; i++) { codeword_count = ult_generate_codewords(symbol, segs[i].source, segs[i].length, segs[i].eci, gs1, symbol_mode, ¤t_mode, codewords, codeword_count); } return codeword_count; } INTERNAL int ultra(struct zint_symbol *symbol, struct zint_seg segs[], const int seg_count) { int data_cw_count = 0; int acc, qcc; int scr[3] = {0}, scr_cw_count = 0; /* Symbol Control Region (only if have Structured Append) */ int dr_count; int ecc_level; int rows, columns; int total_cws; int pads; int cw_memalloc; // Allow for 3 pads in final 57th (60th incl. clock tracks) column of 5-row symbol (57 * 5 == 285) int codeword[282 + 3]; int i, j, locn; int total_height, total_width; char tilepat[6]; int tilex, tiley; int dcc; int revision_idx = 0; const int debug_print = (symbol->debug & ZINT_DEBUG_PRINT); #ifdef _MSC_VER int *data_codewords; char *pattern; #endif /* _MSC_VER */ (void)seg_count; if (symbol->eci > 811799) { strcpy(symbol->errtxt, "590: ECI value not supported by Ultracode"); return ZINT_ERROR_INVALID_OPTION; } if (symbol->structapp.count) { int link2 = 2; /* Draft Table 7, Structured Append Group (SAG) with no File Number */ if (symbol->structapp.count < 2 || symbol->structapp.count > 8) { strcpy(symbol->errtxt, "558: Structured Append count out of range (2-8)"); return ZINT_ERROR_INVALID_OPTION; } if (symbol->structapp.index < 1 || symbol->structapp.index > symbol->structapp.count) { sprintf(symbol->errtxt, "559: Structured Append index out of range (1-%d)", symbol->structapp.count); return ZINT_ERROR_INVALID_OPTION; } scr_cw_count = 1; if (symbol->structapp.id[0]) { int id, id_len; for (id_len = 0; id_len < 32 && symbol->structapp.id[id_len]; id_len++); if (id_len > 5) { /* 282 * 283 + 282 = 80088 */ strcpy(symbol->errtxt, "727: Structured Append ID too long (5 digit maximum)"); return ZINT_ERROR_INVALID_OPTION; } id = to_int((const unsigned char *) symbol->structapp.id, id_len); if (id == -1) { strcpy(symbol->errtxt, "728: Invalid Structured Append ID (digits only)"); return ZINT_ERROR_INVALID_OPTION; } if (id > 80088) { sprintf(symbol->errtxt, "729: Structured Append ID '%d' out of range (1-80088)", id); return ZINT_ERROR_INVALID_OPTION; } if (id) { link2 = 3; /* Missing from draft Table 7 but mentioned 7.4.3 - SAG with File Number */ scr[1] = id / 283; scr[2] = id % 283; /* 7.4.3.2 says 1-282 but can be 0 if id >= 283 */ scr_cw_count += 2; } } scr[0] = link2 * 70 + (symbol->structapp.count - 1) * 8 + symbol->structapp.index - 1; } cw_memalloc = segs_length(segs, seg_count) * 2; if (cw_memalloc < 283) { cw_memalloc = 283; } #ifndef _MSC_VER int data_codewords[cw_memalloc]; #else data_codewords = (int *) _alloca(cw_memalloc * sizeof(int)); #endif /* _MSC_VER */ data_cw_count = ult_generate_codewords_segs(symbol, segs, seg_count, data_codewords); if (debug_print) { printf("Codewords (%d):", data_cw_count); for (i = 0; i < data_cw_count; i++) { printf(" %d", data_codewords[i]); } printf("\n"); } #ifdef ZINT_TEST if (symbol->debug & ZINT_DEBUG_TEST) { debug_test_codeword_dump_int(symbol, data_codewords, data_cw_count); } #endif data_cw_count += 2 + scr_cw_count; // 2 == MCC + ACC (data codeword count includes start char) if (symbol->option_2 > 0) { if (symbol->option_2 > 2) { strcpy(symbol->errtxt, "592: Revision must be 1 or 2"); return ZINT_ERROR_INVALID_OPTION; } if (symbol->option_2 == 2) { /* Revision 2, swop and inversion of DCCU/DCCL tiles */ revision_idx = 1; } } /* Default ECC level is EC2 */ if ((symbol->option_1 <= 0) || (symbol->option_1 > 6)) { ecc_level = 2; } else { ecc_level = symbol->option_1 - 1; } /* ECC calculation from section 7.7.2 */ if (ecc_level == 0) { qcc = 3; } else { if ((data_cw_count % 25) == 0) { qcc = (ult_kec[ecc_level] * (data_cw_count / 25)) + 3 + 2; } else { qcc = (ult_kec[ecc_level] * ((data_cw_count / 25) + 1)) + 3 + 2; } } if (debug_print) { printf("EC%d codewords: %d\n", ecc_level + 1, qcc); } acc = qcc - 3; if (scr_cw_count) { acc += 70; /* Link1 = 1 (* 70) means SCR present */ } if (debug_print) { printf("MCC: %d, ACC: %d, SCR: %d", data_cw_count, acc, scr_cw_count); if (scr_cw_count) { printf(", SCR0: %d", scr[0]); if (scr_cw_count > 1) { printf(", SCR1: %d, SCR2: %d", scr[1], scr[2]); } } printf("\n"); } /* Maximum capacity is 282 codewords */ total_cws = data_cw_count + qcc + 3; // 3 == TCC pattern + RSEC pattern + QCC pattern if (total_cws - 3 > 282) { strcpy(symbol->errtxt, "591: Data too long for selected error correction capacity"); return ZINT_ERROR_TOO_LONG; } rows = 5; for (i = 2; i >= 0; i--) { // Total codewords less 6 (+ SCR) overhead (Start + MCC + ACC (+ SCR) + 3 TCC/RSEC/QCC patterns) if (total_cws - (6 + scr_cw_count) <= ult_maxsize[i]) { rows--; } } if ((total_cws % rows) == 0) { pads = 0; columns = total_cws / rows; } else { pads = rows - (total_cws % rows); columns = (total_cws / rows) + 1; } columns += columns / 15; // Secondary vertical clock tracks if (debug_print) { printf("Calculated size is %d rows by %d columns (pads %d)\n", rows, columns, pads); } /* Insert MCC and ACC and possibly SCR into data codewords */ for (i = 282; i > 2 + scr_cw_count; i--) { data_codewords[i] = data_codewords[i - (2 + scr_cw_count)]; } data_codewords[1] = data_cw_count; // MCC data_codewords[2] = acc; // ACC for (i = 0; i < scr_cw_count; i++) { // SCR data_codewords[3 + i] = scr[i]; } /* Calculate error correction codewords (RSEC) */ ult_gf283((short) data_cw_count, (short) qcc, data_codewords); if (debug_print) { printf("ECCs (%d):", qcc); for (i = 0; i < qcc; i++) { printf(" %d", data_codewords[(282 - qcc) + i]); } printf("\n"); } /* Rearrange to make final codeword sequence */ locn = 0; codeword[locn++] = data_codewords[282 - (data_cw_count + qcc)]; // Start Character codeword[locn++] = data_cw_count; // MCC for (i = 0; i < qcc; i++) { codeword[locn++] = data_codewords[(282 - qcc) + i]; // RSEC Region } codeword[locn++] = data_cw_count + qcc; // TCC = C + Q - section 6.11.4 codeword[locn++] = 283; // Separator codeword[locn++] = acc; // ACC for (i = 0; i < scr_cw_count; i++) { // SCR codeword[locn++] = scr[i]; } dr_count = data_cw_count - (3 + scr_cw_count); for (i = 0; i < dr_count; i++) { codeword[locn++] = data_codewords[(282 - (dr_count + qcc)) + i]; // Data Region } for (i = 0; i < pads; i++) { codeword[locn++] = 284; // Pad pattern } codeword[locn++] = qcc; // QCC if (debug_print) { printf("Rearranged codewords with ECC:\n"); for (i = 0; i < locn; i++) { printf("%d ", codeword[i]); } printf("\n"); } total_height = (rows * 6) + 1; total_width = columns + 6; /* Build symbol */ #ifndef _MSC_VER char pattern[total_height * total_width]; #else pattern = (char *) _alloca(total_height * total_width); #endif /* _MSC_VER */ for (i = 0; i < (total_height * total_width); i++) { pattern[i] = 'W'; } /* Border */ for (i = 0; i < total_width; i++) { pattern[i] = 'K'; // Top pattern[(total_height * total_width) - i - 1] = 'K'; // Bottom } for (i = 0; i < total_height; i++) { pattern[total_width * i] = 'K'; // Left pattern[(total_width * i) + 3] = 'K'; pattern[(total_width * i) + (total_width - 1)] = 'K'; // Right } /* Clock tracks */ for (i = 0; i < total_height; i += 2) { pattern[(total_width * i) + 1] = 'K'; // Primary vertical clock track if (total_width > 20) { pattern[(total_width * i) + 19] = 'K'; // Secondary vertical clock track } if (total_width > 36) { pattern[(total_width * i) + 35] = 'K'; // Secondary vertical clock track } if (total_width > 52) { pattern[(total_width * i) + 51] = 'K'; // Secondary vertical clock track } } for (i = 6; i < total_height; i += 6) { for (j = 5; j < total_width; j += 2) { pattern[(total_width * i) + j] = 'K'; // Horizontal clock track } } /* Place tiles */ tilepat[5] = '\0'; tilex = 0; tiley = 0; for (i = 0; i < locn; i++) { for (j = 0; j < 5; j++) { tilepat[4 - j] = ult_colour[(ult_tiles[codeword[i]] >> (3 * j)) & 0x07]; } if ((tiley + 1) >= total_height) { tiley = 0; tilex++; if (tilex == 14) { tilex++; } else if (tilex == 30) { tilex++; } else if (tilex == 46) { tilex++; } } for (j = 0; j < 5; j++) { pattern[((tiley + j + 1) * total_width) + (tilex + 5)] = tilepat[j]; } tiley += 6; } /* Add data column count */ dcc = columns - ult_mincols[rows - 2]; tilex = 2; tiley = (total_height - 11) / 2; /* DCCU */ for (j = 0; j < 5; j++) { tilepat[4 - j] = ult_colour[(ult_dccu[revision_idx][dcc] >> (3 * j)) & 0x07]; } for (j = 0; j < 5; j++) { pattern[((tiley + j) * total_width) + tilex] = tilepat[j]; } /* DCCL */ tiley += 6; for (j = 0; j < 5; j++) { tilepat[4 - j] = ult_colour[(ult_dccl[revision_idx][dcc] >> (3 * j)) & 0x07]; } for (j = 0; j < 5; j++) { pattern[((tiley + j) * total_width) + tilex] = tilepat[j]; } if (debug_print) { printf("DCC: %d\n", dcc); for (i = 0; i < (total_height * total_width); i++) { printf("%c", pattern[i]); if ((i + 1) % total_width == 0) { printf("\n"); } } } /* Put pattern into symbol */ symbol->rows = total_height; symbol->width = total_width; for (i = 0; i < total_height; i++) { symbol->row_height[i] = 1; for (j = 0; j < total_width; j++) { set_module_colour(symbol, i, j, posn(ult_colour, pattern[(i * total_width) + j])); } } symbol->height = total_height; return 0; } /* vim: set ts=4 sw=4 et : */