/* micqr.c - Handles Micro QR Code versions M1 - M4 */ /* libzint - the open source barcode library Copyright (C) 2009 Robin Stuart 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 3 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include "common.h" #include "micqr.h" #include "reedsol.h" #define NUMERIC 1 #define ALPHANUM 2 #define BYTE 3 #define KANJI 4 #define QRSET "0123456789ABCDEFGHIJKLNMOPQRSTUVWXYZ $%*+-./:" void qrnumeric_encode(char binary[], unsigned char source[]) { /* Encodes numeric data according to section 6.4.3 */ int input_length, blocks, remainder, i; char block_binary[11]; int block_value; block_value = 0; input_length = ustrlen(source); blocks = input_length / 3; remainder = input_length % 3; for(i = 0; i < blocks; i++) { block_value = ctoi(source[(i * 3)]) * 100; block_value += ctoi(source[(i * 3) + 1]) * 10; block_value += ctoi(source[(i * 3) + 2]); strcpy(block_binary, ""); if(block_value & 0x200) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x100) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x80) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x40) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x20) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x10) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x08) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x04) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x02) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x01) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } concat(binary, block_binary); } if(remainder == 2) { block_value = ctoi(source[(i * 3)]) * 10; block_value += ctoi(source[(i * 3) + 1]); } if(remainder == 1) { block_value = ctoi(source[(i * 3)]); } strcpy(block_binary, ""); switch(remainder) { case 2: if(block_value & 0x40) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x20) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x10) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } case 1: if(block_value & 0x08) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x04) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x02) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x01) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } break; } concat(binary, block_binary); return; } void qralpha_encode(char binary[], unsigned char source[]) { /* Encodes alphanumeric data according to 6.4.4 */ int input_length, blocks, remainder, i; char block_binary[12]; int block_value; input_length = ustrlen(source); blocks = input_length / 2; remainder = input_length % 2; for(i = 0; i < blocks; i++) { block_value = posn(QRSET, source[i * 2]) * 45; block_value += posn(QRSET, source[(i * 2) + 1]); strcpy(block_binary, ""); if(block_value & 0x400) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x200) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x100) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x80) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x40) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x20) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x10) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x08) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x04) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x02) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x01) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } concat(binary, block_binary); } if(remainder == 1) { block_value = posn(QRSET, source[i * 2]); strcpy(block_binary, ""); if(block_value & 0x20) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x10) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x08) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x04) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x02) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } if(block_value & 0x01) { concat(block_binary, "1"); } else { concat(block_binary, "0"); } concat(binary, block_binary); } return; } void qrbyte_encode(char binary[], unsigned char source[]) { /* Encodes byte mode data according to 6.4.5 */ int input_length, i; input_length = ustrlen(source); for(i = 0; i < input_length; i++) { if(source[i] & 0x80) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x40) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x20) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x10) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x08) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x04) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x02) { concat(binary, "1"); } else { concat(binary, "0"); } if(source[i] & 0x01) { concat(binary, "1"); } else { concat(binary, "0"); } } return; } int qrkanji_encode(char binary[], unsigned char source[]) { /* Assumes input is in Shift-JIS format */ int i, len, h, val, count; len = ustrlen(source); count = 0; for(i=0; i> 8) * 0xc0; val = (val & 0xff) + h; if(val & 0x1000) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x800) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x400) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x200) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x100) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x80) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x40) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x20) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x10) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x08) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x04) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x02) { concat(binary, "1"); } else { concat(binary, "0"); } if(val & 0x01) { concat(binary, "1"); } else { concat(binary, "0"); } count++; } return count; } void versionm1(char binary_data[], unsigned char source[]) { int input_length, i, latch; int bits_total, bits_left, remainder; int data_codewords, ecc_codewords; unsigned char data_blocks[4], ecc_blocks[3]; input_length = ustrlen(source); bits_total = 20; latch = 0; /* Character count indicator */ if(input_length & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } qrnumeric_encode(binary_data, source); /* Add terminator */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 3) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } else { concat(binary_data, "000"); } if(latch == 0) { /* Manage last (4-bit) block */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 4) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } } if(latch == 0) { /* Complete current byte */ remainder = 8 - (strlen(binary_data) % 8); if(remainder == 8) { remainder = 0; } for(i = 0; i < remainder; i++) { concat(binary_data, "0"); } /* Add padding */ bits_left = bits_total - strlen(binary_data); if(bits_left > 4) { remainder = (bits_left - 4) / 8; for(i = 0; i < remainder; i++) { if((i % 2) == 0) { concat(binary_data, "11101100"); } if((i % 2) == 1) { concat(binary_data, "00010001"); } } } concat(binary_data, "0000"); } data_codewords = 3; ecc_codewords = 2; /* Copy data into codewords */ for(i = 0; i < (data_codewords - 1); i++) { data_blocks[i] = 0; if(binary_data[i * 8] == '1') { data_blocks[i] += 0x80; } if(binary_data[(i * 8) + 1] == '1') { data_blocks[i] += 0x40; } if(binary_data[(i * 8) + 2] == '1') { data_blocks[i] += 0x20; } if(binary_data[(i * 8) + 3] == '1') { data_blocks[i] += 0x10; } if(binary_data[(i * 8) + 4] == '1') { data_blocks[i] += 0x08; } if(binary_data[(i * 8) + 5] == '1') { data_blocks[i] += 0x04; } if(binary_data[(i * 8) + 6] == '1') { data_blocks[i] += 0x02; } if(binary_data[(i * 8) + 7] == '1') { data_blocks[i] += 0x01; } } data_blocks[2] = 0; if(binary_data[16] == '1') { data_blocks[2] += 0x08; } if(binary_data[17] == '1') { data_blocks[2] += 0x04; } if(binary_data[18] == '1') { data_blocks[2] += 0x02; } if(binary_data[19] == '1') { data_blocks[2] += 0x01; } /* Calculate Reed-Solomon error codewords */ rs_init_gf(0x11d); rs_init_code(ecc_codewords, 1); rs_encode(data_codewords,data_blocks,ecc_blocks); rs_free(); /* Add Reed-Solomon codewords to binary data */ for(i = 0; i < ecc_codewords; i++) { if(ecc_blocks[i] & 0x80) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x40) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x20) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } return; } void versionm2(char binary_data[], unsigned char source[], int char_system, int ecc_mode) { int input_length, i, latch; int bits_total, bits_left, remainder; int data_codewords, ecc_codewords; unsigned char data_blocks[6], ecc_blocks[7]; input_length = ustrlen(source); latch = 0; if(ecc_mode == 1) { bits_total = 40; } if(ecc_mode == 2) { bits_total = 32; } /* Mode indicator */ if(char_system == NUMERIC) { concat(binary_data, "0"); } if(char_system == ALPHANUM) { concat(binary_data, "1"); } /* Character count indicator */ if(char_system == NUMERIC) { if(input_length & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } if(input_length & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(char_system == NUMERIC) { qrnumeric_encode(binary_data, source); } if(char_system == ALPHANUM) { qralpha_encode(binary_data, source); } /* Add terminator */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 5) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } else { concat(binary_data, "00000"); } if(latch == 0) { /* Complete current byte */ remainder = 8 - (strlen(binary_data) % 8); if(remainder == 8) { remainder = 0; } for(i = 0; i < remainder; i++) { concat(binary_data, "0"); } /* Add padding */ bits_left = bits_total - strlen(binary_data); remainder = bits_left / 8; for(i = 0; i < remainder; i++) { if((i % 2) == 0) { concat(binary_data, "11101100"); } if((i % 2) == 1) { concat(binary_data, "00010001"); } } } if(ecc_mode == 1) { data_codewords = 5; ecc_codewords = 5; } if(ecc_mode == 2) { data_codewords = 4; ecc_codewords = 6; } /* Copy data into codewords */ for(i = 0; i < data_codewords; i++) { data_blocks[i] = 0; if(binary_data[i * 8] == '1') { data_blocks[i] += 0x80; } if(binary_data[(i * 8) + 1] == '1') { data_blocks[i] += 0x40; } if(binary_data[(i * 8) + 2] == '1') { data_blocks[i] += 0x20; } if(binary_data[(i * 8) + 3] == '1') { data_blocks[i] += 0x10; } if(binary_data[(i * 8) + 4] == '1') { data_blocks[i] += 0x08; } if(binary_data[(i * 8) + 5] == '1') { data_blocks[i] += 0x04; } if(binary_data[(i * 8) + 6] == '1') { data_blocks[i] += 0x02; } if(binary_data[(i * 8) + 7] == '1') { data_blocks[i] += 0x01; } } /* Calculate Reed-Solomon error codewords */ rs_init_gf(0x11d); rs_init_code(ecc_codewords, 1); rs_encode(data_codewords,data_blocks,ecc_blocks); rs_free(); /* Add Reed-Solomon codewords to binary data */ for(i = 0; i < ecc_codewords; i++) { if(ecc_blocks[i] & 0x80) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x40) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x20) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } return; } void versionm3(char binary_data[], unsigned char source[], int char_system, int ecc_mode) { int input_length, i, latch; int bits_total, bits_left, remainder; int data_codewords, ecc_codewords; unsigned char data_blocks[12], ecc_blocks[9]; int sjis_count; input_length = ustrlen(source); latch = 0; if(ecc_mode == 1) { bits_total = 84; } if(ecc_mode == 2) { bits_total = 68; } /* Mode indicator */ if(char_system == NUMERIC) { concat(binary_data, "00"); } if(char_system == ALPHANUM) { concat(binary_data, "01"); } if(char_system == BYTE) { concat(binary_data, "10"); } if(char_system == KANJI) { concat(binary_data, "11"); } /* Character count indicator */ if(char_system == KANJI) { concat(binary_data, "XXX"); /* Place holder */ } else { if(char_system == NUMERIC) { if(input_length & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } if(input_length & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } if(char_system == NUMERIC) { qrnumeric_encode(binary_data, source); } if(char_system == ALPHANUM) { qralpha_encode(binary_data, source); } if(char_system == BYTE) { qrbyte_encode(binary_data, source); } if(char_system == KANJI) { sjis_count = qrkanji_encode(binary_data, source); } if(char_system == KANJI) { if(sjis_count & 0x04) { binary_data[2] = '1'; } else { binary_data[2] = '0'; } if(sjis_count & 0x02) { binary_data[3] = '1'; } else { binary_data[3] = '0'; } if(sjis_count & 0x01) { binary_data[4] = '1'; } else { binary_data[4] = '0'; } } /* Add terminator */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 7) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } else { concat(binary_data, "0000000"); } if(latch == 0) { /* Manage last (4-bit) block */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 4) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } } if(latch == 0) { /* Complete current byte */ remainder = 8 - (strlen(binary_data) % 8); if(remainder == 8) { remainder = 0; } for(i = 0; i < remainder; i++) { concat(binary_data, "0"); } /* Add padding */ bits_left = bits_total - strlen(binary_data); if(bits_left > 4) { remainder = (bits_left - 4) / 8; for(i = 0; i < remainder; i++) { if((i % 2) == 0) { concat(binary_data, "11101100"); } if((i % 2) == 1) { concat(binary_data, "00010001"); } } } concat(binary_data, "0000"); } if(ecc_mode == 1) { data_codewords = 11; ecc_codewords = 6; } if(ecc_mode == 2) { data_codewords = 9; ecc_codewords = 8; } /* Copy data into codewords */ for(i = 0; i < (data_codewords - 1); i++) { data_blocks[i] = 0; if(binary_data[i * 8] == '1') { data_blocks[i] += 0x80; } if(binary_data[(i * 8) + 1] == '1') { data_blocks[i] += 0x40; } if(binary_data[(i * 8) + 2] == '1') { data_blocks[i] += 0x20; } if(binary_data[(i * 8) + 3] == '1') { data_blocks[i] += 0x10; } if(binary_data[(i * 8) + 4] == '1') { data_blocks[i] += 0x08; } if(binary_data[(i * 8) + 5] == '1') { data_blocks[i] += 0x04; } if(binary_data[(i * 8) + 6] == '1') { data_blocks[i] += 0x02; } if(binary_data[(i * 8) + 7] == '1') { data_blocks[i] += 0x01; } } if(ecc_mode == 1) { data_blocks[11] = 0; if(binary_data[80] == '1') { data_blocks[2] += 0x08; } if(binary_data[81] == '1') { data_blocks[2] += 0x04; } if(binary_data[82] == '1') { data_blocks[2] += 0x02; } if(binary_data[83] == '1') { data_blocks[2] += 0x01; } } if(ecc_mode == 2) { data_blocks[9] = 0; if(binary_data[64] == '1') { data_blocks[2] += 0x08; } if(binary_data[65] == '1') { data_blocks[2] += 0x04; } if(binary_data[66] == '1') { data_blocks[2] += 0x02; } if(binary_data[67] == '1') { data_blocks[2] += 0x01; } } /* Calculate Reed-Solomon error codewords */ rs_init_gf(0x11d); rs_init_code(ecc_codewords, 1); rs_encode(data_codewords,data_blocks,ecc_blocks); rs_free(); /* Add Reed-Solomon codewords to binary data */ for(i = 0; i < ecc_codewords; i++) { if(ecc_blocks[i] & 0x80) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x40) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x20) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } return; } void versionm4(char binary_data[], unsigned char source[], int char_system, int ecc_mode) { int input_length, i, latch; int bits_total, bits_left, remainder; int data_codewords, ecc_codewords; unsigned char data_blocks[17], ecc_blocks[15]; int sjis_count; input_length = ustrlen(source); latch = 0; if(ecc_mode == 1) { bits_total = 128; } if(ecc_mode == 2) { bits_total = 112; } if(ecc_mode == 3) { bits_total = 80; } /* Mode indicator */ if(char_system == NUMERIC) { concat(binary_data, "000"); } if(char_system == ALPHANUM) { concat(binary_data, "001"); } if(char_system == BYTE) { concat(binary_data, "010"); } if(char_system == KANJI) { concat(binary_data, "011"); } /* Character count indicator */ if(char_system == KANJI) { concat(binary_data, "XXXX"); /* Place holder */ } else { if(char_system == NUMERIC) { if(input_length & 0x20) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } if(input_length & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(input_length & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } if(char_system == NUMERIC) { qrnumeric_encode(binary_data, source); } if(char_system == ALPHANUM) { qralpha_encode(binary_data, source); } if(char_system == BYTE) { qrbyte_encode(binary_data, source); } if(char_system == KANJI) { sjis_count = qrkanji_encode(binary_data, source); } if(char_system == KANJI) { if(sjis_count & 0x08) { binary_data[3] = '1'; } else { binary_data[3] = '0'; } if(sjis_count & 0x04) { binary_data[4] = '1'; } else { binary_data[4] = '0'; } if(sjis_count & 0x02) { binary_data[5] = '1'; } else { binary_data[5] = '0'; } if(sjis_count & 0x01) { binary_data[6] = '1'; } else { binary_data[6] = '0'; } } /* Add terminator */ bits_left = bits_total - strlen(binary_data); if(bits_left <= 9) { for(i = 0; i < bits_left; i++) { concat(binary_data, "0"); } latch = 1; } else { concat(binary_data, "000000000"); } if(latch == 0) { /* Complete current byte */ remainder = 8 - (strlen(binary_data) % 8); if(remainder == 8) { remainder = 0; } for(i = 0; i < remainder; i++) { concat(binary_data, "0"); } /* Add padding */ bits_left = bits_total - strlen(binary_data); remainder = bits_left / 8; for(i = 0; i < remainder; i++) { if((i % 2) == 0) { concat(binary_data, "11101100"); } if((i % 2) == 1) { concat(binary_data, "00010001"); } } } if(ecc_mode == 1) { data_codewords = 16; ecc_codewords = 8; } if(ecc_mode == 2) { data_codewords = 14; ecc_codewords = 10; } if(ecc_mode == 3) { data_codewords = 10; ecc_codewords = 14; } /* Copy data into codewords */ for(i = 0; i < data_codewords; i++) { data_blocks[i] = 0; if(binary_data[i * 8] == '1') { data_blocks[i] += 0x80; } if(binary_data[(i * 8) + 1] == '1') { data_blocks[i] += 0x40; } if(binary_data[(i * 8) + 2] == '1') { data_blocks[i] += 0x20; } if(binary_data[(i * 8) + 3] == '1') { data_blocks[i] += 0x10; } if(binary_data[(i * 8) + 4] == '1') { data_blocks[i] += 0x08; } if(binary_data[(i * 8) + 5] == '1') { data_blocks[i] += 0x04; } if(binary_data[(i * 8) + 6] == '1') { data_blocks[i] += 0x02; } if(binary_data[(i * 8) + 7] == '1') { data_blocks[i] += 0x01; } } /* Calculate Reed-Solomon error codewords */ rs_init_gf(0x11d); rs_init_code(ecc_codewords, 1); rs_encode(data_codewords,data_blocks,ecc_blocks); rs_free(); /* Add Reed-Solomon codewords to binary data */ for(i = 0; i < ecc_codewords; i++) { if(ecc_blocks[i] & 0x80) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x40) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x20) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x10) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x08) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x04) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x02) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } if(ecc_blocks[i] & 0x01) { concat(binary_data, "1"); } else { concat(binary_data, "0"); } } return; } int microqr(struct zint_symbol *symbol, unsigned char source[]) { int symbol_size; int char_system, input_length; char binary_data[200]; int latch; char bitmask[17][17]; char imagemap[17][17]; char candidate[17][17]; char pattern_bit; int width, i, j, pattern_no; int sum1, sum2, evaluation[4], format, format_full; char formatstr[16]; /* Analise input data and select encoding method - zint does not attempt to optimise the symbol by switching encoding method part way through the symbol, but merely chooses an encoding method for the whole symbol */ input_length = ustrlen(source); char_system = BYTE; symbol_size = 0; if(is_sane(QRSET, source) == 0) { char_system = ALPHANUM; } if(is_sane(NESET, source) == 0) { char_system = NUMERIC; } if(symbol->input_mode == KANJI_MODE) { char_system = KANJI; } if(symbol->input_mode == SJIS_MODE) { char_system = KANJI; } width = 0; format = 0; if(symbol->option_1 == 4) { strcpy(symbol->errtxt, "Error correction level H not available for Micro QR symbols"); return ERROR_INVALID_OPTION; } if((symbol->option_1 < 1) || (symbol->option_1 > 4)) { symbol->option_1 = 1; } /* Check that the data is not too long */ /* Note that there is no switching between error correction levels - this decision is left to the user: invalid combinations fail */ latch = 0; switch(symbol->option_1) { case 1: /* ECC Level L */ switch(char_system) { case NUMERIC: if(input_length > 35) latch = 1; break; case ALPHANUM: if(input_length > 21) latch = 1; break; case BYTE: if(input_length > 15) latch = 1; break; case KANJI: if(input_length > 18) latch = 1; break; } break; case 2: /* ECC Level M */ switch(char_system) { case NUMERIC: if(input_length > 30) latch = 1; break; case ALPHANUM: if(input_length > 18) latch = 1; break; case BYTE: if(input_length > 13) latch = 1; break; case KANJI: if(input_length > 16) latch = 1; break; } break; case 3: /* ECC Level Q */ symbol_size = 4; /* Only size M4 supports level Q */ switch(char_system) { case NUMERIC: if(input_length > 21) latch = 1; break; case ALPHANUM: if(input_length > 13) latch = 1; break; case BYTE: if(input_length > 9) latch = 1; break; case KANJI: if(input_length > 10) latch = 1; break; } break; } if(latch == 1) { strcpy(symbol->errtxt, "Input data too long"); return ERROR_TOO_LONG; } symbol_size = symbol->option_2; if((symbol_size < 0) || (symbol_size > 4)) { symbol_size = 0; } /* Decide symbol size */ if(symbol_size == 0) { if(symbol->option_1 == 1) { /* ECC Level L */ switch(char_system) { case NUMERIC: symbol_size = 4; if(input_length <= 23) { symbol_size = 3; } if(input_length <= 10) { symbol_size = 2; } if(input_length <= 5) { symbol_size = 1; } break; case ALPHANUM: symbol_size = 4; if(input_length <= 14) { symbol_size = 3; } if(input_length <= 6) { symbol_size = 2; } break; case BYTE: symbol_size = 4; if(input_length <= 9) { symbol_size = 3; } break; case KANJI: symbol_size = 4; if(input_length <= 12) { symbol_size = 3; } } } else { /* ECC Level M */ switch(char_system) { case NUMERIC: symbol_size = 4; if(input_length <= 18) { symbol_size = 3; } if(input_length <= 8) { symbol_size = 2; } break; case ALPHANUM: symbol_size = 4; if(input_length <= 11) { symbol_size = 3; } if(input_length <= 5) { symbol_size = 2; } break; case BYTE: symbol_size = 4; if(input_length <= 7) { symbol_size = 3; } break; case KANJI: symbol_size = 4; if(input_length <= 8) { symbol_size = 3; } } } } strcpy(binary_data, ""); switch(symbol_size) { case 1: versionm1(binary_data, source); break; case 2: versionm2(binary_data, source, char_system, symbol->option_1); break; case 3: versionm3(binary_data, source, char_system, symbol->option_1); break; case 4: versionm4(binary_data, source, char_system, symbol->option_1); break; } switch(symbol_size) { case 1: width = 11; break; case 2: width = 13; break; case 3: width = 15; break; case 4: width = 17; break; } for(i = 0; i < 17; i++) { for(j = 0; j < 17; j++) { bitmask[i][j] = '0'; imagemap[i][j] = '0'; candidate[i][j] = '0'; } } /* "bitmask" seperates data area */ for(i = 1; i < width; i++) { for(j = 1; j < width; j++) { bitmask[i][j] = '1'; } } for(i = 1; i < 9; i++) { for(j = 1; j < 9; j++) { bitmask[i][j] = '0'; } } /* Copy data into symbol grid */ for(i = 0; i < width; i++) { for(j = 0; j < width; j++) { if(bitmask[i][j] == '1') { switch(symbol_size) { case 1: imagemap[i][j] = binary_data[fig11m1[(i * width) + j]]; break; case 2: imagemap[i][j] = binary_data[fig11m2[(i * width) + j]]; break; case 3: imagemap[i][j] = binary_data[fig11m3[(i * width) + j]]; break; case 4: imagemap[i][j] = binary_data[fig11m4[(i * width) + j]]; break; } } } } /* XOR with data masks and evaluate */ for(pattern_no = 0; pattern_no < 4; pattern_no++) { for(i = 0; i < width; i++) { for(j = 0; j < width; j++) { pattern_bit = '0'; candidate[i][j] = '0'; switch(pattern_no) { case 0: if((i % 2) == 0) { pattern_bit = '1'; } break; case 1: if((((i / 2) + (j / 3)) % 2) == 0) { pattern_bit = '1'; } break; case 2: if((((i * j) % 2 + (i * j) % 3) % 2) == 0) { pattern_bit = '1'; } break; case 3: if((((i + j) % 2 + (i * j) % 3) % 2) == 0) { pattern_bit = '1'; } break; } if(bitmask[i][j] == '1') { if(pattern_bit != imagemap[i][j]) { candidate[i][j] = '1'; } } } } sum1 = 0; sum2 = 0; for(i = 1; i < width; i++) { if(candidate[i][width - 1] == '1') { sum1++; } if(candidate[width - 1][i] == '1') { sum2++; } } if(sum1 <= sum2) { evaluation[pattern_no] = (sum1 * 16) + sum2; } else { evaluation[pattern_no] = (sum2 * 16) + sum1; } } /* Choose best data mask */ j = evaluation[0]; pattern_no = 0; for(i = 1; i < 4; i++) { if(evaluation[i] > j) { pattern_no = i; j = evaluation[i]; } } /* Apply data mask */ for(i = 0; i < width; i++) { for(j = 0; j < width; j++) { pattern_bit = '0'; candidate[i][j] = '0'; switch(pattern_no) { case 0: if((i % 2) == 0) { pattern_bit = '1'; } break; case 1: if((((i / 2) + (j / 3)) % 2) == 0) { pattern_bit = '1'; } break; case 2: if((((i * j) % 2 + (i * j) % 3) % 2) == 0) { pattern_bit = '1'; } break; case 3: if((((i + j) % 2 + (i * j) % 3) % 2) == 0) { pattern_bit = '1'; } break; } if(bitmask[i][j] == '1') { if(pattern_bit != imagemap[i][j]) { candidate[i][j] = '1'; } } } } /* Calculate format data */ switch(symbol_size) { case 1: format = 0; break; case 2: switch(symbol->option_1) { case 1: format = 1; break; case 2: format = 2; break; } break; case 3: switch(symbol->option_1) { case 1: format = 3; break; case 2: format = 4; break; } break; case 4: switch(symbol->option_1) { case 1: format = 5; break; case 2: format = 6; break; case 3: format = 7; break; } break; } format *= 4; format += pattern_no; format_full = tablec1[format]; strcpy(formatstr, ""); if(format_full & 0x2000) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x1000) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x800) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x400) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x200) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x100) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x80) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x80) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x40) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x20) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x10) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x08) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x04) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x02) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } if(format_full & 0x01) { concat(formatstr, "1"); } else { concat(formatstr, "0"); } /* Add format data to symbol */ for(i = 0; i < 8; i++) { candidate[i + 1][8] = formatstr[i]; } for(i = 0; i < 7; i++) { candidate[8][7 - i] = formatstr[i + 8]; } /* Add timer pattern */ for(i = 0; i < width; i += 2) { candidate[i][0] = '1'; candidate[0][i] = '1'; } /* Add finder pattern */ for(i = 0; i < 7; i ++) { for(j = 0; j < 7; j++) { if(finder[(i * 7) + j] == 1) { candidate[i][j] = '1'; } } } /* Copy data into symbol */ for(i = 0; i < width; i++) { for(j = 0; j < width; j++) { symbol->encoded_data[i][j] = candidate[i][j]; } symbol->row_height[i] = 1; } symbol->rows = width; symbol->width = width; return 0; }