zint/backend/qr.c

3083 lines
95 KiB
C

/* qr.c Handles QR Code, Micro QR Code, UPNQR and rMQR
libzint - the open source barcode library
Copyright (C) 2009 - 2019 Robin Stuart <rstuart114@gmail.com>
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.
*/
/* vim: set ts=4 sw=4 et : */
#include <string.h>
#ifdef _MSC_VER
#include <malloc.h>
#endif
#include "common.h"
#include <stdio.h>
#include "sjis.h"
#include "qr.h"
#include "reedsol.h"
#include <stdlib.h> /* abs */
#include <assert.h>
extern int utf_to_eci(const int eci, const unsigned char source[], unsigned char dest[], size_t *length); /* Convert Unicode to other encodings */
/* Returns true if input glyph is in the Alphanumeric set */
static int is_alpha(const unsigned int glyph, const int gs1) {
int retval = 0;
if ((glyph >= '0') && (glyph <= '9')) {
retval = 1;
} else if ((glyph >= 'A') && (glyph <= 'Z')) {
retval = 1;
} else if (gs1 && glyph == '[') {
retval = 1;
} else {
switch (glyph) {
case ' ':
case '$':
case '%':
case '*':
case '+':
case '-':
case '.':
case '/':
case ':':
retval = 1;
break;
}
}
return retval;
}
/* Bits multiplied by this for costs, so as to be whole integer divisible by 2 and 3 */
#define QR_MULT 6
/* Whether in numeric or not. If in numeric, *p_end is set to position after numeric, and *p_cost is set to per-numeric cost */
static int in_numeric(const unsigned int jisdata[], const size_t length, const int posn, unsigned int* p_end, unsigned int* p_cost) {
int i, digit_cnt;
if (posn < *p_end) {
return 1;
}
/* Attempt to calculate the average 'cost' of using numeric mode in number of bits (times QR_MULT) */
for (i = posn; i < length && i < posn + 4 && jisdata[i] >= '0' && jisdata[i] <= '9'; i++);
digit_cnt = i - posn;
if (digit_cnt == 0) {
*p_end = 0;
return 0;
}
*p_end = i;
*p_cost = digit_cnt == 1 ? 24 /* 4 * QR_MULT */ : digit_cnt == 2 ? 21 /* (7 / 2) * QR_MULT */ : 20 /* (10 / 3) * QR_MULT) */;
return 1;
}
/* Whether in alpha or not. If in alpha, *p_end is set to position after alpha, and *p_cost is set to per-alpha cost. For GS1, *p_pcent set if 2nd char percent */
static int in_alpha(const unsigned int jisdata[], const size_t length, const int posn, unsigned int* p_end, unsigned int* p_cost, unsigned int* p_pcent, unsigned int gs1) {
int two_alphas;
if (posn < *p_end) {
if (gs1 && *p_pcent) {
/* Previous 2nd char was a percent, so allow for second half of doubled-up percent here */
two_alphas = posn < length - 1 && is_alpha(jisdata[posn + 1], gs1);
*p_cost = two_alphas ? 33 /* (11 / 2) * QR_MULT */ : 36 /* 6 * QR_MULT */;
*p_pcent = 0;
}
return 1;
}
/* Attempt to calculate the average 'cost' of using alphanumeric mode in number of bits (times QR_MULT) */
if (!is_alpha(jisdata[posn], gs1)) {
*p_end = 0;
*p_pcent = 0;
return 0;
}
if (gs1 && jisdata[posn] == '%') { /* Must double-up so counts as 2 chars */
*p_end = posn + 1;
*p_cost = 66; /* 11 * QR_MULT */
*p_pcent = 0;
return 1;
}
two_alphas = posn < length - 1 && is_alpha(jisdata[posn + 1], gs1);
*p_end = two_alphas ? posn + 2 : posn + 1;
*p_cost = two_alphas ? 33 /* (11 / 2) * QR_MULT */ : 36 /* 6 * QR_MULT */;
*p_pcent = two_alphas && gs1 && jisdata[posn + 1] == '%'; /* 2nd char is percent */
return 1;
}
/* Indexes into mode_types array (and state array) */
#define QR_N 0 /* Numeric */
#define QR_A 1 /* Alphanumeric */
#define QR_B 2 /* Byte */
#define QR_K 3 /* Kanji */
static char mode_types[] = { 'N', 'A', 'B', 'K', }; /* Must be in same order as QR_N etc */
#define QR_NUM_MODES 4
/* Indexes into state array (0..3 head costs) */
#define QR_VER 4 /* Version */
#define QR_GS1 5 /* GS1 mode (boolean) */
#define QR_N_END 6 /* Numeric end index */
#define QR_N_COST 7 /* Numeric cost */
#define QR_A_END 8 /* Alpha end index */
#define QR_A_COST 9 /* Alpha cost */
#define QR_A_PCENT 10 /* Alpha 2nd char percent (GS1-specific) */
/* Costs set to this for invalid MICROQR modes for versions M1 and M2.
* 128 is the max number of data bits for M4-L (ISO/IEC 18004:2015 Table 7) */
#define QR_MICROQR_MAX 774 /* (128 + 1) * QR_MULT */
/* Initial mode costs */
static unsigned int* qr_head_costs(unsigned int state[]) {
static int head_costs[7][QR_NUM_MODES] = {
/* N A B K */
{ (10 + 4) * QR_MULT, (9 + 4) * QR_MULT, (8 + 4) * QR_MULT, (8 + 4) * QR_MULT, }, /* QR */
{ (12 + 4) * QR_MULT, (11 + 4) * QR_MULT, (16 + 4) * QR_MULT, (10 + 4) * QR_MULT, },
{ (14 + 4) * QR_MULT, (13 + 4) * QR_MULT, (16 + 4) * QR_MULT, (12 + 4) * QR_MULT, },
{ 3 * QR_MULT, QR_MICROQR_MAX, QR_MICROQR_MAX, QR_MICROQR_MAX, }, /* MICROQR */
{ (4 + 1) * QR_MULT, (3 + 1) * QR_MULT, QR_MICROQR_MAX, QR_MICROQR_MAX, },
{ (5 + 2) * QR_MULT, (4 + 2) * QR_MULT, (4 + 2) * QR_MULT, (3 + 2) * QR_MULT, },
{ (6 + 3) * QR_MULT, (5 + 3) * QR_MULT, (5 + 3) * QR_MULT, (4 + 3) * QR_MULT, }
};
int version;
/* Head costs kept in states 0..3 */
if (state[QR_N] != 0) { /* Numeric non-zero in all configs */
return state; /* Already set */
}
version = state[QR_VER];
if (version < RMQR_VERSION) { /* QRCODE */
if (version < 10) {
memcpy(state, head_costs, QR_NUM_MODES * sizeof(unsigned int));
} else if (version < 27) {
memcpy(state, head_costs + 1, QR_NUM_MODES * sizeof(unsigned int));
} else {
memcpy(state, head_costs + 2, QR_NUM_MODES * sizeof(unsigned int));
}
} else if (version < MICROQR_VERSION) { /* RMQR */
version -= RMQR_VERSION;
state[QR_N] = (rmqr_numeric_cci[version] + 3) * QR_MULT;
state[QR_A] = (rmqr_alphanum_cci[version] + 3) * QR_MULT;
state[QR_B] = (rmqr_byte_cci[version] + 3) * QR_MULT;
state[QR_K] = (rmqr_kanji_cci[version] + 3) * QR_MULT;
} else { /* MICROQR */
memcpy(state, head_costs + 3 + (version - MICROQR_VERSION), QR_NUM_MODES * sizeof(unsigned int));
}
return state;
}
/* Costs of switching modes from k to j */
static unsigned int qr_switch_cost(unsigned int state[], const int k, const int j) {
return state[j]; /* Same as head cost */
}
/* Calculate cost of encoding character */
static void qr_cur_cost(unsigned int state[], const unsigned int jisdata[], const size_t length, const int i, char* char_modes, unsigned int prev_costs[], unsigned int cur_costs[]) {
int cm_i = i * QR_NUM_MODES, m1, m2;
unsigned int version = state[QR_VER];
unsigned int gs1 = state[QR_GS1];
unsigned int* p_numeric_end = &state[QR_N_END];
unsigned int* p_numeric_cost = &state[QR_N_COST];
unsigned int* p_alpha_end = &state[QR_A_END];
unsigned int* p_alpha_cost = &state[QR_A_COST];
unsigned int* p_alpha_pcent = &state[QR_A_PCENT];
m1 = version == MICROQR_VERSION;
m2 = version == MICROQR_VERSION + 1;
if (jisdata[i] > 0xFF) {
cur_costs[QR_B] = prev_costs[QR_B] + ((m1 || m2) ? QR_MICROQR_MAX : 96); /* 16 * QR_MULT */
char_modes[cm_i + QR_B] = 'B';
cur_costs[QR_K] = prev_costs[QR_K] + ((m1 || m2) ? QR_MICROQR_MAX : 78); /* 13 * QR_MULT */
char_modes[cm_i + QR_K] = 'K';
} else {
if (in_numeric(jisdata, length, i, p_numeric_end, p_numeric_cost)) {
cur_costs[QR_N] = prev_costs[QR_N] + *p_numeric_cost;
char_modes[cm_i + QR_N] = 'N';
}
if (in_alpha(jisdata, length, i, p_alpha_end, p_alpha_cost, p_alpha_pcent, gs1)) {
cur_costs[QR_A] = prev_costs[QR_A] + (m1 ? QR_MICROQR_MAX : *p_alpha_cost);
char_modes[cm_i + QR_A] = 'A';
}
cur_costs[QR_B] = prev_costs[QR_B] + ((m1 || m2) ? QR_MICROQR_MAX : 48); /* 8 * QR_MULT */
char_modes[cm_i + QR_B] = 'B';
}
}
static void qr_define_mode(char mode[], const unsigned int jisdata[], const size_t length, const int gs1, const int version, const int debug) {
unsigned int state[11] = {
0 /*N*/, 0 /*A*/, 0 /*B*/, 0 /*K*/,
version, gs1,
0 /*numeric_end*/, 0 /*numeric_cost*/, 0 /*alpha_end*/, 0 /*alpha_cost*/, 0 /*alpha_pcent*/
};
pn_define_mode(mode, jisdata, length, debug, state, mode_types, QR_NUM_MODES, qr_head_costs, qr_switch_cost, NULL, qr_cur_cost);
}
/* Return mode indicator bits based on version */
static int mode_bits(const int version) {
if (version < RMQR_VERSION) {
return 4; /* QRCODE */
}
if (version < MICROQR_VERSION) {
return 3; /* RMQR */
}
return version - MICROQR_VERSION; /* MICROQR */
}
/* Return character count indicator bits based on version and mode */
static int cci_bits(const int version, const int mode) {
static int cci_bits[7][QR_NUM_MODES] = {
/* N A B K */
{ 10, 9, 8, 8, }, /* QRCODE */
{ 12, 11, 16, 10, },
{ 14, 13, 16, 12, },
{ 3, 0, 0, 0, }, /* MICROQR */
{ 4, 3, 0, 0, },
{ 5, 4, 4, 3, },
{ 6, 5, 5, 4, }
};
static const unsigned short int* rmqr_ccis[QR_NUM_MODES] = {
rmqr_numeric_cci, rmqr_alphanum_cci, rmqr_byte_cci, rmqr_kanji_cci,
};
int mode_index = strchr(mode_types, mode) - mode_types;
if (version < RMQR_VERSION) { /* QRCODE */
if (version < 10) {
return cci_bits[0][mode_index];
}
if (version < 27) {
return cci_bits[1][mode_index];
}
return cci_bits[2][mode_index];
}
if (version < MICROQR_VERSION) { /* RMQR */
return rmqr_ccis[mode_index][version - RMQR_VERSION];
}
return cci_bits[3 + (version - MICROQR_VERSION)][mode_index]; /* MICROQR */
}
/* Returns mode indicator based on version and mode */
static const char* mode_indicator(const int version, const int mode) {
static const char* mode_indicators[6][QR_NUM_MODES] = {
/* N A B K */
{ "0001", "0010", "0100", "1000", }, /* QRCODE */
{ "001", "010", "011", "100", }, /* RMQR */
{ "", "", "", "", }, /* MICROQR */
{ "0", "1", "", "", },
{ "00", "01", "10", "11", },
{ "000", "001", "010", "011", },
};
int mode_index = strchr(mode_types, mode) - mode_types;
if (version < RMQR_VERSION) {
return mode_indicators[0][mode_index]; /* QRCODE */
}
if (version < MICROQR_VERSION) {
return mode_indicators[1][mode_index] /* RMQR */;
}
return mode_indicators[2 + version - MICROQR_VERSION][mode_index]; /* MICROQR */
}
/* Returns terminator bits based on version */
static int terminator_bits(const int version) {
if (version < RMQR_VERSION) {
return 4; /* QRCODE */
}
if (version < MICROQR_VERSION) {
return 3; /* RMQR */
}
return 3 + (version - MICROQR_VERSION) * 2; /* MICROQR (Note not actually using this at the moment) */
}
/* Convert input data to a binary stream and add padding */
static void qr_binary(unsigned char datastream[], const int version, const int target_codewords, const char mode[], const unsigned int jisdata[], const size_t length,
const int gs1, const int eci, const int est_binlen, const int debug) {
int position = 0;
int i;
int termbits, padbits;
int current_binlen, current_bytes;
int toggle, percent;
int percent_count;
#ifndef _MSC_VER
char binary[est_binlen + 12];
#else
char* binary = (char *) _alloca(est_binlen + 12);
#endif
strcpy(binary, "");
if (gs1) { /* Not applicable to MICROQR */
if (version < RMQR_VERSION) {
strcat(binary, "0101"); /* FNC1 */
} else {
strcat(binary, "101");
}
}
if (eci != 0) { /* Not applicable to RMQR or MICROQR */
strcat(binary, "0111"); /* ECI (Table 4) */
if (eci <= 127) {
bin_append(eci, 8, binary); /* 000000 to 000127 */
} else if (eci <= 16383) {
bin_append(0x8000 + eci, 16, binary); /* 000000 to 016383 */
} else {
bin_append(0xC00000 + eci, 24, binary); /* 000000 to 999999 */
}
}
if (debug & ZINT_DEBUG_PRINT) {
for (i = 0; i < length; i++) {
printf("%c", mode[i]);
}
printf("\n");
}
percent = 0;
do {
char data_block = mode[position];
int short_data_block_length = 0;
int double_byte = 0;
do {
if (data_block == 'B' && jisdata[position + short_data_block_length] > 0xFF) {
double_byte++;
}
short_data_block_length++;
} while (((short_data_block_length + position) < length)
&& (mode[position + short_data_block_length] == data_block));
switch (data_block) {
case 'K':
/* Kanji mode */
/* Mode indicator */
strcat(binary, mode_indicator(version, data_block));
/* Character count indicator */
bin_append(short_data_block_length, cci_bits(version, data_block), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("Kanji block (length %d)\n\t", short_data_block_length);
}
/* Character representation */
for (i = 0; i < short_data_block_length; i++) {
unsigned int jis = jisdata[position + i];
int prod;
if (jis >= 0x8140 && jis <= 0x9ffc)
jis -= 0x8140;
else if (jis >= 0xe040 && jis <= 0xebbf)
jis -= 0xc140;
prod = ((jis >> 8) * 0xc0) + (jis & 0xff);
bin_append(prod, 13, binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("0x%04X ", prod);
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case 'B':
/* Byte mode */
/* Mode indicator */
strcat(binary, mode_indicator(version, data_block));
/* Character count indicator */
bin_append(short_data_block_length + double_byte, cci_bits(version, data_block), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("Byte block (length %d)\n\t", short_data_block_length + double_byte);
}
/* Character representation */
for (i = 0; i < short_data_block_length; i++) {
unsigned int byte = jisdata[position + i];
if (gs1 && (byte == '[')) {
byte = 0x1d; /* FNC1 */
}
bin_append(byte, byte > 0xFF ? 16 : 8, binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("0x%02X(%d) ", byte, byte);
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case 'A':
/* Alphanumeric mode */
/* Mode indicator */
strcat(binary, mode_indicator(version, data_block));
percent_count = 0;
if (gs1) {
for (i = 0; i < short_data_block_length; i++) {
if (jisdata[position + i] == '%') {
percent_count++;
}
}
}
/* Character count indicator */
bin_append(short_data_block_length + percent_count, cci_bits(version, data_block), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("Alpha block (length %d)\n\t", short_data_block_length + percent_count);
}
/* Character representation */
i = 0;
while (i < short_data_block_length) {
int count;
int first = 0, second = 0, prod;
if (percent == 0) {
if (gs1 && (jisdata[position + i] == '%')) {
first = posn(RHODIUM, '%');
second = posn(RHODIUM, '%');
count = 2;
prod = (first * 45) + second;
i++;
} else {
if (gs1 && (jisdata[position + i] == '[')) {
first = posn(RHODIUM, '%'); /* FNC1 */
} else {
first = posn(RHODIUM, (char) jisdata[position + i]);
}
count = 1;
i++;
prod = first;
if (i < short_data_block_length && mode[position + i] == 'A') {
if (gs1 && (jisdata[position + i] == '%')) {
second = posn(RHODIUM, '%');
count = 2;
prod = (first * 45) + second;
percent = 1;
} else {
if (gs1 && (jisdata[position + i] == '[')) {
second = posn(RHODIUM, '%'); /* FNC1 */
} else {
second = posn(RHODIUM, (char) jisdata[position + i]);
}
count = 2;
i++;
prod = (first * 45) + second;
}
}
}
} else {
first = posn(RHODIUM, '%');
count = 1;
i++;
prod = first;
percent = 0;
if (i < short_data_block_length && mode[position + i] == 'A') {
if (gs1 && (jisdata[position + i] == '%')) {
second = posn(RHODIUM, '%');
count = 2;
prod = (first * 45) + second;
percent = 1;
} else {
if (gs1 && (jisdata[position + i] == '[')) {
second = posn(RHODIUM, '%'); /* FNC1 */
} else {
second = posn(RHODIUM, (char) jisdata[position + i]);
}
count = 2;
i++;
prod = (first * 45) + second;
}
}
}
bin_append(prod, 1 + (5 * count), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("0x%X ", prod);
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case 'N':
/* Numeric mode */
/* Mode indicator */
strcat(binary, mode_indicator(version, data_block));
/* Character count indicator */
bin_append(short_data_block_length, cci_bits(version, data_block), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("Number block (length %d)\n\t", short_data_block_length);
}
/* Character representation */
i = 0;
while (i < short_data_block_length) {
int count;
int first = 0, prod;
first = posn(NEON, (char) jisdata[position + i]);
count = 1;
prod = first;
if (i + 1 < short_data_block_length && mode[position + i + 1] == 'N') {
int second = posn(NEON, (char) jisdata[position + i + 1]);
count = 2;
prod = (prod * 10) + second;
if (i + 2 < short_data_block_length && mode[position + i + 2] == 'N') {
int third = posn(NEON, (char) jisdata[position + i + 2]);
count = 3;
prod = (prod * 10) + third;
}
}
bin_append(prod, 1 + (3 * count), binary);
if (debug & ZINT_DEBUG_PRINT) {
printf("0x%X(%d) ", prod, prod);
}
i += count;
};
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
}
position += short_data_block_length;
} while (position < length);
if (version >= MICROQR_VERSION && version < MICROQR_VERSION + 4) {
/* MICROQR does its own terminating/padding */
strcpy((char*)datastream, binary);
return;
}
/* Terminator */
current_binlen = (int)strlen(binary);
termbits = 8 - current_binlen % 8;
if (termbits == 8) {
termbits = 0;
}
current_bytes = (current_binlen + termbits) / 8;
if (termbits || current_bytes < target_codewords) {
int max_termbits = terminator_bits(version);
termbits = termbits < max_termbits && current_bytes == target_codewords ? termbits : max_termbits;
bin_append(0, termbits, binary);
current_binlen += termbits;
}
/* Padding bits */
padbits = 8 - current_binlen % 8;
if (padbits == 8) {
padbits = 0;
}
if (padbits) {
current_bytes = (current_binlen + padbits) / 8;
bin_append(0, padbits, binary);
}
/* Put data into 8-bit codewords */
for (i = 0; i < current_bytes; i++) {
int p;
datastream[i] = 0x00;
for (p = 0; p < 8; p++) {
if (binary[i * 8 + p] == '1') {
datastream[i] += (0x80 >> p);
}
}
}
/* Add pad codewords */
toggle = 0;
for (i = current_bytes; i < target_codewords; i++) {
if (toggle == 0) {
datastream[i] = 0xec;
toggle = 1;
} else {
datastream[i] = 0x11;
toggle = 0;
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Resulting codewords:\n\t");
for (i = 0; i < target_codewords; i++) {
printf("0x%02X ", datastream[i]);
}
printf("\n");
}
}
/* Split data into blocks, add error correction and then interleave the blocks and error correction data */
static void add_ecc(unsigned char fullstream[], const unsigned char datastream[], const int version, const int data_cw, const int blocks, int debug) {
int ecc_cw;
int short_data_block_length;
int qty_long_blocks;
int qty_short_blocks;
int ecc_block_length;
int i, j, length_this_block, posn;
#ifdef _MSC_VER
unsigned char* data_block;
unsigned char* ecc_block;
unsigned char* interleaved_data;
unsigned char* interleaved_ecc;
#endif
if (version < RMQR_VERSION) {
ecc_cw = qr_total_codewords[version - 1] - data_cw;
} else {
ecc_cw = rmqr_total_codewords[version - RMQR_VERSION] - data_cw;
}
short_data_block_length = data_cw / blocks;
qty_long_blocks = data_cw % blocks;
qty_short_blocks = blocks - qty_long_blocks;
ecc_block_length = ecc_cw / blocks;
#ifndef _MSC_VER
unsigned char data_block[short_data_block_length + 2];
unsigned char ecc_block[ecc_block_length + 2];
unsigned char interleaved_data[data_cw + 2];
unsigned char interleaved_ecc[ecc_cw + 2];
#else
data_block = (unsigned char *) _alloca(short_data_block_length + 2);
ecc_block = (unsigned char *) _alloca(ecc_block_length + 2);
interleaved_data = (unsigned char *) _alloca(data_cw + 2);
interleaved_ecc = (unsigned char *) _alloca(ecc_cw + 2);
#endif
posn = 0;
for (i = 0; i < blocks; i++) {
if (i < qty_short_blocks) {
length_this_block = short_data_block_length;
} else {
length_this_block = short_data_block_length + 1;
}
for (j = 0; j < ecc_block_length; j++) {
ecc_block[j] = 0;
}
for (j = 0; j < length_this_block; j++) {
data_block[j] = datastream[posn + j];
}
rs_init_gf(0x11d);
rs_init_code(ecc_block_length, 0);
rs_encode(length_this_block, data_block, ecc_block);
rs_free();
if (debug & ZINT_DEBUG_PRINT) {
printf("Block %d: ", i + 1);
for (j = 0; j < length_this_block; j++) {
printf("%2X ", data_block[j]);
}
if (i < qty_short_blocks) {
printf(" ");
}
printf(" // ");
for (j = 0; j < ecc_block_length; j++) {
printf("%2X ", ecc_block[ecc_block_length - j - 1]);
}
printf("\n");
}
for (j = 0; j < short_data_block_length; j++) {
interleaved_data[(j * blocks) + i] = data_block[j];
}
if (i >= qty_short_blocks) {
interleaved_data[(short_data_block_length * blocks) + (i - qty_short_blocks)] = data_block[short_data_block_length];
}
for (j = 0; j < ecc_block_length; j++) {
interleaved_ecc[(j * blocks) + i] = ecc_block[ecc_block_length - j - 1];
}
posn += length_this_block;
}
for (j = 0; j < data_cw; j++) {
fullstream[j] = interleaved_data[j];
}
for (j = 0; j < ecc_cw; j++) {
fullstream[j + data_cw] = interleaved_ecc[j];
}
if (debug & ZINT_DEBUG_PRINT) {
printf("\nData Stream: \n");
for (j = 0; j < (data_cw + ecc_cw); j++) {
printf("%2X ", fullstream[j]);
}
printf("\n");
}
}
static void place_finder(unsigned char grid[],const int size,const int x,const int y) {
int xp, yp;
char finder[] = {0x7F, 0x41, 0x5D, 0x5D, 0x5D, 0x41, 0x7F};
for (xp = 0; xp < 7; xp++) {
for (yp = 0; yp < 7; yp++) {
if (finder[yp] & 0x40 >> xp) {
grid[((yp + y) * size) + (xp + x)] = 0x11;
} else {
grid[((yp + y) * size) + (xp + x)] = 0x10;
}
}
}
}
static void place_align(unsigned char grid[],const int size,int x,int y) {
int xp, yp;
char alignment[] = {0x1F, 0x11, 0x15, 0x11, 0x1F};
x -= 2;
y -= 2; /* Input values represent centre of pattern */
for (xp = 0; xp < 5; xp++) {
for (yp = 0; yp < 5; yp++) {
if (alignment[yp] & 0x10 >> xp) {
grid[((yp + y) * size) + (xp + x)] = 0x11;
} else {
grid[((yp + y) * size) + (xp + x)] = 0x10;
}
}
}
}
static void setup_grid(unsigned char* grid,const int size,const int version) {
int i, toggle = 1;
/* Add timing patterns */
for (i = 0; i < size; i++) {
if (toggle == 1) {
grid[(6 * size) + i] = 0x21;
grid[(i * size) + 6] = 0x21;
toggle = 0;
} else {
grid[(6 * size) + i] = 0x20;
grid[(i * size) + 6] = 0x20;
toggle = 1;
}
}
/* Add finder patterns */
place_finder(grid, size, 0, 0);
place_finder(grid, size, 0, size - 7);
place_finder(grid, size, size - 7, 0);
/* Add separators */
for (i = 0; i < 7; i++) {
grid[(7 * size) + i] = 0x10;
grid[(i * size) + 7] = 0x10;
grid[(7 * size) + (size - 1 - i)] = 0x10;
grid[(i * size) + (size - 8)] = 0x10;
grid[((size - 8) * size) + i] = 0x10;
grid[((size - 1 - i) * size) + 7] = 0x10;
}
grid[(7 * size) + 7] = 0x10;
grid[(7 * size) + (size - 8)] = 0x10;
grid[((size - 8) * size) + 7] = 0x10;
/* Add alignment patterns */
if (version != 1) {
/* Version 1 does not have alignment patterns */
int loopsize = qr_align_loopsize[version - 1];
int x, y;
for (x = 0; x < loopsize; x++) {
for (y = 0; y < loopsize; y++) {
int xcoord = qr_table_e1[((version - 2) * 7) + x];
int ycoord = qr_table_e1[((version - 2) * 7) + y];
if (!(grid[(ycoord * size) + xcoord] & 0x10)) {
place_align(grid, size, xcoord, ycoord);
}
}
}
}
/* Reserve space for format information */
for (i = 0; i < 8; i++) {
grid[(8 * size) + i] += 0x20;
grid[(i * size) + 8] += 0x20;
grid[(8 * size) + (size - 1 - i)] = 0x20;
grid[((size - 1 - i) * size) + 8] = 0x20;
}
grid[(8 * size) + 8] += 0x20;
grid[((size - 1 - 7) * size) + 8] = 0x21; /* Dark Module from Figure 25 */
/* Reserve space for version information */
if (version >= 7) {
for (i = 0; i < 6; i++) {
grid[((size - 9) * size) + i] = 0x20;
grid[((size - 10) * size) + i] = 0x20;
grid[((size - 11) * size) + i] = 0x20;
grid[(i * size) + (size - 9)] = 0x20;
grid[(i * size) + (size - 10)] = 0x20;
grid[(i * size) + (size - 11)] = 0x20;
}
}
}
static int cwbit(const unsigned char* fullstream, const int i) {
int resultant = 0;
if (fullstream[(i / 8)] & (0x80 >> (i % 8))) {
resultant = 1;
}
return resultant;
}
static void populate_grid(unsigned char* grid, const int h_size, const int v_size, const unsigned char* fullstream, const int cw) {
int direction = 1; /* up */
int row = 0; /* right hand side */
int i, n, y;
n = cw * 8;
y = v_size - 1;
i = 0;
do {
int x = (h_size - 2) - (row * 2);
if ((x < 6) && (v_size == h_size))
x--; /* skip over vertical timing pattern */
if (!(grid[(y * h_size) + (x + 1)] & 0xf0)) {
if (cwbit(fullstream, i)) {
grid[(y * h_size) + (x + 1)] = 0x01;
} else {
grid[(y * h_size) + (x + 1)] = 0x00;
}
i++;
}
if (i < n) {
if (!(grid[(y * h_size) + x] & 0xf0)) {
if (cwbit(fullstream, i)) {
grid[(y * h_size) + x] = 0x01;
} else {
grid[(y * h_size) + x] = 0x00;
}
i++;
}
}
if (direction) {
y--;
} else {
y++;
}
if (y == -1) {
/* reached the top */
row++;
y = 0;
direction = 0;
}
if (y == v_size) {
/* reached the bottom */
row++;
y = v_size - 1;
direction = 1;
}
} while (i < n);
}
#ifdef ZINTLOG
static int append_log(char log) {
FILE *file;
file = fopen("zintlog.txt", "a+");
fprintf(file, "%c", log);
fclose(file);
return 0;
}
static int write_log(char log[]) {
FILE *file;
file = fopen("zintlog.txt", "a+");
fprintf(file, log); /*writes*/
fprintf(file, "\r\n"); /*writes*/
fclose(file);
return 0;
}
#endif
static int evaluate(unsigned char *eval,const int size,const int pattern) {
int x, y, block, weight;
int result = 0;
char state;
int p;
int dark_mods;
int percentage, k;
int a, b, afterCount, beforeCount;
#ifdef ZINTLOG
int result_b = 0;
char str[15];
#endif
#ifndef _MSC_VER
char local[size * size];
#else
char* local = (char *) _alloca((size * size) * sizeof (char));
#endif
#ifdef ZINTLOG
write_log("");
sprintf(str, "%d", pattern);
write_log(str);
#endif
/* all eight bitmask variants have been encoded in the 8 bits of the bytes
* that make up the grid array. select them for evaluation according to the
* desired pattern.*/
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if ((eval[(y * size) + x] & (0x01 << pattern)) != 0) {
local[(y * size) + x] = '1';
} else {
local[(y * size) + x] = '0';
}
}
}
#ifdef ZINTLOG
//bitmask output
for (y = 0; y < size; y++) {
strcpy(str, "");
for (x = 0; x < size; x++) {
state = local[(y * size) + x];
append_log(state);
}
write_log("");
}
write_log("");
#endif
/* Test 1: Adjacent modules in row/column in same colour */
/* Vertical */
for (x = 0; x < size; x++) {
state = local[x];
block = 0;
for (y = 0; y < size; y++) {
if (local[(y * size) + x] == state) {
block++;
} else {
if (block > 5) {
result += (3 + (block - 5));
}
block = 0;
state = local[(y * size) + x];
}
}
if (block > 5) {
result += (3 + (block - 5));
}
}
/* Horizontal */
for (y = 0; y < size; y++) {
state = local[y * size];
block = 0;
for (x = 0; x < size; x++) {
if (local[(y * size) + x] == state) {
block++;
} else {
if (block > 5) {
result += (3 + (block - 5));
}
block = 0;
state = local[(y * size) + x];
}
}
if (block > 5) {
result += (3 + (block - 5));
}
}
#ifdef ZINTLOG
/* output Test 1 */
sprintf(str, "%d", result);
result_b = result;
write_log(str);
#endif
/* Test 2: Block of modules in same color */
for (x = 0; x < size - 1; x++) {
for (y = 0; y < size - 1; y++) {
if (((local[(y * size) + x] == local[((y + 1) * size) + x]) &&
(local[(y * size) + x] == local[(y * size) + (x + 1)])) &&
(local[(y * size) + x] == local[((y + 1) * size) + (x + 1)])) {
result += 3;
}
}
}
#ifdef ZINTLOG
/* output Test 2 */
sprintf(str, "%d", result - result_b);
result_b = result;
write_log(str);
#endif
/* Test 3: 1:1:3:1:1 ratio pattern in row/column */
/* Vertical */
for (x = 0; x < size; x++) {
for (y = 0; y < (size - 7); y++) {
p = 0;
for (weight = 0; weight < 7; weight++) {
if (local[((y + weight) * size) + x] == '1') {
p += (0x40 >> weight);
}
}
if (p == 0x5d) {
/* Pattern found, check before and after */
beforeCount = 0;
for (b = (y - 4); b < y; b++) {
if (b < 0) {
beforeCount++;
} else {
if (local[(b * size) + x] == '0') {
beforeCount++;
} else {
beforeCount = 0;
}
}
}
afterCount = 0;
for (a = (y + 7); a <= (y + 10); a++) {
if (a >= size) {
afterCount++;
} else {
if (local[(a * size) + x] == '0') {
afterCount++;
} else {
afterCount = 0;
}
}
}
if ((beforeCount == 4) || (afterCount == 4)) {
/* Pattern is preceeded or followed by light area
4 modules wide */
result += 40;
}
}
}
}
/* Horizontal */
for (y = 0; y < size; y++) {
for (x = 0; x < (size - 7); x++) {
p = 0;
for (weight = 0; weight < 7; weight++) {
if (local[(y * size) + x + weight] == '1') {
p += (0x40 >> weight);
}
}
if (p == 0x5d) {
/* Pattern found, check before and after */
beforeCount = 0;
for (b = (x - 4); b < x; b++) {
if (b < 0) {
beforeCount++;
} else {
if (local[(y * size) + b] == '0') {
beforeCount++;
} else {
beforeCount = 0;
}
}
}
afterCount = 0;
for (a = (x + 7); a <= (x + 10); a++) {
if (a >= size) {
afterCount++;
} else {
if (local[(y * size) + a] == '0') {
afterCount++;
} else {
afterCount = 0;
}
}
}
if ((beforeCount == 4) || (afterCount == 4)) {
/* Pattern is preceeded or followed by light area
4 modules wide */
result += 40;
}
}
}
}
#ifdef ZINTLOG
/* output Test 3 */
sprintf(str, "%d", result - result_b);
result_b = result;
write_log(str);
#endif
/* Test 4: Proportion of dark modules in entire symbol */
dark_mods = 0;
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if (local[(y * size) + x] == '1') {
dark_mods++;
}
}
}
percentage = 100 * (dark_mods / (size * size));
if (percentage <= 50) {
k = ((100 - percentage) - 50) / 5;
} else {
k = (percentage - 50) / 5;
}
result += 10 * k;
#ifdef ZINTLOG
/* output Test 4+summary */
sprintf(str, "%d", result - result_b);
write_log(str);
write_log("==========");
sprintf(str, "%d", result);
write_log(str);
#endif
return result;
}
static void add_format_info_eval(unsigned char *eval,const int size,const int ecc_level,const int pattern) {
/* Add format information to grid */
int format = pattern;
unsigned int seq;
int i;
switch (ecc_level) {
case LEVEL_L: format += 0x08;
break;
case LEVEL_Q: format += 0x18;
break;
case LEVEL_H: format += 0x10;
break;
}
seq = qr_annex_c[format];
for (i = 0; i < 6; i++) {
eval[(i * size) + 8] = ((seq >> i) & 0x01) ? (0x01 >> pattern) : 0x00;
}
for (i = 0; i < 8; i++) {
eval[(8 * size) + (size - i - 1)] = ((seq >> i) & 0x01) ? (0x01 >> pattern) : 0x00;
}
for (i = 0; i < 6; i++) {
eval[(8 * size) + (5 - i)] = ((seq >> (i + 9)) & 0x01) ? (0x01 >> pattern) : 0x00;
}
for (i = 0; i < 7; i++) {
eval[(((size - 7) + i) * size) + 8] = ((seq >> (i + 8)) & 0x01) ? (0x01 >> pattern) : 0x00;
}
eval[(7 * size) + 8] = ((seq >> 6) & 0x01) ? (0x01 >> pattern) : 0x00;
eval[(8 * size) + 8] = ((seq >> 7) & 0x01) ? (0x01 >> pattern) : 0x00;
eval[(8 * size) + 7] = ((seq >> 8) & 0x01) ? (0x01 >> pattern) : 0x00;
}
static int apply_bitmask(unsigned char *grid,const int size,const int ecc_level) {
int x, y;
unsigned char p;
int pattern, penalty[8];
int best_val, best_pattern;
#ifndef _MSC_VER
unsigned char mask[size * size];
unsigned char eval[size * size];
#else
unsigned char* mask = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
unsigned char* eval = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
#endif
/* Perform data masking */
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
mask[(y * size) + x] = 0x00;
// all eight bitmask variants are encoded in the 8 bits of the bytes that make up the mask array.
if (!(grid[(y * size) + x] & 0xf0)) { // exclude areas not to be masked.
if (((y + x) & 1) == 0) {
mask[(y * size) + x] += 0x01;
}
if ((y & 1) == 0) {
mask[(y * size) + x] += 0x02;
}
if ((x % 3) == 0) {
mask[(y * size) + x] += 0x04;
}
if (((y + x) % 3) == 0) {
mask[(y * size) + x] += 0x08;
}
if ((((y / 2) + (x / 3)) & 1) == 0) {
mask[(y * size) + x] += 0x10;
}
if ((((y * x) & 1) + ((y * x) % 3)) == 0) {
mask[(y * size) + x] += 0x20;
}
if (((((y * x) & 1) + ((y * x) % 3)) & 1) == 0) {
mask[(y * size) + x] += 0x40;
}
if (((((y + x) & 1) + ((y * x) % 3)) & 1) == 0) {
mask[(y * size) + x] += 0x80;
}
}
}
}
// apply data masks to grid, result in eval
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if (grid[(y * size) + x] & 0x01) {
p = 0xff;
} else {
p = 0x00;
}
eval[(y * size) + x] = mask[(y * size) + x] ^ p;
}
}
/* Evaluate result */
for (pattern = 0; pattern < 8; pattern++) {
add_format_info_eval(eval, size, ecc_level, pattern);
penalty[pattern] = evaluate(eval, size, pattern);
}
best_pattern = 0;
best_val = penalty[0];
for (pattern = 1; pattern < 8; pattern++) {
if (penalty[pattern] < best_val) {
best_pattern = pattern;
best_val = penalty[pattern];
}
}
#ifdef ZINTLOG
char str[15];
sprintf(str, "%d", best_val);
write_log("choosed pattern:");
write_log(str);
#endif
/* Apply mask */
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if (mask[(y * size) + x] & (0x01 << best_pattern)) {
if (grid[(y * size) + x] & 0x01) {
grid[(y * size) + x] = 0x00;
} else {
grid[(y * size) + x] = 0x01;
}
}
}
}
return best_pattern;
}
/* Add format information to grid */
static void add_format_info(unsigned char *grid,const int size,const int ecc_level,const int pattern) {
int format = pattern;
unsigned int seq;
int i;
switch (ecc_level) {
case LEVEL_L: format += 0x08;
break;
case LEVEL_Q: format += 0x18;
break;
case LEVEL_H: format += 0x10;
break;
}
seq = qr_annex_c[format];
for (i = 0; i < 6; i++) {
grid[(i * size) + 8] += (seq >> i) & 0x01;
}
for (i = 0; i < 8; i++) {
grid[(8 * size) + (size - i - 1)] += (seq >> i) & 0x01;
}
for (i = 0; i < 6; i++) {
grid[(8 * size) + (5 - i)] += (seq >> (i + 9)) & 0x01;
}
for (i = 0; i < 7; i++) {
grid[(((size - 7) + i) * size) + 8] += (seq >> (i + 8)) & 0x01;
}
grid[(7 * size) + 8] += (seq >> 6) & 0x01;
grid[(8 * size) + 8] += (seq >> 7) & 0x01;
grid[(8 * size) + 7] += (seq >> 8) & 0x01;
}
/* Add version information */
static void add_version_info(unsigned char *grid,const int size,const int version) {
int i;
long int version_data = qr_annex_d[version - 7];
for (i = 0; i < 6; i++) {
grid[((size - 11) * size) + i] += (version_data >> (i * 3)) & 0x41;
grid[((size - 10) * size) + i] += (version_data >> ((i * 3) + 1)) & 0x41;
grid[((size - 9) * size) + i] += (version_data >> ((i * 3) + 2)) & 0x41;
grid[(i * size) + (size - 11)] += (version_data >> (i * 3)) & 0x41;
grid[(i * size) + (size - 10)] += (version_data >> ((i * 3) + 1)) & 0x41;
grid[(i * size) + (size - 9)] += (version_data >> ((i * 3) + 2)) & 0x41;
}
}
static size_t blockLength(const size_t start,const char inputMode[],const size_t inputLength) {
/* Find the length of the block starting from 'start' */
size_t i;
int count;
char mode = inputMode[start];
count = 0;
i = start;
do {
count++;
} while (((i + count) < inputLength) && (inputMode[i + count] == mode));
return count;
}
static int getBinaryLength(const int version, char inputMode[], const unsigned int inputData[], const size_t inputLength, const int gs1, const int eci, const int debug) {
/* Calculate the actual bitlength of the proposed binary string */
size_t i;
char currentMode;
int j;
int count = 0;
int alphalength;
int blocklength;
qr_define_mode(inputMode, inputData, inputLength, gs1, version, debug);
currentMode = ' '; // Null
if (gs1 == 1) { /* Not applicable to MICROQR */
if (version < RMQR_VERSION) {
count += 4;
} else {
count += 3;
}
}
if (eci != 0) { // RMQR and MICROQR do not support ECI
count += 4;
if (eci <= 127) {
count += 8;
} else if (eci <= 16383) {
count += 16;
} else {
count += 24;
}
}
for (i = 0; i < inputLength; i++) {
if (inputMode[i] != currentMode) {
count += mode_bits(version) + cci_bits(version, inputMode[i]);
blocklength = blockLength(i, inputMode, inputLength);
switch (inputMode[i]) {
case 'K':
count += (blocklength * 13);
break;
case 'B':
for (j = i; j < (i + blocklength); j++) {
if (inputData[j] > 0xff) {
count += 16;
} else {
count += 8;
}
}
break;
case 'A':
alphalength = blocklength;
if (gs1) {
// In alphanumeric mode % becomes %%
for (j = i; j < (i + blocklength); j++) {
if (inputData[j] == '%') {
alphalength++;
}
}
}
switch (alphalength % 2) {
case 0:
count += (alphalength / 2) * 11;
break;
case 1:
count += ((alphalength - 1) / 2) * 11;
count += 6;
break;
}
break;
case 'N':
switch (blocklength % 3) {
case 0:
count += (blocklength / 3) * 10;
break;
case 1:
count += ((blocklength - 1) / 3) * 10;
count += 4;
break;
case 2:
count += ((blocklength - 2) / 3) * 10;
count += 7;
break;
}
break;
}
currentMode = inputMode[i];
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Estimated Binary Length: %d (version %d, eci %d, gs1 %d)\n", count, version, eci, gs1);
}
return count;
}
int qr_code(struct zint_symbol *symbol, const unsigned char source[], size_t length) {
int i, j, est_binlen;
int ecc_level, autosize, version, max_cw, target_codewords, blocks, size;
int bitmask, gs1;
int canShrink;
#ifndef _MSC_VER
unsigned int jisdata[length + 1];
char mode[length + 1];
#else
unsigned char* datastream;
unsigned char* fullstream;
unsigned char* grid;
unsigned int* jisdata = (unsigned int *) _alloca((length + 1) * sizeof (unsigned int));
char* mode = (char *) _alloca(length + 1);
#endif
gs1 = ((symbol->input_mode & 0x07) == GS1_MODE);
if ((symbol->input_mode & 0x07) == DATA_MODE) {
sjis_cpy(source, &length, jisdata);
} else {
int done = 0;
if (symbol->eci != 20) { /* Unless ECI 20 (Shift JIS) */
/* Try single byte (Latin) conversion first */
int error_number = sjis_utf8tosb(symbol->eci && symbol->eci <= 899 ? symbol->eci : 3, source, &length, jisdata);
if (error_number == 0) {
done = 1;
} else if (symbol->eci && symbol->eci <= 899) {
strcpy(symbol->errtxt, "575: Invalid characters in input data");
return error_number;
}
}
if (!done) {
/* Try Shift-JIS */
int error_number = sjis_utf8tomb(symbol, source, &length, jisdata);
if (error_number != 0) {
return error_number;
}
}
}
est_binlen = getBinaryLength(40, mode, jisdata, length, gs1, symbol->eci, symbol->debug);
ecc_level = LEVEL_L;
max_cw = 2956;
if ((symbol->option_1 >= 1) && (symbol->option_1 <= 4)) {
switch (symbol->option_1) {
case 1:
break;
case 2: ecc_level = LEVEL_M;
max_cw = 2334;
break;
case 3: ecc_level = LEVEL_Q;
max_cw = 1666;
break;
case 4: ecc_level = LEVEL_H;
max_cw = 1276;
break;
}
}
if (est_binlen > (8 * max_cw)) {
strcpy(symbol->errtxt, "561: Input too long for selected error correction level");
return ZINT_ERROR_TOO_LONG;
}
autosize = 40;
for (i = 39; i >= 0; i--) {
switch (ecc_level) {
case LEVEL_L:
if ((8 * qr_data_codewords_L[i]) >= est_binlen) {
autosize = i + 1;
}
break;
case LEVEL_M:
if ((8 * qr_data_codewords_M[i]) >= est_binlen) {
autosize = i + 1;
}
break;
case LEVEL_Q:
if ((8 * qr_data_codewords_Q[i]) >= est_binlen) {
autosize = i + 1;
}
break;
case LEVEL_H:
if ((8 * qr_data_codewords_H[i]) >= est_binlen) {
autosize = i + 1;
}
break;
}
}
if (autosize != 40) {
est_binlen = getBinaryLength(autosize, mode, jisdata, length, gs1, symbol->eci, symbol->debug);
}
// Now see if the optimised binary will fit in a smaller symbol.
canShrink = 1;
do {
if (autosize == 1) {
canShrink = 0;
} else {
est_binlen = getBinaryLength(autosize - 1, mode, jisdata, length, gs1, symbol->eci, symbol->debug);
switch (ecc_level) {
case LEVEL_L:
if ((8 * qr_data_codewords_L[autosize - 2]) < est_binlen) {
canShrink = 0;
}
break;
case LEVEL_M:
if ((8 * qr_data_codewords_M[autosize - 2]) < est_binlen) {
canShrink = 0;
}
break;
case LEVEL_Q:
if ((8 * qr_data_codewords_Q[autosize - 2]) < est_binlen) {
canShrink = 0;
}
break;
case LEVEL_H:
if ((8 * qr_data_codewords_H[autosize - 2]) < est_binlen) {
canShrink = 0;
}
break;
}
if (canShrink == 1) {
// Optimisation worked - data will fit in a smaller symbol
autosize--;
} else {
// Data did not fit in the smaller symbol, revert to original size
est_binlen = getBinaryLength(autosize, mode, jisdata, length, gs1, symbol->eci, symbol->debug);
}
}
} while (canShrink == 1);
version = autosize;
if ((symbol->option_2 >= 1) && (symbol->option_2 <= 40)) {
/* If the user has selected a larger symbol than the smallest available,
then use the size the user has selected, and re-optimise for this
symbol size.
*/
if (symbol->option_2 > version) {
version = symbol->option_2;
est_binlen = getBinaryLength(symbol->option_2, mode, jisdata, length, gs1, symbol->eci, symbol->debug);
}
if (symbol->option_2 < version) {
strcpy(symbol->errtxt, "569: Input too long for selected symbol size");
return ZINT_ERROR_TOO_LONG;
}
}
/* Ensure maxium error correction capacity unless user-specified */
if (symbol->option_1 == -1 || symbol->option_1 != ecc_level) {
if (est_binlen <= qr_data_codewords_M[version - 1] * 8) {
ecc_level = LEVEL_M;
}
if (est_binlen <= qr_data_codewords_Q[version - 1] * 8) {
ecc_level = LEVEL_Q;
}
if (est_binlen <= qr_data_codewords_H[version - 1] * 8) {
ecc_level = LEVEL_H;
}
}
target_codewords = qr_data_codewords_L[version - 1];
blocks = qr_blocks_L[version - 1];
switch (ecc_level) {
case LEVEL_M: target_codewords = qr_data_codewords_M[version - 1];
blocks = qr_blocks_M[version - 1];
break;
case LEVEL_Q: target_codewords = qr_data_codewords_Q[version - 1];
blocks = qr_blocks_Q[version - 1];
break;
case LEVEL_H: target_codewords = qr_data_codewords_H[version - 1];
blocks = qr_blocks_H[version - 1];
break;
}
#ifndef _MSC_VER
unsigned char datastream[target_codewords + 1];
unsigned char fullstream[qr_total_codewords[version - 1] + 1];
#else
datastream = (unsigned char *) _alloca(target_codewords + 1);
fullstream = (unsigned char *) _alloca(qr_total_codewords[version - 1] + 1);
#endif
qr_binary(datastream, version, target_codewords, mode, jisdata, length, gs1, symbol->eci, est_binlen, symbol->debug);
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, datastream, target_codewords);
add_ecc(fullstream, datastream, version, target_codewords, blocks, symbol->debug);
size = qr_sizes[version - 1];
#ifndef _MSC_VER
unsigned char grid[size * size];
#else
grid = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
#endif
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
grid[(i * size) + j] = 0;
}
}
setup_grid(grid, size, version);
populate_grid(grid, size, size, fullstream, qr_total_codewords[version - 1]);
if (version >= 7) {
add_version_info(grid, size, version);
}
bitmask = apply_bitmask(grid, size, ecc_level);
add_format_info(grid, size, ecc_level, bitmask);
symbol->width = size;
symbol->rows = size;
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
if (grid[(i * size) + j] & 0x01) {
set_module(symbol, i, j);
}
}
symbol->row_height[i] = 1;
}
return 0;
}
static void micro_qr_m1(struct zint_symbol *symbol, char binary_data[]) {
int i, j, latch;
int bits_total, bits_left;
int data_codewords, ecc_codewords;
unsigned char data_blocks[4], ecc_blocks[3];
bits_total = 20;
latch = 0;
/* Add terminator */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 3) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
} else {
strcat(binary_data, "000");
}
if (latch == 0) {
/* Manage last (4-bit) block */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 4) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
}
}
if (latch == 0) {
/* Complete current byte */
int remainder = 8 - (strlen(binary_data) % 8);
if (remainder == 8) {
remainder = 0;
}
for (i = 0; i < remainder; i++) {
strcat(binary_data, "0");
}
/* Add padding */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left > 4) {
remainder = (bits_left - 4) / 8;
for (i = 0; i < remainder; i++) {
strcat(binary_data, (i & 1) ? "00010001" : "11101100");
}
}
bin_append(0, 4, binary_data);
}
data_codewords = 3;
ecc_codewords = 2;
/* Copy data into codewords */
for (i = 0; i < (data_codewords - 1); i++) {
data_blocks[i] = 0;
for (j = 0; j < 8; j++) {
if (binary_data[(i * 8) + j] == '1') {
data_blocks[i] += 0x80 >> j;
}
}
}
data_blocks[2] = 0;
for (j = 0; j < 4; j++) {
if (binary_data[16 + j] == '1') {
data_blocks[2] += 0x80 >> j;
}
}
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, data_blocks, data_codewords);
/* Calculate Reed-Solomon error codewords */
rs_init_gf(0x11d);
rs_init_code(ecc_codewords, 0);
rs_encode(data_codewords, data_blocks, ecc_blocks);
rs_free();
/* Add Reed-Solomon codewords to binary data */
for (i = 0; i < ecc_codewords; i++) {
bin_append(ecc_blocks[ecc_codewords - i - 1], 8, binary_data);
}
}
static void micro_qr_m2(struct zint_symbol *symbol, char binary_data[], const int ecc_mode) {
int i, j, latch;
int bits_total=0, bits_left;
int data_codewords=0, ecc_codewords=0;
unsigned char data_blocks[6], ecc_blocks[7];
latch = 0;
if (ecc_mode == LEVEL_L) {
bits_total = 40;
}
else if (ecc_mode == LEVEL_M) {
bits_total = 32;
}
else assert(0);
/* Add terminator */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 5) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
} else {
bin_append(0, 5, binary_data);
}
if (latch == 0) {
/* Complete current byte */
int remainder = 8 - (strlen(binary_data) % 8);
if (remainder == 8) {
remainder = 0;
}
for (i = 0; i < remainder; i++) {
strcat(binary_data, "0");
}
/* Add padding */
bits_left = bits_total - (int)strlen(binary_data);
remainder = bits_left / 8;
for (i = 0; i < remainder; i++) {
strcat(binary_data, (i & 1) ? "00010001" : "11101100");
}
}
if (ecc_mode == LEVEL_L) {
data_codewords = 5;
ecc_codewords = 5;
}
else if (ecc_mode == LEVEL_M) {
data_codewords = 4;
ecc_codewords = 6;
}
else assert(0);
/* Copy data into codewords */
for (i = 0; i < data_codewords; i++) {
data_blocks[i] = 0;
for (j = 0; j < 8; j++) {
if (binary_data[(i * 8) + j] == '1') {
data_blocks[i] += 0x80 >> j;
}
}
}
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, data_blocks, data_codewords);
/* Calculate Reed-Solomon error codewords */
rs_init_gf(0x11d);
rs_init_code(ecc_codewords, 0);
rs_encode(data_codewords, data_blocks, ecc_blocks);
rs_free();
/* Add Reed-Solomon codewords to binary data */
for (i = 0; i < ecc_codewords; i++) {
bin_append(ecc_blocks[ecc_codewords - i - 1], 8, binary_data);
}
return;
}
static void micro_qr_m3(struct zint_symbol *symbol, char binary_data[], const int ecc_mode) {
int i, j, latch;
int bits_total=0, bits_left;
int data_codewords=0, ecc_codewords=0;
unsigned char data_blocks[12], ecc_blocks[9];
latch = 0;
if (ecc_mode == LEVEL_L) {
bits_total = 84;
}
else if (ecc_mode == LEVEL_M) {
bits_total = 68;
}
else assert(0);
/* Add terminator */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 7) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
} else {
bin_append(0, 7, binary_data);
}
if (latch == 0) {
/* Manage last (4-bit) block */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 4) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
}
}
if (latch == 0) {
/* Complete current byte */
int remainder = 8 - (strlen(binary_data) % 8);
if (remainder == 8) {
remainder = 0;
}
for (i = 0; i < remainder; i++) {
strcat(binary_data, "0");
}
/* Add padding */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left > 4) {
remainder = (bits_left - 4) / 8;
for (i = 0; i < remainder; i++) {
strcat(binary_data, (i & 1) ? "00010001" : "11101100");
}
}
bin_append(0, 4, binary_data);
}
if (ecc_mode == LEVEL_L) {
data_codewords = 11;
ecc_codewords = 6;
}
else if (ecc_mode == LEVEL_M) {
data_codewords = 9;
ecc_codewords = 8;
}
else assert(0);
/* Copy data into codewords */
for (i = 0; i < (data_codewords - 1); i++) {
data_blocks[i] = 0;
for (j = 0; j < 8; j++) {
if (binary_data[(i * 8) + j] == '1') {
data_blocks[i] += 0x80 >> j;
}
}
}
if (ecc_mode == LEVEL_L) {
data_blocks[10] = 0;
for (j = 0; j < 4; j++) {
if (binary_data[80 + j] == '1') {
data_blocks[10] += 0x80 >> j;
}
}
}
if (ecc_mode == LEVEL_M) {
data_blocks[8] = 0;
for (j = 0; j < 4; j++) {
if (binary_data[64 + j] == '1') {
data_blocks[8] += 0x80 >> j;
}
}
}
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, data_blocks, data_codewords);
/* Calculate Reed-Solomon error codewords */
rs_init_gf(0x11d);
rs_init_code(ecc_codewords, 0);
rs_encode(data_codewords, data_blocks, ecc_blocks);
rs_free();
/* Add Reed-Solomon codewords to binary data */
for (i = 0; i < ecc_codewords; i++) {
bin_append(ecc_blocks[ecc_codewords - i - 1], 8, binary_data);
}
return;
}
static void micro_qr_m4(struct zint_symbol *symbol, char binary_data[], const int ecc_mode) {
int i, j, latch;
int bits_total=0, bits_left;
int data_codewords=0, ecc_codewords=0;
unsigned char data_blocks[17], ecc_blocks[15];
latch = 0;
if (ecc_mode == LEVEL_L) {
bits_total = 128;
}
else if (ecc_mode == LEVEL_M) {
bits_total = 112;
}
else if (ecc_mode == LEVEL_Q) {
bits_total = 80;
}
else assert(0);
/* Add terminator */
bits_left = bits_total - (int)strlen(binary_data);
if (bits_left <= 9) {
for (i = 0; i < bits_left; i++) {
strcat(binary_data, "0");
}
latch = 1;
} else {
bin_append(0, 9, binary_data);
}
if (latch == 0) {
/* Complete current byte */
int remainder = 8 - (strlen(binary_data) % 8);
if (remainder == 8) {
remainder = 0;
}
for (i = 0; i < remainder; i++) {
strcat(binary_data, "0");
}
/* Add padding */
bits_left = bits_total - (int)strlen(binary_data);
remainder = bits_left / 8;
for (i = 0; i < remainder; i++) {
strcat(binary_data, (i & 1) ? "00010001" : "11101100");
}
}
if (ecc_mode == LEVEL_L) {
data_codewords = 16;
ecc_codewords = 8;
}
else if (ecc_mode == LEVEL_M) {
data_codewords = 14;
ecc_codewords = 10;
}
else if (ecc_mode == LEVEL_Q) {
data_codewords = 10;
ecc_codewords = 14;
}
else assert(0);
/* Copy data into codewords */
for (i = 0; i < data_codewords; i++) {
data_blocks[i] = 0;
for (j = 0; j < 8; j++) {
if (binary_data[(i * 8) + j] == '1') {
data_blocks[i] += 0x80 >> j;
}
}
}
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, data_blocks, data_codewords);
/* Calculate Reed-Solomon error codewords */
rs_init_gf(0x11d);
rs_init_code(ecc_codewords, 0);
rs_encode(data_codewords, data_blocks, ecc_blocks);
rs_free();
/* Add Reed-Solomon codewords to binary data */
for (i = 0; i < ecc_codewords; i++) {
bin_append(ecc_blocks[ecc_codewords - i - 1], 8, binary_data);
}
}
static void micro_setup_grid(unsigned char* grid,const int size) {
int i, toggle = 1;
/* Add timing patterns */
for (i = 0; i < size; i++) {
if (toggle == 1) {
grid[i] = 0x21;
grid[(i * size)] = 0x21;
toggle = 0;
} else {
grid[i] = 0x20;
grid[(i * size)] = 0x20;
toggle = 1;
}
}
/* Add finder patterns */
place_finder(grid, size, 0, 0);
/* Add separators */
for (i = 0; i < 7; i++) {
grid[(7 * size) + i] = 0x10;
grid[(i * size) + 7] = 0x10;
}
grid[(7 * size) + 7] = 0x10;
/* Reserve space for format information */
for (i = 0; i < 8; i++) {
grid[(8 * size) + i] += 0x20;
grid[(i * size) + 8] += 0x20;
}
grid[(8 * size) + 8] += 20;
}
static void micro_populate_grid(unsigned char* grid,const int size,const char full_stream[]) {
int direction = 1; /* up */
int row = 0; /* right hand side */
size_t n;
int i, y;
n = strlen(full_stream);
y = size - 1;
i = 0;
do {
int x = (size - 2) - (row * 2);
if (!(grid[(y * size) + (x + 1)] & 0xf0)) {
if (full_stream[i] == '1') {
grid[(y * size) + (x + 1)] = 0x01;
} else {
grid[(y * size) + (x + 1)] = 0x00;
}
i++;
}
if (i < n) {
if (!(grid[(y * size) + x] & 0xf0)) {
if (full_stream[i] == '1') {
grid[(y * size) + x] = 0x01;
} else {
grid[(y * size) + x] = 0x00;
}
i++;
}
}
if (direction) {
y--;
} else {
y++;
}
if (y == 0) {
/* reached the top */
row++;
y = 1;
direction = 0;
}
if (y == size) {
/* reached the bottom */
row++;
y = size - 1;
direction = 1;
}
} while (i < n);
}
static int micro_evaluate(const unsigned char *grid,const int size,const int pattern) {
int sum1, sum2, i, filter = 0, retval;
switch (pattern) {
case 0: filter = 0x01;
break;
case 1: filter = 0x02;
break;
case 2: filter = 0x04;
break;
case 3: filter = 0x08;
break;
}
sum1 = 0;
sum2 = 0;
for (i = 1; i < size; i++) {
if (grid[(i * size) + size - 1] & filter) {
sum1++;
}
if (grid[((size - 1) * size) + i] & filter) {
sum2++;
}
}
if (sum1 <= sum2) {
retval = (sum1 * 16) + sum2;
} else {
retval = (sum2 * 16) + sum1;
}
return retval;
}
static int micro_apply_bitmask(unsigned char *grid,const int size) {
int x, y;
unsigned char p;
int pattern, value[8];
int best_val, best_pattern;
#ifndef _MSC_VER
unsigned char mask[size * size];
unsigned char eval[size * size];
#else
unsigned char* mask = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
unsigned char* eval = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
#endif
/* Perform data masking */
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
mask[(y * size) + x] = 0x00;
if (!(grid[(y * size) + x] & 0xf0)) {
if ((y & 1) == 0) {
mask[(y * size) + x] += 0x01;
}
if ((((y / 2) + (x / 3)) & 1) == 0) {
mask[(y * size) + x] += 0x02;
}
if (((((y * x) & 1) + ((y * x) % 3)) & 1) == 0) {
mask[(y * size) + x] += 0x04;
}
if (((((y + x) & 1) + ((y * x) % 3)) & 1) == 0) {
mask[(y * size) + x] += 0x08;
}
}
}
}
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if (grid[(y * size) + x] & 0x01) {
p = 0xff;
} else {
p = 0x00;
}
eval[(y * size) + x] = mask[(y * size) + x] ^ p;
}
}
/* Evaluate result */
for (pattern = 0; pattern < 8; pattern++) {
value[pattern] = micro_evaluate(eval, size, pattern);
}
best_pattern = 0;
best_val = value[0];
for (pattern = 1; pattern < 4; pattern++) {
if (value[pattern] > best_val) {
best_pattern = pattern;
best_val = value[pattern];
}
}
/* Apply mask */
for (x = 0; x < size; x++) {
for (y = 0; y < size; y++) {
if (mask[(y * size) + x] & (0x01 << best_pattern)) {
if (grid[(y * size) + x] & 0x01) {
grid[(y * size) + x] = 0x00;
} else {
grid[(y * size) + x] = 0x01;
}
}
}
}
return best_pattern;
}
int microqr(struct zint_symbol *symbol, const unsigned char source[], size_t length) {
size_t i;
int j, size;
char full_stream[200];
unsigned int jisdata[40];
char mode[40];
int alpha_used = 0, byte_or_kanji_used = 0;
int version_valid[4];
int binary_count[4];
int ecc_level, autoversion, version;
int bitmask, format, format_full;
#ifdef _MSC_VER
unsigned char* grid;
#endif
if (length > 35) {
strcpy(symbol->errtxt, "562: Input data too long");
return ZINT_ERROR_TOO_LONG;
}
/* Check option 1 in combination with option 2 */
ecc_level = LEVEL_L;
if (symbol->option_1 >= 1 && symbol->option_1 <= 4) {
if (symbol->option_1 == 4) {
strcpy(symbol->errtxt, "566: Error correction level H not available");
return ZINT_ERROR_INVALID_OPTION;
}
if (symbol->option_2 >= 1 && symbol->option_2 <= 4) {
if (symbol->option_2 == 1 && symbol->option_1 != 1) {
strcpy(symbol->errtxt, "574: Version M1 supports error correction level L only");
return ZINT_ERROR_INVALID_OPTION;
}
if (symbol->option_2 != 4 && symbol->option_1 == 3) {
strcpy(symbol->errtxt, "575: Error correction level Q requires Version M4");
return ZINT_ERROR_INVALID_OPTION;
}
}
ecc_level = symbol->option_1;
}
if ((symbol->input_mode & 0x07) == DATA_MODE) {
sjis_cpy(source, &length, jisdata);
} else {
/* Try ISO 8859-1 conversion first */
int error_number = sjis_utf8tosb(3, source, &length, jisdata);
if (error_number != 0) {
/* Try Shift-JIS */
error_number = sjis_utf8tomb(symbol, source, &length, jisdata);
if (error_number != 0) {
return error_number;
}
}
}
/* Determine if alpha (excluding numerics), byte or kanji used */
for (i = 0; i < length && (alpha_used == 0 || byte_or_kanji_used == 0); i++) {
if (jisdata[i] < '0' || jisdata[i] > '9') {
if (is_alpha(jisdata[i], 0 /*gs1*/)) {
alpha_used = 1;
} else {
byte_or_kanji_used = 1;
}
}
}
for (i = 0; i < 4; i++) {
version_valid[i] = 1;
}
/* Eliminate possible versions depending on type of content */
if (byte_or_kanji_used) {
version_valid[0] = 0;
version_valid[1] = 0;
} else if (alpha_used) {
version_valid[0] = 0;
}
/* Eliminate possible versions depending on error correction level specified */
if (ecc_level == LEVEL_Q) {
version_valid[0] = 0;
version_valid[1] = 0;
version_valid[2] = 0;
} else if (ecc_level == LEVEL_M) {
version_valid[0] = 0;
}
/* Determine length of binary data */
for (i = 0; i < 4; i++) {
if (version_valid[i]) {
binary_count[i] = getBinaryLength(MICROQR_VERSION + i, mode, jisdata, length, 0 /*gs1*/, 0 /*eci*/, symbol->debug);
} else {
binary_count[i] = 128 + 1;
}
}
/* Eliminate possible versions depending on length of binary data */
if (binary_count[0] > 20) {
version_valid[0] = 0;
}
if (binary_count[1] > 40) {
version_valid[1] = 0;
}
if (binary_count[2] > 84) {
version_valid[2] = 0;
}
if (binary_count[3] > 128) {
strcpy(symbol->errtxt, "565: Input data too long");
return ZINT_ERROR_TOO_LONG;
}
/* Eliminate possible versions depending on binary length and error correction level specified */
if (ecc_level == LEVEL_Q) {
if (binary_count[3] > 80) {
strcpy(symbol->errtxt, "567: Input data too long");
return ZINT_ERROR_TOO_LONG;
}
} else if (ecc_level == LEVEL_M) {
if (binary_count[1] > 32) {
version_valid[1] = 0;
}
if (binary_count[2] > 68) {
version_valid[2] = 0;
}
if (binary_count[3] > 112) {
strcpy(symbol->errtxt, "568: Input data too long");
return ZINT_ERROR_TOO_LONG;
}
}
autoversion = 3;
if (version_valid[2]) {
autoversion = 2;
}
if (version_valid[1]) {
autoversion = 1;
}
if (version_valid[0]) {
autoversion = 0;
}
version = autoversion;
/* Get version from user */
if ((symbol->option_2 >= 1) && (symbol->option_2 <= 4)) {
if (symbol->option_2 - 1 >= autoversion) {
version = symbol->option_2 - 1;
} else {
strcpy(symbol->errtxt, "570: Input too long for selected symbol size");
return ZINT_ERROR_TOO_LONG;
}
}
/* If there is enough unused space then increase the error correction level, unless user-specified */
if (symbol->option_1 == -1 || symbol->option_1 != ecc_level) {
if (version == 3) {
if (binary_count[3] <= 112) {
ecc_level = LEVEL_M;
}
if (binary_count[3] <= 80) {
ecc_level = LEVEL_Q;
}
} else if (version == 2) {
if (binary_count[2] <= 68) {
ecc_level = LEVEL_M;
}
} else if (version == 1) {
if (binary_count[1] <= 32) {
ecc_level = LEVEL_M;
}
}
}
qr_define_mode(mode, jisdata, length, 0 /*gs1*/, MICROQR_VERSION + version, symbol->debug);
qr_binary((unsigned char*)full_stream, MICROQR_VERSION + version, 0 /*target_codewords*/, mode, jisdata, length, 0 /*gs1*/, 0 /*eci*/, binary_count[version], symbol->debug);
switch (version) {
case 0: micro_qr_m1(symbol, full_stream);
break;
case 1: micro_qr_m2(symbol, full_stream, ecc_level);
break;
case 2: micro_qr_m3(symbol, full_stream, ecc_level);
break;
case 3: micro_qr_m4(symbol, full_stream, ecc_level);
break;
}
size = micro_qr_sizes[version];
#ifndef _MSC_VER
unsigned char grid[size * size];
#else
grid = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
#endif
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
grid[(i * size) + j] = 0;
}
}
micro_setup_grid(grid, size);
micro_populate_grid(grid, size, full_stream);
bitmask = micro_apply_bitmask(grid, size);
/* Add format data */
format = 0;
switch (version) {
case 1: switch (ecc_level) {
case 1: format = 1;
break;
case 2: format = 2;
break;
}
break;
case 2: switch (ecc_level) {
case 1: format = 3;
break;
case 2: format = 4;
break;
}
break;
case 3: switch (ecc_level) {
case 1: format = 5;
break;
case 2: format = 6;
break;
case 3: format = 7;
break;
}
break;
}
format_full = qr_annex_c1[(format << 2) + bitmask];
if (format_full & 0x4000) {
grid[(8 * size) + 1] += 0x01;
}
if (format_full & 0x2000) {
grid[(8 * size) + 2] += 0x01;
}
if (format_full & 0x1000) {
grid[(8 * size) + 3] += 0x01;
}
if (format_full & 0x800) {
grid[(8 * size) + 4] += 0x01;
}
if (format_full & 0x400) {
grid[(8 * size) + 5] += 0x01;
}
if (format_full & 0x200) {
grid[(8 * size) + 6] += 0x01;
}
if (format_full & 0x100) {
grid[(8 * size) + 7] += 0x01;
}
if (format_full & 0x80) {
grid[(8 * size) + 8] += 0x01;
}
if (format_full & 0x40) {
grid[(7 * size) + 8] += 0x01;
}
if (format_full & 0x20) {
grid[(6 * size) + 8] += 0x01;
}
if (format_full & 0x10) {
grid[(5 * size) + 8] += 0x01;
}
if (format_full & 0x08) {
grid[(4 * size) + 8] += 0x01;
}
if (format_full & 0x04) {
grid[(3 * size) + 8] += 0x01;
}
if (format_full & 0x02) {
grid[(2 * size) + 8] += 0x01;
}
if (format_full & 0x01) {
grid[(1 * size) + 8] += 0x01;
}
symbol->width = size;
symbol->rows = size;
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
if (grid[(i * size) + j] & 0x01) {
set_module(symbol, i, j);
}
}
symbol->row_height[i] = 1;
}
return 0;
}
/* For UPNQR the symbol size and error correction capacity is fixed */
int upnqr(struct zint_symbol *symbol, const unsigned char source[], size_t length) {
int i, j, est_binlen;
int ecc_level, version, target_codewords, blocks, size;
int bitmask, error_number;
#ifndef _MSC_VER
unsigned int jisdata[length + 1];
char mode[length + 1];
#else
unsigned char* datastream;
unsigned char* fullstream;
unsigned char* grid;
unsigned int* jisdata = (unsigned int *) _alloca((length + 1) * sizeof (unsigned int));
char* mode = (char *) _alloca(length + 1);
#endif
#ifndef _MSC_VER
unsigned char preprocessed[length + 1];
#else
unsigned char* preprocessed = (unsigned char*) _alloca(length + 1);
#endif
symbol->eci = 4; /* Set before any processing */
switch (symbol->input_mode & 0x07) {
case DATA_MODE:
/* Input is already in ISO-8859-2 format */
for (i = 0; i < length; i++) {
jisdata[i] = source[i];
mode[i] = 'B';
}
break;
case GS1_MODE:
strcpy(symbol->errtxt, "571: UPNQR does not support GS-1 encoding");
return ZINT_ERROR_INVALID_OPTION;
break;
case UNICODE_MODE:
error_number = utf_to_eci(4, source, preprocessed, &length);
if (error_number != 0) {
strcpy(symbol->errtxt, "572: Invalid characters in input data");
return error_number;
}
for (i = 0; i < length; i++) {
jisdata[i] = preprocessed[i];
mode[i] = 'B';
}
break;
}
est_binlen = getBinaryLength(15, mode, jisdata, length, 0, symbol->eci, symbol->debug);
ecc_level = LEVEL_M;
if (est_binlen > 3320) {
strcpy(symbol->errtxt, "573: Input too long for selected symbol");
return ZINT_ERROR_TOO_LONG;
}
version = 15; // 77 x 77
target_codewords = qr_data_codewords_M[version - 1];
blocks = qr_blocks_M[version - 1];
#ifndef _MSC_VER
unsigned char datastream[target_codewords + 1];
unsigned char fullstream[qr_total_codewords[version - 1] + 1];
#else
datastream = (unsigned char *) _alloca(target_codewords + 1);
fullstream = (unsigned char *) _alloca(qr_total_codewords[version - 1] + 1);
#endif
qr_binary(datastream, version, target_codewords, mode, jisdata, length, 0, symbol->eci, est_binlen, symbol->debug);
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, datastream, target_codewords);
add_ecc(fullstream, datastream, version, target_codewords, blocks, symbol->debug);
size = qr_sizes[version - 1];
#ifndef _MSC_VER
unsigned char grid[size * size];
#else
grid = (unsigned char *) _alloca((size * size) * sizeof (unsigned char));
#endif
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
grid[(i * size) + j] = 0;
}
}
setup_grid(grid, size, version);
populate_grid(grid, size, size, fullstream, qr_total_codewords[version - 1]);
add_version_info(grid, size, version);
bitmask = apply_bitmask(grid, size, ecc_level);
add_format_info(grid, size, ecc_level, bitmask);
symbol->width = size;
symbol->rows = size;
for (i = 0; i < size; i++) {
for (j = 0; j < size; j++) {
if (grid[(i * size) + j] & 0x01) {
set_module(symbol, i, j);
}
}
symbol->row_height[i] = 1;
}
return 0;
}
static void setup_rmqr_grid(unsigned char* grid,const int h_size,const int v_size,const int version) {
int i, j;
char alignment[] = {0x1F, 0x11, 0x15, 0x11, 0x1F};
int h_version, finder_position;
/* Add timing patterns - top and bottom */
for (i = 0; i < h_size; i++) {
if (i % 2) {
grid[i] = 0x20;
grid[((v_size - 1) * h_size) + i] = 0x20;
} else {
grid[i] = 0x21;
grid[((v_size - 1) * h_size) + i] = 0x21;
}
}
/* Add timing patterns - left and right */
for (i = 0; i < v_size; i++) {
if (i % 2) {
grid[i * h_size] = 0x20;
grid[(i * h_size) + (h_size - 1)] = 0x20;
} else {
grid[i * h_size] = 0x21;
grid[(i * h_size) + (h_size - 1)] = 0x21;
}
}
/* Add finder pattern */
place_finder(grid, h_size, 0, 0); // This works because finder is always top left
/* Add finder sub-pattern to bottom right */
for (i = 0; i < 5; i++) {
for (j = 0; j < 5; j++) {
if (alignment[j] & 0x10 >> i) {
grid[((v_size - 5) * h_size) + (h_size * i) + (h_size - 5) + j] = 0x11;
} else {
grid[((v_size - 5) * h_size) + (h_size * i) + (h_size - 5) + j] = 0x10;
}
}
}
/* Add corner finder pattern - bottom left */
grid[(v_size - 2) * h_size] = 0x11;
grid[((v_size - 2) * h_size) + 1] = 0x10;
grid[((v_size - 1) * h_size) + 1] = 0x11;
/* Add corner finder pattern - top right */
grid[h_size - 2] = 0x11;
grid[(h_size * 2) - 2] = 0x10;
grid[(h_size * 2) - 1] = 0x11;
/* Add seperator */
for (i = 0; i < 7; i++) {
grid[(i * h_size) + 7] = 0x20;
}
if (v_size > 7) {
// Note for v_size = 9 this overrides the bottom right corner finder pattern
for(i = 0; i < 8; i++) {
grid[(7 * h_size) + i] = 0x20;
}
}
/* Add alignment patterns */
if (h_size > 27) {
for(i = 0; i < 5; i++) {
if (h_size == rmqr_width[i]) {
h_version = i;
}
}
for(i = 0; i < 4; i++) {
finder_position = rmqr_table_d1[(h_version * 4) + i];
if (finder_position != 0) {
for (j = 0; j < v_size; j++) {
if (j % 2) {
grid[(j * h_size) + finder_position] = 0x10;
} else {
grid[(j * h_size) + finder_position] = 0x11;
}
}
// Top square
grid[h_size + finder_position - 1] = 0x11;
grid[(h_size * 2) + finder_position - 1] = 0x11;
grid[h_size + finder_position + 1] = 0x11;
grid[(h_size * 2) + finder_position + 1] = 0x11;
// Bottom square
grid[(h_size * (v_size - 3)) + finder_position - 1] = 0x11;
grid[(h_size * (v_size - 2)) + finder_position - 1] = 0x11;
grid[(h_size * (v_size - 3)) + finder_position + 1] = 0x11;
grid[(h_size * (v_size - 2)) + finder_position + 1] = 0x11;
}
}
}
/* Reserve space for format information */
for (i = 0; i < 5; i++) {
for (j = 0; j < 3; j++) {
grid[(h_size * (i + 1)) + j + 8] = 0x20;
grid[(h_size * (v_size - 6)) + (h_size * i) + j + (h_size - 8)] = 0x20;
}
}
grid[(h_size * 1) + 11] = 0x20;
grid[(h_size * 2) + 11] = 0x20;
grid[(h_size * 3) + 11] = 0x20;
grid[(h_size * (v_size - 6)) + (h_size - 5)] = 0x20;
grid[(h_size * (v_size - 6)) + (h_size - 4)] = 0x20;
grid[(h_size * (v_size - 6)) + (h_size - 3)] = 0x20;
}
/* rMQR according to 2018 draft standard */
int rmqr(struct zint_symbol *symbol, const unsigned char source[], size_t length) {
int i, j, est_binlen;
int ecc_level, autosize, version, max_cw, target_codewords, blocks, h_size, v_size;
int gs1;
int footprint, best_footprint, format_data;
unsigned int left_format_info, right_format_info;
#ifndef _MSC_VER
unsigned int jisdata[length + 1];
char mode[length + 1];
#else
unsigned char* datastream;
unsigned char* fullstream;
unsigned char* grid;
unsigned int* jisdata = (unsigned int *) _alloca((length + 1) * sizeof (unsigned int));
char* mode = (char *) _alloca(length + 1);
#endif
gs1 = ((symbol->input_mode & 0x07) == GS1_MODE);
if ((symbol->input_mode & 0x07) == DATA_MODE) {
sjis_cpy(source, &length, jisdata);
} else {
/* Try ISO 8859-1 conversion first */
int error_number = sjis_utf8tosb(3, source, &length, jisdata);
if (error_number != 0) {
/* Try Shift-JIS */
error_number = sjis_utf8tomb(symbol, source, &length, jisdata);
if (error_number != 0) {
return error_number;
}
}
}
est_binlen = getBinaryLength(RMQR_VERSION + 31, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
ecc_level = LEVEL_M;
max_cw = 152;
if (symbol->option_1 == 1) {
strcpy(symbol->errtxt, "576: Error correction level L not available in rMQR");
return ZINT_ERROR_INVALID_OPTION;
}
if (symbol->option_1 == 3) {
strcpy(symbol->errtxt, "577: Error correction level Q not available in rMQR");
return ZINT_ERROR_INVALID_OPTION;
}
if (symbol->option_1 == 4) {
ecc_level = LEVEL_H;
max_cw = 76;
}
if (est_binlen > (8 * max_cw)) {
strcpy(symbol->errtxt, "578: Input too long for selected error correction level");
return ZINT_ERROR_TOO_LONG;
}
if ((symbol->option_2 < 0) || (symbol->option_2 > 38)) {
strcpy(symbol->errtxt, "579: Invalid rMQR symbol size");
return ZINT_ERROR_INVALID_OPTION;
}
version = 31; // Set default to keep compiler happy
if (symbol->option_2 == 0) {
// Automatic symbol size
autosize = 31;
best_footprint = rmqr_height[31] * rmqr_width[31];
for (version = 30; version >= 0; version--) {
est_binlen = getBinaryLength(RMQR_VERSION + version, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
footprint = rmqr_height[version] * rmqr_width[version];
if (ecc_level == LEVEL_M) {
if (8 * rmqr_data_codewords_M[version] >= est_binlen) {
if (footprint < best_footprint) {
autosize = version;
best_footprint = footprint;
}
}
} else {
if (8 * rmqr_data_codewords_H[version] >= est_binlen) {
if (footprint < best_footprint) {
autosize = version;
best_footprint = footprint;
}
}
}
}
version = autosize;
est_binlen = getBinaryLength(RMQR_VERSION + version, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
}
if ((symbol->option_2 >= 1) && (symbol->option_2 <= 32)) {
// User specified symbol size
version = symbol->option_2 - 1;
est_binlen = getBinaryLength(RMQR_VERSION + version, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
}
if (symbol->option_2 >= 33) {
// User has specified symbol height only
version = rmqr_fixed_height_upper_bound[symbol->option_2 - 32];
for(i = version - 1; i > rmqr_fixed_height_upper_bound[symbol->option_2 - 33]; i--) {
est_binlen = getBinaryLength(RMQR_VERSION + i, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
if (ecc_level == LEVEL_M) {
if (8 * rmqr_data_codewords_M[i] >= est_binlen) {
version = i;
}
} else {
if (8 * rmqr_data_codewords_H[i] >= est_binlen) {
version = i;
}
}
}
est_binlen = getBinaryLength(RMQR_VERSION + version, mode, jisdata, length, gs1, 0 /*eci*/, symbol->debug);
}
if (symbol->option_1 == -1) {
// Detect if there is enough free space to increase ECC level
if (est_binlen < (rmqr_data_codewords_H[version] * 8)) {
ecc_level = LEVEL_H;
}
}
if (ecc_level == LEVEL_M) {
target_codewords = rmqr_data_codewords_M[version];
blocks = rmqr_blocks_M[version];
} else {
target_codewords = rmqr_data_codewords_H[version];
blocks = rmqr_blocks_H[version];
}
if (est_binlen > (target_codewords * 8)) {
// User has selected a symbol too small for the data
strcpy(symbol->errtxt, "580: Input too long for selected symbol size");
return ZINT_ERROR_TOO_LONG;
}
if (symbol->debug & ZINT_DEBUG_PRINT) {
printf("Minimum codewords = %d\n", est_binlen / 8);
printf("Selected version: %d = R%dx%d-", (version + 1), rmqr_height[version], rmqr_width[version]);
if (ecc_level == LEVEL_M) {
printf("M\n");
} else {
printf("H\n");
}
printf("Number of data codewords in symbol = %d\n", target_codewords);
printf("Number of ECC blocks = %d\n", blocks);
}
#ifndef _MSC_VER
unsigned char datastream[target_codewords + 1];
unsigned char fullstream[rmqr_total_codewords[version] + 1];
#else
datastream = (unsigned char *) _alloca((target_codewords + 1) * sizeof (unsigned char));
fullstream = (unsigned char *) _alloca((rmqr_total_codewords[version] + 1) * sizeof (unsigned char));
#endif
qr_binary(datastream, RMQR_VERSION + version, target_codewords, mode, jisdata, length, gs1, 0 /*eci*/, est_binlen, symbol->debug);
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, datastream, target_codewords);
add_ecc(fullstream, datastream, RMQR_VERSION + version, target_codewords, blocks, symbol->debug);
h_size = rmqr_width[version];
v_size = rmqr_height[version];
#ifndef _MSC_VER
unsigned char grid[h_size * v_size];
#else
grid = (unsigned char *) _alloca((h_size * v_size) * sizeof (unsigned char));
#endif
for (i = 0; i < v_size; i++) {
for (j = 0; j < h_size; j++) {
grid[(i * h_size) + j] = 0;
}
}
setup_rmqr_grid(grid, h_size, v_size, version);
populate_grid(grid, h_size, v_size, fullstream, rmqr_total_codewords[version]);
/* apply bitmask */
for (i = 0; i < v_size; i++) {
for (j = 0; j < h_size; j++) {
if ((grid[(i * h_size) + j] & 0xf0) == 0) {
// This is a data module
if (((i / 2) + (j / 3)) % 2 == 0) { // < This is the data mask from section 7.8.2
// This module needs to be changed
if (grid[(i * h_size) + j] == 0x01) {
grid[(i * h_size) + j] = 0x00;
} else {
grid[(i * h_size) + j] = 0x01;
}
}
}
}
}
/* add format information */
format_data = version;
if (ecc_level == LEVEL_H) {
format_data += 32;
}
left_format_info = rmqr_format_info_left[format_data];
right_format_info = rmqr_format_info_right[format_data];
for (i = 0; i < 5; i++) {
for (j = 0; j < 3; j++) {
grid[(h_size * (i + 1)) + j + 8] = (left_format_info >> ((j * 5) + i)) & 0x01;
grid[(h_size * (v_size - 6)) + (h_size * i) + j + (h_size - 8)] = (right_format_info >> ((j * 5) + i)) & 0x01;
}
}
grid[(h_size * 1) + 11] = (left_format_info >> 15) & 0x01;
grid[(h_size * 2) + 11] = (left_format_info >> 16) & 0x01;
grid[(h_size * 3) + 11] = (left_format_info >> 17) & 0x01;
grid[(h_size * (v_size - 6)) + (h_size - 5)] = (right_format_info >> 15) & 0x01;
grid[(h_size * (v_size - 6)) + (h_size - 4)] = (right_format_info >> 16) & 0x01;
grid[(h_size * (v_size - 6)) + (h_size - 3)] = (right_format_info >> 17) & 0x01;
symbol->width = h_size;
symbol->rows = v_size;
for (i = 0; i < v_size; i++) {
for (j = 0; j < h_size; j++) {
if (grid[(i * h_size) + j] & 0x01) {
set_module(symbol, i, j);
}
}
symbol->row_height[i] = 1;
}
return 0;
}