zint/backend/hanxin.c

1660 lines
54 KiB
C

/* hanxin.c - Han Xin Code
libzint - the open source barcode library
Copyright (C) 2009-2020 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 : */
/* This code attempts to implement Han Xin Code according to ISO/IEC 20830 (draft 2019-10-10)
* (previously AIMD-015:2010 (Rev 0.8)) */
#include <stdio.h>
#ifdef _MSC_VER
#include <malloc.h>
#endif
#include "common.h"
#include "reedsol.h"
#include "hanxin.h"
#include "gb2312.h"
#include "gb18030.h"
#include "assert.h"
/* Find which submode to use for a text character */
static int getsubmode(const unsigned int input) {
if ((input >= '0') && (input <= '9')) {
return 1;
}
if ((input >= 'A') && (input <= 'Z')) {
return 1;
}
if ((input >= 'a') && (input <= 'z')) {
return 1;
}
return 2;
}
/* Return length of terminator for encoding mode */
static int terminator_length(const char mode) {
int result = 0;
switch (mode) {
case 'n':
result = 10;
break;
case 't':
result = 6;
break;
case '1':
case '2':
result = 12;
break;
case 'd':
result = 15;
break;
}
return result;
}
/* Calculate the length of the binary string */
static int calculate_binlength(const char mode[], const unsigned int source[], const int length, const int eci) {
int i;
char lastmode = '\0';
int est_binlen = 0;
int submode = 1;
int numeric_run = 0;
if (eci != 0) {
est_binlen += 4;
if (eci <= 127) {
est_binlen += 8;
} else if (eci <= 16383) {
est_binlen += 16;
} else {
est_binlen += 24;
}
}
i = 0;
do {
if (mode[i] != lastmode) {
if (i > 0) {
est_binlen += terminator_length(lastmode);
}
/* GB 4-byte has indicator for each character (and no terminator) so not included here */
/* Region1/Region2 have special terminator to go directly into each other's mode so not included here */
if (mode[i] != 'f' || ((mode[i] == '1' && lastmode == '2') || (mode[i] == '2' && lastmode == '1'))) {
est_binlen += 4;
}
if (mode[i] == 'b') { /* Byte mode has byte count (and no terminator) */
est_binlen += 13;
}
lastmode = mode[i];
submode = 1;
numeric_run = 0;
}
switch (mode[i]) {
case 'n':
if (numeric_run % 3 == 0) {
est_binlen += 10;
}
numeric_run++;
break;
case 't':
if (getsubmode(source[i]) != submode) {
est_binlen += 6;
submode = getsubmode(source[i]);
}
est_binlen += 6;
break;
case 'b':
est_binlen += source[i] > 0xFF ? 16 : 8;
break;
case '1':
case '2':
est_binlen += 12;
break;
case 'd':
est_binlen += 15;
break;
case 'f':
est_binlen += 25;
i++;
break;
}
i++;
} while (i < length);
est_binlen += terminator_length(lastmode);
return est_binlen;
}
static int isRegion1(const unsigned int glyph) {
unsigned int byte;
byte = glyph >> 8;
if ((byte >= 0xb0) && (byte <= 0xd7)) {
byte = glyph & 0xff;
if ((byte >= 0xa1) && (byte <= 0xfe)) {
return 1;
}
} else if ((byte >= 0xa1) && (byte <= 0xa3)) {
byte = glyph & 0xff;
if ((byte >= 0xa1) && (byte <= 0xfe)) {
return 1;
}
} else if ((glyph >= 0xa8a1) && (glyph <= 0xa8c0)) {
return 1;
}
return 0;
}
static int isRegion2(const unsigned int glyph) {
unsigned int byte;
byte = glyph >> 8;
if ((byte >= 0xd8) && (byte <= 0xf7)) {
byte = glyph & 0xff;
if ((byte >= 0xa1) && (byte <= 0xfe)) {
return 1;
}
}
return 0;
}
static int isDoubleByte(const unsigned int glyph) {
unsigned int byte;
byte = glyph >> 8;
if ((byte >= 0x81) && (byte <= 0xfe)) {
byte = glyph & 0xff;
if ((byte >= 0x40) && (byte <= 0x7e)) {
return 1;
}
if ((byte >= 0x80) && (byte <= 0xfe)) {
return 1;
}
}
return 0;
}
static int isFourByte(const unsigned int glyph, const unsigned int glyph2) {
unsigned int byte;
byte = glyph >> 8;
if ((byte >= 0x81) && (byte <= 0xfe)) {
byte = glyph & 0xff;
if ((byte >= 0x30) && (byte <= 0x39)) {
byte = glyph2 >> 8;
if ((byte >= 0x81) && (byte <= 0xfe)) {
byte = glyph2 & 0xff;
if ((byte >= 0x30) && (byte <= 0x39)) {
return 1;
}
}
}
}
return 0;
}
/* Convert Text 1 sub-mode character to encoding value, as given in table 3 */
static int lookup_text1(const unsigned int input) {
if ((input >= '0') && (input <= '9')) {
return input - '0';
}
if ((input >= 'A') && (input <= 'Z')) {
return input - 'A' + 10;
}
if ((input >= 'a') && (input <= 'z')) {
return input - 'a' + 36;
}
return -1;
}
/* Convert Text 2 sub-mode character to encoding value, as given in table 4 */
static int lookup_text2(const unsigned int input) {
if (input <= 27) {
return input;
}
if ((input >= ' ') && (input <= '/')) {
return input - ' ' + 28;
}
if ((input >= ':') && (input <= '@')) {
return input - ':' + 44;
}
if ((input >= '[') && (input <= 96)) {
return input - '[' + 51;
}
if ((input >= '{') && (input <= 127)) {
return input - '{' + 57;
}
return -1;
}
/* hx_define_mode() stuff */
/* Bits multiplied by this for costs, so as to be whole integer divisible by 2 and 3 */
#define HX_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 gbdata[], const int length, const int in_posn,
unsigned int *p_end, unsigned int *p_cost) {
int i, digit_cnt;
if (in_posn < (int) *p_end) {
return 1;
}
/* Attempt to calculate the average 'cost' of using numeric mode in number of bits (times HX_MULT) */
for (i = in_posn; i < length && i < in_posn + 4 && gbdata[i] >= '0' && gbdata[i] <= '9'; i++);
digit_cnt = i - in_posn;
if (digit_cnt == 0) {
*p_end = 0;
return 0;
}
*p_end = i;
*p_cost = digit_cnt == 1 ? 60 /* 10 * HX_MULT */ : digit_cnt == 2 ? 30 /* (10 / 2) * HX_MULT */ : 20 /* (10 / 3) * HX_MULT */;
return 1;
}
/* Whether in four-byte or not. If in four-byte, *p_fourbyte is set to position after four-byte,
* and *p_fourbyte_cost is set to per-position cost */
static int in_fourbyte(const unsigned int gbdata[], const int length, const int in_posn,
unsigned int *p_end, unsigned int *p_cost) {
if (in_posn < (int) *p_end) {
return 1;
}
if (in_posn == length - 1 || !isFourByte(gbdata[in_posn], gbdata[in_posn + 1])) {
*p_end = 0;
return 0;
}
*p_end = in_posn + 2;
*p_cost = 75; /* ((4 + 21) / 2) * HX_MULT */
return 1;
}
/* Indexes into mode_types array */
#define HX_N 0 /* Numeric */
#define HX_T 1 /* Text */
#define HX_B 2 /* Binary */
#define HX_1 3 /* Common Chinese Region One */
#define HX_2 4 /* Common Chinese Region Two */
#define HX_D 5 /* GB 18030 2-byte Region */
#define HX_F 6 /* GB 18030 4-byte Region */
/* Note Unicode, GS1 and URI modes not implemented */
#define HX_NUM_MODES 7
/* Calculate optimized encoding modes. Adapted from Project Nayuki */
/* Copyright (c) Project Nayuki. (MIT License) See qr.c for detailed notice */
static void hx_define_mode(char *mode, const unsigned int gbdata[], const int length, const int debug) {
/* Must be in same order as HX_N etc */
static const char mode_types[] = { 'n', 't', 'b', '1', '2', 'd', 'f', '\0' };
/* Initial mode costs */
static unsigned int head_costs[HX_NUM_MODES] = {
/* N T B 1 2 D F */
4 * HX_MULT, 4 * HX_MULT, (4 + 13) * HX_MULT, 4 * HX_MULT, 4 * HX_MULT, 4 * HX_MULT, 0
};
/* Cost of switching modes from k to j */
static const unsigned int switch_costs[HX_NUM_MODES][HX_NUM_MODES] = {
/* N T B 1 2 D F */
/*N*/ { 0, (10 + 4) * HX_MULT, (10 + 4 + 13) * HX_MULT, (10 + 4) * HX_MULT, (10 + 4) * HX_MULT, (10 + 4) * HX_MULT, 10 * HX_MULT },
/*T*/ { (6 + 4) * HX_MULT, 0, (6 + 4 + 13) * HX_MULT, (6 + 4) * HX_MULT, (6 + 4) * HX_MULT, (6 + 4) * HX_MULT, 6 * HX_MULT },
/*B*/ { 4 * HX_MULT, 4 * HX_MULT, 0, 4 * HX_MULT, 4 * HX_MULT, 4 * HX_MULT, 0 },
/*1*/ { (12 + 4) * HX_MULT, (12 + 4) * HX_MULT, (12 + 4 + 13) * HX_MULT, 0, 12 * HX_MULT, (12 + 4) * HX_MULT, 12 * HX_MULT },
/*2*/ { (12 + 4) * HX_MULT, (12 + 4) * HX_MULT, (12 + 4 + 13) * HX_MULT, 12 * HX_MULT, 0, (12 + 4) * HX_MULT, 12 * HX_MULT },
/*D*/ { (15 + 4) * HX_MULT, (15 + 4) * HX_MULT, (15 + 4 + 13) * HX_MULT, (15 + 4) * HX_MULT, (15 + 4) * HX_MULT, 0, 15 * HX_MULT },
/*F*/ { 4 * HX_MULT, 4 * HX_MULT, (4 + 13) * HX_MULT, 4 * HX_MULT, 4 * HX_MULT, 4 * HX_MULT, 0 },
};
/* Final end-of-data costs */
static const unsigned int eod_costs[HX_NUM_MODES] = {
/* N T B 1 2 D F */
10 * HX_MULT, 6 * HX_MULT, 0, 12 * HX_MULT, 12 * HX_MULT, 15 * HX_MULT, 0
};
unsigned int numeric_end = 0, numeric_cost = 0, text_submode = 1, fourbyte_end = 0, fourbyte_cost = 0; /* State */
int text1, text2;
int i, j, k, cm_i;
unsigned int min_cost;
char cur_mode;
unsigned int prev_costs[HX_NUM_MODES];
unsigned int cur_costs[HX_NUM_MODES];
#ifndef _MSC_VER
char char_modes[length * HX_NUM_MODES];
#else
char *char_modes = (char *) _alloca(length * HX_NUM_MODES);
#endif
/* char_modes[i * HX_NUM_MODES + j] represents the mode to encode the code point at index i such that the final
* segment ends in mode_types[j] and the total number of bits is minimized over all possible choices */
memset(char_modes, 0, length * HX_NUM_MODES);
/* At the beginning of each iteration of the loop below, prev_costs[j] is the minimum number of 1/6 (1/XX_MULT)
* bits needed to encode the entire string prefix of length i, and end in mode_types[j] */
memcpy(prev_costs, head_costs, HX_NUM_MODES * sizeof(unsigned int));
/* Calculate costs using dynamic programming */
for (i = 0, cm_i = 0; i < length; i++, cm_i += HX_NUM_MODES) {
memset(cur_costs, 0, HX_NUM_MODES * sizeof(unsigned int));
if (in_numeric(gbdata, length, i, &numeric_end, &numeric_cost)) {
cur_costs[HX_N] = prev_costs[HX_N] + numeric_cost;
char_modes[cm_i + HX_N] = 'n';
}
text1 = lookup_text1(gbdata[i]) != -1;
text2 = lookup_text2(gbdata[i]) != -1;
if (text1 || text2) {
if ((text_submode == 1 && text2) || (text_submode == 2 && text1)) {
cur_costs[HX_T] = prev_costs[HX_T] + 72; /* (6 + 6) * HX_MULT */
text_submode = text2 ? 2 : 1;
} else {
cur_costs[HX_T] = prev_costs[HX_T] + 36; /* 6 * HX_MULT */
}
char_modes[cm_i + HX_T] = 't';
} else {
text_submode = 1;
}
/* Binary mode can encode anything */
cur_costs[HX_B] = prev_costs[HX_B] + (gbdata[i] > 0xFF ? 96 : 48); /* (16 : 8) * HX_MULT */
char_modes[cm_i + HX_B] = 'b';
if (isRegion1(gbdata[i])) {
cur_costs[HX_1] = prev_costs[HX_1] + 72; /* 12 * HX_MULT */
char_modes[cm_i + HX_1] = '1';
}
if (isRegion2(gbdata[i])) {
cur_costs[HX_2] = prev_costs[HX_2] + 72; /* 12 * HX_MULT */
char_modes[cm_i + HX_2] = '2';
}
if (isDoubleByte(gbdata[i])) {
cur_costs[HX_D] = prev_costs[HX_D] + 90; /* 15 * HX_MULT */
char_modes[cm_i + HX_D] = 'd';
}
if (in_fourbyte(gbdata, length, i, &fourbyte_end, &fourbyte_cost)) {
cur_costs[HX_F] = prev_costs[HX_F] + fourbyte_cost;
char_modes[cm_i + HX_F] = 'f';
}
if (i == length - 1) { /* Add end of data costs if last character */
for (j = 0; j < HX_NUM_MODES; j++) {
if (char_modes[cm_i + j]) {
cur_costs[j] += eod_costs[j];
}
}
}
/* Start new segment at the end to switch modes */
for (j = 0; j < HX_NUM_MODES; j++) { /* To mode */
for (k = 0; k < HX_NUM_MODES; k++) { /* From mode */
if (j != k && char_modes[cm_i + k]) {
unsigned int new_cost = cur_costs[k] + switch_costs[k][j];
if (!char_modes[cm_i + j] || new_cost < cur_costs[j]) {
cur_costs[j] = new_cost;
char_modes[cm_i + j] = mode_types[k];
}
}
}
}
memcpy(prev_costs, cur_costs, HX_NUM_MODES * sizeof(unsigned int));
}
/* Find optimal ending mode */
min_cost = prev_costs[0];
cur_mode = mode_types[0];
for (i = 1; i < HX_NUM_MODES; i++) {
if (prev_costs[i] < min_cost) {
min_cost = prev_costs[i];
cur_mode = mode_types[i];
}
}
/* Get optimal mode for each code point by tracing backwards */
for (i = length - 1, cm_i = i * HX_NUM_MODES; i >= 0; i--, cm_i -= HX_NUM_MODES) {
j = strchr(mode_types, cur_mode) - mode_types;
cur_mode = char_modes[cm_i + j];
mode[i] = cur_mode;
}
if (debug & ZINT_DEBUG_PRINT) {
printf(" Mode: %.*s\n", length, mode);
}
}
/* Convert input data to binary stream */
static void calculate_binary(char binary[], const char mode[], unsigned int source[], const int length, const int eci,
int *bin_len, const int debug) {
int position = 0;
int i, count, encoding_value;
int first_byte, second_byte;
int third_byte, fourth_byte;
int glyph;
int submode;
int bp = 0;
if (eci != 0) {
/* Encoding ECI assignment number, according to Table 5 */
bp = bin_append_posn(8, 4, binary, bp); // ECI
if (eci <= 127) {
bp = bin_append_posn(eci, 8, binary, bp);
} else if (eci <= 16383) {
bp = bin_append_posn(2, 2, binary, bp);
bp = bin_append_posn(eci, 14, binary, bp);
} else {
bp = bin_append_posn(6, 3, binary, bp);
bp = bin_append_posn(eci, 21, binary, bp);
}
}
do {
int block_length = 0;
int double_byte = 0;
do {
if (mode[position] == 'b' && source[position + block_length] > 0xFF) {
double_byte++;
}
block_length++;
} while (position + block_length < length && mode[position + block_length] == mode[position]);
switch (mode[position]) {
case 'n':
/* Numeric mode */
/* Mode indicator */
bp = bin_append_posn(1, 4, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("Numeric\n");
}
count = 0; /* Suppress gcc -Wmaybe-uninitialized */
i = 0;
while (i < block_length) {
int first = 0;
first = posn(NEON, (char) source[position + i]);
count = 1;
encoding_value = first;
if (i + 1 < block_length && mode[position + i + 1] == 'n') {
int second = posn(NEON, (char) source[position + i + 1]);
count = 2;
encoding_value = (encoding_value * 10) + second;
if (i + 2 < block_length && mode[position + i + 2] == 'n') {
int third = posn(NEON, (char) source[position + i + 2]);
count = 3;
encoding_value = (encoding_value * 10) + third;
}
}
bp = bin_append_posn(encoding_value, 10, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("0x%3x (%d)", encoding_value, encoding_value);
}
i += count;
}
/* Mode terminator depends on number of characters in last group (Table 2) */
switch (count) {
case 1:
bp = bin_append_posn(1021, 10, binary, bp);
break;
case 2:
bp = bin_append_posn(1022, 10, binary, bp);
break;
case 3:
bp = bin_append_posn(1023, 10, binary, bp);
break;
}
if (debug & ZINT_DEBUG_PRINT) {
printf(" (TERM %d)\n", count);
}
break;
case 't':
/* Text mode */
/* Mode indicator */
bp = bin_append_posn(2, 4, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("Text\n");
}
submode = 1;
i = 0;
while (i < block_length) {
if (getsubmode(source[i + position]) != submode) {
/* Change submode */
bp = bin_append_posn(62, 6, binary, bp);
submode = getsubmode(source[i + position]);
if (debug & ZINT_DEBUG_PRINT) {
printf("SWITCH ");
}
}
if (submode == 1) {
encoding_value = lookup_text1(source[i + position]);
} else {
encoding_value = lookup_text2(source[i + position]);
}
bp = bin_append_posn(encoding_value, 6, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("%.2x [ASC %.2x] ", encoding_value, source[i + position]);
}
i++;
}
/* Terminator */
bp = bin_append_posn(63, 6, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case 'b':
/* Binary Mode */
/* Mode indicator */
bp = bin_append_posn(3, 4, binary, bp);
/* Count indicator */
bp = bin_append_posn(block_length + double_byte, 13, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("Binary (length %d)\n", block_length + double_byte);
}
i = 0;
while (i < block_length) {
/* 8-bit bytes with no conversion */
bp = bin_append_posn(source[i + position], source[i + position] > 0xFF ? 16 : 8, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("%d ", source[i + position]);
}
i++;
}
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case '1':
/* Region 1 encoding */
/* Mode indicator */
if (position == 0 || mode[position - 1] != '2') { /* Unless previous mode Region 2 */
bp = bin_append_posn(4, 4, binary, bp);
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Region 1%s\n", position == 0 || mode[position - 1] != '2' ? "" : " (NO indicator)" );
}
i = 0;
while (i < block_length) {
first_byte = (source[i + position] & 0xff00) >> 8;
second_byte = source[i + position] & 0xff;
/* Subset 1 */
glyph = (0x5e * (first_byte - 0xb0)) + (second_byte - 0xa1);
/* Subset 2 */
if ((first_byte >= 0xa1) && (first_byte <= 0xa3)) {
if ((second_byte >= 0xa1) && (second_byte <= 0xfe)) {
glyph = (0x5e * (first_byte - 0xa1)) + (second_byte - 0xa1) + 0xeb0;
}
}
/* Subset 3 */
if ((source[i + position] >= 0xa8a1) && (source[i + position] <= 0xa8c0)) {
glyph = (second_byte - 0xa1) + 0xfca;
}
if (debug & ZINT_DEBUG_PRINT) {
printf("%.3x [GB %.4x] ", glyph, source[i + position]);
}
bp = bin_append_posn(glyph, 12, binary, bp);
i++;
}
/* Terminator */
bp = bin_append_posn(position + block_length == length || mode[position + block_length] != '2' ? 4095 : 4094, 12, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("(TERM %x)\n", position + block_length == length || mode[position + block_length] != '2' ? 4095 : 4094);
}
break;
case '2':
/* Region 2 encoding */
/* Mode indicator */
if (position == 0 || mode[position - 1] != '1') { /* Unless previous mode Region 1 */
bp = bin_append_posn(5, 4, binary, bp);
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Region 2%s\n", position == 0 || mode[position - 1] != '1' ? "" : " (NO indicator)" );
}
i = 0;
while (i < block_length) {
first_byte = (source[i + position] & 0xff00) >> 8;
second_byte = source[i + position] & 0xff;
glyph = (0x5e * (first_byte - 0xd8)) + (second_byte - 0xa1);
if (debug & ZINT_DEBUG_PRINT) {
printf("%.3x [GB %.4x] ", glyph, source[i + position]);
}
bp = bin_append_posn(glyph, 12, binary, bp);
i++;
}
/* Terminator */
bp = bin_append_posn(position + block_length == length || mode[position + block_length] != '1' ? 4095 : 4094, 12, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("(TERM %x)\n", position + block_length == length || mode[position + block_length] != '1' ? 4095 : 4094);
}
break;
case 'd':
/* Double byte encoding */
/* Mode indicator */
bp = bin_append_posn(6, 4, binary, bp);
if (debug & ZINT_DEBUG_PRINT) {
printf("Double byte\n");
}
i = 0;
while (i < block_length) {
first_byte = (source[i + position] & 0xff00) >> 8;
second_byte = source[i + position] & 0xff;
if (second_byte <= 0x7e) {
glyph = (0xbe * (first_byte - 0x81)) + (second_byte - 0x40);
} else {
glyph = (0xbe * (first_byte - 0x81)) + (second_byte - 0x41);
}
if (debug & ZINT_DEBUG_PRINT) {
printf("%.4x ", glyph);
}
bp = bin_append_posn(glyph, 15, binary, bp);
i++;
}
/* Terminator */
bp = bin_append_posn(32767, 15, binary, bp);
/* Terminator sequence of length 12 is a mistake
- confirmed by Wang Yi */
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
case 'f':
/* Four-byte encoding */
if (debug & ZINT_DEBUG_PRINT) {
printf("Four byte\n");
}
i = 0;
while (i < block_length) {
/* Mode indicator */
bp = bin_append_posn(7, 4, binary, bp);
first_byte = (source[i + position] & 0xff00) >> 8;
second_byte = source[i + position] & 0xff;
third_byte = (source[i + position + 1] & 0xff00) >> 8;
fourth_byte = source[i + position + 1] & 0xff;
glyph = (0x3138 * (first_byte - 0x81)) + (0x04ec * (second_byte - 0x30)) +
(0x0a * (third_byte - 0x81)) + (fourth_byte - 0x30);
if (debug & ZINT_DEBUG_PRINT) {
printf("%d ", glyph);
}
bp = bin_append_posn(glyph, 21, binary, bp);
i += 2;
}
/* No terminator */
if (debug & ZINT_DEBUG_PRINT) {
printf("\n");
}
break;
}
position += block_length;
} while (position < length);
binary[bp] = '\0';
if (debug & ZINT_DEBUG_PRINT) printf("Binary (%d): %s\n", bp, binary);
*bin_len = bp;
}
/* Finder pattern for top left of symbol */
static void hx_place_finder_top_left(unsigned char *grid, const int size) {
int xp, yp;
int x = 0, y = 0;
char finder[] = {0x7F, 0x40, 0x5F, 0x50, 0x57, 0x57, 0x57};
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;
}
}
}
}
/* Finder pattern for top right and bottom left of symbol */
static void hx_place_finder(unsigned char *grid, const int size, const int x, const int y) {
int xp, yp;
char finder[] = {0x7F, 0x01, 0x7D, 0x05, 0x75, 0x75, 0x75};
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;
}
}
}
}
/* Finder pattern for bottom right of symbol */
static void hx_place_finder_bottom_right(unsigned char *grid, const int size) {
int xp, yp;
int x = size - 7, y = size - 7;
char finder[] = {0x75, 0x75, 0x75, 0x05, 0x7D, 0x01, 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;
}
}
}
}
/* Avoid plotting outside symbol or over finder patterns */
static void hx_safe_plot(unsigned char *grid, const int size, const int x, const int y, const int value) {
if ((x >= 0) && (x < size)) {
if ((y >= 0) && (y < size)) {
if (grid[(y * size) + x] == 0) {
grid[(y * size) + x] = value;
}
}
}
}
/* Plot an alignment pattern around top and right of a module */
static void hx_plot_alignment(unsigned char *grid, const int size, const int x, const int y, const int w, const int h) {
int i;
hx_safe_plot(grid, size, x, y, 0x11);
hx_safe_plot(grid, size, x - 1, y + 1, 0x10);
for (i = 1; i <= w; i++) {
/* Top */
hx_safe_plot(grid, size, x - i, y, 0x11);
hx_safe_plot(grid, size, x - i - 1, y + 1, 0x10);
}
for (i = 1; i < h; i++) {
/* Right */
hx_safe_plot(grid, size, x, y + i, 0x11);
hx_safe_plot(grid, size, x - 1, y + i + 1, 0x10);
}
}
/* Plot assistant alignment patterns */
static void hx_plot_assistant(unsigned char *grid, const int size, const int x, const int y) {
hx_safe_plot(grid, size, x - 1, y - 1, 0x10);
hx_safe_plot(grid, size, x, y - 1, 0x10);
hx_safe_plot(grid, size, x + 1, y - 1, 0x10);
hx_safe_plot(grid, size, x - 1, y, 0x10);
hx_safe_plot(grid, size, x, y, 0x11);
hx_safe_plot(grid, size, x + 1, y, 0x10);
hx_safe_plot(grid, size, x - 1, y + 1, 0x10);
hx_safe_plot(grid, size, x, y + 1, 0x10);
hx_safe_plot(grid, size, x + 1, y + 1, 0x10);
}
/* Put static elements in the grid */
static void hx_setup_grid(unsigned char *grid, const int size, const int version) {
int i;
memset(grid, 0, (size_t) size * size);
/* Add finder patterns */
hx_place_finder_top_left(grid, size);
hx_place_finder(grid, size, 0, size - 7);
hx_place_finder(grid, size, size - 7, 0);
hx_place_finder_bottom_right(grid, size);
/* Add finder pattern separator region */
for (i = 0; i < 8; i++) {
/* Top left */
grid[(7 * size) + i] = 0x10;
grid[(i * size) + 7] = 0x10;
/* Top right */
grid[(7 * size) + (size - i - 1)] = 0x10;
grid[((size - i - 1) * size) + 7] = 0x10;
/* Bottom left */
grid[(i * size) + (size - 8)] = 0x10;
grid[((size - 8) * size) + i] = 0x10;
/* Bottom right */
grid[((size - 8) * size) + (size - i - 1)] = 0x10;
grid[((size - i - 1) * size) + (size - 8)] = 0x10;
}
/* Reserve function information region */
for (i = 0; i < 9; i++) {
/* Top left */
grid[(8 * size) + i] = 0x10;
grid[(i * size) + 8] = 0x10;
/* Top right */
grid[(8 * size) + (size - i - 1)] = 0x10;
grid[((size - i - 1) * size) + 8] = 0x10;
/* Bottom left */
grid[(i * size) + (size - 9)] = 0x10;
grid[((size - 9) * size) + i] = 0x10;
/* Bottom right */
grid[((size - 9) * size) + (size - i - 1)] = 0x10;
grid[((size - i - 1) * size) + (size - 9)] = 0x10;
}
if (version > 3) {
int k = hx_module_k[version - 1];
int r = hx_module_r[version - 1];
int m = hx_module_m[version - 1];
int x, y, row_switch, column_switch;
int module_height, module_width;
int mod_x, mod_y;
/* Add assistant alignment patterns to left and right */
y = 0;
mod_y = 0;
do {
if (mod_y < m) {
module_height = k;
} else {
module_height = r - 1;
}
if ((mod_y & 1) == 0) {
if ((m & 1) == 1) {
hx_plot_assistant(grid, size, 0, y);
}
} else {
if ((m & 1) == 0) {
hx_plot_assistant(grid, size, 0, y);
}
hx_plot_assistant(grid, size, size - 1, y);
}
mod_y++;
y += module_height;
} while (y < size);
/* Add assistant alignment patterns to top and bottom */
x = (size - 1);
mod_x = 0;
do {
if (mod_x < m) {
module_width = k;
} else {
module_width = r - 1;
}
if ((mod_x & 1) == 0) {
if ((m & 1) == 1) {
hx_plot_assistant(grid, size, x, (size - 1));
}
} else {
if ((m & 1) == 0) {
hx_plot_assistant(grid, size, x, (size - 1));
}
hx_plot_assistant(grid, size, x, 0);
}
mod_x++;
x -= module_width;
} while (x >= 0);
/* Add alignment pattern */
column_switch = 1;
y = 0;
mod_y = 0;
do {
if (mod_y < m) {
module_height = k;
} else {
module_height = r - 1;
}
if (column_switch == 1) {
row_switch = 1;
column_switch = 0;
} else {
row_switch = 0;
column_switch = 1;
}
x = (size - 1);
mod_x = 0;
do {
if (mod_x < m) {
module_width = k;
} else {
module_width = r - 1;
}
if (row_switch == 1) {
if (!(y == 0 && x == (size - 1))) {
hx_plot_alignment(grid, size, x, y, module_width, module_height);
}
row_switch = 0;
} else {
row_switch = 1;
}
mod_x++;
x -= module_width;
} while (x >= 0);
mod_y++;
y += module_height;
} while (y < size);
}
}
/* Calculate error correction codes */
static void hx_add_ecc(unsigned char fullstream[], const unsigned char datastream[], const int data_codewords,
const int version, const int ecc_level) {
unsigned char data_block[180];
unsigned char ecc_block[36];
int i, j, block;
int input_position = -1;
int output_position = -1;
int table_d1_pos = ((version - 1) * 36) + ((ecc_level - 1) * 9);
rs_t rs;
rs_init_gf(&rs, 0x163); // x^8 + x^6 + x^5 + x + 1 = 0
for (i = 0; i < 3; i++) {
int batch_size = hx_table_d1[table_d1_pos + (3 * i)];
int data_length = hx_table_d1[table_d1_pos + (3 * i) + 1];
int ecc_length = hx_table_d1[table_d1_pos + (3 * i) + 2];
rs_init_code(&rs, ecc_length, 1);
for (block = 0; block < batch_size; block++) {
for (j = 0; j < data_length; j++) {
input_position++;
output_position++;
data_block[j] = input_position < data_codewords ? datastream[input_position] : 0;
fullstream[output_position] = data_block[j];
}
rs_encode(&rs, data_length, data_block, ecc_block);
for (j = 0; j < ecc_length; j++) {
output_position++;
fullstream[output_position] = ecc_block[ecc_length - j - 1];
}
}
}
}
static void hx_set_function_info(unsigned char *grid, const int size, const int version, const int ecc_level,
const int bitmask, const int debug) {
int i, j;
char function_information[34];
unsigned char fi_cw[3] = {0};
unsigned char fi_ecc[4];
int bp = 0;
rs_t rs;
/* Form function information string */
bp = bin_append_posn(version + 20, 8, function_information, bp);
bp = bin_append_posn(ecc_level - 1, 2, function_information, bp);
bp = bin_append_posn(bitmask, 2, function_information, bp);
for (i = 0; i < 3; i++) {
for (j = 0; j < 4; j++) {
if (function_information[(i * 4) + j] == '1') {
fi_cw[i] += (0x08 >> j);
}
}
}
rs_init_gf(&rs, 0x13);
rs_init_code(&rs, 4, 1);
rs_encode(&rs, 3, fi_cw, fi_ecc);
for (i = 3; i >= 0; i--) {
bp = bin_append_posn(fi_ecc[i], 4, function_information, bp);
}
/* This alternating filler pattern at end not mentioned in ISO/IEC 20830 (draft 2019-10-10) and does not appear
* in Figure 1 or the figures in Annex K but does appear in Figure 2 and Figures 4-9 */
for (i = 28; i < 34; i++) {
if (i & 1) {
function_information[i] = '1';
} else {
function_information[i] = '0';
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Version: %d, ECC: %d, Mask: %d, Structural Info: %.34s\n", version, ecc_level, bitmask, function_information);
}
/* Add function information to symbol */
for (i = 0; i < 9; i++) {
if (function_information[i] == '1') {
grid[(8 * size) + i] = 0x01;
grid[((size - 8 - 1) * size) + (size - i - 1)] = 0x01;
}
if (function_information[i + 8] == '1') {
grid[((8 - i) * size) + 8] = 0x01;
grid[((size - 8 - 1 + i) * size) + (size - 8 - 1)] = 0x01;
}
if (function_information[i + 17] == '1') {
grid[(i * size) + (size - 1 - 8)] = 0x01;
grid[((size - 1 - i) * size) + 8] = 0x01;
}
if (function_information[i + 25] == '1') {
grid[(8 * size) + (size - 1 - 8 + i)] = 0x01;
grid[((size - 1 - 8) * size) + (8 - i)] = 0x01;
}
}
}
/* Rearrange data in batches of 13 codewords (section 5.8.2) */
static void make_picket_fence(const unsigned char fullstream[], unsigned char picket_fence[], const int streamsize) {
int i, start;
int output_position = 0;
for (start = 0; start < 13; start++) {
for (i = start; i < streamsize; i += 13) {
if (i < streamsize) {
picket_fence[output_position] = fullstream[i];
output_position++;
}
}
}
}
/* Evaluate a bitmask according to table 9 */
static int hx_evaluate(const unsigned char *local, const int size) {
static const unsigned char h1010111[7] = { 1, 0, 1, 0, 1, 1, 1 };
static const unsigned char h1110101[7] = { 1, 1, 1, 0, 1, 0, 1 };
int x, y, r, block;
int result = 0;
int state;
int a, b, afterCount, beforeCount;
/* Test 1: 1:1:1:1:3 or 3:1:1:1:1 ratio pattern in row/column */
/* Vertical */
for (x = 0; x < size; x++) {
for (y = 0; y <= (size - 7); y++) {
if (local[y * size + x] && local[(y + 1) * size + x] != local[(y + 5) * size + x] &&
local[(y + 2) * size + x] && !local[(y + 3) * size + x] &&
local[(y + 4) * size + x] && local[(y + 6) * size + x]) {
/* Pattern found, check before and after */
beforeCount = 0;
for (b = (y - 1); b >= (y - 3); b--) {
if (b < 0) { /* Count < edge as whitespace */
beforeCount = 3;
break;
}
if (local[(b * size) + x]) {
break;
}
beforeCount++;
}
if (beforeCount == 3) {
/* Pattern is preceded by light area 3 modules wide */
result += 50;
} else {
afterCount = 0;
for (a = (y + 7); a <= (y + 9); a++) {
if (a >= size) { /* Count > edge as whitespace */
afterCount = 3;
break;
}
if (local[(a * size) + x]) {
break;
}
afterCount++;
}
if (afterCount == 3) {
/* Pattern is followed by light area 3 modules wide */
result += 50;
}
}
y++; /* Skip to next possible match */
}
}
}
/* Horizontal */
for (y = 0; y < size; y++) {
r = y * size;
for (x = 0; x <= (size - 7); x++) {
if (memcmp(local + r + x, h1010111, 7) == 0 || memcmp(local + r + x, h1110101, 7) == 0) {
/* Pattern found, check before and after */
beforeCount = 0;
for (b = (x - 1); b >= (x - 3); b--) {
if (b < 0) { /* Count < edge as whitespace */
beforeCount = 3;
break;
}
if (local[r + b]) {
break;
}
beforeCount++;
}
if (beforeCount == 3) {
/* Pattern is preceded by light area 3 modules wide */
result += 50;
} else {
afterCount = 0;
for (a = (x + 7); a <= (x + 9); a++) {
if (a >= size) { /* Count > edge as whitespace */
afterCount = 3;
break;
}
if (local[r + a]) {
break;
}
afterCount++;
}
if (afterCount == 3) {
/* Pattern is followed by light area 3 modules wide */
result += 50;
}
}
x++; /* Skip to next possible match */
}
}
}
/* Test 2: Adjacent modules in row/column in same colour */
/* In AIMD-15 section 5.8.3.2 it is stated... “In Table 9 below, i refers to the row
* position of the module.” - however i being the length of the run of the
* same colour (i.e. "block" below) in the same fashion as ISO/IEC 18004
* makes more sense. -- Confirmed by Wang Yi */
/* Fixed in ISO/IEC 20830 (draft 2019-10-10) section 5.8.3.2 "In Table 12 below, i refers to the modules with same color." */
/* Vertical */
for (x = 0; x < size; x++) {
block = 0;
state = 0;
for (y = 0; y < size; y++) {
if (local[(y * size) + x] == state) {
block++;
} else {
if (block >= 3) {
result += block * 4;
}
block = 1;
state = local[(y * size) + x];
}
}
if (block >= 3) {
result += block * 4;
}
}
/* Horizontal */
for (y = 0; y < size; y++) {
r = y * size;
block = 0;
state = 0;
for (x = 0; x < size; x++) {
if (local[r + x] == state) {
block++;
} else {
if (block >= 3) {
result += block * 4;
}
block = 1;
state = local[r + x];
}
}
if (block >= 3) {
result += block * 4;
}
}
return result;
}
/* Apply the four possible bitmasks for evaluation */
/* TODO: Haven't been able to replicate (or even get close to) the penalty scores in ISO/IEC 20830
* (draft 2019-10-10) Annex K examples; however they don't use alternating filler pattern on structural info */
static void hx_apply_bitmask(unsigned char *grid, const int size, const int version, const int ecc_level,
const int user_mask, const int debug) {
int x, y;
int i, j, r, k;
int pattern, penalty[4] = {0};
int best_pattern;
int bit;
int size_squared = size * size;
#ifndef _MSC_VER
unsigned char mask[size_squared];
unsigned char local[size_squared];
#else
unsigned char *mask = (unsigned char *) _alloca(size_squared * sizeof(unsigned char));
unsigned char *local = (unsigned char *) _alloca(size_squared * sizeof(unsigned char));
#endif
/* Perform data masking */
memset(mask, 0, size_squared);
for (y = 0; y < size; y++) {
r = y * size;
for (x = 0; x < size; x++) {
k = r + x;
if (!(grid[k] & 0xf0)) {
j = x + 1;
i = y + 1;
if (((i + j) & 1) == 0) {
mask[k] |= 0x02;
}
if (((((i + j) % 3) + (j % 3)) & 1) == 0) {
mask[k] |= 0x04;
}
if ((((i % j) + (j % i) + (i % 3) + (j % 3)) & 1) == 0) {
mask[k] |= 0x08;
}
}
}
}
if (user_mask) {
best_pattern = user_mask - 1;
} else {
// apply data masks to grid, result in local
/* Do null pattern 00 separately first */
pattern = 0;
for (k = 0; k < size_squared; k++) {
local[k] = grid[k] & 0x0f;
}
/* Set the Structural Info */
hx_set_function_info(local, size, version, ecc_level, pattern, 0 /*debug*/);
/* Evaluate result */
penalty[pattern] = hx_evaluate(local, size);
best_pattern = 0;
for (pattern = 1; pattern < 4; pattern++) {
bit = 1 << pattern;
for (k = 0; k < size_squared; k++) {
if (mask[k] & bit) {
local[k] = grid[k] ^ 0x01;
} else {
local[k] = grid[k] & 0x0f;
}
}
/* Set the Structural Info */
hx_set_function_info(local, size, version, ecc_level, pattern, 0 /*debug*/);
/* Evaluate result */
penalty[pattern] = hx_evaluate(local, size);
if (penalty[pattern] < penalty[best_pattern]) {
best_pattern = pattern;
}
}
}
if (debug & ZINT_DEBUG_PRINT) {
printf("Mask: %d (%s)", best_pattern, user_mask ? "specified" : "automatic");
if (!user_mask) {
for (pattern = 0; pattern < 4; pattern++) printf(" %d:%d", pattern, penalty[pattern]);
}
printf("\n");
}
/* Apply mask */
if (best_pattern) { /* If not null mask */
if (!user_mask && best_pattern == 3) { /* Reuse last */
memcpy(grid, local, size_squared);
} else {
bit = 1 << best_pattern;
for (k = 0; k < size_squared; k++) {
if (mask[k] & bit) {
grid[k] ^= 0x01;
}
}
}
}
/* Set the Structural Info */
hx_set_function_info(grid, size, version, ecc_level, best_pattern, debug);
}
/* Han Xin Code - main */
INTERNAL int han_xin(struct zint_symbol *symbol, unsigned char source[], int length) {
int est_binlen;
int ecc_level = symbol->option_1;
int i, j, j_max, version;
int full_multibyte;
int user_mask;
int data_codewords = 0, size;
int size_squared;
int codewords;
int bin_len;
#ifndef _MSC_VER
unsigned int gbdata[(length + 1) * 2];
char mode[length];
#else
unsigned int* gbdata = (unsigned int *) _alloca(((length + 1) * 2) * sizeof (unsigned int));
char *mode = (char *) _alloca(length);
char* binary;
unsigned char *datastream;
unsigned char *fullstream;
unsigned char *picket_fence;
unsigned char *grid;
#endif
/* If ZINT_FULL_MULTIBYTE set use Hanzi mode in DATA_MODE or for single-byte Latin */
full_multibyte = (symbol->option_3 & 0xFF) == ZINT_FULL_MULTIBYTE;
user_mask = (symbol->option_3 >> 8) & 0x0F; /* User mask is pattern + 1, so >= 1 and <= 4 */
if (user_mask > 4) {
user_mask = 0; /* Ignore */
}
if ((symbol->input_mode & 0x07) == DATA_MODE) {
gb18030_cpy(source, &length, gbdata, full_multibyte);
} else {
int done = 0;
if (symbol->eci != 29) { /* Unless ECI 29 (GB) */
/* Try single byte (Latin) conversion first */
int error_number = gb18030_utf8tosb(symbol->eci && symbol->eci <= 899 ? symbol->eci : 3, source, &length,
gbdata, full_multibyte);
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 GB 18030 */
int error_number = gb18030_utf8tomb(symbol, source, &length, gbdata);
if (error_number != 0) {
return error_number;
}
}
}
hx_define_mode(mode, gbdata, length, symbol->debug);
est_binlen = calculate_binlength(mode, gbdata, length, symbol->eci);
#ifndef _MSC_VER
char binary[est_binlen + 1];
#else
binary = (char *) _alloca((est_binlen + 1) * sizeof (char));
#endif
if ((ecc_level <= 0) || (ecc_level >= 5)) {
ecc_level = 1;
}
calculate_binary(binary, mode, gbdata, length, symbol->eci, &bin_len, symbol->debug);
codewords = bin_len >> 3;
if (bin_len & 0x07) {
codewords++;
}
version = 85;
for (i = 84; i > 0; i--) {
switch (ecc_level) {
case 1:
if (hx_data_codewords_L1[i - 1] > codewords) {
version = i;
data_codewords = hx_data_codewords_L1[i - 1];
}
break;
case 2:
if (hx_data_codewords_L2[i - 1] > codewords) {
version = i;
data_codewords = hx_data_codewords_L2[i - 1];
}
break;
case 3:
if (hx_data_codewords_L3[i - 1] > codewords) {
version = i;
data_codewords = hx_data_codewords_L3[i - 1];
}
break;
case 4:
if (hx_data_codewords_L4[i - 1] > codewords) {
version = i;
data_codewords = hx_data_codewords_L4[i - 1];
}
break;
default:
assert(0);
break;
}
}
if (version == 85) {
strcpy(symbol->errtxt, "541: Input too long for selected error correction level");
return ZINT_ERROR_TOO_LONG;
}
if ((symbol->option_2 < 0) || (symbol->option_2 > 84)) {
symbol->option_2 = 0;
}
if (symbol->option_2 > version) {
version = symbol->option_2;
}
if ((symbol->option_2 != 0) && (symbol->option_2 < version)) {
strcpy(symbol->errtxt, "542: Input too long for selected symbol size");
return ZINT_ERROR_TOO_LONG;
}
/* If there is spare capacity, increase the level of ECC */
if (symbol->option_1 == -1 || symbol->option_1 != ecc_level) { /* Unless explicitly specified (within min/max bounds) by user */
if ((ecc_level == 1) && (codewords < hx_data_codewords_L2[version - 1])) {
ecc_level = 2;
data_codewords = hx_data_codewords_L2[version - 1];
}
if ((ecc_level == 2) && (codewords < hx_data_codewords_L3[version - 1])) {
ecc_level = 3;
data_codewords = hx_data_codewords_L3[version - 1];
}
if ((ecc_level == 3) && (codewords < hx_data_codewords_L4[version - 1])) {
ecc_level = 4;
data_codewords = hx_data_codewords_L4[version - 1];
}
}
size = (version * 2) + 21;
size_squared = size * size;
#ifndef _MSC_VER
unsigned char datastream[data_codewords];
unsigned char fullstream[hx_total_codewords[version - 1]];
unsigned char picket_fence[hx_total_codewords[version - 1]];
unsigned char grid[size_squared];
#else
datastream = (unsigned char *) _alloca((data_codewords) * sizeof (unsigned char));
fullstream = (unsigned char *) _alloca((hx_total_codewords[version - 1]) * sizeof (unsigned char));
picket_fence = (unsigned char *) _alloca((hx_total_codewords[version - 1]) * sizeof (unsigned char));
grid = (unsigned char *) _alloca(size_squared * sizeof(unsigned char));
#endif
memset(datastream, 0, data_codewords);
for (i = 0; i < bin_len; i++) {
if (binary[i] == '1') {
datastream[i >> 3] |= 0x80 >> (i & 0x07);
}
}
if (symbol->debug & ZINT_DEBUG_PRINT) {
printf("Datastream length: %d\n", data_codewords);
printf("Datastream:\n");
for (i = 0; i < data_codewords; i++) {
printf("%.2x ", datastream[i]);
}
printf("\n");
}
#ifdef ZINT_TEST
if (symbol->debug & ZINT_DEBUG_TEST) debug_test_codeword_dump(symbol, datastream, data_codewords);
#endif
hx_setup_grid(grid, size, version);
hx_add_ecc(fullstream, datastream, data_codewords, version, ecc_level);
make_picket_fence(fullstream, picket_fence, hx_total_codewords[version - 1]);
/* Populate grid */
j = 0;
j_max = hx_total_codewords[version - 1] * 8;
for (i = 0; i < size_squared; i++) {
if (grid[i] == 0x00) {
if (j < j_max) {
if (picket_fence[(j >> 3)] & (0x80 >> (j & 0x07))) {
grid[i] = 0x01;
}
j++;
} else {
break;
}
}
}
hx_apply_bitmask(grid, size, version, ecc_level, user_mask, symbol->debug);
symbol->width = size;
symbol->rows = size;
for (i = 0; i < size; i++) {
int r = i * size;
for (j = 0; j < size; j++) {
if (grid[r + j] & 0x01) {
set_module(symbol, i, j);
}
}
symbol->row_height[i] = 1;
}
return 0;
}