/* Association between Unicode characters and their names.
Copyright (C) 2000-2002, 2005-2007, 2009-2015 Free Software Foundation, Inc.
This program is free software: you can redistribute it and/or modify it
under the terms of the GNU Lesser General Public License as published
by the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see . */
#include
/* Specification. */
#include "uniname.h"
#include
#include
#include
#include
#include
#define SIZEOF(a) (sizeof(a) / sizeof(a[0]))
/* Table of Unicode character names, derived from UnicodeData.txt.
This table is generated in a way to minimize the memory footprint:
1. its compiled size is small (less than 350 KB),
2. it resides entirely in the text or read-only data segment of the
executable or shared library: the table contains only immediate
integers, no pointers, and the functions don't do heap allocation.
*/
#include "uninames.h"
/* It contains:
static const char unicode_name_words[36303] = ...;
#define UNICODE_CHARNAME_NUM_WORDS 6260
static const struct { uint16_t extra_offset; uint16_t ind_offset; } unicode_name_by_length[26] = ...;
#define UNICODE_CHARNAME_WORD_HANGUL 3902
#define UNICODE_CHARNAME_WORD_SYLLABLE 4978
#define UNICODE_CHARNAME_WORD_CJK 417
#define UNICODE_CHARNAME_WORD_COMPATIBILITY 6107
static const uint16_t unicode_names[68940] = ...;
static const struct { uint16_t index; uint32_t name:24; } unicode_name_to_index[16626] = ...;
static const struct { uint16_t index; uint32_t name:24; } unicode_index_to_name[16626] = ...;
#define UNICODE_CHARNAME_MAX_LENGTH 83
#define UNICODE_CHARNAME_MAX_WORDS 13
static const struct { uint32_t index; uint32_t gap; uint16_t length; } unicode_ranges[401] = ...;
*/
/* Returns the word with a given index. */
static const char *
unicode_name_word (unsigned int index, unsigned int *lengthp)
{
unsigned int i1;
unsigned int i2;
unsigned int i;
assert (index < UNICODE_CHARNAME_NUM_WORDS);
/* Binary search for i with
unicode_name_by_length[i].ind_offset <= index
and
index < unicode_name_by_length[i+1].ind_offset
*/
i1 = 0;
i2 = SIZEOF (unicode_name_by_length) - 1;
while (i2 - i1 > 1)
{
unsigned int i = (i1 + i2) >> 1;
if (unicode_name_by_length[i].ind_offset <= index)
i1 = i;
else
i2 = i;
}
i = i1;
assert (unicode_name_by_length[i].ind_offset <= index
&& index < unicode_name_by_length[i+1].ind_offset);
*lengthp = i;
return &unicode_name_words[unicode_name_by_length[i].extra_offset
+ (index-unicode_name_by_length[i].ind_offset)*i];
}
/* Looks up the index of a word. */
static int
unicode_name_word_lookup (const char *word, unsigned int length)
{
if (length > 0 && length < SIZEOF (unicode_name_by_length) - 1)
{
/* Binary search among the words of given length. */
unsigned int extra_offset = unicode_name_by_length[length].extra_offset;
unsigned int i0 = unicode_name_by_length[length].ind_offset;
unsigned int i1 = i0;
unsigned int i2 = unicode_name_by_length[length+1].ind_offset;
while (i2 - i1 > 0)
{
unsigned int i = (i1 + i2) >> 1;
const char *p = &unicode_name_words[extra_offset + (i-i0)*length];
const char *w = word;
unsigned int n = length;
for (;;)
{
if (*p < *w)
{
if (i1 == i)
return -1;
/* Note here: i1 < i < i2. */
i1 = i;
break;
}
if (*p > *w)
{
/* Note here: i1 <= i < i2. */
i2 = i;
break;
}
p++; w++; n--;
if (n == 0)
return i;
}
}
}
return -1;
}
#define UNINAME_INVALID_INDEX UINT16_MAX
/* Looks up the internal index of a Unicode character. */
static uint16_t
unicode_code_to_index (ucs4_t c)
{
/* Binary search in unicode_ranges. */
unsigned int i1 = 0;
unsigned int i2 = SIZEOF (unicode_ranges);
for (;;)
{
unsigned int i = (i1 + i2) >> 1;
ucs4_t start_code =
unicode_ranges[i].index + unicode_ranges[i].gap;
ucs4_t end_code =
start_code + unicode_ranges[i].length - 1;
if (start_code <= c && c <= end_code)
return c - unicode_ranges[i].gap;
if (end_code < c)
{
if (i1 == i)
break;
/* Note here: i1 < i < i2. */
i1 = i;
}
else if (c < start_code)
{
if (i2 == i)
break;
/* Note here: i1 <= i < i2. */
i2 = i;
}
}
return UNINAME_INVALID_INDEX;
}
/* Looks up the codepoint of a Unicode character, from the given
internal index. */
static ucs4_t
unicode_index_to_code (uint16_t index)
{
/* Binary search in unicode_ranges. */
unsigned int i1 = 0;
unsigned int i2 = SIZEOF (unicode_ranges);
for (;;)
{
unsigned int i = (i1 + i2) >> 1;
uint16_t start_index = unicode_ranges[i].index;
uint16_t end_index = start_index + unicode_ranges[i].length - 1;
if (start_index <= index && index <= end_index)
return index + unicode_ranges[i].gap;
if (end_index < index)
{
if (i1 == i)
break;
/* Note here: i1 < i < i2. */
i1 = i;
}
else if (index < start_index)
{
if (i2 == i)
break;
/* Note here: i1 <= i < i2. */
i2 = i;
}
}
return UNINAME_INVALID;
}
/* Auxiliary tables for Hangul syllable names, see the Unicode 3.0 book,
sections 3.11 and 4.4. */
static const char jamo_initial_short_name[19][3] =
{
"G", "GG", "N", "D", "DD", "R", "M", "B", "BB", "S", "SS", "", "J", "JJ",
"C", "K", "T", "P", "H"
};
static const char jamo_medial_short_name[21][4] =
{
"A", "AE", "YA", "YAE", "EO", "E", "YEO", "YE", "O", "WA", "WAE", "OE", "YO",
"U", "WEO", "WE", "WI", "YU", "EU", "YI", "I"
};
static const char jamo_final_short_name[28][3] =
{
"", "G", "GG", "GS", "N", "NI", "NH", "D", "L", "LG", "LM", "LB", "LS", "LT",
"LP", "LH", "M", "B", "BS", "S", "SS", "NG", "J", "C", "K", "T", "P", "H"
};
/* Looks up the name of a Unicode character, in uppercase ASCII.
Returns the filled buf, or NULL if the character does not have a name. */
char *
unicode_character_name (ucs4_t c, char *buf)
{
if (c >= 0xAC00 && c <= 0xD7A3)
{
/* Special case for Hangul syllables. Keeps the tables small. */
char *ptr;
unsigned int tmp;
unsigned int index1;
unsigned int index2;
unsigned int index3;
const char *q;
/* buf needs to have at least 16 + 7 bytes here. */
memcpy (buf, "HANGUL SYLLABLE ", 16);
ptr = buf + 16;
tmp = c - 0xAC00;
index3 = tmp % 28; tmp = tmp / 28;
index2 = tmp % 21; tmp = tmp / 21;
index1 = tmp;
q = jamo_initial_short_name[index1];
while (*q != '\0')
*ptr++ = *q++;
q = jamo_medial_short_name[index2];
while (*q != '\0')
*ptr++ = *q++;
q = jamo_final_short_name[index3];
while (*q != '\0')
*ptr++ = *q++;
*ptr = '\0';
return buf;
}
else if ((c >= 0xF900 && c <= 0xFA2D) || (c >= 0xFA30 && c <= 0xFA6A)
|| (c >= 0xFA70 && c <= 0xFAD9) || (c >= 0x2F800 && c <= 0x2FA1D))
{
/* Special case for CJK compatibility ideographs. Keeps the tables
small. */
char *ptr;
int i;
/* buf needs to have at least 28 + 5 bytes here. */
memcpy (buf, "CJK COMPATIBILITY IDEOGRAPH-", 28);
ptr = buf + 28;
for (i = (c < 0x10000 ? 12 : 16); i >= 0; i -= 4)
{
unsigned int x = (c >> i) & 0xf;
*ptr++ = (x < 10 ? '0' : 'A' - 10) + x;
}
*ptr = '\0';
return buf;
}
else if ((c >= 0xFE00 && c <= 0xFE0F) || (c >= 0xE0100 && c <= 0xE01EF))
{
/* Special case for variation selectors. Keeps the tables
small. */
/* buf needs to have at least 19 + 3 bytes here. */
sprintf (buf, "VARIATION SELECTOR-%d",
c <= 0xFE0F ? c - 0xFE00 + 1 : c - 0xE0100 + 17);
return buf;
}
else
{
uint16_t index = unicode_code_to_index (c);
const uint16_t *words = NULL;
if (index != UNINAME_INVALID_INDEX)
{
/* Binary search in unicode_code_to_name. */
unsigned int i1 = 0;
unsigned int i2 = SIZEOF (unicode_index_to_name);
for (;;)
{
unsigned int i = (i1 + i2) >> 1;
if (unicode_index_to_name[i].index == index)
{
words = &unicode_names[unicode_index_to_name[i].name];
break;
}
else if (unicode_index_to_name[i].index < index)
{
if (i1 == i)
{
words = NULL;
break;
}
/* Note here: i1 < i < i2. */
i1 = i;
}
else if (unicode_index_to_name[i].index > index)
{
if (i2 == i)
{
words = NULL;
break;
}
/* Note here: i1 <= i < i2. */
i2 = i;
}
}
}
if (words != NULL)
{
/* Found it in unicode_index_to_name. Now concatenate the words. */
/* buf needs to have at least UNICODE_CHARNAME_MAX_LENGTH bytes. */
char *ptr = buf;
for (;;)
{
unsigned int wordlen;
const char *word = unicode_name_word (*words>>1, &wordlen);
do
*ptr++ = *word++;
while (--wordlen > 0);
if ((*words & 1) == 0)
break;
*ptr++ = ' ';
words++;
}
*ptr = '\0';
return buf;
}
return NULL;
}
}
/* Looks up the Unicode character with a given name, in upper- or lowercase
ASCII. Returns the character if found, or UNINAME_INVALID if not found. */
ucs4_t
unicode_name_character (const char *name)
{
unsigned int len = strlen (name);
if (len > 1 && len <= UNICODE_CHARNAME_MAX_LENGTH)
{
/* Test for "word1 word2 ..." syntax. */
char buf[UNICODE_CHARNAME_MAX_LENGTH];
char *ptr = buf;
for (;;)
{
char c = *name++;
if (!(c >= ' ' && c <= '~'))
break;
*ptr++ = (c >= 'a' && c <= 'z' ? c - 'a' + 'A' : c);
if (--len == 0)
goto filled_buf;
}
if (false)
filled_buf:
{
{
/* Special case for variation selector aliases. Keeps the
tables small. */
const char *p1 = buf;
if (ptr >= buf + 3 && *p1++ == 'V')
{
if (*p1++ == 'S')
{
if (*p1 != '0')
{
unsigned int c = 0;
for (;;)
{
if (*p1 >= '0' && *p1 <= '9')
c += (*p1 - '0');
p1++;
if (p1 == ptr)
{
if (c >= 1 && c <= 16)
return c - 1 + 0xFE00;
else if (c >= 17 && c <= 256)
return c - 17 + 0xE0100;
else
break;
}
c = c * 10;
}
}
}
}
}
/* Convert the constituents to uint16_t words. */
uint16_t words[UNICODE_CHARNAME_MAX_WORDS];
uint16_t *wordptr = words;
{
const char *p1 = buf;
for (;;)
{
{
int word;
const char *p2 = p1;
while (p2 < ptr && *p2 != ' ')
p2++;
word = unicode_name_word_lookup (p1, p2 - p1);
if (word < 0)
break;
if (wordptr == &words[UNICODE_CHARNAME_MAX_WORDS])
break;
*wordptr++ = word;
if (p2 == ptr)
goto filled_words;
p1 = p2 + 1;
}
/* Special case for Hangul syllables. Keeps the tables small. */
if (wordptr == &words[2]
&& words[0] == UNICODE_CHARNAME_WORD_HANGUL
&& words[1] == UNICODE_CHARNAME_WORD_SYLLABLE)
{
/* Split the last word [p1..ptr) into three parts:
1) [BCDGHJKMNPRST]
2) [AEIOUWY]
3) [BCDGHIJKLMNPST]
*/
const char *p2;
const char *p3;
const char *p4;
p2 = p1;
while (p2 < ptr
&& (*p2 == 'B' || *p2 == 'C' || *p2 == 'D'
|| *p2 == 'G' || *p2 == 'H' || *p2 == 'J'
|| *p2 == 'K' || *p2 == 'M' || *p2 == 'N'
|| *p2 == 'P' || *p2 == 'R' || *p2 == 'S'
|| *p2 == 'T'))
p2++;
p3 = p2;
while (p3 < ptr
&& (*p3 == 'A' || *p3 == 'E' || *p3 == 'I'
|| *p3 == 'O' || *p3 == 'U' || *p3 == 'W'
|| *p3 == 'Y'))
p3++;
p4 = p3;
while (p4 < ptr
&& (*p4 == 'B' || *p4 == 'C' || *p4 == 'D'
|| *p4 == 'G' || *p4 == 'H' || *p4 == 'I'
|| *p4 == 'J' || *p4 == 'K' || *p4 == 'L'
|| *p4 == 'M' || *p4 == 'N' || *p4 == 'P'
|| *p4 == 'S' || *p4 == 'T'))
p4++;
if (p4 == ptr)
{
unsigned int n1 = p2 - p1;
unsigned int n2 = p3 - p2;
unsigned int n3 = p4 - p3;
if (n1 <= 2 && (n2 >= 1 && n2 <= 3) && n3 <= 2)
{
unsigned int index1;
for (index1 = 0; index1 < 19; index1++)
if (memcmp (jamo_initial_short_name[index1], p1, n1) == 0
&& jamo_initial_short_name[index1][n1] == '\0')
{
unsigned int index2;
for (index2 = 0; index2 < 21; index2++)
if (memcmp (jamo_medial_short_name[index2], p2, n2) == 0
&& jamo_medial_short_name[index2][n2] == '\0')
{
unsigned int index3;
for (index3 = 0; index3 < 28; index3++)
if (memcmp (jamo_final_short_name[index3], p3, n3) == 0
&& jamo_final_short_name[index3][n3] == '\0')
{
return 0xAC00 + (index1 * 21 + index2) * 28 + index3;
}
break;
}
break;
}
}
}
}
/* Special case for CJK compatibility ideographs. Keeps the
tables small. */
if (wordptr == &words[2]
&& words[0] == UNICODE_CHARNAME_WORD_CJK
&& words[1] == UNICODE_CHARNAME_WORD_COMPATIBILITY
&& p1 + 14 <= ptr
&& p1 + 15 >= ptr
&& memcmp (p1, "IDEOGRAPH-", 10) == 0)
{
const char *p2 = p1 + 10;
if (*p2 != '0')
{
unsigned int c = 0;
for (;;)
{
if (*p2 >= '0' && *p2 <= '9')
c += (*p2 - '0');
else if (*p2 >= 'A' && *p2 <= 'F')
c += (*p2 - 'A' + 10);
else
break;
p2++;
if (p2 == ptr)
{
if ((c >= 0xF900 && c <= 0xFA2D)
|| (c >= 0xFA30 && c <= 0xFA6A)
|| (c >= 0xFA70 && c <= 0xFAD9)
|| (c >= 0x2F800 && c <= 0x2FA1D))
return c;
else
break;
}
c = c << 4;
}
}
}
/* Special case for variation selectors. Keeps the
tables small. */
if (wordptr == &words[1]
&& words[0] == UNICODE_CHARNAME_WORD_VARIATION
&& p1 + 10 <= ptr
&& p1 + 12 >= ptr
&& memcmp (p1, "SELECTOR-", 9) == 0)
{
const char *p2 = p1 + 9;
if (*p2 != '0')
{
unsigned int c = 0;
for (;;)
{
if (*p2 >= '0' && *p2 <= '9')
c += (*p2 - '0');
p2++;
if (p2 == ptr)
{
if (c >= 1 && c <= 16)
return c - 1 + 0xFE00;
else if (c >= 17 && c <= 256)
return c - 17 + 0xE0100;
else
break;
}
c = c * 10;
}
}
}
}
}
if (false)
filled_words:
{
/* Multiply by 2, to simplify later comparisons. */
unsigned int words_length = wordptr - words;
{
int i = words_length - 1;
words[i] = 2 * words[i];
for (; --i >= 0; )
words[i] = 2 * words[i] + 1;
}
/* Binary search in unicode_name_to_index. */
{
unsigned int i1 = 0;
unsigned int i2 = SIZEOF (unicode_name_to_index);
for (;;)
{
unsigned int i = (i1 + i2) >> 1;
const uint16_t *w = words;
const uint16_t *p = &unicode_names[unicode_name_to_index[i].name];
unsigned int n = words_length;
for (;;)
{
if (*p < *w)
{
if (i1 == i)
goto name_not_found;
/* Note here: i1 < i < i2. */
i1 = i;
break;
}
else if (*p > *w)
{
if (i2 == i)
goto name_not_found;
/* Note here: i1 <= i < i2. */
i2 = i;
break;
}
p++; w++; n--;
if (n == 0)
return unicode_index_to_code (unicode_name_to_index[i].index);
}
}
}
name_not_found: ;
}
}
}
return UNINAME_INVALID;
}