freebsd-dev/usr.bin/localedef/wide.c

670 lines
15 KiB
C
Raw Normal View History

/*
* Copyright 2011 Nexenta Systems, Inc. All rights reserved.
* Copyright 2012 Garrett D'Amore <garrett@damore.org> All rights reserved.
* Copyright 2015 John Marino <draco@marino.st>
*
* This source code is derived from the illumos localedef command, and
* provided under BSD-style license terms by Nexenta Systems, Inc.
*
* 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.
*
* 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.
*/
/*
* The functions in this file convert from the standard multibyte forms
* to the wide character forms used internally by libc. Unfortunately,
* this approach means that we need a method for each and every encoding.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <stdlib.h>
#include <wchar.h>
#include <string.h>
#include <sys/types.h>
#include "localedef.h"
static int towide_none(wchar_t *, const char *, unsigned);
static int towide_utf8(wchar_t *, const char *, unsigned);
static int towide_big5(wchar_t *, const char *, unsigned);
static int towide_gbk(wchar_t *, const char *, unsigned);
static int towide_gb2312(wchar_t *, const char *, unsigned);
static int towide_gb18030(wchar_t *, const char *, unsigned);
static int towide_mskanji(wchar_t *, const char *, unsigned);
static int towide_euccn(wchar_t *, const char *, unsigned);
static int towide_eucjp(wchar_t *, const char *, unsigned);
static int towide_euckr(wchar_t *, const char *, unsigned);
static int towide_euctw(wchar_t *, const char *, unsigned);
static int tomb_none(char *, wchar_t);
static int tomb_utf8(char *, wchar_t);
static int tomb_mbs(char *, wchar_t);
static int (*_towide)(wchar_t *, const char *, unsigned) = towide_none;
static int (*_tomb)(char *, wchar_t) = tomb_none;
libc: Fix (and improve) nl_langinfo (CODESET) The output of "locale charmap" is identical to the result of nl_langinfo (CODESET) for any given locale. The logic for returning the codeset was very simplistic. It just returned portion of the locale name after the period (e.g. en_FR.ISO8859-1 returned "ISO8859-1"). When softlinks were added to locales, this broke. e.g.: en_US returned "" en_FR.UTF8 returned "UTF8" en_FR.UTF-8 returned "UTF-8" zh_Hant_HK.Big5HKSCS returned "Big5HKSCS" zh_Hant_TW.Big5 returned "Big5" es_ES@euro returned "" In order to fix this properly, the named locale cannot be used to determine the encoding. This information was almost available in the rune data. Unfortunately, all the single byte encodings were listed as "NONE" encoding. So I adjusted localedef tool to provide more information about the encoding. For example, instead of "NONE", the LC_CTYPE used by fr_FR.ISO8859-15 is now encoded as "NONE:ISO8859-15". The locale handlers now check if the first four characters of the encoding is "NONE" and if so, treats it as a single-byte encoding. The nl_langinfo handling of CODESET was adjusting accordingly. Now the following is returned: en_US returns "ISO8859-1" fr_FR.UTF8 returns "UTF-8" fr_FR.UTF-8 returns "UTF-8" zh_Hant_HK.Big5HKSCS returns "Big5" zh_Hant_TW.Big5 returns "Big5" es_ES@euro returns "ISO8859-15" as before, "C" and "POSIX" locales return "US-ASCII". This is a big improvement. The result of nl_langinfo can never be a zero-length string and it will always exclusively one of the values of the character maps of /usr/src/tools/tools/locale/etc/final-maps. Submitted by: marino Obtained from: DragonflyBSD
2015-11-01 12:00:55 +00:00
static char _encoding_buffer[20] = {'N','O','N','E'};
static const char *_encoding = _encoding_buffer;
static int _nbits = 7;
/*
* Table of supported encodings. We only bother to list the multibyte
* encodings here, because single byte locales are handed by "NONE".
*/
static struct {
const char *name;
/* the name that the underlying libc implemenation uses */
const char *cname;
/* the maximum number of bits required for priorities */
int nbits;
int (*towide)(wchar_t *, const char *, unsigned);
int (*tomb)(char *, wchar_t);
} mb_encodings[] = {
/*
* UTF8 values max out at 0x1fffff (although in theory there could
* be later extensions, but it won't happen.) This means we only need
* 21 bits to be able to encode the entire range of priorities.
*/
{ "UTF-8", "UTF-8", 21, towide_utf8, tomb_utf8 },
{ "UTF8", "UTF-8", 21, towide_utf8, tomb_utf8 },
{ "utf8", "UTF-8", 21, towide_utf8, tomb_utf8 },
{ "utf-8", "UTF-8", 21, towide_utf8, tomb_utf8 },
{ "EUC-CN", "EUC-CN", 16, towide_euccn, tomb_mbs },
{ "eucCN", "EUC-CN", 16, towide_euccn, tomb_mbs },
/*
* Becuase the 3-byte form of EUC-JP use the same leading byte,
* only 17 bits required to provide unique priorities. (The low
* bit of that first byte is set.) By setting this value low,
* we can get by with only 3 bytes in the strxfrm expansion.
*/
{ "EUC-JP", "EUC-JP", 17, towide_eucjp, tomb_mbs },
{ "eucJP", "EUC-JP", 17, towide_eucjp, tomb_mbs },
{ "EUC-KR", "EUC-KR", 16, towide_euckr, tomb_mbs },
{ "eucKR", "EUC-KR", 16, towide_euckr, tomb_mbs },
/*
* EUC-TW uses 2 bytes most of the time, but 4 bytes if the
* high order byte is 0x8E. However, with 4 byte encodings,
* the third byte will be A0-B0. So we only need to consider
* the lower order 24 bits for collation.
*/
{ "EUC-TW", "EUC-TW", 24, towide_euctw, tomb_mbs },
{ "eucTW", "EUC-TW", 24, towide_euctw, tomb_mbs },
{ "MS_Kanji", "MSKanji", 16, towide_mskanji, tomb_mbs },
{ "MSKanji", "MSKanji", 16, towide_mskanji, tomb_mbs },
{ "PCK", "MSKanji", 16, towide_mskanji, tomb_mbs },
{ "SJIS", "MSKanji", 16, towide_mskanji, tomb_mbs },
{ "Shift_JIS", "MSKanji", 16, towide_mskanji, tomb_mbs },
{ "BIG5", "BIG5", 16, towide_big5, tomb_mbs },
{ "big5", "BIG5", 16, towide_big5, tomb_mbs },
{ "Big5", "BIG5", 16, towide_big5, tomb_mbs },
{ "GBK", "GBK", 16, towide_gbk, tomb_mbs },
/*
* GB18030 can get away with just 31 bits. This is because the
* high order bit is always set for 4 byte values, and the
* at least one of the other bits in that 4 byte value will
* be non-zero.
*/
{ "GB18030", "GB18030", 31, towide_gb18030, tomb_mbs },
/*
* This should probably be an aliase for euc-cn, or vice versa.
*/
{ "GB2312", "GB2312", 16, towide_gb2312, tomb_mbs },
{ NULL, NULL, 0, 0, 0 },
};
static char *
show_mb(const char *mb)
{
static char buf[64];
/* ASCII stuff we just print */
if (isascii(*mb) && isgraph(*mb)) {
buf[0] = *mb;
buf[1] = 0;
return (buf);
}
buf[0] = 0;
while (*mb != 0) {
char scr[8];
(void) snprintf(scr, sizeof (scr), "\\x%02x", *mb);
(void) strlcat(buf, scr, sizeof (buf));
mb++;
}
return (buf);
}
static char *widemsg;
void
werr(const char *fmt, ...)
{
char *msg;
va_list va;
va_start(va, fmt);
(void) vasprintf(&msg, fmt, va);
va_end(va);
free(widemsg);
widemsg = msg;
}
/*
* This is used for 8-bit encodings.
*/
int
towide_none(wchar_t *c, const char *mb, unsigned n __unused)
{
if (mb_cur_max != 1) {
werr("invalid or unsupported multibyte locale");
return (-1);
}
*c = (uint8_t)*mb;
return (1);
}
int
tomb_none(char *mb, wchar_t wc)
{
if (mb_cur_max != 1) {
werr("invalid or unsupported multibyte locale");
return (-1);
}
*(uint8_t *)mb = (wc & 0xff);
mb[1] = 0;
return (1);
}
/*
* UTF-8 stores wide characters in UTF-32 form.
*/
int
towide_utf8(wchar_t *wc, const char *mb, unsigned n)
{
wchar_t c;
int nb;
int lv; /* lowest legal value */
int i;
const uint8_t *s = (const uint8_t *)mb;
c = *s;
if ((c & 0x80) == 0) {
/* 7-bit ASCII */
*wc = c;
return (1);
} else if ((c & 0xe0) == 0xc0) {
/* u80-u7ff - two bytes encoded */
nb = 2;
lv = 0x80;
c &= ~0xe0;
} else if ((c & 0xf0) == 0xe0) {
/* u800-uffff - three bytes encoded */
nb = 3;
lv = 0x800;
c &= ~0xf0;
} else if ((c & 0xf8) == 0xf0) {
/* u1000-u1fffff - four bytes encoded */
nb = 4;
lv = 0x1000;
c &= ~0xf8;
} else {
/* 5 and 6 byte encodings are not legal unicode */
werr("utf8 encoding too large (%s)", show_mb(mb));
return (-1);
}
if (nb > (int)n) {
werr("incomplete utf8 sequence (%s)", show_mb(mb));
return (-1);
}
for (i = 1; i < nb; i++) {
if (((s[i]) & 0xc0) != 0x80) {
werr("illegal utf8 byte (%x)", s[i]);
return (-1);
}
c <<= 6;
c |= (s[i] & 0x3f);
}
if (c < lv) {
werr("illegal redundant utf8 encoding (%s)", show_mb(mb));
return (-1);
}
*wc = c;
return (nb);
}
int
tomb_utf8(char *mb, wchar_t wc)
{
uint8_t *s = (uint8_t *)mb;
uint8_t msk;
int cnt;
int i;
if (wc <= 0x7f) {
s[0] = wc & 0x7f;
s[1] = 0;
return (1);
}
if (wc <= 0x7ff) {
cnt = 2;
msk = 0xc0;
} else if (wc <= 0xffff) {
cnt = 3;
msk = 0xe0;
} else if (wc <= 0x1fffff) {
cnt = 4;
msk = 0xf0;
} else {
werr("illegal uf8 char (%x)", wc);
return (-1);
}
for (i = cnt - 1; i; i--) {
s[i] = (wc & 0x3f) | 0x80;
wc >>= 6;
}
s[0] = (msk) | wc;
s[cnt] = 0;
return (cnt);
}
/*
* Several encodings share a simplistic dual byte encoding. In these
* forms, they all indicate that a two byte sequence is to be used if
* the first byte has its high bit set. They all store this simple
* encoding as a 16-bit value, although a great many of the possible
* code points are not used in most character sets. This gives a possible
* set of just over 32,000 valid code points.
*
* 0x00 - 0x7f - 1 byte encoding
* 0x80 - 0x7fff - illegal
* 0x8000 - 0xffff - 2 byte encoding
*/
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wcast-qual"
static int
towide_dbcs(wchar_t *wc, const char *mb, unsigned n)
{
wchar_t c;
c = *(uint8_t *)mb;
if ((c & 0x80) == 0) {
/* 7-bit */
*wc = c;
return (1);
}
if (n < 2) {
werr("incomplete character sequence (%s)", show_mb(mb));
return (-1);
}
/* Store both bytes as a single 16-bit wide. */
c <<= 8;
c |= (uint8_t)(mb[1]);
*wc = c;
return (2);
}
/*
* Most multibyte locales just convert the wide character to the multibyte
* form by stripping leading null bytes, and writing the 32-bit quantity
* in big-endian order.
*/
int
tomb_mbs(char *mb, wchar_t wc)
{
uint8_t *s = (uint8_t *)mb;
int n = 0, c;
if ((wc & 0xff000000U) != 0) {
n = 4;
} else if ((wc & 0x00ff0000U) != 0) {
n = 3;
} else if ((wc & 0x0000ff00U) != 0) {
n = 2;
} else {
n = 1;
}
c = n;
while (n) {
n--;
s[n] = wc & 0xff;
wc >>= 8;
}
/* ensure null termination */
s[c] = 0;
return (c);
}
/*
* big5 is a simple dual byte character set.
*/
int
towide_big5(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_dbcs(wc, mb, n));
}
/*
* GBK encodes wides in the same way that big5 does, the high order
* bit of the first byte indicates a double byte character.
*/
int
towide_gbk(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_dbcs(wc, mb, n));
}
/*
* GB2312 is another DBCS. Its cleaner than others in that the second
* byte does not encode ASCII, but it supports characters.
*/
int
towide_gb2312(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_dbcs(wc, mb, n));
}
/*
* GB18030. This encodes as 8, 16, or 32-bits.
* 7-bit values are in 1 byte, 4 byte sequences are used when
* the second byte encodes 0x30-39 and all other sequences are 2 bytes.
*/
int
towide_gb18030(wchar_t *wc, const char *mb, unsigned n)
{
wchar_t c;
c = *(uint8_t *)mb;
if ((c & 0x80) == 0) {
/* 7-bit */
*wc = c;
return (1);
}
if (n < 2) {
werr("incomplete character sequence (%s)", show_mb(mb));
return (-1);
}
/* pull in the second byte */
c <<= 8;
c |= (uint8_t)(mb[1]);
if (((c & 0xff) >= 0x30) && ((c & 0xff) <= 0x39)) {
if (n < 4) {
werr("incomplete 4-byte character sequence (%s)",
show_mb(mb));
return (-1);
}
c <<= 8;
c |= (uint8_t)(mb[2]);
c <<= 8;
c |= (uint8_t)(mb[3]);
*wc = c;
return (4);
}
*wc = c;
return (2);
}
/*
* MS-Kanji (aka SJIS) is almost a clean DBCS like the others, but it
* also has a range of single byte characters above 0x80. (0xa1-0xdf).
*/
int
towide_mskanji(wchar_t *wc, const char *mb, unsigned n)
{
wchar_t c;
c = *(uint8_t *)mb;
if ((c < 0x80) || ((c > 0xa0) && (c < 0xe0))) {
/* 7-bit */
*wc = c;
return (1);
}
if (n < 2) {
werr("incomplete character sequence (%s)", show_mb(mb));
return (-1);
}
/* Store both bytes as a single 16-bit wide. */
c <<= 8;
c |= (uint8_t)(mb[1]);
*wc = c;
return (2);
}
/*
* EUC forms. EUC encodings are "variable". FreeBSD carries some additional
* variable data to encode these, but we're going to treat each as independent
* instead. Its the only way we can sensibly move forward.
*
* Note that the way in which the different EUC forms vary is how wide
* CS2 and CS3 are and what the first byte of them is.
*/
static int
towide_euc_impl(wchar_t *wc, const char *mb, unsigned n,
uint8_t cs2, uint8_t cs2width, uint8_t cs3, uint8_t cs3width)
{
int i;
int width = 2;
wchar_t c;
c = *(uint8_t *)mb;
/*
* All variations of EUC encode 7-bit ASCII as one byte, and use
* additional bytes for more than that.
*/
if ((c & 0x80) == 0) {
/* 7-bit */
*wc = c;
return (1);
}
/*
* All EUC variants reserve 0xa1-0xff to identify CS1, which
* is always two bytes wide. Note that unused CS will be zero,
* and that cannot be true because we know that the high order
* bit must be set.
*/
if (c >= 0xa1) {
width = 2;
} else if (c == cs2) {
width = cs2width;
} else if (c == cs3) {
width = cs3width;
}
if ((int)n < width) {
werr("incomplete character sequence (%s)", show_mb(mb));
return (-1);
}
for (i = 1; i < width; i++) {
/* pull in the next byte */
c <<= 8;
c |= (uint8_t)(mb[i]);
}
*wc = c;
return (width);
}
#pragma GCC diagnostic pop
/*
* EUC-CN encodes as follows:
*
* Code set 0 (ASCII): 0x21-0x7E
* Code set 1 (CNS 11643-1992 Plane 1): 0xA1A1-0xFEFE
* Code set 2: unused
* Code set 3: unused
*/
int
towide_euccn(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_euc_impl(wc, mb, n, 0x8e, 4, 0, 0));
}
/*
* EUC-JP encodes as follows:
*
* Code set 0 (ASCII or JIS X 0201-1976 Roman): 0x21-0x7E
* Code set 1 (JIS X 0208): 0xA1A1-0xFEFE
* Code set 2 (half-width katakana): 0x8EA1-0x8EDF
* Code set 3 (JIS X 0212-1990): 0x8FA1A1-0x8FFEFE
*/
int
towide_eucjp(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_euc_impl(wc, mb, n, 0x8e, 2, 0x8f, 3));
}
/*
* EUC-KR encodes as follows:
*
* Code set 0 (ASCII or KS C 5636-1993): 0x21-0x7E
* Code set 1 (KS C 5601-1992): 0xA1A1-0xFEFE
* Code set 2: unused
* Code set 3: unused
*/
int
towide_euckr(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_euc_impl(wc, mb, n, 0, 0, 0, 0));
}
/*
* EUC-TW encodes as follows:
*
* Code set 0 (ASCII): 0x21-0x7E
* Code set 1 (CNS 11643-1992 Plane 1): 0xA1A1-0xFEFE
* Code set 2 (CNS 11643-1992 Planes 1-16): 0x8EA1A1A1-0x8EB0FEFE
* Code set 3: unused
*/
int
towide_euctw(wchar_t *wc, const char *mb, unsigned n)
{
return (towide_euc_impl(wc, mb, n, 0x8e, 4, 0, 0));
}
/*
* Public entry points.
*/
int
to_wide(wchar_t *wc, const char *mb)
{
/* this won't fail hard */
return (_towide(wc, mb, strlen(mb)));
}
int
to_mb(char *mb, wchar_t wc)
{
int rv;
if ((rv = _tomb(mb, wc)) < 0) {
errf(widemsg);
free(widemsg);
widemsg = NULL;
}
return (rv);
}
char *
to_mb_string(const wchar_t *wcs)
{
char *mbs;
char *ptr;
int len;
mbs = malloc((wcslen(wcs) * mb_cur_max) + 1);
if (mbs == NULL) {
errf("out of memory");
return (NULL);
}
ptr = mbs;
while (*wcs) {
if ((len = to_mb(ptr, *wcs)) < 0) {
INTERR;
free(mbs);
return (NULL);
}
wcs++;
ptr += len;
}
*ptr = 0;
return (mbs);
}
void
set_wide_encoding(const char *encoding)
{
int i;
_towide = towide_none;
_tomb = tomb_none;
_nbits = 8;
libc: Fix (and improve) nl_langinfo (CODESET) The output of "locale charmap" is identical to the result of nl_langinfo (CODESET) for any given locale. The logic for returning the codeset was very simplistic. It just returned portion of the locale name after the period (e.g. en_FR.ISO8859-1 returned "ISO8859-1"). When softlinks were added to locales, this broke. e.g.: en_US returned "" en_FR.UTF8 returned "UTF8" en_FR.UTF-8 returned "UTF-8" zh_Hant_HK.Big5HKSCS returned "Big5HKSCS" zh_Hant_TW.Big5 returned "Big5" es_ES@euro returned "" In order to fix this properly, the named locale cannot be used to determine the encoding. This information was almost available in the rune data. Unfortunately, all the single byte encodings were listed as "NONE" encoding. So I adjusted localedef tool to provide more information about the encoding. For example, instead of "NONE", the LC_CTYPE used by fr_FR.ISO8859-15 is now encoded as "NONE:ISO8859-15". The locale handlers now check if the first four characters of the encoding is "NONE" and if so, treats it as a single-byte encoding. The nl_langinfo handling of CODESET was adjusting accordingly. Now the following is returned: en_US returns "ISO8859-1" fr_FR.UTF8 returns "UTF-8" fr_FR.UTF-8 returns "UTF-8" zh_Hant_HK.Big5HKSCS returns "Big5" zh_Hant_TW.Big5 returns "Big5" es_ES@euro returns "ISO8859-15" as before, "C" and "POSIX" locales return "US-ASCII". This is a big improvement. The result of nl_langinfo can never be a zero-length string and it will always exclusively one of the values of the character maps of /usr/src/tools/tools/locale/etc/final-maps. Submitted by: marino Obtained from: DragonflyBSD
2015-11-01 12:00:55 +00:00
snprint(_encoding_buffer, sizeof(_encoding_buffer), "NONE:%s", encoding);
for (i = 0; mb_encodings[i].name; i++) {
if (strcasecmp(encoding, mb_encodings[i].name) == 0) {
_towide = mb_encodings[i].towide;
_tomb = mb_encodings[i].tomb;
_encoding = mb_encodings[i].cname;
_nbits = mb_encodings[i].nbits;
break;
}
}
}
const char *
get_wide_encoding(void)
{
return (_encoding);
}
int
max_wide(void)
{
return ((int)((1U << _nbits) - 1));
}