/*
- * encoding.c
- */
-
-/*
- * Copyright (C) 2012, 2013 Eric Biggers
+ * encoding.c - UTF-8 and UTF-16LE codecs and utility functions
+ *
+ * Copyright (C) 2012-2016 Eric Biggers
*
* This file 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
#endif
#include <errno.h>
-#include <iconv.h>
-#include <pthread.h>
#include <string.h>
-#include "wimlib.h"
-#include "wimlib/alloca.h"
-#include "wimlib/assert.h"
#include "wimlib/encoding.h"
#include "wimlib/endianness.h"
#include "wimlib/error.h"
-#include "wimlib/list.h"
+#include "wimlib/unaligned.h"
#include "wimlib/util.h"
+/*
+ * Allow unpaired surrogates, such as might exist in Windows-style filenames ---
+ * which are normally valid UTF-16LE, but are actually treated as opaque
+ * sequences of 16-bit WCHARs by Windows. When decoding "UTF-16LE", unpaired
+ * surrogates will be decoded as their surrogate codepoints; and when encoding
+ * to and from "UTF-8", the encoding will actually be WTF-8 ("Wobbly
+ * Transformation Format - 8-bit"), a superset of UTF-8 which permits the
+ * surrogate codepoints.
+ *
+ * In combination with also allowing the "non-character" codepoints U+FFFE and
+ * U+FFFF, the result is that every Windows-style filename can be translated to
+ * a UNIX-style filename.
+ *
+ * Unfortunately, the converse is not true: not every UNIX filename can be
+ * translated to a Windows filename. Only UNIX filenames that are valid "WTF-8"
+ * can be translated. I considered ways to define a bijective mapping, but
+ * there did not seem to be a straightforward way. The "UTF-8b" scheme, for
+ * example, would map each invalid byte 'b' to a surrogate "escape code" 'U+DC00
+ * + b'. The problem with this was that surrogate escape codes can be combined
+ * to create a valid UTF-8 sequence, thus breaking the bijection by mapping
+ * multiple Windows filenames to a single UNIX filename.
+ */
+#define ALLOW_UNPAIRED_SURROGATES 1
-bool wimlib_mbs_is_utf8 = !TCHAR_IS_UTF16LE;
-
-/* List of iconv_t conversion descriptors for a specific character conversion.
- * The idea is that it is not thread-safe to have just one conversion
- * descriptor, but it also is inefficient to open a new conversion descriptor to
- * convert every string. Both these problems can be solved by maintaining a
- * list of conversion descriptors; then, a thread can use an existing conversion
- * descriptor if available. */
-struct iconv_list_head {
- const char *from_encoding;
- const char *to_encoding;
- struct list_head list;
- pthread_mutex_t mutex;
-};
-
-struct iconv_node {
- iconv_t cd;
- struct list_head list;
- struct iconv_list_head *head;
-};
-
-#define ICONV_LIST(name, from, to) \
-struct iconv_list_head name = { \
- .from_encoding = from, \
- .to_encoding = to, \
-}
+#define INVALID_CODEPOINT 0xFFFFFFFF
+#define VALIDATE(expr) if (validate && unlikely(!(expr))) goto invalid
+#define IS_SURROGATE(c) ((c) >= 0xD800 && (c) < 0xE000)
+#define IS_HIGH_SURROGATE(c) ((c) >= 0xD800 && (c) < 0xDC00)
+#define IS_LOW_SURROGATE(c) ((c) >= 0xDC00 && (c) < 0xE000)
+#define IS_UTF8_TAIL(c) (((c) & 0xC0) == 0x80)
-static iconv_t *
-get_iconv(struct iconv_list_head *head)
+/*
+ * Decode the next Unicode codepoint from the string at @in, which has
+ * @remaining >= 1 bytes remaining. Return the number of bytes consumed and
+ * write the decoded codepoint to *c_ret.
+ *
+ * If the input might not be a valid string in the source encoding, then
+ * @validate must be specified as %true, and then on invalid input the function
+ * consumes at least one byte and sets *c_ret to INVALID_CODEPOINT. If the
+ * input is guaranteed to be valid, then @validate may be specified as %false.
+ */
+typedef unsigned (*decode_codepoint_fn)(const u8 *in, size_t remaining,
+ bool validate, u32 *c_ret);
+
+/* Encode the Unicode codepoint @c and return the number of bytes used. */
+typedef unsigned (*encode_codepoint_fn)(u32 c, u8 *out);
+
+static forceinline unsigned
+utf8_decode_codepoint(const u8 *in, size_t remaining, bool validate, u32 *c_ret)
{
- iconv_t cd;
- iconv_t *cd_p;
- struct iconv_node *i;
-
- pthread_mutex_lock(&head->mutex);
- if (list_empty(&head->list)) {
- cd = iconv_open(head->to_encoding, head->from_encoding);
- if (cd == (iconv_t)-1) {
- ERROR_WITH_ERRNO("Failed to open iconv from %s to %s",
- head->from_encoding, head->to_encoding);
- cd_p = NULL;
- } else {
- i = MALLOC(sizeof(struct iconv_node));
- if (i) {
- i->head = head;
- i->cd = cd;
- cd_p = &i->cd;
- } else {
- iconv_close(cd);
- cd_p = NULL;
- }
- }
- } else {
- i = container_of(head->list.next, struct iconv_node, list);
- list_del(head->list.next);
- cd_p = &i->cd;
+ if (likely(in[0] < 0x80)) { /* U+0...U+7F */
+ *c_ret = in[0];
+ return 1;
}
- pthread_mutex_unlock(&head->mutex);
- return cd_p;
-}
-static void
-put_iconv(iconv_t *cd)
-{
- int errno_save = errno;
- struct iconv_node *i = container_of(cd, struct iconv_node, cd);
- struct iconv_list_head *head = i->head;
-
- pthread_mutex_lock(&head->mutex);
- list_add(&i->list, &head->list);
- pthread_mutex_unlock(&head->mutex);
- errno = errno_save;
-}
+ if (in[0] < 0xE0) { /* U+80...U+7FF */
+ VALIDATE(in[0] >= 0xC2 && remaining >= 2 &&
+ IS_UTF8_TAIL(in[1]));
+ *c_ret = ((u32)(in[0] & 0x1F) << 6) |
+ ((u32)(in[1] & 0x3F) << 0);
+ return 2;
+ }
+
+ if (in[0] < 0xF0) { /* U+800...U+FFFF, possibly excluding surrogates */
+ VALIDATE(remaining >= 3 &&
+ IS_UTF8_TAIL(in[1]) &&
+ IS_UTF8_TAIL(in[2]));
+ *c_ret = ((u32)(in[0] & 0x0F) << 12) |
+ ((u32)(in[1] & 0x3F) << 6) |
+ ((u32)(in[2] & 0x3F) << 0);
+ VALIDATE(*c_ret >= 0x800);
+ #if !ALLOW_UNPAIRED_SURROGATES
+ VALIDATE(!IS_SURROGATE(*c_ret));
+ #endif
+ return 3;
+ }
-#define DEFINE_CHAR_CONVERSION_FUNCTIONS(varname1, longname1, chartype1,\
- varname2, longname2, chartype2,\
- earlyreturn_on_utf8_locale, \
- earlyreturn_expr, \
- worst_case_len_expr, \
- err_return, \
- err_msg, \
- modifier) \
-static ICONV_LIST(iconv_##varname1##_to_##varname2, \
- longname1, longname2); \
- \
-modifier int \
-varname1##_to_##varname2##_nbytes(const chartype1 *in, size_t in_nbytes,\
- size_t *out_nbytes_ret) \
-{ \
- iconv_t *cd = get_iconv(&iconv_##varname1##_to_##varname2); \
- if (cd == NULL) \
- return WIMLIB_ERR_ICONV_NOT_AVAILABLE; \
- \
- chartype2 *buf; \
- size_t bufsize; \
- bool buf_onheap; \
- bufsize = (worst_case_len_expr) * sizeof(chartype2); \
- /* Worst case length */ \
- if (bufsize <= STACK_MAX) { \
- buf = alloca(bufsize); \
- buf_onheap = false; \
- } else { \
- buf = MALLOC(bufsize); \
- if (!buf) \
- return WIMLIB_ERR_NOMEM; \
- buf_onheap = true; \
- } \
- \
- char *inbuf = (char*)in; \
- size_t inbytesleft = in_nbytes; \
- char *outbuf = (char*)buf; \
- size_t outbytesleft = bufsize; \
- size_t len; \
- int ret; \
- \
- len = iconv(*cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); \
- if (len == (size_t)-1) { \
- err_msg; \
- ret = err_return; \
- } else { \
- *out_nbytes_ret = bufsize - outbytesleft; \
- ret = 0; \
- } \
- put_iconv(cd); \
- if (buf_onheap) \
- FREE(buf); \
- return ret; \
-} \
- \
-modifier int \
-varname1##_to_##varname2##_buf(const chartype1 *in, size_t in_nbytes, \
- chartype2 *out) \
-{ \
- iconv_t *cd = get_iconv(&iconv_##varname1##_to_##varname2); \
- if (cd == NULL) \
- return WIMLIB_ERR_ICONV_NOT_AVAILABLE; \
- \
- char *inbuf = (char*)in; \
- size_t inbytesleft = in_nbytes; \
- char *outbuf = (char*)out; \
- const size_t LARGE_NUMBER = 1000000000; \
- size_t outbytesleft = LARGE_NUMBER; \
- size_t len; \
- int ret; \
- \
- len = iconv(*cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); \
- if (len == (size_t)-1) { \
- err_msg; \
- ret = err_return; \
- } else { \
- out[(LARGE_NUMBER-outbytesleft)/sizeof(chartype2)] = 0; \
- ret = 0; \
- } \
- put_iconv(cd); \
- return ret; \
-} \
- \
-modifier int \
-varname1##_to_##varname2(const chartype1 *in, size_t in_nbytes, \
- chartype2 **out_ret, \
- size_t *out_nbytes_ret) \
-{ \
- int ret; \
- chartype2 *out; \
- size_t out_nbytes; \
- \
- if (earlyreturn_on_utf8_locale && wimlib_mbs_is_utf8) { \
- earlyreturn_expr; \
- /* Out same as in */ \
- out = MALLOC(in_nbytes + sizeof(chartype2)); \
- if (!out) \
- return WIMLIB_ERR_NOMEM; \
- memcpy(out, in, in_nbytes); \
- out[in_nbytes / sizeof(chartype2)] = 0; \
- *out_ret = out; \
- *out_nbytes_ret = in_nbytes; \
- return 0; \
- } \
- \
- ret = varname1##_to_##varname2##_nbytes(in, in_nbytes, \
- &out_nbytes); \
- if (ret) \
- return ret; \
- \
- out = MALLOC(out_nbytes + sizeof(chartype2)); \
- if (!out) \
- return WIMLIB_ERR_NOMEM; \
- \
- ret = varname1##_to_##varname2##_buf(in, in_nbytes, out); \
- if (ret) { \
- FREE(out); \
- } else { \
- *out_ret = out; \
- *out_nbytes_ret = out_nbytes; \
- } \
- return ret; \
+ /* U+10000...U+10FFFF */
+ VALIDATE(in[0] < 0xF8 && remaining >= 4 &&
+ IS_UTF8_TAIL(in[1]) &&
+ IS_UTF8_TAIL(in[2]) &&
+ IS_UTF8_TAIL(in[3]));
+ *c_ret = ((u32)(in[0] & 0x07) << 18) |
+ ((u32)(in[1] & 0x3F) << 12) |
+ ((u32)(in[2] & 0x3F) << 6) |
+ ((u32)(in[3] & 0x3F) << 0);
+ VALIDATE(*c_ret >= 0x10000 && *c_ret <= 0x10FFFF);
+ return 4;
+
+invalid:
+ *c_ret = INVALID_CODEPOINT;
+ return 1;
}
-#if !TCHAR_IS_UTF16LE
-
-/* UNIX */
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(utf8, "UTF-8", tchar,
- utf16le, "UTF-16LE", utf16lechar,
- false,
- ,
- in_nbytes * 2,
- WIMLIB_ERR_INVALID_UTF8_STRING,
- ERROR_WITH_ERRNO("Failed to convert UTF-8 string "
- "to UTF-16LE string!"),
- static)
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(utf16le, "UTF-16LE", utf16lechar,
- utf8, "UTF-8", tchar,
- false,
- ,
- in_nbytes * 2,
- WIMLIB_ERR_INVALID_UTF16_STRING,
- ERROR_WITH_ERRNO("Failed to convert UTF-16LE string "
- "to UTF-8 string!"),
- static)
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(tstr, "", tchar,
- utf16le, "UTF-16LE", utf16lechar,
- true,
- return utf8_to_utf16le(in, in_nbytes, out_ret, out_nbytes_ret),
- in_nbytes * 2,
- WIMLIB_ERR_INVALID_MULTIBYTE_STRING,
- ERROR_WITH_ERRNO("Failed to convert multibyte "
- "string \"%"TS"\" to UTF-16LE string!", in);
- ERROR("If the data you provided was UTF-8, please make sure "
- "the character encoding\n"
- " of your current locale is UTF-8."),
- )
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(utf16le, "UTF-16LE", utf16lechar,
- tstr, "", tchar,
- true,
- return utf16le_to_utf8(in, in_nbytes, out_ret, out_nbytes_ret),
- in_nbytes * 2,
- WIMLIB_ERR_UNICODE_STRING_NOT_REPRESENTABLE,
- ERROR("Failed to convert UTF-16LE string to "
- "multibyte string!");
- ERROR("This may be because the UTF-16LE string "
- "could not be represented\n"
- " in your locale's character encoding."),
- )
-#endif
+static forceinline unsigned
+utf8_encode_codepoint(u32 c, u8 *out)
+{
+ if (likely(c < 0x80)) {
+ out[0] = c;
+ return 1;
+ }
-/* tchar to UTF-8 and back */
-#if TCHAR_IS_UTF16LE
-
-/* Windows */
-DEFINE_CHAR_CONVERSION_FUNCTIONS(tstr, "UTF-16LE", tchar,
- utf8, "UTF-8", char,
- false,
- ,
- in_nbytes * 2,
- WIMLIB_ERR_INVALID_UTF16_STRING,
- ERROR_WITH_ERRNO("Failed to convert UTF-16LE "
- "string \"%"TS"\" to UTF-8 string!", in),
- )
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(utf8, "UTF-8", char,
- tstr, "UTF-16LE", tchar,
- false,
- ,
- in_nbytes * 2,
- WIMLIB_ERR_INVALID_UTF8_STRING,
- ERROR_WITH_ERRNO("Failed to convert UTF-8 string "
- "to UTF-16LE string!"),
- )
-#else
-
-/* UNIX */
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(tstr, "", tchar,
- utf8, "UTF-8", char,
- true,
- ,
- in_nbytes * 4,
- WIMLIB_ERR_INVALID_MULTIBYTE_STRING,
- ERROR_WITH_ERRNO("Failed to convert multibyte "
- "string \"%"TS"\" to UTF-8 string!", in);
- ERROR("If the data you provided was UTF-8, please make sure "
- "the character\n"
- " encoding of your current locale is UTF-8."),
- )
-
-DEFINE_CHAR_CONVERSION_FUNCTIONS(utf8, "UTF-8", char,
- tstr, "", tchar,
- true,
- ,
- in_nbytes * 4,
- WIMLIB_ERR_UNICODE_STRING_NOT_REPRESENTABLE,
- ERROR("Failed to convert UTF-8 string to "
- "multibyte string!");
- ERROR("This may be because the UTF-8 data "
- "could not be represented\n"
- " in your locale's character encoding."),
- )
-#endif
+ if (c < 0x800) {
+ out[0] = 0xC0 | (c >> 6);
+ out[1] = 0x80 | (c & 0x3F);
+ return 2;
+ }
-int
-tstr_to_utf8_simple(const tchar *tstr, char **out)
-{
- size_t out_nbytes;
- return tstr_to_utf8(tstr, tstrlen(tstr) * sizeof(tchar),
- out, &out_nbytes);
+ if (c < 0x10000) {
+ out[0] = 0xE0 | (c >> 12);
+ out[1] = 0x80 | ((c >> 6) & 0x3F);
+ out[2] = 0x80 | (c & 0x3F);
+ return 3;
+ }
+
+ out[0] = 0xF0 | (c >> 18);
+ out[1] = 0x80 | ((c >> 12) & 0x3F);
+ out[2] = 0x80 | ((c >> 6) & 0x3F);
+ out[3] = 0x80 | (c & 0x3F);
+ return 4;
}
-int
-utf8_to_tstr_simple(const char *utf8str, tchar **out)
+static forceinline unsigned
+utf16le_decode_codepoint(const u8 *in, size_t remaining, bool validate,
+ u32 *c_ret)
{
- size_t out_nbytes;
- return utf8_to_tstr(utf8str, strlen(utf8str), out, &out_nbytes);
+ u32 h, l;
+
+ VALIDATE(remaining >= 2);
+ h = get_unaligned_le16(in);
+ if (unlikely(IS_SURROGATE(h))) {
+ /* Surrogate pairs are U+10000...U+10FFFF.
+ * Unpaired surrogates are U+D800...U+DFFF. */
+ #if ALLOW_UNPAIRED_SURROGATES
+ if (unlikely(!IS_HIGH_SURROGATE(h) || remaining < 4))
+ goto unpaired;
+ l = get_unaligned_le16(in + 2);
+ if (unlikely(!IS_LOW_SURROGATE(l)))
+ goto unpaired;
+ #else
+ VALIDATE(IS_HIGH_SURROGATE(h) && remaining >= 4);
+ l = get_unaligned_le16(in + 2);
+ VALIDATE(IS_LOW_SURROGATE(l));
+ #endif
+ *c_ret = 0x10000 + ((h - 0xD800) << 10) + (l - 0xDC00);
+ return 4;
+ }
+#if ALLOW_UNPAIRED_SURROGATES
+unpaired:
+#endif
+ *c_ret = h;
+ return 2;
+
+invalid:
+ *c_ret = INVALID_CODEPOINT;
+ return min(remaining, 2);
}
-static void
-iconv_init(struct iconv_list_head *head)
+static forceinline unsigned
+utf16le_encode_codepoint(u32 c, u8 *out)
{
- pthread_mutex_init(&head->mutex, NULL);
- INIT_LIST_HEAD(&head->list);
+ if (likely(c < 0x10000)) {
+ put_unaligned_le16(c, out);
+ return 2;
+ }
+ c -= 0x10000;
+ put_unaligned_le16(0xD800 + (c >> 10), out);
+ put_unaligned_le16(0xDC00 + (c & 0x3FF), out + 2);
+ return 4;
}
-static void
-iconv_cleanup(struct iconv_list_head *head)
+/*
+ * Convert the string @in of size @in_nbytes from the encoding given by the
+ * @decode_codepoint function to the encoding given by the @encode_codepoint
+ * function. @in does not need to be null-terminated, but a null terminator
+ * will be added to the output string.
+ *
+ * On success, write the allocated output string to @out_ret (must not be NULL)
+ * and its size excluding the null terminator to @out_nbytes_ret (may be NULL).
+ *
+ * If the input string is malformed, return @ilseq_err with errno set to EILSEQ.
+ * If out of memory, return WIMLIB_ERR_NOMEM with errno set to ENOMEM.
+ */
+static forceinline int
+convert_string(const u8 * const in, const size_t in_nbytes,
+ u8 **out_ret, size_t *out_nbytes_ret,
+ int ilseq_err,
+ decode_codepoint_fn decode_codepoint,
+ encode_codepoint_fn encode_codepoint)
{
- pthread_mutex_destroy(&head->mutex);
- while (!list_empty(&head->list)) {
- struct iconv_node *i;
-
- i = container_of(head->list.next, struct iconv_node, list);
- list_del(&i->list);
- iconv_close(i->cd);
- FREE(i);
+ const u8 * const in_end = in + in_nbytes;
+ const u8 *p_in;
+ u8 *p_out;
+ size_t out_nbytes = 0;
+ u8 *out;
+ u8 tmp[8]; /* assuming no codepoint requires > 8 bytes to encode */
+ u32 c;
+
+ /* Validate the input string and compute the output size. */
+ for (p_in = in; p_in != in_end; ) {
+ p_in += (*decode_codepoint)(p_in, in_end - p_in, true, &c);
+ if (unlikely(c == INVALID_CODEPOINT)) {
+ errno = EILSEQ;
+ return ilseq_err;
+ }
+ out_nbytes += (*encode_codepoint)(c, tmp);
}
+
+ /* Allocate the output string, including space for a null terminator. */
+ out = MALLOC(out_nbytes + (*encode_codepoint)(0, tmp));
+ if (unlikely(!out))
+ return WIMLIB_ERR_NOMEM;
+
+ /* Do the conversion. */
+ for (p_in = in, p_out = out; p_in != in_end; ) {
+ p_in += (*decode_codepoint)(p_in, in_end - p_in, false, &c);
+ p_out += (*encode_codepoint)(c, p_out);
+ }
+
+ /* Add a null terminator. */
+ (*encode_codepoint)(0, p_out);
+
+ /* Return the output string and its size (by reference). */
+ *out_ret = out;
+ if (out_nbytes_ret)
+ *out_nbytes_ret = out_nbytes;
+ return 0;
}
-void
-iconv_global_init(void)
+int
+utf8_to_utf16le(const char *in, size_t in_nbytes,
+ utf16lechar **out_ret, size_t *out_nbytes_ret)
{
- iconv_init(&iconv_utf8_to_tstr);
- iconv_init(&iconv_tstr_to_utf8);
-#if !TCHAR_IS_UTF16LE
- iconv_init(&iconv_utf16le_to_tstr);
- iconv_init(&iconv_tstr_to_utf16le);
- iconv_init(&iconv_utf16le_to_utf8);
- iconv_init(&iconv_utf8_to_utf16le);
-#endif
+ return convert_string((const u8 *)in, in_nbytes,
+ (u8 **)out_ret, out_nbytes_ret,
+ WIMLIB_ERR_INVALID_UTF8_STRING,
+ utf8_decode_codepoint, utf16le_encode_codepoint);
}
-void
-iconv_global_cleanup(void)
+int
+utf16le_to_utf8(const utf16lechar *in, size_t in_nbytes,
+ char **out_ret, size_t *out_nbytes_ret)
{
- iconv_cleanup(&iconv_utf8_to_tstr);
- iconv_cleanup(&iconv_tstr_to_utf8);
-#if !TCHAR_IS_UTF16LE
- iconv_cleanup(&iconv_utf16le_to_tstr);
- iconv_cleanup(&iconv_tstr_to_utf16le);
- iconv_cleanup(&iconv_utf16le_to_utf8);
- iconv_cleanup(&iconv_utf8_to_utf16le);
-#endif
+ return convert_string((const u8 *)in, in_nbytes,
+ (u8 **)out_ret, out_nbytes_ret,
+ WIMLIB_ERR_INVALID_UTF16_STRING,
+ utf16le_decode_codepoint, utf8_encode_codepoint);
}
-/* A table that maps from UCS-2 characters to their upper case equivalents.
+/*
+ * A table that maps from UCS-2 characters to their upper case equivalents.
* Index and array values are both CPU endian.
* Note: this is only an *approximation* of real UTF-16 case folding.
*/
-static u16 upcase[65536];
+u16 upcase[65536];
void
init_upcase(void)
/* Delta filter */
for (u32 i = 0; i < ARRAY_LEN(upcase); i++)
upcase[i] += i;
-
-#if 0
- /* Sanity checks */
- wimlib_assert(upcase['a'] == 'A');
- wimlib_assert(upcase['A'] == 'A');
- wimlib_assert(upcase['z'] == 'Z');
- wimlib_assert(upcase['Z'] == 'Z');
- wimlib_assert(upcase['1'] == '1');
- wimlib_assert(upcase[0x00e9] == 0x00c9); /* Latin letter e, with acute accent */
- wimlib_assert(upcase[0x00c9] == 0x00c9);
- wimlib_assert(upcase[0x03c1] == 0x03a1); /* Greek letter rho */
- wimlib_assert(upcase[0x03a1] == 0x03a1);
- wimlib_assert(upcase[0x0436] == 0x0416); /* Cyrillic letter zhe */
- wimlib_assert(upcase[0x0416] == 0x0416);
- wimlib_assert(upcase[0x0567] == 0x0537); /* Armenian letter eh */
- wimlib_assert(upcase[0x0537] == 0x0537);
- wimlib_assert(upcase[0x24d0] == 0x24b6); /* Circled Latin letter A
- (is that a real character???) */
- wimlib_assert(upcase[0x24b6] == 0x24b6);
- wimlib_assert(upcase[0x2603] == 0x2603); /* Note to self: Upper case
- snowman symbol does not
- exist. */
-#endif
}
-/* Compare UTF-16LE strings case-sensitively (%ignore_case == false) or
+/*
+ * Compare UTF-16LE strings case-sensitively (%ignore_case == false) or
* case-insensitively (%ignore_case == true).
*
* This is implemented using the default upper-case table used by NTFS. It does
* not handle all possible cases allowed by UTF-16LE. For example, different
* normalizations of the same sequence of "characters" are not considered equal.
- * It hopefully does the right thing most of the time though. */
+ * It hopefully does the right thing most of the time though.
+ */
int
cmp_utf16le_strings(const utf16lechar *s1, size_t n1,
const utf16lechar *s2, size_t n2,
}
}
-/* Duplicate a UTF-16LE string. The input string might not be null terminated
- * and might be misaligned, but the returned string is guaranteed to be null
+/* Duplicate a UTF-16 string. The input string might not be null terminated and
+ * might be misaligned, but the returned string is guaranteed to be null
* terminated and properly aligned. */
utf16lechar *
-utf16le_dupz(const void *ustr, size_t usize)
+utf16le_dupz(const void *s, size_t size)
{
- utf16lechar *dup = MALLOC(usize + sizeof(utf16lechar));
+ utf16lechar *dup = MALLOC(size + sizeof(utf16lechar));
if (dup) {
- memcpy(dup, ustr, usize);
- dup[usize / sizeof(utf16lechar)] = 0;
+ memcpy(dup, s, size);
+ dup[size / sizeof(utf16lechar)] = 0;
}
return dup;
}
-/* Duplicate a null-terminated UTF-16LE string. */
+/* Duplicate a null-terminated UTF-16 string. */
utf16lechar *
-utf16le_dup(const utf16lechar *ustr)
+utf16le_dup(const utf16lechar *s)
{
- const utf16lechar *p = ustr;
- while (*p++)
- ;
- return memdup(ustr, (const u8 *)p - (const u8 *)ustr);
+ return memdup(s, utf16le_len_bytes(s) + sizeof(utf16lechar));
}
-/* Return the length, in bytes, of a UTF-null terminated UTF-16 string,
- * excluding the null terminator. */
+/* Return the length, in bytes, of a null terminated UTF-16 string, excluding
+ * the null terminator. */
size_t
utf16le_len_bytes(const utf16lechar *s)
{
return (p - s) * sizeof(utf16lechar);
}
-/* Return the length, in UTF-16 coding units, of a UTF-null terminated UTF-16
+/* Return the length, in UTF-16 coding units, of a null terminated UTF-16
* string, excluding the null terminator. */
size_t
utf16le_len_chars(const utf16lechar *s)