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glib/glib/gunidecomp.c
Christian Hergert 18a33f72db introspection: use (nullable) or (optional) instead of (allow-none) 
If we have an input parameter (or return value) we need to use (nullable).
However, if it is an (inout) or (out) parameter, (optional) is sufficient.

It looks like (nullable) could be used for everything according to the
Annotation documentation, but (optional) is more specific.
2016-11-22 14:14:37 -08:00

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/* decomp.c - Character decomposition.
*
* Copyright (C) 1999, 2000 Tom Tromey
* Copyright 2000 Red Hat, Inc.
*
* The Gnome Library 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 2 of the
* License, or (at your option) any later version.
*
* The Gnome Library 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 the Gnome Library; see the file COPYING.LIB. If not,
* see <http://www.gnu.org/licenses/>.
*/
/**
* SECTION:unicode
* @Title: Unicode Manipulation
* @Short_description: functions operating on Unicode characters and
* UTF-8 strings
* @See_also: g_locale_to_utf8(), g_locale_from_utf8()
*
* This section describes a number of functions for dealing with
* Unicode characters and strings. There are analogues of the
* traditional `ctype.h` character classification and case conversion
* functions, UTF-8 analogues of some string utility functions,
* functions to perform normalization, case conversion and collation
* on UTF-8 strings and finally functions to convert between the UTF-8,
* UTF-16 and UCS-4 encodings of Unicode.
*
* The implementations of the Unicode functions in GLib are based
* on the Unicode Character Data tables, which are available from
* [www.unicode.org](http://www.unicode.org/).
* GLib 2.8 supports Unicode 4.0, GLib 2.10 supports Unicode 4.1,
* GLib 2.12 supports Unicode 5.0, GLib 2.16.3 supports Unicode 5.1,
* GLib 2.30 supports Unicode 6.0.
*/
#include "config.h"
#include <stdlib.h>
#include "gunicode.h"
#include "gunidecomp.h"
#include "gmem.h"
#include "gunicomp.h"
#include "gunicodeprivate.h"
#define CC_PART1(Page, Char) \
((combining_class_table_part1[Page] >= G_UNICODE_MAX_TABLE_INDEX) \
? (combining_class_table_part1[Page] - G_UNICODE_MAX_TABLE_INDEX) \
: (cclass_data[combining_class_table_part1[Page]][Char]))
#define CC_PART2(Page, Char) \
((combining_class_table_part2[Page] >= G_UNICODE_MAX_TABLE_INDEX) \
? (combining_class_table_part2[Page] - G_UNICODE_MAX_TABLE_INDEX) \
: (cclass_data[combining_class_table_part2[Page]][Char]))
#define COMBINING_CLASS(Char) \
(((Char) <= G_UNICODE_LAST_CHAR_PART1) \
? CC_PART1 ((Char) >> 8, (Char) & 0xff) \
: (((Char) >= 0xe0000 && (Char) <= G_UNICODE_LAST_CHAR) \
? CC_PART2 (((Char) - 0xe0000) >> 8, (Char) & 0xff) \
: 0))
/**
* g_unichar_combining_class:
* @uc: a Unicode character
*
* Determines the canonical combining class of a Unicode character.
*
* Returns: the combining class of the character
*
* Since: 2.14
**/
gint
g_unichar_combining_class (gunichar uc)
{
return COMBINING_CLASS (uc);
}
/* constants for hangul syllable [de]composition */
#define SBase 0xAC00
#define LBase 0x1100
#define VBase 0x1161
#define TBase 0x11A7
#define LCount 19
#define VCount 21
#define TCount 28
#define NCount (VCount * TCount)
#define SCount (LCount * NCount)
/**
* g_unicode_canonical_ordering:
* @string: a UCS-4 encoded string.
* @len: the maximum length of @string to use.
*
* Computes the canonical ordering of a string in-place.
* This rearranges decomposed characters in the string
* according to their combining classes. See the Unicode
* manual for more information.
**/
void
g_unicode_canonical_ordering (gunichar *string,
gsize len)
{
gsize i;
int swap = 1;
while (swap)
{
int last;
swap = 0;
last = COMBINING_CLASS (string[0]);
for (i = 0; i < len - 1; ++i)
{
int next = COMBINING_CLASS (string[i + 1]);
if (next != 0 && last > next)
{
gsize j;
/* Percolate item leftward through string. */
for (j = i + 1; j > 0; --j)
{
gunichar t;
if (COMBINING_CLASS (string[j - 1]) <= next)
break;
t = string[j];
string[j] = string[j - 1];
string[j - 1] = t;
swap = 1;
}
/* We're re-entering the loop looking at the old
character again. */
next = last;
}
last = next;
}
}
}
/* http://www.unicode.org/unicode/reports/tr15/#Hangul
* r should be null or have sufficient space. Calling with r == NULL will
* only calculate the result_len; however, a buffer with space for three
* characters will always be big enough. */
static void
decompose_hangul (gunichar s,
gunichar *r,
gsize *result_len)
{
gint SIndex = s - SBase;
gint TIndex = SIndex % TCount;
if (r)
{
r[0] = LBase + SIndex / NCount;
r[1] = VBase + (SIndex % NCount) / TCount;
}
if (TIndex)
{
if (r)
r[2] = TBase + TIndex;
*result_len = 3;
}
else
*result_len = 2;
}
/* returns a pointer to a null-terminated UTF-8 string */
static const gchar *
find_decomposition (gunichar ch,
gboolean compat)
{
int start = 0;
int end = G_N_ELEMENTS (decomp_table);
if (ch >= decomp_table[start].ch &&
ch <= decomp_table[end - 1].ch)
{
while (TRUE)
{
int half = (start + end) / 2;
if (ch == decomp_table[half].ch)
{
int offset;
if (compat)
{
offset = decomp_table[half].compat_offset;
if (offset == G_UNICODE_NOT_PRESENT_OFFSET)
offset = decomp_table[half].canon_offset;
}
else
{
offset = decomp_table[half].canon_offset;
if (offset == G_UNICODE_NOT_PRESENT_OFFSET)
return NULL;
}
return &(decomp_expansion_string[offset]);
}
else if (half == start)
break;
else if (ch > decomp_table[half].ch)
start = half;
else
end = half;
}
}
return NULL;
}
/**
* g_unicode_canonical_decomposition:
* @ch: a Unicode character.
* @result_len: location to store the length of the return value.
*
* Computes the canonical decomposition of a Unicode character.
*
* Returns: a newly allocated string of Unicode characters.
* @result_len is set to the resulting length of the string.
*
* Deprecated: 2.30: Use the more flexible g_unichar_fully_decompose()
* instead.
**/
gunichar *
g_unicode_canonical_decomposition (gunichar ch,
gsize *result_len)
{
const gchar *decomp;
const gchar *p;
gunichar *r;
/* Hangul syllable */
if (ch >= SBase && ch < SBase + SCount)
{
decompose_hangul (ch, NULL, result_len);
r = g_malloc (*result_len * sizeof (gunichar));
decompose_hangul (ch, r, result_len);
}
else if ((decomp = find_decomposition (ch, FALSE)) != NULL)
{
/* Found it. */
int i;
*result_len = g_utf8_strlen (decomp, -1);
r = g_malloc (*result_len * sizeof (gunichar));
for (p = decomp, i = 0; *p != '\0'; p = g_utf8_next_char (p), i++)
r[i] = g_utf8_get_char (p);
}
else
{
/* Not in our table. */
r = g_malloc (sizeof (gunichar));
*r = ch;
*result_len = 1;
}
return r;
}
/* L,V => LV and LV,T => LVT */
static gboolean
combine_hangul (gunichar a,
gunichar b,
gunichar *result)
{
gint LIndex = a - LBase;
gint SIndex = a - SBase;
gint VIndex = b - VBase;
gint TIndex = b - TBase;
if (0 <= LIndex && LIndex < LCount
&& 0 <= VIndex && VIndex < VCount)
{
*result = SBase + (LIndex * VCount + VIndex) * TCount;
return TRUE;
}
else if (0 <= SIndex && SIndex < SCount && (SIndex % TCount) == 0
&& 0 < TIndex && TIndex < TCount)
{
*result = a + TIndex;
return TRUE;
}
return FALSE;
}
#define CI(Page, Char) \
((compose_table[Page] >= G_UNICODE_MAX_TABLE_INDEX) \
? (compose_table[Page] - G_UNICODE_MAX_TABLE_INDEX) \
: (compose_data[compose_table[Page]][Char]))
#define COMPOSE_INDEX(Char) \
(((Char >> 8) > (COMPOSE_TABLE_LAST)) ? 0 : CI((Char) >> 8, (Char) & 0xff))
static gboolean
combine (gunichar a,
gunichar b,
gunichar *result)
{
gushort index_a, index_b;
if (combine_hangul (a, b, result))
return TRUE;
index_a = COMPOSE_INDEX(a);
if (index_a >= COMPOSE_FIRST_SINGLE_START && index_a < COMPOSE_SECOND_START)
{
if (b == compose_first_single[index_a - COMPOSE_FIRST_SINGLE_START][0])
{
*result = compose_first_single[index_a - COMPOSE_FIRST_SINGLE_START][1];
return TRUE;
}
else
return FALSE;
}
index_b = COMPOSE_INDEX(b);
if (index_b >= COMPOSE_SECOND_SINGLE_START)
{
if (a == compose_second_single[index_b - COMPOSE_SECOND_SINGLE_START][0])
{
*result = compose_second_single[index_b - COMPOSE_SECOND_SINGLE_START][1];
return TRUE;
}
else
return FALSE;
}
if (index_a >= COMPOSE_FIRST_START && index_a < COMPOSE_FIRST_SINGLE_START &&
index_b >= COMPOSE_SECOND_START && index_b < COMPOSE_SECOND_SINGLE_START)
{
gunichar res = compose_array[index_a - COMPOSE_FIRST_START][index_b - COMPOSE_SECOND_START];
if (res)
{
*result = res;
return TRUE;
}
}
return FALSE;
}
gunichar *
_g_utf8_normalize_wc (const gchar *str,
gssize max_len,
GNormalizeMode mode)
{
gsize n_wc;
gunichar *wc_buffer;
const char *p;
gsize last_start;
gboolean do_compat = (mode == G_NORMALIZE_NFKC ||
mode == G_NORMALIZE_NFKD);
gboolean do_compose = (mode == G_NORMALIZE_NFC ||
mode == G_NORMALIZE_NFKC);
n_wc = 0;
p = str;
while ((max_len < 0 || p < str + max_len) && *p)
{
const gchar *decomp;
gunichar wc = g_utf8_get_char (p);
if (wc >= SBase && wc < SBase + SCount)
{
gsize result_len;
decompose_hangul (wc, NULL, &result_len);
n_wc += result_len;
}
else
{
decomp = find_decomposition (wc, do_compat);
if (decomp)
n_wc += g_utf8_strlen (decomp, -1);
else
n_wc++;
}
p = g_utf8_next_char (p);
}
wc_buffer = g_new (gunichar, n_wc + 1);
last_start = 0;
n_wc = 0;
p = str;
while ((max_len < 0 || p < str + max_len) && *p)
{
gunichar wc = g_utf8_get_char (p);
const gchar *decomp;
int cc;
gsize old_n_wc = n_wc;
if (wc >= SBase && wc < SBase + SCount)
{
gsize result_len;
decompose_hangul (wc, wc_buffer + n_wc, &result_len);
n_wc += result_len;
}
else
{
decomp = find_decomposition (wc, do_compat);
if (decomp)
{
const char *pd;
for (pd = decomp; *pd != '\0'; pd = g_utf8_next_char (pd))
wc_buffer[n_wc++] = g_utf8_get_char (pd);
}
else
wc_buffer[n_wc++] = wc;
}
if (n_wc > 0)
{
cc = COMBINING_CLASS (wc_buffer[old_n_wc]);
if (cc == 0)
{
g_unicode_canonical_ordering (wc_buffer + last_start, n_wc - last_start);
last_start = old_n_wc;
}
}
p = g_utf8_next_char (p);
}
if (n_wc > 0)
{
g_unicode_canonical_ordering (wc_buffer + last_start, n_wc - last_start);
last_start = n_wc;
}
wc_buffer[n_wc] = 0;
/* All decomposed and reordered */
if (do_compose && n_wc > 0)
{
gsize i, j;
int last_cc = 0;
last_start = 0;
for (i = 0; i < n_wc; i++)
{
int cc = COMBINING_CLASS (wc_buffer[i]);
if (i > 0 &&
(last_cc == 0 || last_cc < cc) &&
combine (wc_buffer[last_start], wc_buffer[i],
&wc_buffer[last_start]))
{
for (j = i + 1; j < n_wc; j++)
wc_buffer[j-1] = wc_buffer[j];
n_wc--;
i--;
if (i == last_start)
last_cc = 0;
else
last_cc = COMBINING_CLASS (wc_buffer[i-1]);
continue;
}
if (cc == 0)
last_start = i;
last_cc = cc;
}
}
wc_buffer[n_wc] = 0;
return wc_buffer;
}
/**
* g_utf8_normalize:
* @str: a UTF-8 encoded string.
* @len: length of @str, in bytes, or -1 if @str is nul-terminated.
* @mode: the type of normalization to perform.
*
* Converts a string into canonical form, standardizing
* such issues as whether a character with an accent
* is represented as a base character and combining
* accent or as a single precomposed character. The
* string has to be valid UTF-8, otherwise %NULL is
* returned. You should generally call g_utf8_normalize()
* before comparing two Unicode strings.
*
* The normalization mode %G_NORMALIZE_DEFAULT only
* standardizes differences that do not affect the
* text content, such as the above-mentioned accent
* representation. %G_NORMALIZE_ALL also standardizes
* the "compatibility" characters in Unicode, such
* as SUPERSCRIPT THREE to the standard forms
* (in this case DIGIT THREE). Formatting information
* may be lost but for most text operations such
* characters should be considered the same.
*
* %G_NORMALIZE_DEFAULT_COMPOSE and %G_NORMALIZE_ALL_COMPOSE
* are like %G_NORMALIZE_DEFAULT and %G_NORMALIZE_ALL,
* but returned a result with composed forms rather
* than a maximally decomposed form. This is often
* useful if you intend to convert the string to
* a legacy encoding or pass it to a system with
* less capable Unicode handling.
*
* Returns: a newly allocated string, that is the
* normalized form of @str, or %NULL if @str is not
* valid UTF-8.
**/
gchar *
g_utf8_normalize (const gchar *str,
gssize len,
GNormalizeMode mode)
{
gunichar *result_wc = _g_utf8_normalize_wc (str, len, mode);
gchar *result;
result = g_ucs4_to_utf8 (result_wc, -1, NULL, NULL, NULL);
g_free (result_wc);
return result;
}
static gboolean
decompose_hangul_step (gunichar ch,
gunichar *a,
gunichar *b)
{
gint SIndex, TIndex;
if (ch < SBase || ch >= SBase + SCount)
return FALSE; /* not a hangul syllable */
SIndex = ch - SBase;
TIndex = SIndex % TCount;
if (TIndex)
{
/* split LVT -> LV,T */
*a = ch - TIndex;
*b = TBase + TIndex;
}
else
{
/* split LV -> L,V */
*a = LBase + SIndex / NCount;
*b = VBase + (SIndex % NCount) / TCount;
}
return TRUE;
}
/**
* g_unichar_decompose:
* @ch: a Unicode character
* @a: return location for the first component of @ch
* @b: return location for the second component of @ch
*
* Performs a single decomposition step of the
* Unicode canonical decomposition algorithm.
*
* This function does not include compatibility
* decompositions. It does, however, include algorithmic
* Hangul Jamo decomposition, as well as 'singleton'
* decompositions which replace a character by a single
* other character. In the case of singletons *@b will
* be set to zero.
*
* If @ch is not decomposable, *@a is set to @ch and *@b
* is set to zero.
*
* Note that the way Unicode decomposition pairs are
* defined, it is guaranteed that @b would not decompose
* further, but @a may itself decompose. To get the full
* canonical decomposition for @ch, one would need to
* recursively call this function on @a. Or use
* g_unichar_fully_decompose().
*
* See
* [UAX#15](http://unicode.org/reports/tr15/)
* for details.
*
* Returns: %TRUE if the character could be decomposed
*
* Since: 2.30
*/
gboolean
g_unichar_decompose (gunichar ch,
gunichar *a,
gunichar *b)
{
gint start = 0;
gint end = G_N_ELEMENTS (decomp_step_table);
if (decompose_hangul_step (ch, a, b))
return TRUE;
/* TODO use bsearch() */
if (ch >= decomp_step_table[start].ch &&
ch <= decomp_step_table[end - 1].ch)
{
while (TRUE)
{
gint half = (start + end) / 2;
const decomposition_step *p = &(decomp_step_table[half]);
if (ch == p->ch)
{
*a = p->a;
*b = p->b;
return TRUE;
}
else if (half == start)
break;
else if (ch > p->ch)
start = half;
else
end = half;
}
}
*a = ch;
*b = 0;
return FALSE;
}
/**
* g_unichar_compose:
* @a: a Unicode character
* @b: a Unicode character
* @ch: return location for the composed character
*
* Performs a single composition step of the
* Unicode canonical composition algorithm.
*
* This function includes algorithmic Hangul Jamo composition,
* but it is not exactly the inverse of g_unichar_decompose().
* No composition can have either of @a or @b equal to zero.
* To be precise, this function composes if and only if
* there exists a Primary Composite P which is canonically
* equivalent to the sequence <@a,@b>. See the Unicode
* Standard for the definition of Primary Composite.
*
* If @a and @b do not compose a new character, @ch is set to zero.
*
* See
* [UAX#15](http://unicode.org/reports/tr15/)
* for details.
*
* Returns: %TRUE if the characters could be composed
*
* Since: 2.30
*/
gboolean
g_unichar_compose (gunichar a,
gunichar b,
gunichar *ch)
{
if (combine (a, b, ch))
return TRUE;
*ch = 0;
return FALSE;
}
/**
* g_unichar_fully_decompose:
* @ch: a Unicode character.
* @compat: whether perform canonical or compatibility decomposition
* @result: (nullable): location to store decomposed result, or %NULL
* @result_len: length of @result
*
* Computes the canonical or compatibility decomposition of a
* Unicode character. For compatibility decomposition,
* pass %TRUE for @compat; for canonical decomposition
* pass %FALSE for @compat.
*
* The decomposed sequence is placed in @result. Only up to
* @result_len characters are written into @result. The length
* of the full decomposition (irrespective of @result_len) is
* returned by the function. For canonical decomposition,
* currently all decompositions are of length at most 4, but
* this may change in the future (very unlikely though).
* At any rate, Unicode does guarantee that a buffer of length
* 18 is always enough for both compatibility and canonical
* decompositions, so that is the size recommended. This is provided
* as %G_UNICHAR_MAX_DECOMPOSITION_LENGTH.
*
* See
* [UAX#15](http://unicode.org/reports/tr15/)
* for details.
*
* Returns: the length of the full decomposition.
*
* Since: 2.30
**/
gsize
g_unichar_fully_decompose (gunichar ch,
gboolean compat,
gunichar *result,
gsize result_len)
{
const gchar *decomp;
const gchar *p;
/* Hangul syllable */
if (ch >= SBase && ch < SBase + SCount)
{
gsize len, i;
gunichar buffer[3];
decompose_hangul (ch, result ? buffer : NULL, &len);
if (result)
for (i = 0; i < len && i < result_len; i++)
result[i] = buffer[i];
return len;
}
else if ((decomp = find_decomposition (ch, compat)) != NULL)
{
/* Found it. */
gsize len, i;
len = g_utf8_strlen (decomp, -1);
for (p = decomp, i = 0; i < len && i < result_len; p = g_utf8_next_char (p), i++)
result[i] = g_utf8_get_char (p);
return len;
}
/* Does not decompose */
if (result && result_len >= 1)
*result = ch;
return 1;
}
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