Sweden-Number/dlls/usp10/indic.c

364 lines
12 KiB
C

/*
* Implementation of Indic Syllables for the Uniscribe Script Processor
*
* Copyright 2011 CodeWeavers, Aric Stewart
*
* This 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 2.1 of the License, or (at your option) any later version.
*
* This 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 this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*
*/
#include "config.h"
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include "windef.h"
#include "winbase.h"
#include "winuser.h"
#include "wingdi.h"
#include "winnls.h"
#include "usp10.h"
#include "winternl.h"
#include "wine/debug.h"
#include "usp10_internal.h"
WINE_DEFAULT_DEBUG_CHANNEL(uniscribe);
static void debug_output_string(LPCWSTR str, int cChar, lexical_function f)
{
int i;
if (TRACE_ON(uniscribe))
{
for (i = 0; i < cChar; i++)
{
switch (f(str[i]))
{
case lex_Consonant: TRACE("C"); break;
case lex_Ra: TRACE("Ra"); break;
case lex_Vowel: TRACE("V"); break;
case lex_Nukta: TRACE("N"); break;
case lex_Halant: TRACE("H"); break;
case lex_ZWNJ: TRACE("Zwnj"); break;
case lex_ZWJ: TRACE("Zwj"); break;
case lex_Matra_post: TRACE("Mp");break;
case lex_Matra_above: TRACE("Ma");break;
case lex_Matra_below: TRACE("Mb");break;
case lex_Matra_pre: TRACE("Mm");break;
case lex_Modifier: TRACE("Sm"); break;
case lex_Vedic: TRACE("Vd"); break;
case lex_Anudatta: TRACE("A"); break;
case lex_Composed_Vowel: TRACE("t"); break;
default:
TRACE("X"); break;
}
}
TRACE("\n");
}
}
static inline BOOL is_matra( int type )
{
return (type == lex_Matra_above || type == lex_Matra_below ||
type == lex_Matra_pre || type == lex_Matra_post);
}
static inline BOOL is_joiner( int type )
{
return (type == lex_ZWJ || type == lex_ZWNJ);
}
static INT consonant_header(LPCWSTR input, INT cChar, INT start, INT next,
lexical_function lex)
{
if (!is_consonant( lex(input[next]) )) return -1;
next++;
if ((next < cChar) && lex(input[next]) == lex_Nukta)
next++;
if ((next < cChar) && lex(input[next])==lex_Halant)
{
next++;
if((next < cChar) && is_joiner( lex(input[next]) ))
next++;
if ((next < cChar) && is_consonant( lex(input[next]) ))
return next;
}
else if ((next < cChar) && is_joiner( lex(input[next]) ) && lex(input[next+1])==lex_Halant)
{
next+=2;
if ((next < cChar) && is_consonant( lex(input[next]) ))
return next;
}
return -1;
}
static INT parse_consonant_syllable(LPCWSTR input, INT cChar, INT start,
INT *main, INT next, lexical_function lex)
{
int check;
int headers = 0;
do
{
check = consonant_header(input,cChar,start,next,lex);
if (check != -1)
{
next = check;
headers++;
}
} while (check != -1);
if (headers || is_consonant( lex(input[next]) ))
{
*main = next;
next++;
}
else
return -1;
if ((next < cChar) && lex(input[next]) == lex_Nukta)
next++;
if ((next < cChar) && lex(input[next]) == lex_Anudatta)
next++;
if ((next < cChar) && lex(input[next]) == lex_Halant)
{
next++;
if((next < cChar) && is_joiner( lex(input[next]) ))
next++;
}
else if (next < cChar)
{
while((next < cChar) && is_matra( lex(input[next]) ))
next++;
if ((next < cChar) && lex(input[next]) == lex_Nukta)
next++;
if ((next < cChar) && lex(input[next]) == lex_Halant)
next++;
}
if ((next < cChar) && lex(input[next]) == lex_Modifier)
next++;
if ((next < cChar) && lex(input[next]) == lex_Vedic)
next++;
return next;
}
static INT parse_vowel_syllable(LPCWSTR input, INT cChar, INT start,
INT next, lexical_function lex)
{
if ((next < cChar) && lex(input[next]) == lex_Nukta)
next++;
if ((next < cChar) && is_joiner( lex(input[next]) ) && lex(input[next+1])==lex_Halant && is_consonant( lex(input[next+2]) ))
next+=3;
else if ((next < cChar) && lex(input[next])==lex_Halant && is_consonant( lex(input[next+1]) ))
next+=2;
else if ((next < cChar) && lex(input[next])==lex_ZWJ && is_consonant( lex(input[next+1]) ))
next+=2;
if ((next < cChar) && is_matra( lex(input[next]) ))
{
while((next < cChar) && is_matra( lex(input[next]) ))
next++;
if ((next < cChar) && lex(input[next]) == lex_Nukta)
next++;
if ((next < cChar) && lex(input[next]) == lex_Halant)
next++;
}
if ((next < cChar) && lex(input[next]) == lex_Modifier)
next++;
if ((next < cChar) && lex(input[next]) == lex_Vedic)
next++;
return next;
}
static INT Indic_process_next_syllable( LPCWSTR input, INT cChar, INT start, INT* main, INT next, lexical_function lex )
{
if (lex(input[next])==lex_Vowel)
{
*main = next;
return parse_vowel_syllable(input, cChar, start, next+1, lex);
}
else if ((cChar > next+3) && lex(input[next]) == lex_Ra && lex(input[next+1]) == lex_Halant && lex(input[next+2]) == lex_Vowel)
{
*main = next+2;
return parse_vowel_syllable(input, cChar, start, next+3, lex);
}
else if (start == next && lex(input[next])==lex_NBSP)
{
*main = next;
return parse_vowel_syllable(input, cChar, start, next+1, lex);
}
else if (start == next && (cChar > next+3) && lex(input[next]) == lex_Ra && lex(input[next+1]) == lex_Halant && lex(input[next+2]) == lex_NBSP)
{
*main = next+2;
return parse_vowel_syllable(input, cChar, start, next+3, lex);
}
return parse_consonant_syllable(input, cChar, start, main, next, lex);
}
static BOOL Consonent_is_post_base_form(HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR pwChar, IndicSyllable *s, lexical_function lexical, BOOL modern)
{
if (is_consonant(lexical(pwChar[s->base])) && s->base > s->start && lexical(pwChar[s->base-1]) == lex_Halant)
{
if (modern)
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, &pwChar[s->base-1], 1, 2, "pstf") > 0);
else
{
WCHAR cc[2];
cc[0] = pwChar[s->base];
cc[1] = pwChar[s->base-1];
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, cc, 1, 2, "pstf") > 0);
}
}
return FALSE;
}
static BOOL Consonent_is_below_base_form(HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR pwChar, IndicSyllable *s, lexical_function lexical, BOOL modern)
{
if (is_consonant(lexical(pwChar[s->base])) && s->base > s->start && lexical(pwChar[s->base-1]) == lex_Halant)
{
if (modern)
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, &pwChar[s->base-1], 1, 2, "blwf") > 0);
else
{
WCHAR cc[2];
cc[0] = pwChar[s->base];
cc[1] = pwChar[s->base-1];
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, cc, 1, 2, "blwf") > 0);
}
}
return FALSE;
}
static BOOL Consonent_is_pre_base_form(HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR pwChar, IndicSyllable *s, lexical_function lexical, BOOL modern)
{
if (is_consonant(lexical(pwChar[s->base])) && s->base > s->start && lexical(pwChar[s->base-1]) == lex_Halant)
{
if (modern)
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, &pwChar[s->base-1], 1, 2, "pref") > 0);
else
{
WCHAR cc[2];
cc[0] = pwChar[s->base];
cc[1] = pwChar[s->base-1];
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, cc, 1, 2, "pref") > 0);
}
}
return FALSE;
}
static BOOL Consonent_is_ralf(HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR pwChar, IndicSyllable *s, lexical_function lexical)
{
if ((lexical(pwChar[s->start])==lex_Ra) && s->end > s->start && lexical(pwChar[s->start+1]) == lex_Halant)
return (SHAPE_does_GSUB_feature_apply_to_chars(hdc, psa, psc, &pwChar[s->start], 1, 2, "rphf") > 0);
return FALSE;
}
static int FindBaseConsonant(HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR input, IndicSyllable *s, lexical_function lex, BOOL modern)
{
int i;
BOOL blwf = FALSE;
BOOL pref = FALSE;
/* remove ralf from consideration */
if (Consonent_is_ralf(hdc, psa, psc, input, s, lex))
{
s->ralf = s->start;
s->start+=2;
}
/* try to find a base consonant */
if (!is_consonant( lex(input[s->base]) ))
{
for (i = s->end; i >= s->start; i--)
if (is_consonant( lex(input[i]) ))
{
s->base = i;
break;
}
}
while ((blwf = Consonent_is_below_base_form(hdc, psa, psc, input, s, lex, modern)) || Consonent_is_post_base_form(hdc, psa, psc, input, s, lex, modern) || (pref = Consonent_is_pre_base_form(hdc, psa, psc, input, s, lex, modern)))
{
if (blwf && s->blwf == -1)
s->blwf = s->base - 1;
if (pref && s->pref == -1)
s->pref = s->base - 1;
for (i = s->base-1; i >= s->start; i--)
if (is_consonant( lex(input[i]) ))
{
s->base = i;
break;
}
}
if (s->ralf >= 0)
s->start = s->ralf;
if (s->ralf == s->base)
s->ralf = -1;
return s->base;
}
void Indic_ReorderCharacters( HDC hdc, SCRIPT_ANALYSIS *psa, ScriptCache* psc, LPWSTR input, int cChar, IndicSyllable **syllables, int *syllable_count, lexical_function lex, reorder_function reorder_f, BOOL modern)
{
int index = 0;
int next = 0;
int center = 0;
*syllable_count = 0;
if (!lex || ! reorder_f)
{
ERR("Failure to have required functions\n");
return;
}
debug_output_string(input, cChar, lex);
while (next != -1)
{
while((next < cChar) && lex(input[next]) == lex_Generic)
next++;
index = next;
if (next >= cChar)
break;
next = Indic_process_next_syllable(input, cChar, 0, &center, index, lex);
if (next != -1)
{
if (*syllable_count)
*syllables = HeapReAlloc(GetProcessHeap(),0,*syllables, sizeof(IndicSyllable)*(*syllable_count+1));
else
*syllables = HeapAlloc(GetProcessHeap(),0,sizeof(IndicSyllable));
(*syllables)[*syllable_count].start = index;
(*syllables)[*syllable_count].base = center;
(*syllables)[*syllable_count].ralf = -1;
(*syllables)[*syllable_count].blwf = -1;
(*syllables)[*syllable_count].pref = -1;
(*syllables)[*syllable_count].end = next-1;
FindBaseConsonant(hdc, psa, psc, input, &(*syllables)[*syllable_count], lex, modern);
reorder_f(input, &(*syllables)[*syllable_count], lex);
index = next;
*syllable_count = (*syllable_count)+1;
}
else if (index < cChar)
{
TRACE("Processing failed at %i\n",index);
next = ++index;
}
}
TRACE("Processed %i of %i characters into %i syllables\n",index,cChar,*syllable_count);
}