[apple/icu.git] / icuSources / layout / HangulLayoutEngine.cpp

/*
 * HangulLayoutEngine.cpp: OpenType processing for Han fonts.
 *
 * (C) Copyright IBM Corp. 1998-2013 - All Rights Reserved.
 */

#include "LETypes.h"
#include "LEScripts.h"
#include "LELanguages.h"

#include "LayoutEngine.h"
#include "OpenTypeLayoutEngine.h"
#include "HangulLayoutEngine.h"
#include "ScriptAndLanguageTags.h"
#include "LEGlyphStorage.h"
#include "OpenTypeTables.h"

U_NAMESPACE_BEGIN

UOBJECT_DEFINE_RTTI_IMPLEMENTATION(HangulOpenTypeLayoutEngine)


#define FEATURE_MAP(name) {name ## FeatureTag, name ## FeatureMask}

#define LJMO_FIRST 0x1100
#define LJMO_LAST  0x1159
#define LJMO_FILL  0x115F
#define LJMO_COUNT 19

#define VJMO_FIRST 0x1161
#define VJMO_LAST  0x11A2
#define VJMO_FILL  0x1160
#define VJMO_COUNT 21

#define TJMO_FIRST 0x11A7
#define TJMO_LAST  0x11F9
#define TJMO_COUNT 28

#define HSYL_FIRST 0xAC00
#define HSYL_COUNT 11172
#define HSYL_LVCNT (VJMO_COUNT * TJMO_COUNT)

// Character classes
enum
{
    CC_L = 0,
    CC_V,
    CC_T,
    CC_LV,
    CC_LVT,
    CC_X,
    CC_COUNT
};

// Action flags
#define AF_L 1
#define AF_V 2
#define AF_T 4

// Actions
#define a_N   0
#define a_L   (AF_L)
#define a_V   (AF_V)
#define a_T   (AF_T)
#define a_VT  (AF_V | AF_T)
#define a_LV  (AF_L | AF_V)
#define a_LVT (AF_L | AF_V | AF_T)

typedef struct
{
    int32_t newState;
    int32_t actionFlags;
} StateTransition;

static const StateTransition stateTable[][CC_COUNT] =
{
//       L          V          T          LV         LVT           X
    { {1, a_L},  {2, a_LV}, {3, a_LVT}, {2, a_LV}, {3, a_LVT},  {4, a_T}}, // 0 - start
    { {1, a_L},  {2, a_V},  {3, a_VT},  {2, a_LV}, {3, a_LVT}, {-1, a_V}}, // 1 - L+
    {{-1, a_N},  {2, a_V},  {3, a_T},  {-1, a_N}, {-1, a_N},   {-1, a_N}}, // 2 - L+V+
    {{-1, a_N}, {-1, a_N},  {3, a_T},  {-1, a_N}, {-1, a_N},   {-1, a_N}}, // 3 - L+V+T*
    {{-1, a_N}, {-1, a_N}, {-1, a_N},  {-1, a_N}, {-1, a_N},    {4, a_T}}  // 4 - X+
};


#define ccmpFeatureTag LE_CCMP_FEATURE_TAG
#define ljmoFeatureTag LE_LJMO_FEATURE_TAG
#define vjmoFeatureTag LE_VJMO_FEATURE_TAG
#define tjmoFeatureTag LE_TJMO_FEATURE_TAG

#define ccmpFeatureMask 0x80000000UL
#define ljmoFeatureMask 0x40000000UL
#define vjmoFeatureMask 0x20000000UL
#define tjmoFeatureMask 0x10000000UL

static const FeatureMap featureMap[] =
{
    {ccmpFeatureTag, ccmpFeatureMask},
    {ljmoFeatureTag, ljmoFeatureMask},
    {vjmoFeatureTag, vjmoFeatureMask},
    {tjmoFeatureTag, tjmoFeatureMask}
};

static const le_int32 featureMapCount = LE_ARRAY_SIZE(featureMap);

#define nullFeatures 0
#define ljmoFeatures (ccmpFeatureMask | ljmoFeatureMask)
#define vjmoFeatures (ccmpFeatureMask | vjmoFeatureMask | ljmoFeatureMask | tjmoFeatureMask)
#define tjmoFeatures (ccmpFeatureMask | tjmoFeatureMask | ljmoFeatureMask | vjmoFeatureMask)

static le_int32 compose(LEUnicode lead, LEUnicode vowel, LEUnicode trail, LEUnicode &syllable)
{
    le_int32 lIndex = lead  - LJMO_FIRST;
    le_int32 vIndex = vowel - VJMO_FIRST;
    le_int32 tIndex = trail - TJMO_FIRST;
    le_int32 result = 3;

    if ((lIndex < 0 || lIndex >= LJMO_COUNT ) || (vIndex < 0 || vIndex >= VJMO_COUNT)) {
        return 0;
    }

    if (tIndex <= 0 || tIndex >= TJMO_COUNT) {
        tIndex = 0;
        result = 2;
    }

    syllable = (LEUnicode) ((lIndex * VJMO_COUNT + vIndex) * TJMO_COUNT + tIndex + HSYL_FIRST);

    return result;
}

static le_int32 decompose(LEUnicode syllable, LEUnicode &lead, LEUnicode &vowel, LEUnicode &trail)
{
    le_int32 sIndex = syllable - HSYL_FIRST;

    if (sIndex < 0 || sIndex >= HSYL_COUNT) {
        return 0;
    }

    lead  = LJMO_FIRST + (sIndex / HSYL_LVCNT);
    vowel = VJMO_FIRST + (sIndex % HSYL_LVCNT) / TJMO_COUNT;
    trail = TJMO_FIRST + (sIndex % TJMO_COUNT);

    if (trail == TJMO_FIRST) {
        return 2;
    }

    return 3;
}

static le_int32 getCharClass(LEUnicode ch, LEUnicode &lead, LEUnicode &vowel, LEUnicode &trail)
{
    lead  = LJMO_FILL;
    vowel = VJMO_FILL;
    trail = TJMO_FIRST;

    if (ch >= LJMO_FIRST && ch <= LJMO_LAST) {
        lead  = ch;
        return CC_L;
    }

    if (ch >= VJMO_FIRST && ch <= VJMO_LAST) {
        vowel = ch;
        return CC_V;
    }

    if (ch > TJMO_FIRST && ch <= TJMO_LAST) {
        trail = ch;
        return CC_T;
    }

    le_int32 c = decompose(ch, lead, vowel, trail);

    if (c == 2) {
        return CC_LV;
    }

    if (c == 3) {
        return CC_LVT;
    }

    trail = ch;
    return CC_X;
}

HangulOpenTypeLayoutEngine::HangulOpenTypeLayoutEngine(const LEFontInstance *fontInstance, le_int32 scriptCode, le_int32 /*languageCode*/,
                                                       le_int32 typoFlags, const LEReferenceTo<GlyphSubstitutionTableHeader> &gsubTable, LEErrorCode &success)
    : OpenTypeLayoutEngine(fontInstance, scriptCode, korLanguageCode, typoFlags, gsubTable, success)
{
    fFeatureMap = featureMap;
    fFeatureMapCount = featureMapCount;
    fFeatureOrder = TRUE;
}

HangulOpenTypeLayoutEngine::HangulOpenTypeLayoutEngine(const LEFontInstance *fontInstance, le_int32 scriptCode, le_int32 /*languageCode*/,
			                                   le_int32 typoFlags, LEErrorCode &success)
    : OpenTypeLayoutEngine(fontInstance, scriptCode, korLanguageCode, typoFlags, success)
{
    fFeatureMap = featureMap;
    fFeatureMapCount = featureMapCount;
    fFeatureOrder = TRUE;
}

HangulOpenTypeLayoutEngine::~HangulOpenTypeLayoutEngine()
{
    // nothing to do
}

le_int32 HangulOpenTypeLayoutEngine::characterProcessing(const LEUnicode chars[], le_int32 offset, le_int32 count, le_int32 max, le_bool rightToLeft,
        LEUnicode *&outChars, LEGlyphStorage &glyphStorage, LEErrorCode &success)
{
    if (LE_FAILURE(success)) {
        return 0;
    }

    if (chars == NULL || offset < 0 || count < 0 || max < 0 || offset >= max || offset + count > max) {
        success = LE_ILLEGAL_ARGUMENT_ERROR;
        return 0;
    }

    le_int32 worstCase = count * 3;

    outChars = LE_NEW_ARRAY(LEUnicode, worstCase);

    if (outChars == NULL) {
        success = LE_MEMORY_ALLOCATION_ERROR;
        return 0;
    }

    glyphStorage.allocateGlyphArray(worstCase, rightToLeft, success);
    glyphStorage.allocateAuxData(success);

    if (LE_FAILURE(success)) {
        LE_DELETE_ARRAY(outChars);
        return 0;
    }

    le_int32 outCharCount = 0;
    le_int32 limit = offset + count;
    le_int32 i = offset;

    while (i < limit) {
        le_int32 state    = 0;
        le_int32 inStart  = i;
        le_int32 outStart = outCharCount;

        while( i < limit) {
            LEUnicode lead  = 0;
            LEUnicode vowel = 0;
            LEUnicode trail = 0;
            int32_t chClass = getCharClass(chars[i], lead, vowel, trail);
            const StateTransition transition = stateTable[state][chClass];

            if (chClass == CC_X) {
                /* Any character of type X will be stored as a trail jamo */
                if ((transition.actionFlags & AF_T) != 0) {
                    outChars[outCharCount] = trail;
                    glyphStorage.setCharIndex(outCharCount, i-offset, success);
                    glyphStorage.setAuxData(outCharCount++, nullFeatures, success);
                }
            } else {
                /* Any Hangul will be fully decomposed. Output the decomposed characters. */
                if ((transition.actionFlags & AF_L) != 0) {
                    outChars[outCharCount] = lead;
                    glyphStorage.setCharIndex(outCharCount, i-offset, success);
                    glyphStorage.setAuxData(outCharCount++, ljmoFeatures, success);
                }

                if ((transition.actionFlags & AF_V) != 0) {
                    outChars[outCharCount] = vowel;
                    glyphStorage.setCharIndex(outCharCount, i-offset, success);
                    glyphStorage.setAuxData(outCharCount++, vjmoFeatures, success);
                }

                if ((transition.actionFlags & AF_T) != 0) {
                    outChars[outCharCount] = trail;
                    glyphStorage.setCharIndex(outCharCount, i-offset, success);
                    glyphStorage.setAuxData(outCharCount++, tjmoFeatures, success);
                }
            }

            state = transition.newState;

            /* Negative next state means stop. */
            if (state < 0) {
                break;
            }

            i += 1;
        }

        le_int32 inLength  = i - inStart;
        le_int32 outLength = outCharCount - outStart;

        /*
         * See if the syllable can be composed into a single character. There are 5
         * possible cases:
         *
         *   Input     Decomposed to    Compose to
         *   LV        L, V             LV
         *   LVT       L, V, T          LVT
         *   L, V      L, V             LV, DEL
         *   LV, T     L, V, T          LVT, DEL
         *   L, V, T   L, V, T          LVT, DEL, DEL
         */
        if ((inLength >= 1 && inLength <= 3) && (outLength == 2 || outLength == 3)) {
            LEUnicode syllable = 0x0000;
            LEUnicode lead  = outChars[outStart];
            LEUnicode vowel = outChars[outStart + 1];
            LEUnicode trail = outLength == 3? outChars[outStart + 2] : TJMO_FIRST;

            /*
             * If the composition consumes the whole decomposed syllable,
             * we can use it.
             */
            if (compose(lead, vowel, trail, syllable) == outLength) {
                outCharCount = outStart;
                outChars[outCharCount] = syllable;
                glyphStorage.setCharIndex(outCharCount, inStart-offset, success);
                glyphStorage.setAuxData(outCharCount++, nullFeatures, success);

                /*
                 * Replace the rest of the input characters with DEL.
                 */
                for(le_int32 d = inStart + 1; d < i; d += 1) {
                    outChars[outCharCount] = 0xFFFF;
                    glyphStorage.setCharIndex(outCharCount, d - offset, success);
                    glyphStorage.setAuxData(outCharCount++, nullFeatures, success);
                }
            }
        }
    }

    glyphStorage.adoptGlyphCount(outCharCount);
    return outCharCount;
}

U_NAMESPACE_END
Commit	Line	Data
73c04bcf A	1	/*
	2	* HangulLayoutEngine.cpp: OpenType processing for Han fonts.
	3	*
57a6839d	4	* (C) Copyright IBM Corp. 1998-2013 - All Rights Reserved.
73c04bcf A	5	*/
	6
	7	#include "LETypes.h"
	8	#include "LEScripts.h"
	9	#include "LELanguages.h"
	10
	11	#include "LayoutEngine.h"
	12	#include "OpenTypeLayoutEngine.h"
	13	#include "HangulLayoutEngine.h"
	14	#include "ScriptAndLanguageTags.h"
	15	#include "LEGlyphStorage.h"
	16	#include "OpenTypeTables.h"
	17
	18	U_NAMESPACE_BEGIN
	19
	20	UOBJECT_DEFINE_RTTI_IMPLEMENTATION(HangulOpenTypeLayoutEngine)
	21
	22
	23	#define FEATURE_MAP(name) {name ## FeatureTag, name ## FeatureMask}
	24
	25	#define LJMO_FIRST 0x1100
	26	#define LJMO_LAST 0x1159
	27	#define LJMO_FILL 0x115F
	28	#define LJMO_COUNT 19
	29
	30	#define VJMO_FIRST 0x1161
	31	#define VJMO_LAST 0x11A2
	32	#define VJMO_FILL 0x1160
	33	#define VJMO_COUNT 21
	34
	35	#define TJMO_FIRST 0x11A7
	36	#define TJMO_LAST 0x11F9
	37	#define TJMO_COUNT 28
	38
	39	#define HSYL_FIRST 0xAC00
	40	#define HSYL_COUNT 11172
	41	#define HSYL_LVCNT (VJMO_COUNT * TJMO_COUNT)
	42
	43	// Character classes
	44	enum
	45	{
	46	CC_L = 0,
	47	CC_V,
	48	CC_T,
	49	CC_LV,
	50	CC_LVT,
	51	CC_X,
	52	CC_COUNT
	53	};
	54
	55	// Action flags
	56	#define AF_L 1
	57	#define AF_V 2
	58	#define AF_T 4
	59
	60	// Actions
	61	#define a_N 0
	62	#define a_L (AF_L)
	63	#define a_V (AF_V)
	64	#define a_T (AF_T)
	65	#define a_VT (AF_V \| AF_T)
	66	#define a_LV (AF_L \| AF_V)
	67	#define a_LVT (AF_L \| AF_V \| AF_T)
	68
69	typedef struct
70	{
71	int32_t newState;
72	int32_t actionFlags;
73	} StateTransition;
74
75	static const StateTransition stateTable[][CC_COUNT] =
76	{
77	// L V T LV LVT X
78	{ {1, a_L}, {2, a_LV}, {3, a_LVT}, {2, a_LV}, {3, a_LVT}, {4, a_T}}, // 0 - start
79	{ {1, a_L}, {2, a_V}, {3, a_VT}, {2, a_LV}, {3, a_LVT}, {-1, a_V}}, // 1 - L+
80	{{-1, a_N}, {2, a_V}, {3, a_T}, {-1, a_N}, {-1, a_N}, {-1, a_N}}, // 2 - L+V+
81	{{-1, a_N}, {-1, a_N}, {3, a_T}, {-1, a_N}, {-1, a_N}, {-1, a_N}}, // 3 - L+V+T*
82	{{-1, a_N}, {-1, a_N}, {-1, a_N}, {-1, a_N}, {-1, a_N}, {4, a_T}} // 4 - X+
83	};
84
85
86	#define ccmpFeatureTag LE_CCMP_FEATURE_TAG
87	#define ljmoFeatureTag LE_LJMO_FEATURE_TAG
88	#define vjmoFeatureTag LE_VJMO_FEATURE_TAG
89	#define tjmoFeatureTag LE_TJMO_FEATURE_TAG
90
91	#define ccmpFeatureMask 0x80000000UL
92	#define ljmoFeatureMask 0x40000000UL
93	#define vjmoFeatureMask 0x20000000UL
94	#define tjmoFeatureMask 0x10000000UL
95
96	static const FeatureMap featureMap[] =
97	{
98	{ccmpFeatureTag, ccmpFeatureMask},
99	{ljmoFeatureTag, ljmoFeatureMask},
100	{vjmoFeatureTag, vjmoFeatureMask},
101	{tjmoFeatureTag, tjmoFeatureMask}
102	};
103
104	static const le_int32 featureMapCount = LE_ARRAY_SIZE(featureMap);
105
106	#define nullFeatures 0
107	#define ljmoFeatures (ccmpFeatureMask \| ljmoFeatureMask)
108	#define vjmoFeatures (ccmpFeatureMask \| vjmoFeatureMask \| ljmoFeatureMask \| tjmoFeatureMask)
109	#define tjmoFeatures (ccmpFeatureMask \| tjmoFeatureMask \| ljmoFeatureMask \| vjmoFeatureMask)
110
111	static le_int32 compose(LEUnicode lead, LEUnicode vowel, LEUnicode trail, LEUnicode &syllable)
112	{
113	le_int32 lIndex = lead - LJMO_FIRST;
114	le_int32 vIndex = vowel - VJMO_FIRST;
115	le_int32 tIndex = trail - TJMO_FIRST;
116	le_int32 result = 3;
117
118	if ((lIndex < 0 \|\| lIndex >= LJMO_COUNT ) \|\| (vIndex < 0 \|\| vIndex >= VJMO_COUNT)) {
119	return 0;
120	}
121
122	if (tIndex <= 0 \|\| tIndex >= TJMO_COUNT) {
123	tIndex = 0;
124	result = 2;
125	}
126
127	syllable = (LEUnicode) ((lIndex * VJMO_COUNT + vIndex) * TJMO_COUNT + tIndex + HSYL_FIRST);
128
129	return result;
130	}
131
132	static le_int32 decompose(LEUnicode syllable, LEUnicode &lead, LEUnicode &vowel, LEUnicode &trail)
133	{
134	le_int32 sIndex = syllable - HSYL_FIRST;
135
136	if (sIndex < 0 \|\| sIndex >= HSYL_COUNT) {
137	return 0;
138	}
139
140	lead = LJMO_FIRST + (sIndex / HSYL_LVCNT);
141	vowel = VJMO_FIRST + (sIndex % HSYL_LVCNT) / TJMO_COUNT;
142	trail = TJMO_FIRST + (sIndex % TJMO_COUNT);
143
144	if (trail == TJMO_FIRST) {
145	return 2;
146	}
147
148	return 3;
149	}
150
151	static le_int32 getCharClass(LEUnicode ch, LEUnicode &lead, LEUnicode &vowel, LEUnicode &trail)
152	{
153	lead = LJMO_FILL;
154	vowel = VJMO_FILL;
155	trail = TJMO_FIRST;
156
157	if (ch >= LJMO_FIRST && ch <= LJMO_LAST) {
158	lead = ch;
159	return CC_L;
160	}
161
162	if (ch >= VJMO_FIRST && ch <= VJMO_LAST) {
163	vowel = ch;
164	return CC_V;
165	}
166
167	if (ch > TJMO_FIRST && ch <= TJMO_LAST) {
168	trail = ch;
169	return CC_T;
170	}
171
172	le_int32 c = decompose(ch, lead, vowel, trail);
173
174	if (c == 2) {
175	return CC_LV;
176	}
177
178	if (c == 3) {
179	return CC_LVT;
180	}
181
182	trail = ch;
183	return CC_X;
184	}
185
186	HangulOpenTypeLayoutEngine::HangulOpenTypeLayoutEngine(const LEFontInstance fontInstance, le_int32 scriptCode, le_int32 /languageCode*/,
57a6839d	187	le_int32 typoFlags, const LEReferenceTo<GlyphSubstitutionTableHeader> &gsubTable, LEErrorCode &success)
729e4ab9	188	: OpenTypeLayoutEngine(fontInstance, scriptCode, korLanguageCode, typoFlags, gsubTable, success)
73c04bcf A	189	{
	190	fFeatureMap = featureMap;
	191	fFeatureMapCount = featureMapCount;
	192	fFeatureOrder = TRUE;
	193	}
	194
	195	HangulOpenTypeLayoutEngine::HangulOpenTypeLayoutEngine(const LEFontInstance fontInstance, le_int32 scriptCode, le_int32 /languageCode*/,
729e4ab9 A	196	le_int32 typoFlags, LEErrorCode &success)
729e4ab9 A	197	: OpenTypeLayoutEngine(fontInstance, scriptCode, korLanguageCode, typoFlags, success)
73c04bcf A	198	{
	199	fFeatureMap = featureMap;
	200	fFeatureMapCount = featureMapCount;
	201	fFeatureOrder = TRUE;
	202	}
	203
	204	HangulOpenTypeLayoutEngine::~HangulOpenTypeLayoutEngine()
	205	{
	206	// nothing to do
	207	}
	208
	209	le_int32 HangulOpenTypeLayoutEngine::characterProcessing(const LEUnicode chars[], le_int32 offset, le_int32 count, le_int32 max, le_bool rightToLeft,
	210	LEUnicode *&outChars, LEGlyphStorage &glyphStorage, LEErrorCode &success)
	211	{
	212	if (LE_FAILURE(success)) {
	213	return 0;
	214	}
	215
	216	if (chars == NULL \|\| offset < 0 \|\| count < 0 \|\| max < 0 \|\| offset >= max \|\| offset + count > max) {
	217	success = LE_ILLEGAL_ARGUMENT_ERROR;
	218	return 0;
	219	}
	220
	221	le_int32 worstCase = count * 3;
	222
	223	outChars = LE_NEW_ARRAY(LEUnicode, worstCase);
	224
	225	if (outChars == NULL) {
	226	success = LE_MEMORY_ALLOCATION_ERROR;
	227	return 0;
	228	}
	229
	230	glyphStorage.allocateGlyphArray(worstCase, rightToLeft, success);
	231	glyphStorage.allocateAuxData(success);
	232
	233	if (LE_FAILURE(success)) {
	234	LE_DELETE_ARRAY(outChars);
	235	return 0;
	236	}
	237
	238	le_int32 outCharCount = 0;
	239	le_int32 limit = offset + count;
	240	le_int32 i = offset;
	241
	242	while (i < limit) {
	243	le_int32 state = 0;
	244	le_int32 inStart = i;
	245	le_int32 outStart = outCharCount;
	246
	247	while( i < limit) {
	248	LEUnicode lead = 0;
	249	LEUnicode vowel = 0;
	250	LEUnicode trail = 0;
	251	int32_t chClass = getCharClass(chars[i], lead, vowel, trail);
	252	const StateTransition transition = stateTable[state][chClass];
	253
	254	if (chClass == CC_X) {
	255	/* Any character of type X will be stored as a trail jamo */
	256	if ((transition.actionFlags & AF_T) != 0) {
	257	outChars[outCharCount] = trail;
	258	glyphStorage.setCharIndex(outCharCount, i-offset, success);
	259	glyphStorage.setAuxData(outCharCount++, nullFeatures, success);
	260	}
	261	} else {
262	/* Any Hangul will be fully decomposed. Output the decomposed characters. */
263	if ((transition.actionFlags & AF_L) != 0) {
264	outChars[outCharCount] = lead;
265	glyphStorage.setCharIndex(outCharCount, i-offset, success);
266	glyphStorage.setAuxData(outCharCount++, ljmoFeatures, success);
267	}
268
269	if ((transition.actionFlags & AF_V) != 0) {
270	outChars[outCharCount] = vowel;
271	glyphStorage.setCharIndex(outCharCount, i-offset, success);
272	glyphStorage.setAuxData(outCharCount++, vjmoFeatures, success);
273	}
274
275	if ((transition.actionFlags & AF_T) != 0) {
276	outChars[outCharCount] = trail;
277	glyphStorage.setCharIndex(outCharCount, i-offset, success);
278	glyphStorage.setAuxData(outCharCount++, tjmoFeatures, success);
279	}
280	}
281
282	state = transition.newState;
283
284	/* Negative next state means stop. */
285	if (state < 0) {
286	break;
287	}
288
289	i += 1;
290	}
291
292	le_int32 inLength = i - inStart;
293	le_int32 outLength = outCharCount - outStart;
294
295	/*
296	* See if the syllable can be composed into a single character. There are 5
297	* possible cases:
298	*
299	* Input Decomposed to Compose to
300	* LV L, V LV
301	* LVT L, V, T LVT
302	* L, V L, V LV, DEL
303	* LV, T L, V, T LVT, DEL
304	* L, V, T L, V, T LVT, DEL, DEL
305	*/
306	if ((inLength >= 1 && inLength <= 3) && (outLength == 2 \|\| outLength == 3)) {
307	LEUnicode syllable = 0x0000;
308	LEUnicode lead = outChars[outStart];
309	LEUnicode vowel = outChars[outStart + 1];
310	LEUnicode trail = outLength == 3? outChars[outStart + 2] : TJMO_FIRST;
311
312	/*
313	* If the composition consumes the whole decomposed syllable,
314	* we can use it.
315	*/
316	if (compose(lead, vowel, trail, syllable) == outLength) {
317	outCharCount = outStart;
318	outChars[outCharCount] = syllable;
319	glyphStorage.setCharIndex(outCharCount, inStart-offset, success);
320	glyphStorage.setAuxData(outCharCount++, nullFeatures, success);
321
322	/*
323	* Replace the rest of the input characters with DEL.
324	*/
325	for(le_int32 d = inStart + 1; d < i; d += 1) {
326	outChars[outCharCount] = 0xFFFF;
327	glyphStorage.setCharIndex(outCharCount, d - offset, success);
328	glyphStorage.setAuxData(outCharCount++, nullFeatures, success);
329	}
330	}
331	}
332	}
333
334	glyphStorage.adoptGlyphCount(outCharCount);
335	return outCharCount;
336	}
337
338	U_NAMESPACE_END