/*
******************************************************************************
*
* Copyright (C) 2001-2011, International Business Machines
* Corporation and others. All Rights Reserved.
*
******************************************************************************
* file name: utrie2.cpp
* encoding: US-ASCII
* tab size: 8 (not used)
* indentation:4
*
* created on: 2008aug16 (starting from a copy of utrie.c)
* created by: Markus W. Scherer
*
* This is a common implementation of a Unicode trie.
* It is a kind of compressed, serializable table of 16- or 32-bit values associated with
* Unicode code points (0..0x10ffff).
* This is the second common version of a Unicode trie (hence the name UTrie2).
* See utrie2.h for a comparison.
*
* This file contains only the runtime and enumeration code, for read-only access.
* See utrie2_builder.c for the builder code.
*/
#ifdef UTRIE2_DEBUG
# include <stdio.h>
#endif
#include "unicode/utypes.h"
#include "unicode/utf.h"
#include "unicode/utf8.h"
#include "unicode/utf16.h"
#include "cmemory.h"
#include "utrie2.h"
#include "utrie2_impl.h"
#include "uassert.h"
/* Public UTrie2 API implementation ----------------------------------------- */
static uint32_t
get32(const UNewTrie2 *trie, UChar32 c, UBool fromLSCP) {
int32_t i2, block;
if(c>=trie->highStart && (!U_IS_LEAD(c) || fromLSCP)) {
return trie->data[trie->dataLength-UTRIE2_DATA_GRANULARITY];
}
if(U_IS_LEAD(c) && fromLSCP) {
i2=(UTRIE2_LSCP_INDEX_2_OFFSET-(0xd800>>UTRIE2_SHIFT_2))+
(c>>UTRIE2_SHIFT_2);
} else {
i2=trie->index1[c>>UTRIE2_SHIFT_1]+
((c>>UTRIE2_SHIFT_2)&UTRIE2_INDEX_2_MASK);
}
block=trie->index2[i2];
return trie->data[block+(c&UTRIE2_DATA_MASK)];
}
U_CAPI uint32_t U_EXPORT2
utrie2_get32(const UTrie2 *trie, UChar32 c) {
if(trie->data16!=NULL) {
return UTRIE2_GET16(trie, c);
} else if(trie->data32!=NULL) {
return UTRIE2_GET32(trie, c);
} else if((uint32_t)c>0x10ffff) {
return trie->errorValue;
} else {
return get32(trie->newTrie, c, TRUE);
}
}
U_CAPI uint32_t U_EXPORT2
utrie2_get32FromLeadSurrogateCodeUnit(const UTrie2 *trie, UChar32 c) {
if(!U_IS_LEAD(c)) {
return trie->errorValue;
}
if(trie->data16!=NULL) {
return UTRIE2_GET16_FROM_U16_SINGLE_LEAD(trie, c);
} else if(trie->data32!=NULL) {
return UTRIE2_GET32_FROM_U16_SINGLE_LEAD(trie, c);
} else {
return get32(trie->newTrie, c, FALSE);
}
}
static inline int32_t
u8Index(const UTrie2 *trie, UChar32 c, int32_t i) {
int32_t idx=
_UTRIE2_INDEX_FROM_CP(
trie,
trie->data32==NULL ? trie->indexLength : 0,
c);
return (idx<<3)|i;
}
U_CAPI int32_t U_EXPORT2
utrie2_internalU8NextIndex(const UTrie2 *trie, UChar32 c,
const uint8_t *src, const uint8_t *limit) {
int32_t i, length;
i=0;
/* support 64-bit pointers by avoiding cast of arbitrary difference */
if((limit-src)<=7) {
length=(int32_t)(limit-src);
} else {
length=7;
}
c=utf8_nextCharSafeBody(src, &i, length, c, -1);
return u8Index(trie, c, i);
}
U_CAPI int32_t U_EXPORT2
utrie2_internalU8PrevIndex(const UTrie2 *trie, UChar32 c,
const uint8_t *start, const uint8_t *src) {
int32_t i, length;
/* support 64-bit pointers by avoiding cast of arbitrary difference */
if((src-start)<=7) {
i=length=(int32_t)(src-start);
} else {
i=length=7;
start=src-7;
}
c=utf8_prevCharSafeBody(start, 0, &i, c, -1);
i=length-i; /* number of bytes read backward from src */
return u8Index(trie, c, i);
}
U_CAPI UTrie2 * U_EXPORT2
utrie2_openFromSerialized(UTrie2ValueBits valueBits,
const void *data, int32_t length, int32_t *pActualLength,
UErrorCode *pErrorCode) {
const UTrie2Header *header;
const uint16_t *p16;
int32_t actualLength;
UTrie2 tempTrie;
UTrie2 *trie;
if(U_FAILURE(*pErrorCode)) {
return 0;
}
if( length<=0 || (U_POINTER_MASK_LSB(data, 3)!=0) ||
valueBits<0 || UTRIE2_COUNT_VALUE_BITS<=valueBits
) {
*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
/* enough data for a trie header? */
if(length<(int32_t)sizeof(UTrie2Header)) {
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
/* check the signature */
header=(const UTrie2Header *)data;
if(header->signature!=UTRIE2_SIG) {
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
/* get the options */
if(valueBits!=(UTrie2ValueBits)(header->options&UTRIE2_OPTIONS_VALUE_BITS_MASK)) {
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
/* get the length values and offsets */
uprv_memset(&tempTrie, 0, sizeof(tempTrie));
tempTrie.indexLength=header->indexLength;
tempTrie.dataLength=header->shiftedDataLength<<UTRIE2_INDEX_SHIFT;
tempTrie.index2NullOffset=header->index2NullOffset;
tempTrie.dataNullOffset=header->dataNullOffset;
tempTrie.highStart=header->shiftedHighStart<<UTRIE2_SHIFT_1;
tempTrie.highValueIndex=tempTrie.dataLength-UTRIE2_DATA_GRANULARITY;
if(valueBits==UTRIE2_16_VALUE_BITS) {
tempTrie.highValueIndex+=tempTrie.indexLength;
}
/* calculate the actual length */
actualLength=(int32_t)sizeof(UTrie2Header)+tempTrie.indexLength*2;
if(valueBits==UTRIE2_16_VALUE_BITS) {
actualLength+=tempTrie.dataLength*2;
} else {
actualLength+=tempTrie.dataLength*4;
}
if(length<actualLength) {
*pErrorCode=U_INVALID_FORMAT_ERROR; /* not enough bytes */
return 0;
}
/* allocate the trie */
trie=(UTrie2 *)uprv_malloc(sizeof(UTrie2));
if(trie==NULL) {
*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
return 0;
}
uprv_memcpy(trie, &tempTrie, sizeof(tempTrie));
trie->memory=(uint32_t *)data;
trie->length=actualLength;
trie->isMemoryOwned=FALSE;
/* set the pointers to its index and data arrays */
p16=(const uint16_t *)(header+1);
trie->index=p16;
p16+=trie->indexLength;
/* get the data */
switch(valueBits) {
case UTRIE2_16_VALUE_BITS:
trie->data16=p16;
trie->data32=NULL;
trie->initialValue=trie->index[trie->dataNullOffset];
trie->errorValue=trie->data16[UTRIE2_BAD_UTF8_DATA_OFFSET];
break;
case UTRIE2_32_VALUE_BITS:
trie->data16=NULL;
trie->data32=(const uint32_t *)p16;
trie->initialValue=trie->data32[trie->dataNullOffset];
trie->errorValue=trie->data32[UTRIE2_BAD_UTF8_DATA_OFFSET];
break;
default:
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
if(pActualLength!=NULL) {
*pActualLength=actualLength;
}
return trie;
}
U_CAPI UTrie2 * U_EXPORT2
utrie2_openDummy(UTrie2ValueBits valueBits,
uint32_t initialValue, uint32_t errorValue,
UErrorCode *pErrorCode) {
UTrie2 *trie;
UTrie2Header *header;
uint32_t *p;
uint16_t *dest16;
int32_t indexLength, dataLength, length, i;
int32_t dataMove; /* >0 if the data is moved to the end of the index array */
if(U_FAILURE(*pErrorCode)) {
return 0;
}
if(valueBits<0 || UTRIE2_COUNT_VALUE_BITS<=valueBits) {
*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
/* calculate the total length of the dummy trie data */
indexLength=UTRIE2_INDEX_1_OFFSET;
dataLength=UTRIE2_DATA_START_OFFSET+UTRIE2_DATA_GRANULARITY;
length=(int32_t)sizeof(UTrie2Header)+indexLength*2;
if(valueBits==UTRIE2_16_VALUE_BITS) {
length+=dataLength*2;
} else {
length+=dataLength*4;
}
/* allocate the trie */
trie=(UTrie2 *)uprv_malloc(sizeof(UTrie2));
if(trie==NULL) {
*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
return 0;
}
uprv_memset(trie, 0, sizeof(UTrie2));
trie->memory=uprv_malloc(length);
if(trie->memory==NULL) {
uprv_free(trie);
*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
return 0;
}
trie->length=length;
trie->isMemoryOwned=TRUE;
/* set the UTrie2 fields */
if(valueBits==UTRIE2_16_VALUE_BITS) {
dataMove=indexLength;
} else {
dataMove=0;
}
trie->indexLength=indexLength;
trie->dataLength=dataLength;
trie->index2NullOffset=UTRIE2_INDEX_2_OFFSET;
trie->dataNullOffset=(uint16_t)dataMove;
trie->initialValue=initialValue;
trie->errorValue=errorValue;
trie->highStart=0;
trie->highValueIndex=dataMove+UTRIE2_DATA_START_OFFSET;
/* set the header fields */
header=(UTrie2Header *)trie->memory;
header->signature=UTRIE2_SIG; /* "Tri2" */
header->options=(uint16_t)valueBits;
header->indexLength=(uint16_t)indexLength;
header->shiftedDataLength=(uint16_t)(dataLength>>UTRIE2_INDEX_SHIFT);
header->index2NullOffset=(uint16_t)UTRIE2_INDEX_2_OFFSET;
header->dataNullOffset=(uint16_t)dataMove;
header->shiftedHighStart=0;
/* fill the index and data arrays */
dest16=(uint16_t *)(header+1);
trie->index=dest16;
/* write the index-2 array values shifted right by UTRIE2_INDEX_SHIFT */
for(i=0; i<UTRIE2_INDEX_2_BMP_LENGTH; ++i) {
*dest16++=(uint16_t)(dataMove>>UTRIE2_INDEX_SHIFT); /* null data block */
}
/* write UTF-8 2-byte index-2 values, not right-shifted */
for(i=0; i<(0xc2-0xc0); ++i) { /* C0..C1 */
*dest16++=(uint16_t)(dataMove+UTRIE2_BAD_UTF8_DATA_OFFSET);
}
for(; i<(0xe0-0xc0); ++i) { /* C2..DF */
*dest16++=(uint16_t)dataMove;
}
/* write the 16/32-bit data array */
switch(valueBits) {
case UTRIE2_16_VALUE_BITS:
/* write 16-bit data values */
trie->data16=dest16;
trie->data32=NULL;
for(i=0; i<0x80; ++i) {
*dest16++=(uint16_t)initialValue;
}
for(; i<0xc0; ++i) {
*dest16++=(uint16_t)errorValue;
}
/* highValue and reserved values */
for(i=0; i<UTRIE2_DATA_GRANULARITY; ++i) {
*dest16++=(uint16_t)initialValue;
}
break;
case UTRIE2_32_VALUE_BITS:
/* write 32-bit data values */
p=(uint32_t *)dest16;
trie->data16=NULL;
trie->data32=p;
for(i=0; i<0x80; ++i) {
*p++=initialValue;
}
for(; i<0xc0; ++i) {
*p++=errorValue;
}
/* highValue and reserved values */
for(i=0; i<UTRIE2_DATA_GRANULARITY; ++i) {
*p++=initialValue;
}
break;
default:
*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
return trie;
}
U_CAPI void U_EXPORT2
utrie2_close(UTrie2 *trie) {
if(trie!=NULL) {
if(trie->isMemoryOwned) {
uprv_free(trie->memory);
}
if(trie->newTrie!=NULL) {
uprv_free(trie->newTrie->data);
uprv_free(trie->newTrie);
}
uprv_free(trie);
}
}
U_CAPI int32_t U_EXPORT2
utrie2_getVersion(const void *data, int32_t length, UBool anyEndianOk) {
uint32_t signature;
if(length<16 || data==NULL || (U_POINTER_MASK_LSB(data, 3)!=0)) {
return 0;
}
signature=*(const uint32_t *)data;
if(signature==UTRIE2_SIG) {
return 2;
}
if(anyEndianOk && signature==UTRIE2_OE_SIG) {
return 2;
}
if(signature==UTRIE_SIG) {
return 1;
}
if(anyEndianOk && signature==UTRIE_OE_SIG) {
return 1;
}
return 0;
}
U_CAPI int32_t U_EXPORT2
utrie2_swap(const UDataSwapper *ds,
const void *inData, int32_t length, void *outData,
UErrorCode *pErrorCode) {
const UTrie2Header *inTrie;
UTrie2Header trie;
int32_t dataLength, size;
UTrie2ValueBits valueBits;
if(U_FAILURE(*pErrorCode)) {
return 0;
}
if(ds==NULL || inData==NULL || (length>=0 && outData==NULL)) {
*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
/* setup and swapping */
if(length>=0 && length<(int32_t)sizeof(UTrie2Header)) {
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
return 0;
}
inTrie=(const UTrie2Header *)inData;
trie.signature=ds->readUInt32(inTrie->signature);
trie.options=ds->readUInt16(inTrie->options);
trie.indexLength=ds->readUInt16(inTrie->indexLength);
trie.shiftedDataLength=ds->readUInt16(inTrie->shiftedDataLength);
valueBits=(UTrie2ValueBits)(trie.options&UTRIE2_OPTIONS_VALUE_BITS_MASK);
dataLength=(int32_t)trie.shiftedDataLength<<UTRIE2_INDEX_SHIFT;
if( trie.signature!=UTRIE2_SIG ||
valueBits<0 || UTRIE2_COUNT_VALUE_BITS<=valueBits ||
trie.indexLength<UTRIE2_INDEX_1_OFFSET ||
dataLength<UTRIE2_DATA_START_OFFSET
) {
*pErrorCode=U_INVALID_FORMAT_ERROR; /* not a UTrie */
return 0;
}
size=sizeof(UTrie2Header)+trie.indexLength*2;
switch(valueBits) {
case UTRIE2_16_VALUE_BITS:
size+=dataLength*2;
break;
case UTRIE2_32_VALUE_BITS:
size+=dataLength*4;
break;
default:
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
if(length>=0) {
UTrie2Header *outTrie;
if(length<size) {
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
return 0;
}
outTrie=(UTrie2Header *)outData;
/* swap the header */
ds->swapArray32(ds, &inTrie->signature, 4, &outTrie->signature, pErrorCode);
ds->swapArray16(ds, &inTrie->options, 12, &outTrie->options, pErrorCode);
/* swap the index and the data */
switch(valueBits) {
case UTRIE2_16_VALUE_BITS:
ds->swapArray16(ds, inTrie+1, (trie.indexLength+dataLength)*2, outTrie+1, pErrorCode);
break;
case UTRIE2_32_VALUE_BITS:
ds->swapArray16(ds, inTrie+1, trie.indexLength*2, outTrie+1, pErrorCode);
ds->swapArray32(ds, (const uint16_t *)(inTrie+1)+trie.indexLength, dataLength*4,
(uint16_t *)(outTrie+1)+trie.indexLength, pErrorCode);
break;
default:
*pErrorCode=U_INVALID_FORMAT_ERROR;
return 0;
}
}
return size;
}
// utrie2_swapAnyVersion() should be defined here but lives in utrie2_builder.c
// to avoid a dependency from utrie2.cpp on utrie.c.
/* enumeration -------------------------------------------------------------- */
#define MIN_VALUE(a, b) ((a)<(b) ? (a) : (b))
/* default UTrie2EnumValue() returns the input value itself */
static uint32_t U_CALLCONV
enumSameValue(const void * /*context*/, uint32_t value) {
return value;
}
/**
* Enumerate all ranges of code points with the same relevant values.
* The values are transformed from the raw trie entries by the enumValue function.
*
* Currently requires start<limit and both start and limit must be multiples
* of UTRIE2_DATA_BLOCK_LENGTH.
*
* Optimizations:
* - Skip a whole block if we know that it is filled with a single value,
* and it is the same as we visited just before.
* - Handle the null block specially because we know a priori that it is filled
* with a single value.
*/
static void
enumEitherTrie(const UTrie2 *trie,
UChar32 start, UChar32 limit,
UTrie2EnumValue *enumValue, UTrie2EnumRange *enumRange, const void *context) {
const uint32_t *data32;
const uint16_t *idx;
uint32_t value, prevValue, initialValue;
UChar32 c, prev, highStart;
int32_t j, i2Block, prevI2Block, index2NullOffset, block, prevBlock, nullBlock;
if(enumRange==NULL) {
return;
}
if(enumValue==NULL) {
enumValue=enumSameValue;
}
if(trie->newTrie==NULL) {
/* frozen trie */
idx=trie->index;
U_ASSERT(idx!=NULL); /* the following code assumes trie->newTrie is not NULL when idx is NULL */
data32=trie->data32;
index2NullOffset=trie->index2NullOffset;
nullBlock=trie->dataNullOffset;
} else {
/* unfrozen, mutable trie */
idx=NULL;
data32=trie->newTrie->data;
U_ASSERT(data32!=NULL); /* the following code assumes idx is not NULL when data32 is NULL */
index2NullOffset=trie->newTrie->index2NullOffset;
nullBlock=trie->newTrie->dataNullOffset;
}
highStart=trie->highStart;
/* get the enumeration value that corresponds to an initial-value trie data entry */
initialValue=enumValue(context, trie->initialValue);
/* set variables for previous range */
prevI2Block=-1;
prevBlock=-1;
prev=start;
prevValue=0;
/* enumerate index-2 blocks */
for(c=start; c<limit && c<highStart;) {
/* Code point limit for iterating inside this i2Block. */
UChar32 tempLimit=c+UTRIE2_CP_PER_INDEX_1_ENTRY;
if(limit<tempLimit) {
tempLimit=limit;
}
if(c<=0xffff) {
if(!U_IS_SURROGATE(c)) {
i2Block=c>>UTRIE2_SHIFT_2;
} else if(U_IS_SURROGATE_LEAD(c)) {
/*
* Enumerate values for lead surrogate code points, not code units:
* This special block has half the normal length.
*/
i2Block=UTRIE2_LSCP_INDEX_2_OFFSET;
tempLimit=MIN_VALUE(0xdc00, limit);
} else {
/*
* Switch back to the normal part of the index-2 table.
* Enumerate the second half of the surrogates block.
*/
i2Block=0xd800>>UTRIE2_SHIFT_2;
tempLimit=MIN_VALUE(0xe000, limit);
}
} else {
/* supplementary code points */
if(idx!=NULL) {
i2Block=idx[(UTRIE2_INDEX_1_OFFSET-UTRIE2_OMITTED_BMP_INDEX_1_LENGTH)+
(c>>UTRIE2_SHIFT_1)];
} else {
i2Block=trie->newTrie->index1[c>>UTRIE2_SHIFT_1];
}
if(i2Block==prevI2Block && (c-prev)>=UTRIE2_CP_PER_INDEX_1_ENTRY) {
/*
* The index-2 block is the same as the previous one, and filled with prevValue.
* Only possible for supplementary code points because the linear-BMP index-2
* table creates unique i2Block values.
*/
c+=UTRIE2_CP_PER_INDEX_1_ENTRY;
continue;
}
}
prevI2Block=i2Block;
if(i2Block==index2NullOffset) {
/* this is the null index-2 block */
if(prevValue!=initialValue) {
if(prev<c && !enumRange(context, prev, c-1, prevValue)) {
return;
}
prevBlock=nullBlock;
prev=c;
prevValue=initialValue;
}
c+=UTRIE2_CP_PER_INDEX_1_ENTRY;
} else {
/* enumerate data blocks for one index-2 block */
int32_t i2, i2Limit;
i2=(c>>UTRIE2_SHIFT_2)&UTRIE2_INDEX_2_MASK;
if((c>>UTRIE2_SHIFT_1)==(tempLimit>>UTRIE2_SHIFT_1)) {
i2Limit=(tempLimit>>UTRIE2_SHIFT_2)&UTRIE2_INDEX_2_MASK;
} else {
i2Limit=UTRIE2_INDEX_2_BLOCK_LENGTH;
}
for(; i2<i2Limit; ++i2) {
if(idx!=NULL) {
block=(int32_t)idx[i2Block+i2]<<UTRIE2_INDEX_SHIFT;
} else {
block=trie->newTrie->index2[i2Block+i2];
}
if(block==prevBlock && (c-prev)>=UTRIE2_DATA_BLOCK_LENGTH) {
/* the block is the same as the previous one, and filled with prevValue */
c+=UTRIE2_DATA_BLOCK_LENGTH;
continue;
}
prevBlock=block;
if(block==nullBlock) {
/* this is the null data block */
if(prevValue!=initialValue) {
if(prev<c && !enumRange(context, prev, c-1, prevValue)) {
return;
}
prev=c;
prevValue=initialValue;
}
c+=UTRIE2_DATA_BLOCK_LENGTH;
} else {
for(j=0; j<UTRIE2_DATA_BLOCK_LENGTH; ++j) {
value=enumValue(context, data32!=NULL ? data32[block+j] : idx[block+j]);
if(value!=prevValue) {
if(prev<c && !enumRange(context, prev, c-1, prevValue)) {
return;
}
prev=c;
prevValue=value;
}
++c;
}
}
}
}
}
if(c>limit) {
c=limit; /* could be higher if in the index2NullOffset */
} else if(c<limit) {
/* c==highStart<limit */
uint32_t highValue;
if(idx!=NULL) {
highValue=
data32!=NULL ?
data32[trie->highValueIndex] :
idx[trie->highValueIndex];
} else {
highValue=trie->newTrie->data[trie->newTrie->dataLength-UTRIE2_DATA_GRANULARITY];
}
value=enumValue(context, highValue);
if(value!=prevValue) {
if(prev<c && !enumRange(context, prev, c-1, prevValue)) {
return;
}
prev=c;
prevValue=value;
}
c=limit;
}
/* deliver last range */
enumRange(context, prev, c-1, prevValue);
}
U_CAPI void U_EXPORT2
utrie2_enum(const UTrie2 *trie,
UTrie2EnumValue *enumValue, UTrie2EnumRange *enumRange, const void *context) {
enumEitherTrie(trie, 0, 0x110000, enumValue, enumRange, context);
}
U_CAPI void U_EXPORT2
utrie2_enumForLeadSurrogate(const UTrie2 *trie, UChar32 lead,
UTrie2EnumValue *enumValue, UTrie2EnumRange *enumRange,
const void *context) {
if(!U16_IS_LEAD(lead)) {
return;
}
lead=(lead-0xd7c0)<<10; /* start code point */
enumEitherTrie(trie, lead, lead+0x400, enumValue, enumRange, context);
}
/* C++ convenience wrappers ------------------------------------------------- */
U_NAMESPACE_BEGIN
uint16_t BackwardUTrie2StringIterator::previous16() {
codePointLimit=codePointStart;
if(start>=codePointStart) {
codePoint=U_SENTINEL;
return 0;
}
uint16_t result;
UTRIE2_U16_PREV16(trie, start, codePointStart, codePoint, result);
return result;
}
uint16_t ForwardUTrie2StringIterator::next16() {
codePointStart=codePointLimit;
if(codePointLimit==limit) {
codePoint=U_SENTINEL;
return 0;
}
uint16_t result;
UTRIE2_U16_NEXT16(trie, codePointLimit, limit, codePoint, result);
return result;
}
UTrie2 *UTrie2Singleton::getInstance(InstantiatorFn *instantiator, const void *context,
UErrorCode &errorCode) {
void *duplicate;
UTrie2 *instance=(UTrie2 *)singleton.getInstance(instantiator, context, duplicate, errorCode);
utrie2_close((UTrie2 *)duplicate);
return instance;
}
U_NAMESPACE_END