/*
******************************************************************************
*
* Copyright (C) 2001-2012, International Business Machines
* Corporation and others. All Rights Reserved.
*
******************************************************************************
*
* File ustrtrns.cpp
*
* Modification History:
*
* Date Name Description
* 9/10/2001 Ram Creation.
******************************************************************************
*/
/*******************************************************************************
*
* u_strTo* and u_strFrom* APIs
* WCS functions moved to ustr_wcs.c for better modularization
*
*******************************************************************************
*/
#include "unicode/putil.h"
#include "unicode/ustring.h"
#include "unicode/utf.h"
#include "unicode/utf8.h"
#include "unicode/utf16.h"
#include "cstring.h"
#include "cmemory.h"
#include "ustr_imp.h"
#include "uassert.h"
U_CAPI UChar* U_EXPORT2
u_strFromUTF32WithSub(UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar32 *src,
int32_t srcLength,
UChar32 subchar, int32_t *pNumSubstitutions,
UErrorCode *pErrorCode) {
const UChar32 *srcLimit;
UChar32 ch;
UChar *destLimit;
UChar *pDest;
int32_t reqLength;
int32_t numSubstitutions;
/* args check */
if(U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(destCapacity<0) || (dest == NULL && destCapacity > 0) ||
subchar > 0x10ffff || U_IS_SURROGATE(subchar)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(pNumSubstitutions != NULL) {
*pNumSubstitutions = 0;
}
pDest = dest;
destLimit = (dest!=NULL)?(dest + destCapacity):NULL;
reqLength = 0;
numSubstitutions = 0;
if(srcLength < 0) {
/* simple loop for conversion of a NUL-terminated BMP string */
while((ch=*src) != 0 &&
((uint32_t)ch < 0xd800 || (0xe000 <= ch && ch <= 0xffff))) {
++src;
if(pDest < destLimit) {
*pDest++ = (UChar)ch;
} else {
++reqLength;
}
}
srcLimit = src;
if(ch != 0) {
/* "complicated" case, find the end of the remaining string */
while(*++srcLimit != 0) {}
}
} else {
srcLimit = (src!=NULL)?(src + srcLength):NULL;
}
/* convert with length */
while(src < srcLimit) {
ch = *src++;
do {
/* usually "loops" once; twice only for writing subchar */
if((uint32_t)ch < 0xd800 || (0xe000 <= ch && ch <= 0xffff)) {
if(pDest < destLimit) {
*pDest++ = (UChar)ch;
} else {
++reqLength;
}
break;
} else if(0x10000 <= ch && ch <= 0x10ffff) {
if(pDest!=NULL && ((pDest + 2) <= destLimit)) {
*pDest++ = U16_LEAD(ch);
*pDest++ = U16_TRAIL(ch);
} else {
reqLength += 2;
}
break;
} else if((ch = subchar) < 0) {
/* surrogate code point, or not a Unicode code point at all */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else {
++numSubstitutions;
}
} while(TRUE);
}
reqLength += (int32_t)(pDest - dest);
if(pDestLength) {
*pDestLength = reqLength;
}
if(pNumSubstitutions != NULL) {
*pNumSubstitutions = numSubstitutions;
}
/* Terminate the buffer */
u_terminateUChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
U_CAPI UChar* U_EXPORT2
u_strFromUTF32(UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar32 *src,
int32_t srcLength,
UErrorCode *pErrorCode) {
return u_strFromUTF32WithSub(
dest, destCapacity, pDestLength,
src, srcLength,
U_SENTINEL, NULL,
pErrorCode);
}
U_CAPI UChar32* U_EXPORT2
u_strToUTF32WithSub(UChar32 *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar *src,
int32_t srcLength,
UChar32 subchar, int32_t *pNumSubstitutions,
UErrorCode *pErrorCode) {
const UChar *srcLimit;
UChar32 ch;
UChar ch2;
UChar32 *destLimit;
UChar32 *pDest;
int32_t reqLength;
int32_t numSubstitutions;
/* args check */
if(U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(destCapacity<0) || (dest == NULL && destCapacity > 0) ||
subchar > 0x10ffff || U_IS_SURROGATE(subchar)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(pNumSubstitutions != NULL) {
*pNumSubstitutions = 0;
}
pDest = dest;
destLimit = (dest!=NULL)?(dest + destCapacity):NULL;
reqLength = 0;
numSubstitutions = 0;
if(srcLength < 0) {
/* simple loop for conversion of a NUL-terminated BMP string */
while((ch=*src) != 0 && !U16_IS_SURROGATE(ch)) {
++src;
if(pDest < destLimit) {
*pDest++ = ch;
} else {
++reqLength;
}
}
srcLimit = src;
if(ch != 0) {
/* "complicated" case, find the end of the remaining string */
while(*++srcLimit != 0) {}
}
} else {
srcLimit = (src!=NULL)?(src + srcLength):NULL;
}
/* convert with length */
while(src < srcLimit) {
ch = *src++;
if(!U16_IS_SURROGATE(ch)) {
/* write or count ch below */
} else if(U16_IS_SURROGATE_LEAD(ch) && src < srcLimit && U16_IS_TRAIL(ch2 = *src)) {
++src;
ch = U16_GET_SUPPLEMENTARY(ch, ch2);
} else if((ch = subchar) < 0) {
/* unpaired surrogate */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else {
++numSubstitutions;
}
if(pDest < destLimit) {
*pDest++ = ch;
} else {
++reqLength;
}
}
reqLength += (int32_t)(pDest - dest);
if(pDestLength) {
*pDestLength = reqLength;
}
if(pNumSubstitutions != NULL) {
*pNumSubstitutions = numSubstitutions;
}
/* Terminate the buffer */
u_terminateUChar32s(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
U_CAPI UChar32* U_EXPORT2
u_strToUTF32(UChar32 *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar *src,
int32_t srcLength,
UErrorCode *pErrorCode) {
return u_strToUTF32WithSub(
dest, destCapacity, pDestLength,
src, srcLength,
U_SENTINEL, NULL,
pErrorCode);
}
/* for utf8_nextCharSafeBodyTerminated() */
static const UChar32
utf8_minLegal[4]={ 0, 0x80, 0x800, 0x10000 };
/*
* Version of utf8_nextCharSafeBody() with the following differences:
* - checks for NUL termination instead of length
* - works with pointers instead of indexes
* - always strict (strict==-1)
*
* *ps points to after the lead byte and will be moved to after the last trail byte.
* c is the lead byte.
* @return the code point, or U_SENTINEL
*/
static UChar32
utf8_nextCharSafeBodyTerminated(const uint8_t **ps, UChar32 c) {
const uint8_t *s=*ps;
uint8_t trail, illegal=0;
uint8_t count=U8_COUNT_TRAIL_BYTES(c);
U_ASSERT(count<6);
U8_MASK_LEAD_BYTE((c), count);
/* count==0 for illegally leading trail bytes and the illegal bytes 0xfe and 0xff */
switch(count) {
/* each branch falls through to the next one */
case 5:
case 4:
/* count>=4 is always illegal: no more than 3 trail bytes in Unicode's UTF-8 */
illegal=1;
break;
case 3:
trail=(uint8_t)(*s++ - 0x80);
c=(c<<6)|trail;
if(trail>0x3f || c>=0x110) {
/* not a trail byte, or code point>0x10ffff (outside Unicode) */
illegal=1;
break;
}
case 2: /*fall through*/
trail=(uint8_t)(*s++ - 0x80);
if(trail>0x3f) {
/* not a trail byte */
illegal=1;
break;
}
c=(c<<6)|trail;
case 1: /*fall through*/
trail=(uint8_t)(*s++ - 0x80);
if(trail>0x3f) {
/* not a trail byte */
illegal=1;
}
c=(c<<6)|trail;
break;
case 0:
return U_SENTINEL;
/* no default branch to optimize switch() - all values are covered */
}
/* correct sequence - all trail bytes have (b7..b6)==(10)? */
/* illegal is also set if count>=4 */
if(illegal || c<utf8_minLegal[count] || U_IS_SURROGATE(c)) {
/* error handling */
/* don't go beyond this sequence */
s=*ps;
while(count>0 && U8_IS_TRAIL(*s)) {
++s;
--count;
}
c=U_SENTINEL;
}
*ps=s;
return c;
}
/*
* Version of utf8_nextCharSafeBody() with the following differences:
* - works with pointers instead of indexes
* - always strict (strict==-1)
*
* *ps points to after the lead byte and will be moved to after the last trail byte.
* c is the lead byte.
* @return the code point, or U_SENTINEL
*/
static UChar32
utf8_nextCharSafeBodyPointer(const uint8_t **ps, const uint8_t *limit, UChar32 c) {
const uint8_t *s=*ps;
uint8_t trail, illegal=0;
uint8_t count=U8_COUNT_TRAIL_BYTES(c);
if((limit-s)>=count) {
U8_MASK_LEAD_BYTE((c), count);
/* count==0 for illegally leading trail bytes and the illegal bytes 0xfe and 0xff */
switch(count) {
/* each branch falls through to the next one */
case 5:
case 4:
/* count>=4 is always illegal: no more than 3 trail bytes in Unicode's UTF-8 */
illegal=1;
break;
case 3:
trail=*s++;
c=(c<<6)|(trail&0x3f);
if(c<0x110) {
illegal|=(trail&0xc0)^0x80;
} else {
/* code point>0x10ffff, outside Unicode */
illegal=1;
break;
}
case 2: /*fall through*/
trail=*s++;
c=(c<<6)|(trail&0x3f);
illegal|=(trail&0xc0)^0x80;
case 1: /*fall through*/
trail=*s++;
c=(c<<6)|(trail&0x3f);
illegal|=(trail&0xc0)^0x80;
break;
case 0:
return U_SENTINEL;
/* no default branch to optimize switch() - all values are covered */
}
} else {
illegal=1; /* too few bytes left */
}
/* correct sequence - all trail bytes have (b7..b6)==(10)? */
/* illegal is also set if count>=4 */
U_ASSERT(count<sizeof(utf8_minLegal)/sizeof(utf8_minLegal[0]));
if(illegal || c<utf8_minLegal[count] || U_IS_SURROGATE(c)) {
/* error handling */
/* don't go beyond this sequence */
s=*ps;
while(count>0 && s<limit && U8_IS_TRAIL(*s)) {
++s;
--count;
}
c=U_SENTINEL;
}
*ps=s;
return c;
}
U_CAPI UChar* U_EXPORT2
u_strFromUTF8WithSub(UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const char* src,
int32_t srcLength,
UChar32 subchar, int32_t *pNumSubstitutions,
UErrorCode *pErrorCode){
UChar *pDest = dest;
UChar *pDestLimit = dest+destCapacity;
UChar32 ch;
int32_t reqLength = 0;
const uint8_t* pSrc = (const uint8_t*) src;
uint8_t t1, t2; /* trail bytes */
int32_t numSubstitutions;
/* args check */
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(destCapacity<0) || (dest == NULL && destCapacity > 0) ||
subchar > 0x10ffff || U_IS_SURROGATE(subchar)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=0;
}
numSubstitutions=0;
/*
* Inline processing of UTF-8 byte sequences:
*
* Byte sequences for the most common characters are handled inline in
* the conversion loops. In order to reduce the path lengths for those
* characters, the tests are arranged in a kind of binary search.
* ASCII (<=0x7f) is checked first, followed by the dividing point
* between 2- and 3-byte sequences (0xe0).
* The 3-byte branch is tested first to speed up CJK text.
* The compiler should combine the subtractions for the two tests for 0xe0.
* Each branch then tests for the other end of its range.
*/
if(srcLength < 0){
/*
* Transform a NUL-terminated string.
* The code explicitly checks for NULs only in the lead byte position.
* A NUL byte in the trail byte position fails the trail byte range check anyway.
*/
while(((ch = *pSrc) != 0) && (pDest < pDestLimit)) {
if(ch <= 0x7f){
*pDest++=(UChar)ch;
++pSrc;
} else {
if(ch > 0xe0) {
if( /* handle U+1000..U+CFFF inline */
ch <= 0xec &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f &&
(t2 = (uint8_t)(pSrc[2] - 0x80)) <= 0x3f
) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
*pDest++ = (UChar)((ch << 12) | (t1 << 6) | t2);
pSrc += 3;
continue;
}
} else if(ch < 0xe0) {
if( /* handle U+0080..U+07FF inline */
ch >= 0xc2 &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f
) {
*pDest++ = (UChar)(((ch & 0x1f) << 6) | t1);
pSrc += 2;
continue;
}
}
/* function call for "complicated" and error cases */
++pSrc; /* continue after the lead byte */
ch=utf8_nextCharSafeBodyTerminated(&pSrc, ch);
if(ch<0 && (++numSubstitutions, ch = subchar) < 0) {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else if(ch<=0xFFFF) {
*(pDest++)=(UChar)ch;
} else {
*(pDest++)=U16_LEAD(ch);
if(pDest<pDestLimit) {
*(pDest++)=U16_TRAIL(ch);
} else {
reqLength++;
break;
}
}
}
}
/* Pre-flight the rest of the string. */
while((ch = *pSrc) != 0) {
if(ch <= 0x7f){
++reqLength;
++pSrc;
} else {
if(ch > 0xe0) {
if( /* handle U+1000..U+CFFF inline */
ch <= 0xec &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f &&
(uint8_t)(pSrc[2] - 0x80) <= 0x3f
) {
++reqLength;
pSrc += 3;
continue;
}
} else if(ch < 0xe0) {
if( /* handle U+0080..U+07FF inline */
ch >= 0xc2 &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f
) {
++reqLength;
pSrc += 2;
continue;
}
}
/* function call for "complicated" and error cases */
++pSrc; /* continue after the lead byte */
ch=utf8_nextCharSafeBodyTerminated(&pSrc, ch);
if(ch<0 && (++numSubstitutions, ch = subchar) < 0) {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
reqLength += U16_LENGTH(ch);
}
}
} else /* srcLength >= 0 */ {
const uint8_t *pSrcLimit = pSrc + srcLength;
int32_t count;
/* Faster loop without ongoing checking for pSrcLimit and pDestLimit. */
for(;;) {
/*
* Each iteration of the inner loop progresses by at most 3 UTF-8
* bytes and one UChar, for most characters.
* For supplementary code points (4 & 2), which are rare,
* there is an additional adjustment.
*/
count = (int32_t)(pDestLimit - pDest);
srcLength = (int32_t)((pSrcLimit - pSrc) / 3);
if(count > srcLength) {
count = srcLength; /* min(remaining dest, remaining src/3) */
}
if(count < 3) {
/*
* Too much overhead if we get near the end of the string,
* continue with the next loop.
*/
break;
}
do {
ch = *pSrc;
if(ch <= 0x7f){
*pDest++=(UChar)ch;
++pSrc;
} else {
if(ch > 0xe0) {
if( /* handle U+1000..U+CFFF inline */
ch <= 0xec &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f &&
(t2 = (uint8_t)(pSrc[2] - 0x80)) <= 0x3f
) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
*pDest++ = (UChar)((ch << 12) | (t1 << 6) | t2);
pSrc += 3;
continue;
}
} else if(ch < 0xe0) {
if( /* handle U+0080..U+07FF inline */
ch >= 0xc2 &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f
) {
*pDest++ = (UChar)(((ch & 0x1f) << 6) | t1);
pSrc += 2;
continue;
}
}
if(ch >= 0xf0 || subchar > 0xffff) {
/*
* We may read up to six bytes and write up to two UChars,
* which we didn't account for with computing count,
* so we adjust it here.
*/
if(--count == 0) {
break;
}
}
/* function call for "complicated" and error cases */
++pSrc; /* continue after the lead byte */
ch=utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
if(ch<0 && (++numSubstitutions, ch = subchar) < 0){
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}else if(ch<=0xFFFF){
*(pDest++)=(UChar)ch;
}else{
*(pDest++)=U16_LEAD(ch);
*(pDest++)=U16_TRAIL(ch);
}
}
} while(--count > 0);
}
while((pSrc<pSrcLimit) && (pDest<pDestLimit)) {
ch = *pSrc;
if(ch <= 0x7f){
*pDest++=(UChar)ch;
++pSrc;
} else {
if(ch > 0xe0) {
if( /* handle U+1000..U+CFFF inline */
ch <= 0xec &&
((pSrcLimit - pSrc) >= 3) &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f &&
(t2 = (uint8_t)(pSrc[2] - 0x80)) <= 0x3f
) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
*pDest++ = (UChar)((ch << 12) | (t1 << 6) | t2);
pSrc += 3;
continue;
}
} else if(ch < 0xe0) {
if( /* handle U+0080..U+07FF inline */
ch >= 0xc2 &&
((pSrcLimit - pSrc) >= 2) &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f
) {
*pDest++ = (UChar)(((ch & 0x1f) << 6) | t1);
pSrc += 2;
continue;
}
}
/* function call for "complicated" and error cases */
++pSrc; /* continue after the lead byte */
ch=utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
if(ch<0 && (++numSubstitutions, ch = subchar) < 0){
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}else if(ch<=0xFFFF){
*(pDest++)=(UChar)ch;
}else{
*(pDest++)=U16_LEAD(ch);
if(pDest<pDestLimit){
*(pDest++)=U16_TRAIL(ch);
}else{
reqLength++;
break;
}
}
}
}
/* do not fill the dest buffer just count the UChars needed */
while(pSrc < pSrcLimit){
ch = *pSrc;
if(ch <= 0x7f){
reqLength++;
++pSrc;
} else {
if(ch > 0xe0) {
if( /* handle U+1000..U+CFFF inline */
ch <= 0xec &&
((pSrcLimit - pSrc) >= 3) &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f &&
(uint8_t)(pSrc[2] - 0x80) <= 0x3f
) {
reqLength++;
pSrc += 3;
continue;
}
} else if(ch < 0xe0) {
if( /* handle U+0080..U+07FF inline */
ch >= 0xc2 &&
((pSrcLimit - pSrc) >= 2) &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f
) {
reqLength++;
pSrc += 2;
continue;
}
}
/* function call for "complicated" and error cases */
++pSrc; /* continue after the lead byte */
ch=utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
if(ch<0 && (++numSubstitutions, ch = subchar) < 0){
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
reqLength+=U16_LENGTH(ch);
}
}
}
reqLength+=(int32_t)(pDest - dest);
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=numSubstitutions;
}
if(pDestLength){
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateUChars(dest,destCapacity,reqLength,pErrorCode);
return dest;
}
U_CAPI UChar* U_EXPORT2
u_strFromUTF8(UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const char* src,
int32_t srcLength,
UErrorCode *pErrorCode){
return u_strFromUTF8WithSub(
dest, destCapacity, pDestLength,
src, srcLength,
U_SENTINEL, NULL,
pErrorCode);
}
U_CAPI UChar * U_EXPORT2
u_strFromUTF8Lenient(UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const char *src,
int32_t srcLength,
UErrorCode *pErrorCode) {
UChar *pDest = dest;
UChar32 ch;
int32_t reqLength = 0;
uint8_t* pSrc = (uint8_t*) src;
/* args check */
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(destCapacity<0) || (dest == NULL && destCapacity > 0)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(srcLength < 0) {
/* Transform a NUL-terminated string. */
UChar *pDestLimit = (dest!=NULL)?(dest+destCapacity):NULL;
uint8_t t1, t2, t3; /* trail bytes */
while(((ch = *pSrc) != 0) && (pDest < pDestLimit)) {
if(ch < 0xc0) {
/*
* ASCII, or a trail byte in lead position which is treated like
* a single-byte sequence for better character boundary
* resynchronization after illegal sequences.
*/
*pDest++=(UChar)ch;
++pSrc;
continue;
} else if(ch < 0xe0) { /* U+0080..U+07FF */
if((t1 = pSrc[1]) != 0) {
/* 0x3080 = (0xc0 << 6) + 0x80 */
*pDest++ = (UChar)((ch << 6) + t1 - 0x3080);
pSrc += 2;
continue;
}
} else if(ch < 0xf0) { /* U+0800..U+FFFF */
if((t1 = pSrc[1]) != 0 && (t2 = pSrc[2]) != 0) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
/* 0x2080 = (0x80 << 6) + 0x80 */
*pDest++ = (UChar)((ch << 12) + (t1 << 6) + t2 - 0x2080);
pSrc += 3;
continue;
}
} else /* f0..f4 */ { /* U+10000..U+10FFFF */
if((t1 = pSrc[1]) != 0 && (t2 = pSrc[2]) != 0 && (t3 = pSrc[3]) != 0) {
pSrc += 4;
/* 0x3c82080 = (0xf0 << 18) + (0x80 << 12) + (0x80 << 6) + 0x80 */
ch = (ch << 18) + (t1 << 12) + (t2 << 6) + t3 - 0x3c82080;
*(pDest++) = U16_LEAD(ch);
if(pDest < pDestLimit) {
*(pDest++) = U16_TRAIL(ch);
} else {
reqLength = 1;
break;
}
continue;
}
}
/* truncated character at the end */
*pDest++ = 0xfffd;
while(*++pSrc != 0) {}
break;
}
/* Pre-flight the rest of the string. */
while((ch = *pSrc) != 0) {
if(ch < 0xc0) {
/*
* ASCII, or a trail byte in lead position which is treated like
* a single-byte sequence for better character boundary
* resynchronization after illegal sequences.
*/
++reqLength;
++pSrc;
continue;
} else if(ch < 0xe0) { /* U+0080..U+07FF */
if(pSrc[1] != 0) {
++reqLength;
pSrc += 2;
continue;
}
} else if(ch < 0xf0) { /* U+0800..U+FFFF */
if(pSrc[1] != 0 && pSrc[2] != 0) {
++reqLength;
pSrc += 3;
continue;
}
} else /* f0..f4 */ { /* U+10000..U+10FFFF */
if(pSrc[1] != 0 && pSrc[2] != 0 && pSrc[3] != 0) {
reqLength += 2;
pSrc += 4;
continue;
}
}
/* truncated character at the end */
++reqLength;
break;
}
} else /* srcLength >= 0 */ {
const uint8_t *pSrcLimit = (pSrc!=NULL)?(pSrc + srcLength):NULL;
/*
* This function requires that if srcLength is given, then it must be
* destCapatity >= srcLength so that we need not check for
* destination buffer overflow in the loop.
*/
if(destCapacity < srcLength) {
if(pDestLength != NULL) {
*pDestLength = srcLength; /* this likely overestimates the true destLength! */
}
*pErrorCode = U_BUFFER_OVERFLOW_ERROR;
return NULL;
}
if((pSrcLimit - pSrc) >= 4) {
pSrcLimit -= 3; /* temporarily reduce pSrcLimit */
/* in this loop, we can always access at least 4 bytes, up to pSrc+3 */
do {
ch = *pSrc++;
if(ch < 0xc0) {
/*
* ASCII, or a trail byte in lead position which is treated like
* a single-byte sequence for better character boundary
* resynchronization after illegal sequences.
*/
*pDest++=(UChar)ch;
} else if(ch < 0xe0) { /* U+0080..U+07FF */
/* 0x3080 = (0xc0 << 6) + 0x80 */
*pDest++ = (UChar)((ch << 6) + *pSrc++ - 0x3080);
} else if(ch < 0xf0) { /* U+0800..U+FFFF */
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
/* 0x2080 = (0x80 << 6) + 0x80 */
ch = (ch << 12) + (*pSrc++ << 6);
*pDest++ = (UChar)(ch + *pSrc++ - 0x2080);
} else /* f0..f4 */ { /* U+10000..U+10FFFF */
/* 0x3c82080 = (0xf0 << 18) + (0x80 << 12) + (0x80 << 6) + 0x80 */
ch = (ch << 18) + (*pSrc++ << 12);
ch += *pSrc++ << 6;
ch += *pSrc++ - 0x3c82080;
*(pDest++) = U16_LEAD(ch);
*(pDest++) = U16_TRAIL(ch);
}
} while(pSrc < pSrcLimit);
pSrcLimit += 3; /* restore original pSrcLimit */
}
while(pSrc < pSrcLimit) {
ch = *pSrc++;
if(ch < 0xc0) {
/*
* ASCII, or a trail byte in lead position which is treated like
* a single-byte sequence for better character boundary
* resynchronization after illegal sequences.
*/
*pDest++=(UChar)ch;
continue;
} else if(ch < 0xe0) { /* U+0080..U+07FF */
if(pSrc < pSrcLimit) {
/* 0x3080 = (0xc0 << 6) + 0x80 */
*pDest++ = (UChar)((ch << 6) + *pSrc++ - 0x3080);
continue;
}
} else if(ch < 0xf0) { /* U+0800..U+FFFF */
if((pSrcLimit - pSrc) >= 2) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
/* 0x2080 = (0x80 << 6) + 0x80 */
ch = (ch << 12) + (*pSrc++ << 6);
*pDest++ = (UChar)(ch + *pSrc++ - 0x2080);
pSrc += 3;
continue;
}
} else /* f0..f4 */ { /* U+10000..U+10FFFF */
if((pSrcLimit - pSrc) >= 3) {
/* 0x3c82080 = (0xf0 << 18) + (0x80 << 12) + (0x80 << 6) + 0x80 */
ch = (ch << 18) + (*pSrc++ << 12);
ch += *pSrc++ << 6;
ch += *pSrc++ - 0x3c82080;
*(pDest++) = U16_LEAD(ch);
*(pDest++) = U16_TRAIL(ch);
pSrc += 4;
continue;
}
}
/* truncated character at the end */
*pDest++ = 0xfffd;
break;
}
}
reqLength+=(int32_t)(pDest - dest);
if(pDestLength){
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateUChars(dest,destCapacity,reqLength,pErrorCode);
return dest;
}
static inline uint8_t *
_appendUTF8(uint8_t *pDest, UChar32 c) {
/* it is 0<=c<=0x10ffff and not a surrogate if called by a validating function */
if((c)<=0x7f) {
*pDest++=(uint8_t)c;
} else if(c<=0x7ff) {
*pDest++=(uint8_t)((c>>6)|0xc0);
*pDest++=(uint8_t)((c&0x3f)|0x80);
} else if(c<=0xffff) {
*pDest++=(uint8_t)((c>>12)|0xe0);
*pDest++=(uint8_t)(((c>>6)&0x3f)|0x80);
*pDest++=(uint8_t)(((c)&0x3f)|0x80);
} else /* if((uint32_t)(c)<=0x10ffff) */ {
*pDest++=(uint8_t)(((c)>>18)|0xf0);
*pDest++=(uint8_t)((((c)>>12)&0x3f)|0x80);
*pDest++=(uint8_t)((((c)>>6)&0x3f)|0x80);
*pDest++=(uint8_t)(((c)&0x3f)|0x80);
}
return pDest;
}
U_CAPI char* U_EXPORT2
u_strToUTF8WithSub(char *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar *pSrc,
int32_t srcLength,
UChar32 subchar, int32_t *pNumSubstitutions,
UErrorCode *pErrorCode){
int32_t reqLength=0;
uint32_t ch=0,ch2=0;
uint8_t *pDest = (uint8_t *)dest;
uint8_t *pDestLimit = (pDest!=NULL)?(pDest + destCapacity):NULL;
int32_t numSubstitutions;
/* args check */
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)){
return NULL;
}
if( (pSrc==NULL && srcLength!=0) || srcLength < -1 ||
(destCapacity<0) || (dest == NULL && destCapacity > 0) ||
subchar > 0x10ffff || U_IS_SURROGATE(subchar)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=0;
}
numSubstitutions=0;
if(srcLength==-1) {
while((ch=*pSrc)!=0) {
++pSrc;
if(ch <= 0x7f) {
if(pDest<pDestLimit) {
*pDest++ = (uint8_t)ch;
} else {
reqLength = 1;
break;
}
} else if(ch <= 0x7ff) {
if((pDestLimit - pDest) >= 2) {
*pDest++=(uint8_t)((ch>>6)|0xc0);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 2;
break;
}
} else if(ch <= 0xd7ff || ch >= 0xe000) {
if((pDestLimit - pDest) >= 3) {
*pDest++=(uint8_t)((ch>>12)|0xe0);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 3;
break;
}
} else /* ch is a surrogate */ {
int32_t length;
/*need not check for NUL because NUL fails U16_IS_TRAIL() anyway*/
if(U16_IS_SURROGATE_LEAD(ch) && U16_IS_TRAIL(ch2=*pSrc)) {
++pSrc;
ch=U16_GET_SUPPLEMENTARY(ch, ch2);
} else if(subchar>=0) {
ch=subchar;
++numSubstitutions;
} else {
/* Unicode 3.2 forbids surrogate code points in UTF-8 */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
length = U8_LENGTH(ch);
if((pDestLimit - pDest) >= length) {
/* convert and append*/
pDest=_appendUTF8(pDest, ch);
} else {
reqLength = length;
break;
}
}
}
while((ch=*pSrc++)!=0) {
if(ch<=0x7f) {
++reqLength;
} else if(ch<=0x7ff) {
reqLength+=2;
} else if(!U16_IS_SURROGATE(ch)) {
reqLength+=3;
} else if(U16_IS_SURROGATE_LEAD(ch) && U16_IS_TRAIL(ch2=*pSrc)) {
++pSrc;
reqLength+=4;
} else if(subchar>=0) {
reqLength+=U8_LENGTH(subchar);
++numSubstitutions;
} else {
/* Unicode 3.2 forbids surrogate code points in UTF-8 */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
}
} else {
const UChar *pSrcLimit = (pSrc!=NULL)?(pSrc+srcLength):NULL;
int32_t count;
/* Faster loop without ongoing checking for pSrcLimit and pDestLimit. */
for(;;) {
/*
* Each iteration of the inner loop progresses by at most 3 UTF-8
* bytes and one UChar, for most characters.
* For supplementary code points (4 & 2), which are rare,
* there is an additional adjustment.
*/
count = (int32_t)((pDestLimit - pDest) / 3);
srcLength = (int32_t)(pSrcLimit - pSrc);
if(count > srcLength) {
count = srcLength; /* min(remaining dest/3, remaining src) */
}
if(count < 3) {
/*
* Too much overhead if we get near the end of the string,
* continue with the next loop.
*/
break;
}
do {
ch=*pSrc++;
if(ch <= 0x7f) {
*pDest++ = (uint8_t)ch;
} else if(ch <= 0x7ff) {
*pDest++=(uint8_t)((ch>>6)|0xc0);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else if(ch <= 0xd7ff || ch >= 0xe000) {
*pDest++=(uint8_t)((ch>>12)|0xe0);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else /* ch is a surrogate */ {
/*
* We will read two UChars and probably output four bytes,
* which we didn't account for with computing count,
* so we adjust it here.
*/
if(--count == 0) {
--pSrc; /* undo ch=*pSrc++ for the lead surrogate */
break; /* recompute count */
}
if(U16_IS_SURROGATE_LEAD(ch) && U16_IS_TRAIL(ch2=*pSrc)) {
++pSrc;
ch=U16_GET_SUPPLEMENTARY(ch, ch2);
/* writing 4 bytes per 2 UChars is ok */
*pDest++=(uint8_t)((ch>>18)|0xf0);
*pDest++=(uint8_t)(((ch>>12)&0x3f)|0x80);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
/* Unicode 3.2 forbids surrogate code points in UTF-8 */
if(subchar>=0) {
ch=subchar;
++numSubstitutions;
} else {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
/* convert and append*/
pDest=_appendUTF8(pDest, ch);
}
}
} while(--count > 0);
}
while(pSrc<pSrcLimit) {
ch=*pSrc++;
if(ch <= 0x7f) {
if(pDest<pDestLimit) {
*pDest++ = (uint8_t)ch;
} else {
reqLength = 1;
break;
}
} else if(ch <= 0x7ff) {
if((pDestLimit - pDest) >= 2) {
*pDest++=(uint8_t)((ch>>6)|0xc0);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 2;
break;
}
} else if(ch <= 0xd7ff || ch >= 0xe000) {
if((pDestLimit - pDest) >= 3) {
*pDest++=(uint8_t)((ch>>12)|0xe0);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 3;
break;
}
} else /* ch is a surrogate */ {
int32_t length;
if(U16_IS_SURROGATE_LEAD(ch) && pSrc<pSrcLimit && U16_IS_TRAIL(ch2=*pSrc)) {
++pSrc;
ch=U16_GET_SUPPLEMENTARY(ch, ch2);
} else if(subchar>=0) {
ch=subchar;
++numSubstitutions;
} else {
/* Unicode 3.2 forbids surrogate code points in UTF-8 */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
length = U8_LENGTH(ch);
if((pDestLimit - pDest) >= length) {
/* convert and append*/
pDest=_appendUTF8(pDest, ch);
} else {
reqLength = length;
break;
}
}
}
while(pSrc<pSrcLimit) {
ch=*pSrc++;
if(ch<=0x7f) {
++reqLength;
} else if(ch<=0x7ff) {
reqLength+=2;
} else if(!U16_IS_SURROGATE(ch)) {
reqLength+=3;
} else if(U16_IS_SURROGATE_LEAD(ch) && pSrc<pSrcLimit && U16_IS_TRAIL(ch2=*pSrc)) {
++pSrc;
reqLength+=4;
} else if(subchar>=0) {
reqLength+=U8_LENGTH(subchar);
++numSubstitutions;
} else {
/* Unicode 3.2 forbids surrogate code points in UTF-8 */
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
}
}
}
reqLength+=(int32_t)(pDest - (uint8_t *)dest);
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=numSubstitutions;
}
if(pDestLength){
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
U_CAPI char* U_EXPORT2
u_strToUTF8(char *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar *pSrc,
int32_t srcLength,
UErrorCode *pErrorCode){
return u_strToUTF8WithSub(
dest, destCapacity, pDestLength,
pSrc, srcLength,
U_SENTINEL, NULL,
pErrorCode);
}
U_CAPI UChar* U_EXPORT2
u_strFromJavaModifiedUTF8WithSub(
UChar *dest,
int32_t destCapacity,
int32_t *pDestLength,
const char *src,
int32_t srcLength,
UChar32 subchar, int32_t *pNumSubstitutions,
UErrorCode *pErrorCode) {
UChar *pDest = dest;
UChar *pDestLimit = dest+destCapacity;
UChar32 ch;
int32_t reqLength = 0;
const uint8_t* pSrc = (const uint8_t*) src;
const uint8_t *pSrcLimit;
int32_t count;
uint8_t t1, t2; /* trail bytes */
int32_t numSubstitutions;
/* args check */
if(U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(dest==NULL && destCapacity!=0) || destCapacity<0 ||
subchar > 0x10ffff || U_IS_SURROGATE(subchar)
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=0;
}
numSubstitutions=0;
if(srcLength < 0) {
/*
* Transform a NUL-terminated ASCII string.
* Handle non-ASCII strings with slower code.
*/
while(((ch = *pSrc) != 0) && ch <= 0x7f && (pDest < pDestLimit)) {
*pDest++=(UChar)ch;
++pSrc;
}
if(ch == 0) {
reqLength=(int32_t)(pDest - dest);
if(pDestLength) {
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateUChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
srcLength = uprv_strlen((const char *)pSrc);
}
/* Faster loop without ongoing checking for pSrcLimit and pDestLimit. */
pSrcLimit = (pSrc == NULL) ? NULL : pSrc + srcLength;
for(;;) {
count = (int32_t)(pDestLimit - pDest);
srcLength = (int32_t)(pSrcLimit - pSrc);
if(count >= srcLength && srcLength > 0 && *pSrc <= 0x7f) {
/* fast ASCII loop */
const uint8_t *prevSrc = pSrc;
int32_t delta;
while(pSrc < pSrcLimit && (ch = *pSrc) <= 0x7f) {
*pDest++=(UChar)ch;
++pSrc;
}
delta = (int32_t)(pSrc - prevSrc);
count -= delta;
srcLength -= delta;
}
/*
* Each iteration of the inner loop progresses by at most 3 UTF-8
* bytes and one UChar.
*/
srcLength /= 3;
if(count > srcLength) {
count = srcLength; /* min(remaining dest, remaining src/3) */
}
if(count < 3) {
/*
* Too much overhead if we get near the end of the string,
* continue with the next loop.
*/
break;
}
do {
ch = *pSrc;
if(ch <= 0x7f){
*pDest++=(UChar)ch;
++pSrc;
} else {
if(ch >= 0xe0) {
if( /* handle U+0000..U+FFFF inline */
ch <= 0xef &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f &&
(t2 = (uint8_t)(pSrc[2] - 0x80)) <= 0x3f
) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
*pDest++ = (UChar)((ch << 12) | (t1 << 6) | t2);
pSrc += 3;
continue;
}
} else {
if( /* handle U+0000..U+07FF inline */
ch >= 0xc0 &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f
) {
*pDest++ = (UChar)(((ch & 0x1f) << 6) | t1);
pSrc += 2;
continue;
}
}
if(subchar < 0) {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else if(subchar > 0xffff && --count == 0) {
/*
* We need to write two UChars, adjusted count for that,
* and ran out of space.
*/
break;
} else {
/* function call for error cases */
++pSrc; /* continue after the lead byte */
utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
++numSubstitutions;
if(subchar<=0xFFFF) {
*(pDest++)=(UChar)subchar;
} else {
*(pDest++)=U16_LEAD(subchar);
*(pDest++)=U16_TRAIL(subchar);
}
}
}
} while(--count > 0);
}
while((pSrc<pSrcLimit) && (pDest<pDestLimit)) {
ch = *pSrc;
if(ch <= 0x7f){
*pDest++=(UChar)ch;
++pSrc;
} else {
if(ch >= 0xe0) {
if( /* handle U+0000..U+FFFF inline */
ch <= 0xef &&
((pSrcLimit - pSrc) >= 3) &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f &&
(t2 = (uint8_t)(pSrc[2] - 0x80)) <= 0x3f
) {
/* no need for (ch & 0xf) because the upper bits are truncated after <<12 in the cast to (UChar) */
*pDest++ = (UChar)((ch << 12) | (t1 << 6) | t2);
pSrc += 3;
continue;
}
} else {
if( /* handle U+0000..U+07FF inline */
ch >= 0xc0 &&
((pSrcLimit - pSrc) >= 2) &&
(t1 = (uint8_t)(pSrc[1] - 0x80)) <= 0x3f
) {
*pDest++ = (UChar)(((ch & 0x1f) << 6) | t1);
pSrc += 2;
continue;
}
}
if(subchar < 0) {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else {
/* function call for error cases */
++pSrc; /* continue after the lead byte */
utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
++numSubstitutions;
if(subchar<=0xFFFF) {
*(pDest++)=(UChar)subchar;
} else {
*(pDest++)=U16_LEAD(subchar);
if(pDest<pDestLimit) {
*(pDest++)=U16_TRAIL(subchar);
} else {
reqLength++;
break;
}
}
}
}
}
/* do not fill the dest buffer just count the UChars needed */
while(pSrc < pSrcLimit){
ch = *pSrc;
if(ch <= 0x7f) {
reqLength++;
++pSrc;
} else {
if(ch >= 0xe0) {
if( /* handle U+0000..U+FFFF inline */
ch <= 0xef &&
((pSrcLimit - pSrc) >= 3) &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f &&
(uint8_t)(pSrc[2] - 0x80) <= 0x3f
) {
reqLength++;
pSrc += 3;
continue;
}
} else {
if( /* handle U+0000..U+07FF inline */
ch >= 0xc0 &&
((pSrcLimit - pSrc) >= 2) &&
(uint8_t)(pSrc[1] - 0x80) <= 0x3f
) {
reqLength++;
pSrc += 2;
continue;
}
}
if(subchar < 0) {
*pErrorCode = U_INVALID_CHAR_FOUND;
return NULL;
} else {
/* function call for error cases */
++pSrc; /* continue after the lead byte */
utf8_nextCharSafeBodyPointer(&pSrc, pSrcLimit, ch);
++numSubstitutions;
reqLength+=U16_LENGTH(ch);
}
}
}
if(pNumSubstitutions!=NULL) {
*pNumSubstitutions=numSubstitutions;
}
reqLength+=(int32_t)(pDest - dest);
if(pDestLength) {
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateUChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
U_CAPI char* U_EXPORT2
u_strToJavaModifiedUTF8(
char *dest,
int32_t destCapacity,
int32_t *pDestLength,
const UChar *src,
int32_t srcLength,
UErrorCode *pErrorCode) {
int32_t reqLength=0;
uint32_t ch=0;
uint8_t *pDest = (uint8_t *)dest;
uint8_t *pDestLimit = pDest + destCapacity;
const UChar *pSrcLimit;
int32_t count;
/* args check */
if(U_FAILURE(*pErrorCode)){
return NULL;
}
if( (src==NULL && srcLength!=0) || srcLength < -1 ||
(dest==NULL && destCapacity!=0) || destCapacity<0
) {
*pErrorCode = U_ILLEGAL_ARGUMENT_ERROR;
return NULL;
}
if(srcLength==-1) {
/* Convert NUL-terminated ASCII, then find the string length. */
while((ch=*src)<=0x7f && ch != 0 && pDest<pDestLimit) {
*pDest++ = (uint8_t)ch;
++src;
}
if(ch == 0) {
reqLength=(int32_t)(pDest - (uint8_t *)dest);
if(pDestLength) {
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}
srcLength = u_strlen(src);
}
/* Faster loop without ongoing checking for pSrcLimit and pDestLimit. */
pSrcLimit = (src!=NULL)?(src+srcLength):NULL;
for(;;) {
count = (int32_t)(pDestLimit - pDest);
srcLength = (int32_t)(pSrcLimit - src);
if(count >= srcLength && srcLength > 0 && *src <= 0x7f) {
/* fast ASCII loop */
const UChar *prevSrc = src;
int32_t delta;
while(src < pSrcLimit && (ch = *src) <= 0x7f && ch != 0) {
*pDest++=(uint8_t)ch;
++src;
}
delta = (int32_t)(src - prevSrc);
count -= delta;
srcLength -= delta;
}
/*
* Each iteration of the inner loop progresses by at most 3 UTF-8
* bytes and one UChar.
*/
count /= 3;
if(count > srcLength) {
count = srcLength; /* min(remaining dest/3, remaining src) */
}
if(count < 3) {
/*
* Too much overhead if we get near the end of the string,
* continue with the next loop.
*/
break;
}
do {
ch=*src++;
if(ch <= 0x7f && ch != 0) {
*pDest++ = (uint8_t)ch;
} else if(ch <= 0x7ff) {
*pDest++=(uint8_t)((ch>>6)|0xc0);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
*pDest++=(uint8_t)((ch>>12)|0xe0);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
}
} while(--count > 0);
}
while(src<pSrcLimit) {
ch=*src++;
if(ch <= 0x7f && ch != 0) {
if(pDest<pDestLimit) {
*pDest++ = (uint8_t)ch;
} else {
reqLength = 1;
break;
}
} else if(ch <= 0x7ff) {
if((pDestLimit - pDest) >= 2) {
*pDest++=(uint8_t)((ch>>6)|0xc0);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 2;
break;
}
} else {
if((pDestLimit - pDest) >= 3) {
*pDest++=(uint8_t)((ch>>12)|0xe0);
*pDest++=(uint8_t)(((ch>>6)&0x3f)|0x80);
*pDest++=(uint8_t)((ch&0x3f)|0x80);
} else {
reqLength = 3;
break;
}
}
}
while(src<pSrcLimit) {
ch=*src++;
if(ch <= 0x7f && ch != 0) {
++reqLength;
} else if(ch<=0x7ff) {
reqLength+=2;
} else {
reqLength+=3;
}
}
reqLength+=(int32_t)(pDest - (uint8_t *)dest);
if(pDestLength){
*pDestLength = reqLength;
}
/* Terminate the buffer */
u_terminateChars(dest, destCapacity, reqLength, pErrorCode);
return dest;
}