/* ********************************************************************** * Copyright (C) 2002-2009, International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************** * file name: ucnv_u16.c * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created on: 2002jul01 * created by: Markus W. Scherer * * UTF-16 converter implementation. Used to be in ucnv_utf.c. */ #include "unicode/utypes.h" #if !UCONFIG_NO_CONVERSION #include "unicode/ucnv.h" #include "ucnv_bld.h" #include "ucnv_cnv.h" #include "cmemory.h" enum { UCNV_NEED_TO_WRITE_BOM=1 }; /* * The UTF-16 toUnicode implementation is also used for the Java-specific * "with BOM" variants of UTF-16BE and UTF-16LE. */ static void _UTF16ToUnicodeWithOffsets(UConverterToUnicodeArgs *pArgs, UErrorCode *pErrorCode); /* UTF-16BE ----------------------------------------------------------------- */ #if U_IS_BIG_ENDIAN # define _UTF16PEFromUnicodeWithOffsets _UTF16BEFromUnicodeWithOffsets #else # define _UTF16PEFromUnicodeWithOffsets _UTF16LEFromUnicodeWithOffsets #endif static void _UTF16BEFromUnicodeWithOffsets(UConverterFromUnicodeArgs *pArgs, UErrorCode *pErrorCode) { UConverter *cnv; const UChar *source; char *target; int32_t *offsets; uint32_t targetCapacity, length, sourceIndex; UChar c, trail; char overflow[4]; source=pArgs->source; length=(int32_t)(pArgs->sourceLimit-source); if(length<=0) { /* no input, nothing to do */ return; } cnv=pArgs->converter; /* write the BOM if necessary */ if(cnv->fromUnicodeStatus==UCNV_NEED_TO_WRITE_BOM) { static const char bom[]={ (char)0xfe, (char)0xff }; ucnv_fromUWriteBytes(cnv, bom, 2, &pArgs->target, pArgs->targetLimit, &pArgs->offsets, -1, pErrorCode); cnv->fromUnicodeStatus=0; } target=pArgs->target; if(target >= pArgs->targetLimit) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; return; } targetCapacity=(uint32_t)(pArgs->targetLimit-target); offsets=pArgs->offsets; sourceIndex=0; /* c!=0 indicates in several places outside the main loops that a surrogate was found */ if((c=(UChar)cnv->fromUChar32)!=0 && U16_IS_TRAIL(trail=*source) && targetCapacity>=4) { /* the last buffer ended with a lead surrogate, output the surrogate pair */ ++source; --length; target[0]=(uint8_t)(c>>8); target[1]=(uint8_t)c; target[2]=(uint8_t)(trail>>8); target[3]=(uint8_t)trail; target+=4; targetCapacity-=4; if(offsets!=NULL) { *offsets++=-1; *offsets++=-1; *offsets++=-1; *offsets++=-1; } sourceIndex=1; cnv->fromUChar32=c=0; } if(c==0) { /* copy an even number of bytes for complete UChars */ uint32_t count=2*length; if(count>targetCapacity) { count=targetCapacity&~1; } /* count is even */ targetCapacity-=count; count>>=1; length-=count; if(offsets==NULL) { while(count>0) { c=*source++; if(U16_IS_SINGLE(c)) { target[0]=(uint8_t)(c>>8); target[1]=(uint8_t)c; target+=2; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=*source)) { ++source; --count; target[0]=(uint8_t)(c>>8); target[1]=(uint8_t)c; target[2]=(uint8_t)(trail>>8); target[3]=(uint8_t)trail; target+=4; } else { break; } --count; } } else { while(count>0) { c=*source++; if(U16_IS_SINGLE(c)) { target[0]=(uint8_t)(c>>8); target[1]=(uint8_t)c; target+=2; *offsets++=sourceIndex; *offsets++=sourceIndex++; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=*source)) { ++source; --count; target[0]=(uint8_t)(c>>8); target[1]=(uint8_t)c; target[2]=(uint8_t)(trail>>8); target[3]=(uint8_t)trail; target+=4; *offsets++=sourceIndex; *offsets++=sourceIndex; *offsets++=sourceIndex; *offsets++=sourceIndex; sourceIndex+=2; } else { break; } --count; } } if(count==0) { /* done with the loop for complete UChars */ if(length>0 && targetCapacity>0) { /* * there is more input and some target capacity - * it must be targetCapacity==1 because otherwise * the above would have copied more; * prepare for overflow output */ if(U16_IS_SINGLE(c=*source++)) { overflow[0]=(char)(c>>8); overflow[1]=(char)c; length=2; /* 2 bytes to output */ c=0; /* } else { keep c for surrogate handling, length will be set there */ } } else { length=0; c=0; } } else { /* keep c for surrogate handling, length will be set there */ targetCapacity+=2*count; } } else { length=0; /* from here on, length counts the bytes in overflow[] */ } if(c!=0) { /* * c is a surrogate, and * - source or target too short * - or the surrogate is unmatched */ length=0; if(U16_IS_SURROGATE_LEAD(c)) { if(sourcesourceLimit) { if(U16_IS_TRAIL(trail=*source)) { /* output the surrogate pair, will overflow (see conditions comment above) */ ++source; overflow[0]=(char)(c>>8); overflow[1]=(char)c; overflow[2]=(char)(trail>>8); overflow[3]=(char)trail; length=4; /* 4 bytes to output */ c=0; } else { /* unmatched lead surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } else { /* see if the trail surrogate is in the next buffer */ } } else { /* unmatched trail surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } cnv->fromUChar32=c; } if(length>0) { /* output length bytes with overflow (length>targetCapacity>0) */ ucnv_fromUWriteBytes(cnv, overflow, length, (char **)&target, pArgs->targetLimit, &offsets, sourceIndex, pErrorCode); targetCapacity=(uint32_t)(pArgs->targetLimit-(char *)target); } if(U_SUCCESS(*pErrorCode) && sourcesourceLimit && targetCapacity==0) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } /* write back the updated pointers */ pArgs->source=source; pArgs->target=(char *)target; pArgs->offsets=offsets; } static void _UTF16BEToUnicodeWithOffsets(UConverterToUnicodeArgs *pArgs, UErrorCode *pErrorCode) { UConverter *cnv; const uint8_t *source; UChar *target; int32_t *offsets; uint32_t targetCapacity, length, count, sourceIndex; UChar c, trail; if(pArgs->converter->mode<8) { _UTF16ToUnicodeWithOffsets(pArgs, pErrorCode); return; } cnv=pArgs->converter; source=(const uint8_t *)pArgs->source; length=(int32_t)((const uint8_t *)pArgs->sourceLimit-source); if(length<=0 && cnv->toUnicodeStatus==0) { /* no input, nothing to do */ return; } target=pArgs->target; if(target >= pArgs->targetLimit) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; return; } targetCapacity=(uint32_t)(pArgs->targetLimit-target); offsets=pArgs->offsets; sourceIndex=0; c=0; /* complete a partial UChar or pair from the last call */ if(cnv->toUnicodeStatus!=0) { /* * special case: single byte from a previous buffer, * where the byte turned out not to belong to a trail surrogate * and the preceding, unmatched lead surrogate was put into toUBytes[] * for error handling */ cnv->toUBytes[0]=(uint8_t)cnv->toUnicodeStatus; cnv->toULength=1; cnv->toUnicodeStatus=0; } if((count=cnv->toULength)!=0) { uint8_t *p=cnv->toUBytes; do { p[count++]=*source++; ++sourceIndex; --length; if(count==2) { c=((UChar)p[0]<<8)|p[1]; if(U16_IS_SINGLE(c)) { /* output the BMP code point */ *target++=c; if(offsets!=NULL) { *offsets++=-1; } --targetCapacity; count=0; c=0; break; } else if(U16_IS_SURROGATE_LEAD(c)) { /* continue collecting bytes for the trail surrogate */ c=0; /* avoid unnecessary surrogate handling below */ } else { /* fall through to error handling for an unmatched trail surrogate */ break; } } else if(count==4) { c=((UChar)p[0]<<8)|p[1]; trail=((UChar)p[2]<<8)|p[3]; if(U16_IS_TRAIL(trail)) { /* output the surrogate pair */ *target++=c; if(targetCapacity>=2) { *target++=trail; if(offsets!=NULL) { *offsets++=-1; *offsets++=-1; } targetCapacity-=2; } else /* targetCapacity==1 */ { targetCapacity=0; cnv->UCharErrorBuffer[0]=trail; cnv->UCharErrorBufferLength=1; *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } count=0; c=0; break; } else { /* unmatched lead surrogate, handle here for consistent toUBytes[] */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; /* back out reading the code unit after it */ if(((const uint8_t *)pArgs->source-source)>=2) { source-=2; } else { /* * if the trail unit's first byte was in a previous buffer, then * we need to put it into a special place because toUBytes[] will be * used for the lead unit's bytes */ cnv->toUnicodeStatus=0x100|p[2]; --source; } cnv->toULength=2; /* write back the updated pointers */ pArgs->source=(const char *)source; pArgs->target=target; pArgs->offsets=offsets; return; } } } while(length>0); cnv->toULength=(int8_t)count; } /* copy an even number of bytes for complete UChars */ count=2*targetCapacity; if(count>length) { count=length&~1; } if(c==0 && count>0) { length-=count; count>>=1; targetCapacity-=count; if(offsets==NULL) { do { c=((UChar)source[0]<<8)|source[1]; source+=2; if(U16_IS_SINGLE(c)) { *target++=c; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=((UChar)source[0]<<8)|source[1]) ) { source+=2; --count; *target++=c; *target++=trail; } else { break; } } while(--count>0); } else { do { c=((UChar)source[0]<<8)|source[1]; source+=2; if(U16_IS_SINGLE(c)) { *target++=c; *offsets++=sourceIndex; sourceIndex+=2; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=((UChar)source[0]<<8)|source[1]) ) { source+=2; --count; *target++=c; *target++=trail; *offsets++=sourceIndex; *offsets++=sourceIndex; sourceIndex+=4; } else { break; } } while(--count>0); } if(count==0) { /* done with the loop for complete UChars */ c=0; } else { /* keep c for surrogate handling, trail will be set there */ length+=2*(count-1); /* one more byte pair was consumed than count decremented */ targetCapacity+=count; } } if(c!=0) { /* * c is a surrogate, and * - source or target too short * - or the surrogate is unmatched */ cnv->toUBytes[0]=(uint8_t)(c>>8); cnv->toUBytes[1]=(uint8_t)c; cnv->toULength=2; if(U16_IS_SURROGATE_LEAD(c)) { if(length>=2) { if(U16_IS_TRAIL(trail=((UChar)source[0]<<8)|source[1])) { /* output the surrogate pair, will overflow (see conditions comment above) */ source+=2; length-=2; *target++=c; if(offsets!=NULL) { *offsets++=sourceIndex; } cnv->UCharErrorBuffer[0]=trail; cnv->UCharErrorBufferLength=1; cnv->toULength=0; *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } else { /* unmatched lead surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } else { /* see if the trail surrogate is in the next buffer */ } } else { /* unmatched trail surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } if(U_SUCCESS(*pErrorCode)) { /* check for a remaining source byte */ if(length>0) { if(targetCapacity==0) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } else { /* it must be length==1 because otherwise the above would have copied more */ cnv->toUBytes[cnv->toULength++]=*source++; } } } /* write back the updated pointers */ pArgs->source=(const char *)source; pArgs->target=target; pArgs->offsets=offsets; } static UChar32 _UTF16BEGetNextUChar(UConverterToUnicodeArgs *pArgs, UErrorCode *err) { const uint8_t *s, *sourceLimit; UChar32 c; if(pArgs->converter->mode<8) { return UCNV_GET_NEXT_UCHAR_USE_TO_U; } s=(const uint8_t *)pArgs->source; sourceLimit=(const uint8_t *)pArgs->sourceLimit; if(s>=sourceLimit) { /* no input */ *err=U_INDEX_OUTOFBOUNDS_ERROR; return 0xffff; } if(s+2>sourceLimit) { /* only one byte: truncated UChar */ pArgs->converter->toUBytes[0]=*s++; pArgs->converter->toULength=1; pArgs->source=(const char *)s; *err = U_TRUNCATED_CHAR_FOUND; return 0xffff; } /* get one UChar */ c=((UChar32)*s<<8)|s[1]; s+=2; /* check for a surrogate pair */ if(U_IS_SURROGATE(c)) { if(U16_IS_SURROGATE_LEAD(c)) { if(s+2<=sourceLimit) { UChar trail; /* get a second UChar and see if it is a trail surrogate */ trail=((UChar)*s<<8)|s[1]; if(U16_IS_TRAIL(trail)) { c=U16_GET_SUPPLEMENTARY(c, trail); s+=2; } else { /* unmatched lead surrogate */ c=-2; } } else { /* too few (2 or 3) bytes for a surrogate pair: truncated code point */ uint8_t *bytes=pArgs->converter->toUBytes; s-=2; pArgs->converter->toULength=(int8_t)(sourceLimit-s); do { *bytes++=*s++; } while(sconverter->toUBytes; pArgs->converter->toULength=2; *bytes=*(s-2); bytes[1]=*(s-1); c=0xffff; *err=U_ILLEGAL_CHAR_FOUND; } } pArgs->source=(const char *)s; return c; } static void _UTF16BEReset(UConverter *cnv, UConverterResetChoice choice) { if(choice<=UCNV_RESET_TO_UNICODE) { /* reset toUnicode state */ if(UCNV_GET_VERSION(cnv)==0) { cnv->mode=8; /* no BOM handling */ } else { cnv->mode=0; /* Java-specific "UnicodeBig" requires BE BOM or no BOM */ } } if(choice!=UCNV_RESET_TO_UNICODE && UCNV_GET_VERSION(cnv)==1) { /* reset fromUnicode for "UnicodeBig": prepare to output the UTF-16BE BOM */ cnv->fromUnicodeStatus=UCNV_NEED_TO_WRITE_BOM; } } static void _UTF16BEOpen(UConverter *cnv, UConverterLoadArgs *pArgs, UErrorCode *pErrorCode) { if(pArgs->onlyTestIsLoadable) { pArgs->isLoadable=TRUE; } else { if(UCNV_GET_VERSION(cnv)>1) { cnv->options=0; } _UTF16BEReset(cnv, UCNV_RESET_BOTH); } } static const char * _UTF16BEGetName(const UConverter *cnv) { if(UCNV_GET_VERSION(cnv)==0) { return "UTF-16BE"; } else { return "UTF-16BE,version=1"; } } static const UConverterImpl _UTF16BEImpl={ UCNV_UTF16_BigEndian, NULL, NULL, _UTF16BEOpen, NULL, _UTF16BEReset, _UTF16BEToUnicodeWithOffsets, _UTF16BEToUnicodeWithOffsets, _UTF16BEFromUnicodeWithOffsets, _UTF16BEFromUnicodeWithOffsets, _UTF16BEGetNextUChar, NULL, _UTF16BEGetName, NULL, NULL, ucnv_getNonSurrogateUnicodeSet }; static const UConverterStaticData _UTF16BEStaticData={ sizeof(UConverterStaticData), "UTF-16BE", 1200, UCNV_IBM, UCNV_UTF16_BigEndian, 2, 4, { 0xff, 0xfd, 0, 0 },2,FALSE,FALSE, 0, 0, { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 } /* reserved */ }; const UConverterSharedData _UTF16BEData={ sizeof(UConverterSharedData), ~((uint32_t) 0), NULL, NULL, &_UTF16BEStaticData, FALSE, &_UTF16BEImpl, 0 }; /* UTF-16LE ----------------------------------------------------------------- */ static void _UTF16LEFromUnicodeWithOffsets(UConverterFromUnicodeArgs *pArgs, UErrorCode *pErrorCode) { UConverter *cnv; const UChar *source; char *target; int32_t *offsets; uint32_t targetCapacity, length, sourceIndex; UChar c, trail; char overflow[4]; source=pArgs->source; length=(int32_t)(pArgs->sourceLimit-source); if(length<=0) { /* no input, nothing to do */ return; } cnv=pArgs->converter; /* write the BOM if necessary */ if(cnv->fromUnicodeStatus==UCNV_NEED_TO_WRITE_BOM) { static const char bom[]={ (char)0xff, (char)0xfe }; ucnv_fromUWriteBytes(cnv, bom, 2, &pArgs->target, pArgs->targetLimit, &pArgs->offsets, -1, pErrorCode); cnv->fromUnicodeStatus=0; } target=pArgs->target; if(target >= pArgs->targetLimit) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; return; } targetCapacity=(uint32_t)(pArgs->targetLimit-pArgs->target); offsets=pArgs->offsets; sourceIndex=0; /* c!=0 indicates in several places outside the main loops that a surrogate was found */ if((c=(UChar)cnv->fromUChar32)!=0 && U16_IS_TRAIL(trail=*source) && targetCapacity>=4) { /* the last buffer ended with a lead surrogate, output the surrogate pair */ ++source; --length; target[0]=(uint8_t)c; target[1]=(uint8_t)(c>>8); target[2]=(uint8_t)trail; target[3]=(uint8_t)(trail>>8); target+=4; targetCapacity-=4; if(offsets!=NULL) { *offsets++=-1; *offsets++=-1; *offsets++=-1; *offsets++=-1; } sourceIndex=1; cnv->fromUChar32=c=0; } if(c==0) { /* copy an even number of bytes for complete UChars */ uint32_t count=2*length; if(count>targetCapacity) { count=targetCapacity&~1; } /* count is even */ targetCapacity-=count; count>>=1; length-=count; if(offsets==NULL) { while(count>0) { c=*source++; if(U16_IS_SINGLE(c)) { target[0]=(uint8_t)c; target[1]=(uint8_t)(c>>8); target+=2; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=*source)) { ++source; --count; target[0]=(uint8_t)c; target[1]=(uint8_t)(c>>8); target[2]=(uint8_t)trail; target[3]=(uint8_t)(trail>>8); target+=4; } else { break; } --count; } } else { while(count>0) { c=*source++; if(U16_IS_SINGLE(c)) { target[0]=(uint8_t)c; target[1]=(uint8_t)(c>>8); target+=2; *offsets++=sourceIndex; *offsets++=sourceIndex++; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=*source)) { ++source; --count; target[0]=(uint8_t)c; target[1]=(uint8_t)(c>>8); target[2]=(uint8_t)trail; target[3]=(uint8_t)(trail>>8); target+=4; *offsets++=sourceIndex; *offsets++=sourceIndex; *offsets++=sourceIndex; *offsets++=sourceIndex; sourceIndex+=2; } else { break; } --count; } } if(count==0) { /* done with the loop for complete UChars */ if(length>0 && targetCapacity>0) { /* * there is more input and some target capacity - * it must be targetCapacity==1 because otherwise * the above would have copied more; * prepare for overflow output */ if(U16_IS_SINGLE(c=*source++)) { overflow[0]=(char)c; overflow[1]=(char)(c>>8); length=2; /* 2 bytes to output */ c=0; /* } else { keep c for surrogate handling, length will be set there */ } } else { length=0; c=0; } } else { /* keep c for surrogate handling, length will be set there */ targetCapacity+=2*count; } } else { length=0; /* from here on, length counts the bytes in overflow[] */ } if(c!=0) { /* * c is a surrogate, and * - source or target too short * - or the surrogate is unmatched */ length=0; if(U16_IS_SURROGATE_LEAD(c)) { if(sourcesourceLimit) { if(U16_IS_TRAIL(trail=*source)) { /* output the surrogate pair, will overflow (see conditions comment above) */ ++source; overflow[0]=(char)c; overflow[1]=(char)(c>>8); overflow[2]=(char)trail; overflow[3]=(char)(trail>>8); length=4; /* 4 bytes to output */ c=0; } else { /* unmatched lead surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } else { /* see if the trail surrogate is in the next buffer */ } } else { /* unmatched trail surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } cnv->fromUChar32=c; } if(length>0) { /* output length bytes with overflow (length>targetCapacity>0) */ ucnv_fromUWriteBytes(cnv, overflow, length, &target, pArgs->targetLimit, &offsets, sourceIndex, pErrorCode); targetCapacity=(uint32_t)(pArgs->targetLimit-(char *)target); } if(U_SUCCESS(*pErrorCode) && sourcesourceLimit && targetCapacity==0) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } /* write back the updated pointers */ pArgs->source=source; pArgs->target=target; pArgs->offsets=offsets; } static void _UTF16LEToUnicodeWithOffsets(UConverterToUnicodeArgs *pArgs, UErrorCode *pErrorCode) { UConverter *cnv; const uint8_t *source; UChar *target; int32_t *offsets; uint32_t targetCapacity, length, count, sourceIndex; UChar c, trail; if(pArgs->converter->mode<8) { _UTF16ToUnicodeWithOffsets(pArgs, pErrorCode); return; } cnv=pArgs->converter; source=(const uint8_t *)pArgs->source; length=(int32_t)((const uint8_t *)pArgs->sourceLimit-source); if(length<=0 && cnv->toUnicodeStatus==0) { /* no input, nothing to do */ return; } target=pArgs->target; if(target >= pArgs->targetLimit) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; return; } targetCapacity=(uint32_t)(pArgs->targetLimit-pArgs->target); offsets=pArgs->offsets; sourceIndex=0; c=0; /* complete a partial UChar or pair from the last call */ if(cnv->toUnicodeStatus!=0) { /* * special case: single byte from a previous buffer, * where the byte turned out not to belong to a trail surrogate * and the preceding, unmatched lead surrogate was put into toUBytes[] * for error handling */ cnv->toUBytes[0]=(uint8_t)cnv->toUnicodeStatus; cnv->toULength=1; cnv->toUnicodeStatus=0; } if((count=cnv->toULength)!=0) { uint8_t *p=cnv->toUBytes; do { p[count++]=*source++; ++sourceIndex; --length; if(count==2) { c=((UChar)p[1]<<8)|p[0]; if(U16_IS_SINGLE(c)) { /* output the BMP code point */ *target++=c; if(offsets!=NULL) { *offsets++=-1; } --targetCapacity; count=0; c=0; break; } else if(U16_IS_SURROGATE_LEAD(c)) { /* continue collecting bytes for the trail surrogate */ c=0; /* avoid unnecessary surrogate handling below */ } else { /* fall through to error handling for an unmatched trail surrogate */ break; } } else if(count==4) { c=((UChar)p[1]<<8)|p[0]; trail=((UChar)p[3]<<8)|p[2]; if(U16_IS_TRAIL(trail)) { /* output the surrogate pair */ *target++=c; if(targetCapacity>=2) { *target++=trail; if(offsets!=NULL) { *offsets++=-1; *offsets++=-1; } targetCapacity-=2; } else /* targetCapacity==1 */ { targetCapacity=0; cnv->UCharErrorBuffer[0]=trail; cnv->UCharErrorBufferLength=1; *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } count=0; c=0; break; } else { /* unmatched lead surrogate, handle here for consistent toUBytes[] */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; /* back out reading the code unit after it */ if(((const uint8_t *)pArgs->source-source)>=2) { source-=2; } else { /* * if the trail unit's first byte was in a previous buffer, then * we need to put it into a special place because toUBytes[] will be * used for the lead unit's bytes */ cnv->toUnicodeStatus=0x100|p[2]; --source; } cnv->toULength=2; /* write back the updated pointers */ pArgs->source=(const char *)source; pArgs->target=target; pArgs->offsets=offsets; return; } } } while(length>0); cnv->toULength=(int8_t)count; } /* copy an even number of bytes for complete UChars */ count=2*targetCapacity; if(count>length) { count=length&~1; } if(c==0 && count>0) { length-=count; count>>=1; targetCapacity-=count; if(offsets==NULL) { do { c=((UChar)source[1]<<8)|source[0]; source+=2; if(U16_IS_SINGLE(c)) { *target++=c; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=((UChar)source[1]<<8)|source[0]) ) { source+=2; --count; *target++=c; *target++=trail; } else { break; } } while(--count>0); } else { do { c=((UChar)source[1]<<8)|source[0]; source+=2; if(U16_IS_SINGLE(c)) { *target++=c; *offsets++=sourceIndex; sourceIndex+=2; } else if(U16_IS_SURROGATE_LEAD(c) && count>=2 && U16_IS_TRAIL(trail=((UChar)source[1]<<8)|source[0]) ) { source+=2; --count; *target++=c; *target++=trail; *offsets++=sourceIndex; *offsets++=sourceIndex; sourceIndex+=4; } else { break; } } while(--count>0); } if(count==0) { /* done with the loop for complete UChars */ c=0; } else { /* keep c for surrogate handling, trail will be set there */ length+=2*(count-1); /* one more byte pair was consumed than count decremented */ targetCapacity+=count; } } if(c!=0) { /* * c is a surrogate, and * - source or target too short * - or the surrogate is unmatched */ cnv->toUBytes[0]=(uint8_t)c; cnv->toUBytes[1]=(uint8_t)(c>>8); cnv->toULength=2; if(U16_IS_SURROGATE_LEAD(c)) { if(length>=2) { if(U16_IS_TRAIL(trail=((UChar)source[1]<<8)|source[0])) { /* output the surrogate pair, will overflow (see conditions comment above) */ source+=2; length-=2; *target++=c; if(offsets!=NULL) { *offsets++=sourceIndex; } cnv->UCharErrorBuffer[0]=trail; cnv->UCharErrorBufferLength=1; cnv->toULength=0; *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } else { /* unmatched lead surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } else { /* see if the trail surrogate is in the next buffer */ } } else { /* unmatched trail surrogate */ *pErrorCode=U_ILLEGAL_CHAR_FOUND; } } if(U_SUCCESS(*pErrorCode)) { /* check for a remaining source byte */ if(length>0) { if(targetCapacity==0) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } else { /* it must be length==1 because otherwise the above would have copied more */ cnv->toUBytes[cnv->toULength++]=*source++; } } } /* write back the updated pointers */ pArgs->source=(const char *)source; pArgs->target=target; pArgs->offsets=offsets; } static UChar32 _UTF16LEGetNextUChar(UConverterToUnicodeArgs *pArgs, UErrorCode *err) { const uint8_t *s, *sourceLimit; UChar32 c; if(pArgs->converter->mode<8) { return UCNV_GET_NEXT_UCHAR_USE_TO_U; } s=(const uint8_t *)pArgs->source; sourceLimit=(const uint8_t *)pArgs->sourceLimit; if(s>=sourceLimit) { /* no input */ *err=U_INDEX_OUTOFBOUNDS_ERROR; return 0xffff; } if(s+2>sourceLimit) { /* only one byte: truncated UChar */ pArgs->converter->toUBytes[0]=*s++; pArgs->converter->toULength=1; pArgs->source=(const char *)s; *err = U_TRUNCATED_CHAR_FOUND; return 0xffff; } /* get one UChar */ c=((UChar32)s[1]<<8)|*s; s+=2; /* check for a surrogate pair */ if(U_IS_SURROGATE(c)) { if(U16_IS_SURROGATE_LEAD(c)) { if(s+2<=sourceLimit) { UChar trail; /* get a second UChar and see if it is a trail surrogate */ trail=((UChar)s[1]<<8)|*s; if(U16_IS_TRAIL(trail)) { c=U16_GET_SUPPLEMENTARY(c, trail); s+=2; } else { /* unmatched lead surrogate */ c=-2; } } else { /* too few (2 or 3) bytes for a surrogate pair: truncated code point */ uint8_t *bytes=pArgs->converter->toUBytes; s-=2; pArgs->converter->toULength=(int8_t)(sourceLimit-s); do { *bytes++=*s++; } while(sconverter->toUBytes; pArgs->converter->toULength=2; *bytes=*(s-2); bytes[1]=*(s-1); c=0xffff; *err=U_ILLEGAL_CHAR_FOUND; } } pArgs->source=(const char *)s; return c; } static void _UTF16LEReset(UConverter *cnv, UConverterResetChoice choice) { if(choice<=UCNV_RESET_TO_UNICODE) { /* reset toUnicode state */ if(UCNV_GET_VERSION(cnv)==0) { cnv->mode=8; /* no BOM handling */ } else { cnv->mode=0; /* Java-specific "UnicodeLittle" requires LE BOM or no BOM */ } } if(choice!=UCNV_RESET_TO_UNICODE && UCNV_GET_VERSION(cnv)==1) { /* reset fromUnicode for "UnicodeLittle": prepare to output the UTF-16LE BOM */ cnv->fromUnicodeStatus=UCNV_NEED_TO_WRITE_BOM; } } static void _UTF16LEOpen(UConverter *cnv, UConverterLoadArgs *pArgs, UErrorCode *pErrorCode) { if(pArgs->onlyTestIsLoadable) { pArgs->isLoadable=TRUE; } else { if(UCNV_GET_VERSION(cnv)>1) { cnv->options=0; } _UTF16LEReset(cnv, UCNV_RESET_BOTH); } } static const char * _UTF16LEGetName(const UConverter *cnv) { if(UCNV_GET_VERSION(cnv)==0) { return "UTF-16LE"; } else { return "UTF-16LE,version=1"; } } static const UConverterImpl _UTF16LEImpl={ UCNV_UTF16_LittleEndian, NULL, NULL, _UTF16LEOpen, NULL, _UTF16LEReset, _UTF16LEToUnicodeWithOffsets, _UTF16LEToUnicodeWithOffsets, _UTF16LEFromUnicodeWithOffsets, _UTF16LEFromUnicodeWithOffsets, _UTF16LEGetNextUChar, NULL, _UTF16LEGetName, NULL, NULL, ucnv_getNonSurrogateUnicodeSet }; static const UConverterStaticData _UTF16LEStaticData={ sizeof(UConverterStaticData), "UTF-16LE", 1202, UCNV_IBM, UCNV_UTF16_LittleEndian, 2, 4, { 0xfd, 0xff, 0, 0 },2,FALSE,FALSE, 0, 0, { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 } /* reserved */ }; const UConverterSharedData _UTF16LEData={ sizeof(UConverterSharedData), ~((uint32_t) 0), NULL, NULL, &_UTF16LEStaticData, FALSE, &_UTF16LEImpl, 0 }; /* UTF-16 (Detect BOM) ------------------------------------------------------ */ /* * Detect a BOM at the beginning of the stream and select UTF-16BE or UTF-16LE * accordingly. * This is a simpler version of the UTF-32 converter, with * fewer states for shorter BOMs. * * State values: * 0 initial state * 1 saw first byte * 2..5 - * 6..7 see _UTF16ToUnicodeWithOffsets() comments in state 1 * 8 UTF-16BE mode * 9 UTF-16LE mode * * During detection: state==number of initial bytes seen so far. * * On output, emit U+FEFF as the first code point. * * Variants: * - UTF-16,version=1 (Java "Unicode" encoding) treats a missing BOM as an error. * - UTF-16BE,version=1 (Java "UnicodeBig" encoding) and * UTF-16LE,version=1 (Java "UnicodeLittle" encoding) treat a reverse BOM as an error. */ static void _UTF16Reset(UConverter *cnv, UConverterResetChoice choice) { if(choice<=UCNV_RESET_TO_UNICODE) { /* reset toUnicode: state=0 */ cnv->mode=0; } if(choice!=UCNV_RESET_TO_UNICODE) { /* reset fromUnicode: prepare to output the UTF-16PE BOM */ cnv->fromUnicodeStatus=UCNV_NEED_TO_WRITE_BOM; } } static void _UTF16Open(UConverter *cnv, UConverterLoadArgs *pArgs, UErrorCode *pErrorCode) { if(pArgs->onlyTestIsLoadable) { pArgs->isLoadable=TRUE; } else { if(UCNV_GET_VERSION(cnv)>1) { cnv->options=0; } _UTF16Reset(cnv, UCNV_RESET_BOTH); } } static const char * _UTF16GetName(const UConverter *cnv) { if(UCNV_GET_VERSION(cnv)==0) { return "UTF-16"; } else { return "UTF-16,version=1"; } } const UConverterSharedData _UTF16Data; #define IS_UTF16BE(cnv) ((cnv)->sharedData==&_UTF16BEData) #define IS_UTF16LE(cnv) ((cnv)->sharedData==&_UTF16LEData) #define IS_UTF16(cnv) ((cnv)->sharedData==&_UTF16Data) static void _UTF16ToUnicodeWithOffsets(UConverterToUnicodeArgs *pArgs, UErrorCode *pErrorCode) { UConverter *cnv=pArgs->converter; const char *source=pArgs->source; const char *sourceLimit=pArgs->sourceLimit; int32_t *offsets=pArgs->offsets; int32_t state, offsetDelta; uint8_t b; state=cnv->mode; /* * If we detect a BOM in this buffer, then we must add the BOM size to the * offsets because the actual converter function will not see and count the BOM. * offsetDelta will have the number of the BOM bytes that are in the current buffer. */ offsetDelta=0; while(sourcetoUBytes[0]=(uint8_t)*source++; cnv->toULength=1; state=1; break; case 1: /* * Only inside this switch case can the state variable * temporarily take two additional values: * 6: BOM error, continue with BE * 7: BOM error, continue with LE */ b=*source; if(cnv->toUBytes[0]==0xfe && b==0xff) { if(IS_UTF16LE(cnv)) { state=7; /* illegal reverse BOM for Java "UnicodeLittle" */ } else { state=8; /* detect UTF-16BE */ } } else if(cnv->toUBytes[0]==0xff && b==0xfe) { if(IS_UTF16BE(cnv)) { state=6; /* illegal reverse BOM for Java "UnicodeBig" */ } else { state=9; /* detect UTF-16LE */ } } else if((IS_UTF16(cnv) && UCNV_GET_VERSION(cnv)==1)) { state=6; /* illegal missing BOM for Java "Unicode" */ } if(state>=8) { /* BOM detected, consume it */ ++source; cnv->toULength=0; offsetDelta=(int32_t)(source-pArgs->source); } else if(state<6) { /* ok: no BOM, and not a reverse BOM */ if(source!=pArgs->source) { /* reset the source for a correct first offset */ source=pArgs->source; cnv->toULength=0; } if(IS_UTF16LE(cnv)) { /* Make Java "UnicodeLittle" default to LE. */ state=9; } else { /* Make standard UTF-16 and Java "UnicodeBig" default to BE. */ state=8; } } else { /* * error: missing BOM, or reverse BOM * UTF-16,version=1: Java-specific "Unicode" requires a BOM. * UTF-16BE,version=1: Java-specific "UnicodeBig" requires a BE BOM or no BOM. * UTF-16LE,version=1: Java-specific "UnicodeLittle" requires an LE BOM or no BOM. */ /* report the non-BOM or reverse BOM as an illegal sequence */ cnv->toUBytes[1]=b; cnv->toULength=2; pArgs->source=source+1; /* continue with conversion if the callback resets the error */ /* * Make Java "Unicode" default to BE like standard UTF-16. * Make Java "UnicodeBig" and "UnicodeLittle" default * to their normal endiannesses. */ cnv->mode=state+2; *pErrorCode=U_ILLEGAL_ESCAPE_SEQUENCE; return; } /* convert the rest of the stream */ cnv->mode=state; continue; case 8: /* call UTF-16BE */ pArgs->source=source; _UTF16BEToUnicodeWithOffsets(pArgs, pErrorCode); source=pArgs->source; break; case 9: /* call UTF-16LE */ pArgs->source=source; _UTF16LEToUnicodeWithOffsets(pArgs, pErrorCode); source=pArgs->source; break; default: break; /* does not occur */ } } /* add BOM size to offsets - see comment at offsetDelta declaration */ if(offsets!=NULL && offsetDelta!=0) { int32_t *offsetsLimit=pArgs->offsets; while(offsetssource=source; if(source==sourceLimit && pArgs->flush) { /* handle truncated input */ switch(state) { case 0: break; /* no input at all, nothing to do */ case 8: _UTF16BEToUnicodeWithOffsets(pArgs, pErrorCode); break; case 9: _UTF16LEToUnicodeWithOffsets(pArgs, pErrorCode); break; default: /* 0mode=state; } static UChar32 _UTF16GetNextUChar(UConverterToUnicodeArgs *pArgs, UErrorCode *pErrorCode) { switch(pArgs->converter->mode) { case 8: return _UTF16BEGetNextUChar(pArgs, pErrorCode); case 9: return _UTF16LEGetNextUChar(pArgs, pErrorCode); default: return UCNV_GET_NEXT_UCHAR_USE_TO_U; } } static const UConverterImpl _UTF16Impl = { UCNV_UTF16, NULL, NULL, _UTF16Open, NULL, _UTF16Reset, _UTF16ToUnicodeWithOffsets, _UTF16ToUnicodeWithOffsets, _UTF16PEFromUnicodeWithOffsets, _UTF16PEFromUnicodeWithOffsets, _UTF16GetNextUChar, NULL, /* ### TODO implement getStarters for all Unicode encodings?! */ _UTF16GetName, NULL, NULL, ucnv_getNonSurrogateUnicodeSet }; static const UConverterStaticData _UTF16StaticData = { sizeof(UConverterStaticData), "UTF-16", 1204, /* CCSID for BOM sensitive UTF-16 */ UCNV_IBM, UCNV_UTF16, 2, 4, #if U_IS_BIG_ENDIAN { 0xff, 0xfd, 0, 0 }, 2, #else { 0xfd, 0xff, 0, 0 }, 2, #endif FALSE, FALSE, 0, 0, { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 } /* reserved */ }; const UConverterSharedData _UTF16Data = { sizeof(UConverterSharedData), ~((uint32_t) 0), NULL, NULL, &_UTF16StaticData, FALSE, &_UTF16Impl, 0 }; #endif