/* ******************************************************************************** * Copyright (C) 1996-2003, International Business Machines * Corporation and others. All Rights Reserved. ******************************************************************************** * * File UCHAR.C * * Modification History: * * Date Name Description * 04/02/97 aliu Creation. * 4/15/99 Madhu Updated all the function definitions for C Implementation * 5/20/99 Madhu Added the function u_getVersion() * 8/19/1999 srl Upgraded scripts to Unicode3.0 * 11/11/1999 weiv added u_isalnum(), cleaned comments * 01/11/2000 helena Renamed u_getVersion to u_getUnicodeVersion. * 06/20/2000 helena OS/400 port changes; mostly typecast. ****************************************************************************** */ #include "unicode/utypes.h" #include "unicode/uchar.h" #include "unicode/udata.h" #include "unicode/uloc.h" #include "unicode/uiter.h" #include "unicode/uset.h" #include "umutex.h" #include "cmemory.h" #include "ucln_cmn.h" #include "utrie.h" #include "ustr_imp.h" #include "uprops.h" #define LENGTHOF(array) (int32_t)(sizeof(array)/sizeof((array)[0])) /* dynamically loaded Unicode character properties -------------------------- */ /* * loaded uprops.dat - * for a description of the file format, see icu/source/tools/genprops/store.c */ static const char DATA_NAME[] = "uprops"; static const char DATA_TYPE[] = "icu"; static UDataMemory *propsData=NULL; static UErrorCode dataErrorCode=U_ZERO_ERROR; static uint8_t formatVersion[4]={ 0, 0, 0, 0 }; static UVersionInfo dataVersion={ 3, 0, 0, 0 }; static UTrie propsTrie={ 0 }, propsVectorsTrie={ 0 }; static const uint32_t *pData32=NULL, *props32Table=NULL, *exceptionsTable=NULL, *propsVectors=NULL; static const UChar *ucharsTable=NULL; static int32_t countPropsVectors=0, propsVectorsColumns=0; static int8_t havePropsData=0; /* index values loaded from uprops.dat */ static int32_t indexes[UPROPS_INDEX_COUNT]; /* if bit 15 is set, then the folding offset is in bits 14..0 of the 16-bit trie result */ static int32_t U_CALLCONV getFoldingPropsOffset(uint32_t data) { if(data&0x8000) { return (int32_t)(data&0x7fff); } else { return 0; } } static UBool U_CALLCONV isAcceptable(void *context, const char *type, const char *name, const UDataInfo *pInfo) { if( pInfo->size>=20 && pInfo->isBigEndian==U_IS_BIG_ENDIAN && pInfo->charsetFamily==U_CHARSET_FAMILY && pInfo->dataFormat[0]==0x55 && /* dataFormat="UPro" */ pInfo->dataFormat[1]==0x50 && pInfo->dataFormat[2]==0x72 && pInfo->dataFormat[3]==0x6f && pInfo->formatVersion[0]==3 && pInfo->formatVersion[2]==UTRIE_SHIFT && pInfo->formatVersion[3]==UTRIE_INDEX_SHIFT ) { uprv_memcpy(formatVersion, pInfo->formatVersion, 4); uprv_memcpy(dataVersion, pInfo->dataVersion, 4); return TRUE; } else { return FALSE; } } UBool uchar_cleanup() { if (propsData) { udata_close(propsData); propsData=NULL; } pData32=NULL; props32Table=NULL; exceptionsTable=NULL; ucharsTable=NULL; propsVectors=NULL; countPropsVectors=0; dataErrorCode=U_ZERO_ERROR; havePropsData=FALSE; return TRUE; } static int8_t loadPropsData(void) { /* load Unicode character properties data from file if necessary */ if(havePropsData==0) { UTrie trie={ 0 }, trie2={ 0 }; UErrorCode errorCode=U_ZERO_ERROR; UDataMemory *data; const uint32_t *p=NULL; int32_t length; /* open the data outside the mutex block */ data=udata_openChoice(NULL, DATA_TYPE, DATA_NAME, isAcceptable, NULL, &errorCode); dataErrorCode=errorCode; if(U_FAILURE(errorCode)) { return havePropsData=-1; } p=(const uint32_t *)udata_getMemory(data); /* unserialize the trie; it is directly after the int32_t indexes[UPROPS_INDEX_COUNT] */ length=(int32_t)p[UPROPS_PROPS32_INDEX]*4; length=utrie_unserialize(&trie, (const uint8_t *)(p+UPROPS_INDEX_COUNT), length-64, &errorCode); if(U_FAILURE(errorCode)) { dataErrorCode=errorCode; udata_close(data); return havePropsData=-1; } trie.getFoldingOffset=getFoldingPropsOffset; /* unserialize the properties vectors trie, if any */ if( p[UPROPS_ADDITIONAL_TRIE_INDEX]!=0 && p[UPROPS_ADDITIONAL_VECTORS_INDEX]!=0 ) { length=(int32_t)(p[UPROPS_ADDITIONAL_VECTORS_INDEX]-p[UPROPS_ADDITIONAL_TRIE_INDEX])*4; length=utrie_unserialize(&trie2, (const uint8_t *)(p+p[UPROPS_ADDITIONAL_TRIE_INDEX]), length, &errorCode); if(U_FAILURE(errorCode)) { uprv_memset(&trie2, 0, sizeof(trie2)); } else { trie2.getFoldingOffset=getFoldingPropsOffset; } } /* in the mutex block, set the data for this process */ umtx_lock(NULL); if(propsData==NULL) { propsData=data; data=NULL; pData32=p; p=NULL; uprv_memcpy(&propsTrie, &trie, sizeof(trie)); uprv_memcpy(&propsVectorsTrie, &trie2, sizeof(trie2)); } umtx_unlock(NULL); /* initialize some variables */ uprv_memcpy(indexes, pData32, sizeof(indexes)); props32Table=pData32+indexes[UPROPS_PROPS32_INDEX]; exceptionsTable=pData32+indexes[UPROPS_EXCEPTIONS_INDEX]; ucharsTable=(const UChar *)(pData32+indexes[UPROPS_EXCEPTIONS_TOP_INDEX]); /* additional properties */ if(indexes[UPROPS_ADDITIONAL_VECTORS_INDEX]!=0) { propsVectors=pData32+indexes[UPROPS_ADDITIONAL_VECTORS_INDEX]; countPropsVectors=indexes[UPROPS_RESERVED_INDEX]-indexes[UPROPS_ADDITIONAL_VECTORS_INDEX]; propsVectorsColumns=indexes[UPROPS_ADDITIONAL_VECTORS_COLUMNS_INDEX]; } havePropsData=1; /* if a different thread set it first, then close the extra data */ if(data!=NULL) { udata_close(data); /* NULL if it was set correctly */ } } return havePropsData; } /* constants and macros for access to the data */ /* getting a uint32_t properties word from the data */ #define HAVE_DATA (havePropsData>0 || (havePropsData==0 && loadPropsData()>0)) #define VALIDATE(c) (((uint32_t)(c))<=0x10ffff && HAVE_DATA) #define GET_PROPS_UNSAFE(c, result) \ UTRIE_GET16(&propsTrie, c, result); \ (result)=props32Table[(result)] #define GET_PROPS(c, result) \ if(HAVE_DATA) { \ GET_PROPS_UNSAFE(c, result); \ } else { \ (result)=0; \ } /* finding an exception value */ #define HAVE_EXCEPTION_VALUE(flags, index) ((flags)&(1UL<<(index))) /* number of bits in an 8-bit integer value */ #define EXC_GROUP 8 static const uint8_t flagsOffset[256]={ 0, 1, 1, 2, 1, 2, 2, 3, 1, 2, 2, 3, 2, 3, 3, 4, 1, 2, 2, 3, 2, 3, 3, 4, 2, 3, 3, 4, 3, 4, 4, 5, 1, 2, 2, 3, 2, 3, 3, 4, 2, 3, 3, 4, 3, 4, 4, 5, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 1, 2, 2, 3, 2, 3, 3, 4, 2, 3, 3, 4, 3, 4, 4, 5, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 3, 4, 4, 5, 4, 5, 5, 6, 4, 5, 5, 6, 5, 6, 6, 7, 1, 2, 2, 3, 2, 3, 3, 4, 2, 3, 3, 4, 3, 4, 4, 5, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 3, 4, 4, 5, 4, 5, 5, 6, 4, 5, 5, 6, 5, 6, 6, 7, 2, 3, 3, 4, 3, 4, 4, 5, 3, 4, 4, 5, 4, 5, 5, 6, 3, 4, 4, 5, 4, 5, 5, 6, 4, 5, 5, 6, 5, 6, 6, 7, 3, 4, 4, 5, 4, 5, 5, 6, 4, 5, 5, 6, 5, 6, 6, 7, 4, 5, 5, 6, 5, 6, 6, 7, 5, 6, 6, 7, 6, 7, 7, 8 }; #define ADD_EXCEPTION_OFFSET(flags, index, offset) { \ if((index)>=EXC_GROUP) { \ (offset)+=flagsOffset[(flags)&((1<>=EXC_GROUP; \ (index)-=EXC_GROUP; \ } \ (offset)+=flagsOffset[(flags)&((1<<(index))-1)]; \ } U_CFUNC UBool uprv_haveProperties(UErrorCode *pErrorCode) { if(HAVE_DATA) { return TRUE; } else { *pErrorCode=dataErrorCode; return FALSE; } } /* API functions ------------------------------------------------------------ */ /* Gets the Unicode character's general category.*/ U_CAPI int8_t U_EXPORT2 u_charType(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (int8_t)GET_CATEGORY(props); } /* Enumerate all code points with their general categories. */ struct _EnumTypeCallback { UCharEnumTypeRange *enumRange; const void *context; }; static uint32_t U_CALLCONV _enumTypeValue(const void *context, uint32_t value) { /* access the general category from the 32-bit properties, and those from the 16-bit trie value */ return GET_CATEGORY(props32Table[value]); } static UBool U_CALLCONV _enumTypeRange(const void *context, UChar32 start, UChar32 limit, uint32_t value) { /* just cast the value to UCharCategory */ return ((struct _EnumTypeCallback *)context)-> enumRange(((struct _EnumTypeCallback *)context)->context, start, limit, (UCharCategory)value); } U_CAPI void U_EXPORT2 u_enumCharTypes(UCharEnumTypeRange *enumRange, const void *context) { struct _EnumTypeCallback callback; if(enumRange==NULL || !HAVE_DATA) { return; } callback.enumRange=enumRange; callback.context=context; utrie_enum(&propsTrie, _enumTypeValue, _enumTypeRange, &callback); } /* Checks if ch is a lower case letter.*/ U_CAPI UBool U_EXPORT2 u_islower(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_LOWERCASE_LETTER); } /* Checks if ch is an upper case letter.*/ U_CAPI UBool U_EXPORT2 u_isupper(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_UPPERCASE_LETTER); } /* Checks if ch is a title case letter; usually upper case letters.*/ U_CAPI UBool U_EXPORT2 u_istitle(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_TITLECASE_LETTER); } /* Checks if ch is a decimal digit. */ U_CAPI UBool U_EXPORT2 u_isdigit(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_DECIMAL_DIGIT_NUMBER); } U_CAPI UBool U_EXPORT2 u_isxdigit(UChar32 c) { uint32_t props; /* check ASCII and Fullwidth ASCII a-fA-F */ if( (c<=0x66 && c>=0x41 && (c<=0x46 || c>=0x61)) || (c>=0xff21 && c<=0xff46 && (c<=0xff26 || c>=0xff41)) ) { return TRUE; } GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_DECIMAL_DIGIT_NUMBER); } /* Checks if the Unicode character is a letter.*/ U_CAPI UBool U_EXPORT2 u_isalpha(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&U_GC_L_MASK)!=0); } /* Checks if ch is a letter or a decimal digit */ U_CAPI UBool U_EXPORT2 u_isalnum(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&(U_GC_L_MASK|U_GC_ND_MASK))!=0); } /* Checks if ch is a unicode character with assigned character type.*/ U_CAPI UBool U_EXPORT2 u_isdefined(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)!=0); } /* Checks if the Unicode character is a base form character that can take a diacritic.*/ U_CAPI UBool U_EXPORT2 u_isbase(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&(U_GC_L_MASK|U_GC_N_MASK|U_GC_MC_MASK|U_GC_ME_MASK))!=0); } /* Checks if the Unicode character is a control character.*/ U_CAPI UBool U_EXPORT2 u_iscntrl(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&(U_GC_CC_MASK|U_GC_CF_MASK|U_GC_ZL_MASK|U_GC_ZP_MASK))!=0); } U_CAPI UBool U_EXPORT2 u_isISOControl(UChar32 c) { return (uint32_t)c<=0x9f && (c<=0x1f || c>=0x7f); } /* Some control characters that are used as space. */ #define IS_THAT_CONTROL_SPACE(c) \ (c<=0x9f && ((c>=TAB && c<=CR) || (c>=0x1c && c <=0x1f) || c==NL)) /* Checks if the Unicode character is a space character.*/ U_CAPI UBool U_EXPORT2 u_isspace(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&U_GC_Z_MASK)!=0 || IS_THAT_CONTROL_SPACE(c)); } U_CAPI UBool U_EXPORT2 u_isJavaSpaceChar(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&U_GC_Z_MASK)!=0); } /* Checks if the Unicode character is a whitespace character.*/ U_CAPI UBool U_EXPORT2 u_isWhitespace(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)( ((CAT_MASK(props)&U_GC_Z_MASK)!=0 && c!=NBSP && c!=FIGURESP && c!=NNBSP) || /* exclude no-break spaces */ IS_THAT_CONTROL_SPACE(c) ); } U_CAPI UBool U_EXPORT2 u_isblank(UChar32 c) { if((uint32_t)c<=0x9f) { return c==9 || c==0x20; /* TAB or SPACE */ } else { /* White_Space but not LS (Zl) or PS (Zp) */ return u_isUWhiteSpace(c) && ((c&0xfffffffe)!=0x2028); } } /* Checks if the Unicode character is printable.*/ U_CAPI UBool U_EXPORT2 u_isprint(UChar32 c) { uint32_t props; GET_PROPS(c, props); /* comparing ==0 returns FALSE for the categories mentioned */ return (UBool)((CAT_MASK(props)&U_GC_C_MASK)==0); } U_CAPI UBool U_EXPORT2 u_isgraph(UChar32 c) { uint32_t props; GET_PROPS(c, props); /* comparing ==0 returns FALSE for the categories mentioned */ return (UBool)((CAT_MASK(props)& (U_GC_CC_MASK|U_GC_CF_MASK|U_GC_CS_MASK|U_GC_CN_MASK|U_GC_Z_MASK)) ==0); } U_CAPI UBool U_EXPORT2 u_ispunct(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&U_GC_P_MASK)!=0); } /* Checks if the Unicode character can start a Unicode identifier.*/ U_CAPI UBool U_EXPORT2 u_isIDStart(UChar32 c) { /* same as u_isalpha() */ uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&(U_GC_L_MASK|U_GC_NL_MASK))!=0); } /* Checks if the Unicode character can be a Unicode identifier part other than starting the identifier.*/ U_CAPI UBool U_EXPORT2 u_isIDPart(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)( (CAT_MASK(props)& (U_GC_ND_MASK|U_GC_NL_MASK| U_GC_L_MASK| U_GC_PC_MASK|U_GC_MC_MASK|U_GC_MN_MASK) )!=0 || u_isIDIgnorable(c)); } /*Checks if the Unicode character can be ignorable in a Java or Unicode identifier.*/ U_CAPI UBool U_EXPORT2 u_isIDIgnorable(UChar32 c) { if(c<=0x9f) { return u_isISOControl(c) && !IS_THAT_CONTROL_SPACE(c); } else { uint32_t props; GET_PROPS(c, props); return (UBool)(GET_CATEGORY(props)==U_FORMAT_CHAR); } } /*Checks if the Unicode character can start a Java identifier.*/ U_CAPI UBool U_EXPORT2 u_isJavaIDStart(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)((CAT_MASK(props)&(U_GC_L_MASK|U_GC_SC_MASK|U_GC_PC_MASK))!=0); } /*Checks if the Unicode character can be a Java identifier part other than starting the * identifier. */ U_CAPI UBool U_EXPORT2 u_isJavaIDPart(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)( (CAT_MASK(props)& (U_GC_ND_MASK|U_GC_NL_MASK| U_GC_L_MASK| U_GC_SC_MASK|U_GC_PC_MASK| U_GC_MC_MASK|U_GC_MN_MASK) )!=0 || u_isIDIgnorable(c)); } /* Transforms the Unicode character to its lower case equivalent.*/ U_CAPI UChar32 U_EXPORT2 u_tolower(UChar32 c) { uint32_t props; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(CAT_MASK(props)&(U_GC_LU_MASK|U_GC_LT_MASK)) { return c+GET_SIGNED_VALUE(props); } } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_LOWERCASE)) { int i=EXC_LOWERCASE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (UChar32)*pe; } } return c; /* no mapping - return c itself */ } /* Transforms the Unicode character to its upper case equivalent.*/ U_CAPI UChar32 U_EXPORT2 u_toupper(UChar32 c) { uint32_t props; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(GET_CATEGORY(props)==U_LOWERCASE_LETTER) { return c-GET_SIGNED_VALUE(props); } } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_UPPERCASE)) { int i=EXC_UPPERCASE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (UChar32)*pe; } } return c; /* no mapping - return c itself */ } /* Transforms the Unicode character to its title case equivalent.*/ U_CAPI UChar32 U_EXPORT2 u_totitle(UChar32 c) { uint32_t props; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(GET_CATEGORY(props)==U_LOWERCASE_LETTER) { /* here, titlecase is same as uppercase */ return c-GET_SIGNED_VALUE(props); } } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_TITLECASE)) { int i=EXC_TITLECASE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (UChar32)*pe; } else if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_UPPERCASE)) { /* here, titlecase is same as uppercase */ int i=EXC_UPPERCASE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (UChar32)*pe; } } return c; /* no mapping - return c itself */ } U_CAPI int32_t U_EXPORT2 u_charDigitValue(UChar32 c) { uint32_t props, numericType; GET_PROPS(c, props); numericType=GET_NUMERIC_TYPE(props); if(numericType==1) { if(!PROPS_VALUE_IS_EXCEPTION(props)) { return GET_SIGNED_VALUE(props); } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_NUMERIC_VALUE)) { int i=EXC_NUMERIC_VALUE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (int32_t)*pe; } } } return -1; } U_CAPI double U_EXPORT2 u_getNumericValue(UChar32 c) { uint32_t props, numericType; GET_PROPS(c, props); numericType=GET_NUMERIC_TYPE(props); if(numericType==0 || numericType>=(int32_t)U_NT_COUNT) { return U_NO_NUMERIC_VALUE; } else { if(!PROPS_VALUE_IS_EXCEPTION(props)) { return GET_SIGNED_VALUE(props); } else { const uint32_t *pe; uint32_t firstExceptionValue; double numValue; uint32_t denominator; pe=GET_EXCEPTIONS(props); firstExceptionValue=*pe++; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_NUMERIC_VALUE)) { uint32_t flags=firstExceptionValue; int i=EXC_NUMERIC_VALUE; const uint32_t *p=pe; int32_t numerator; ADD_EXCEPTION_OFFSET(flags, i, p); numerator=(int32_t)*p; /* * There are special values for huge numbers that are powers of ten. * genprops/store.c documents: * if numericValue=0x7fffff00+x then numericValue=10^x */ if(numerator<0x7fffff00) { numValue=(double)numerator; } else { numerator&=0xff; /* 10^x without math.h */ numValue=1.; while(numerator>=4) { numValue*=10000.; numerator-=4; } switch(numerator) { case 3: numValue*=1000.; break; case 2: numValue*=100.; break; case 1: numValue*=10.; break; case 0: default: break; } } } else { numValue=0.; } if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_DENOMINATOR_VALUE)) { uint32_t flags=firstExceptionValue; int i=EXC_DENOMINATOR_VALUE; const uint32_t *p=pe; ADD_EXCEPTION_OFFSET(flags, i, p); denominator=*p; } else { denominator=0; } switch(firstExceptionValue&((1UL<0) */ default: return U_NO_NUMERIC_VALUE; } } } } /* Gets the character's linguistic directionality.*/ U_CAPI UCharDirection U_EXPORT2 u_charDirection(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UCharDirection)GET_BIDI_CLASS(props); } U_CAPI UBool U_EXPORT2 u_isMirrored(UChar32 c) { uint32_t props; GET_PROPS(c, props); return (UBool)(props&(1UL<=0x61 && ch<=0x7A) { value=(int8_t)(ch-0x57); /* ch - 'a' + 10 */ } else if(ch>=0x41 && ch<=0x5A) { value=(int8_t)(ch-0x37); /* ch - 'A' + 10 */ } else if(ch>=0xFF41 && ch<=0xFF5A) { value=(int8_t)(ch-0xFF37); /* fullwidth ASCII a-z */ } else if(ch>=0xFF21 && ch<=0xFF3A) { value=(int8_t)(ch-0xFF17); /* fullwidth ASCII A-Z */ } } } else { value=-1; /* invalid radix */ } return (int8_t)((value(36-2) || (uint32_t)digit>=(uint32_t)radix) { return 0; } else if(digit<10) { return (UChar32)(0x30+digit); } else { return (UChar32)((0x61-10)+digit); } } /* static data tables ------------------------------------------------------- */ static const UChar cellWidthRanges[] = { 0x0000, /* general scripts area*/ 0x1100, /* combining Hangul choseong*/ 0x1160, /* combining Hangul jungseong and jongseong*/ 0x1e00, /* Latin Extended Additional, Greek Extended*/ 0x2000, /* symbols and punctuation*/ 0x3000, /* CJK phonetics & symbols, CJK ideographs, Hangul syllables*/ 0xd800, /* surrogates, private use*/ 0xf900, /* CJK compatibility ideographs*/ 0xfb00, /* alphabetic presentation forms, Arabic presentations forms A, combining half marks*/ 0xfe30, /* CJK compatibility forms, small form variants*/ 0xfe70, /* Arabic presentation forms B*/ 0xff00, /* fullwidth ASCII*/ 0xff60, /* halfwidth, CJK punctuation, Katakana, Hangul Jamo*/ 0xffe0, /* fullwidth punctuation and currency signs*/ 0xffe8, /* halfwidth forms, arrows, and shapes*/ 0xfff0 /* specials*/ }; static const UChar cellWidthValues[] = { U_HALF_WIDTH, /* general scripts area*/ U_FULL_WIDTH, /* combining Hangul choseong*/ U_ZERO_WIDTH, /* combining Hangul jungseong and jongseong*/ U_HALF_WIDTH, /* Latin extended aAdditional, Greek extended*/ U_NEUTRAL_WIDTH, /* symbols and punctuation*/ U_FULL_WIDTH, /* CJK phonetics & symbols, CJK ideographs, Hangul syllables*/ U_NEUTRAL_WIDTH, /* surrogates, private use*/ U_FULL_WIDTH, /* CJK compatibility ideographs*/ U_HALF_WIDTH, /* alphabetic presentation forms, Arabic presentations forms A, combining half marks*/ U_FULL_WIDTH, /* CJK compatibility forms, small form variants*/ U_HALF_WIDTH, /* Arabic presentation forms B*/ U_FULL_WIDTH, /* fullwidth ASCII*/ U_HALF_WIDTH, /* halfwidth CJK punctuation, Katakana, Hangul Jamo*/ U_FULL_WIDTH, /* fullwidth punctuation and currency signs*/ U_HALF_WIDTH, /* halfwidth forms, arrows, and shapes*/ U_ZERO_WIDTH /* specials*/ }; #define NUM_CELL_WIDTH_VALUES (sizeof(cellWidthValues)/sizeof(cellWidthValues[0])) /* Gets table cell width of the Unicode character.*/ U_CAPI uint16_t U_EXPORT2 u_charCellWidth(UChar32 ch) { int16_t i; int32_t type = u_charType(ch); /* surrogate support is still incomplete */ if((uint32_t)ch>0xffff) { return U_ZERO_WIDTH; } /* these Unicode character types are scattered throughout the Unicode range, so special-case for them*/ switch (type) { case U_UNASSIGNED: case U_NON_SPACING_MARK: case U_ENCLOSING_MARK: case U_LINE_SEPARATOR: case U_PARAGRAPH_SEPARATOR: case U_CONTROL_CHAR: case U_FORMAT_CHAR: return U_ZERO_WIDTH; default: /* for all remaining characters, find out which Unicode range they belong to using the table above, and then look up the appropriate return value in that table*/ for (i = 0; i < (int16_t)NUM_CELL_WIDTH_VALUES; ++i) { if (ch < cellWidthRanges[i]) { break; } } --i; return cellWidthValues[i]; } } /* miscellaneous, and support for uprops.c ---------------------------------- */ U_CAPI void U_EXPORT2 u_getUnicodeVersion(UVersionInfo versionArray) { if(versionArray!=NULL) { if(HAVE_DATA) { uprv_memcpy(versionArray, dataVersion, U_MAX_VERSION_LENGTH); } else { uprv_memset(versionArray, 0, U_MAX_VERSION_LENGTH); } } } U_CFUNC uint32_t u_getUnicodeProperties(UChar32 c, int32_t column) { uint16_t vecIndex; if(column==-1) { uint32_t props; GET_PROPS(c, props); return props; } else if( !HAVE_DATA || countPropsVectors==0 || (uint32_t)c>0x10ffff || column<0 || column>=propsVectorsColumns ) { return 0; } else { UTRIE_GET16(&propsVectorsTrie, c, vecIndex); return propsVectors[vecIndex+column]; } } U_CFUNC int32_t uprv_getMaxValues(int32_t column) { if(HAVE_DATA) { switch(column) { case 0: return indexes[UPROPS_MAX_VALUES_INDEX]; case 2: return indexes[UPROPS_MAX_VALUES_2_INDEX]; default: return 0; } } else { return 0; } } static UBool U_CALLCONV _enumPropertyStartsRange(const void *context, UChar32 start, UChar32 limit, uint32_t value) { /* add the start code point to the USet */ uset_add((USet *)context, start); return TRUE; } #define USET_ADD_CP_AND_NEXT(set, cp) uset_add(set, cp); uset_add(set, cp+1) U_CAPI void U_EXPORT2 uchar_addPropertyStarts(USet *set, UErrorCode *pErrorCode) { UChar32 c; int32_t value, value2; if(!HAVE_DATA) { *pErrorCode=dataErrorCode; return; } /* add the start code point of each same-value range of each trie */ utrie_enum(&propsTrie, NULL, _enumPropertyStartsRange, set); utrie_enum(&propsVectorsTrie, NULL, _enumPropertyStartsRange, set); /* add code points with hardcoded properties, plus the ones following them */ /* add for IS_THAT_CONTROL_SPACE() */ uset_add(set, TAB); /* range TAB..CR */ uset_add(set, CR+1); uset_add(set, 0x1c); uset_add(set, 0x1f+1); USET_ADD_CP_AND_NEXT(set, NL); /* add for u_isIDIgnorable() what was not added above */ uset_add(set, DEL); /* range DEL..NBSP-1, NBSP added below */ uset_add(set, HAIRSP); uset_add(set, RLM+1); uset_add(set, INHSWAP); uset_add(set, NOMDIG+1); USET_ADD_CP_AND_NEXT(set, ZWNBSP); /* add no-break spaces for u_isWhitespace() what was not added above */ USET_ADD_CP_AND_NEXT(set, NBSP); USET_ADD_CP_AND_NEXT(set, FIGURESP); USET_ADD_CP_AND_NEXT(set, NNBSP); /* add for u_charDigitValue() */ USET_ADD_CP_AND_NEXT(set, 0x3007); USET_ADD_CP_AND_NEXT(set, 0x4e00); USET_ADD_CP_AND_NEXT(set, 0x4e8c); USET_ADD_CP_AND_NEXT(set, 0x4e09); USET_ADD_CP_AND_NEXT(set, 0x56db); USET_ADD_CP_AND_NEXT(set, 0x4e94); USET_ADD_CP_AND_NEXT(set, 0x516d); USET_ADD_CP_AND_NEXT(set, 0x4e03); USET_ADD_CP_AND_NEXT(set, 0x516b); USET_ADD_CP_AND_NEXT(set, 0x4e5d); /* add for u_digit() */ uset_add(set, U_a); uset_add(set, U_z+1); uset_add(set, U_A); uset_add(set, U_Z+1); /* add for UCHAR_DEFAULT_IGNORABLE_CODE_POINT what was not added above */ uset_add(set, WJ); /* range WJ..NOMDIG */ uset_add(set, 0xfff0); uset_add(set, 0xfffb+1); uset_add(set, 0xe0000); uset_add(set, 0xe0fff+1); /* add for UCHAR_GRAPHEME_BASE and others */ USET_ADD_CP_AND_NEXT(set, CGJ); /* add for UCHAR_JOINING_TYPE */ uset_add(set, ZWNJ); /* range ZWNJ..ZWJ */ uset_add(set, ZWJ+1); /* add Jamo type boundaries for UCHAR_HANGUL_SYLLABLE_TYPE */ uset_add(set, 0x1100); value=U_HST_LEADING_JAMO; for(c=0x115a; c<=0x115f; ++c) { value2=u_getIntPropertyValue(c, UCHAR_HANGUL_SYLLABLE_TYPE); if(value!=value2) { value=value2; uset_add(set, c); } } uset_add(set, 0x1160); value=U_HST_VOWEL_JAMO; for(c=0x11a3; c<=0x11a7; ++c) { value2=u_getIntPropertyValue(c, UCHAR_HANGUL_SYLLABLE_TYPE); if(value!=value2) { value=value2; uset_add(set, c); } } uset_add(set, 0x11a8); value=U_HST_TRAILING_JAMO; for(c=0x11fa; c<=0x11ff; ++c) { value2=u_getIntPropertyValue(c, UCHAR_HANGUL_SYLLABLE_TYPE); if(value!=value2) { value=value2; uset_add(set, c); } } /* * Omit code points for u_charCellWidth() because * - it is deprecated and not a real Unicode property * - they are probably already set from the trie enumeration */ /* * Omit code points with hardcoded specialcasing properties * because we do not build property UnicodeSets for them right now. */ } /* string casing ------------------------------------------------------------ */ /* * These internal string case mapping functions are here instead of ustring.c * because we need efficient access to the character properties. * * This section contains helper functions that check for conditions * in the input text surrounding the current code point * according to SpecialCasing.txt. * * Starting with ICU 2.1, the "surrounding text" is passed in as an instance of * UCharIterator to allow the core case mapping functions to be used * inside transliterators (using Replaceable instead of UnicodeString/UChar *) * etc. * * Each helper function gets the index * - after the current code point if it looks at following text * - before the current code point if it looks at preceding text * * Unicode 3.2 UAX 21 "Case Mappings" defines the conditions as follows: * * Final_Sigma * C is preceded by a sequence consisting of * a cased letter and a case-ignorable sequence, * and C is not followed by a sequence consisting of * an ignorable sequence and then a cased letter. * * More_Above * C is followed by one or more characters of combining class 230 (ABOVE) * in the combining character sequence. * * After_Soft_Dotted * The last preceding character with combining class of zero before C * was Soft_Dotted, * and there is no intervening combining character class 230 (ABOVE). * * Before_Dot * C is followed by combining dot above (U+0307). * Any sequence of characters with a combining class that is neither 0 nor 230 * may intervene between the current character and the combining dot above. * * The erratum from 2002-10-31 adds the condition * * After_I * The last preceding base character was an uppercase I, and there is no * intervening combining character class 230 (ABOVE). * * (See Jitterbug 2344 and the comments on After_I below.) * * Helper definitions in Unicode 3.2 UAX 21: * * D1. A character C is defined to be cased * if it meets any of the following criteria: * * - The general category of C is Titlecase Letter (Lt) * - In [CoreProps], C has one of the properties Uppercase, or Lowercase * - Given D = NFD(C), then it is not the case that: * D = UCD_lower(D) = UCD_upper(D) = UCD_title(D) * (This third criterium does not add any characters to the list * for Unicode 3.2. Ignored.) * * D2. A character C is defined to be case-ignorable * if it meets either of the following criteria: * * - The general category of C is * Nonspacing Mark (Mn), or Enclosing Mark (Me), or Format Control (Cf), or * Letter Modifier (Lm), or Symbol Modifier (Sk) * - C is one of the following characters * U+0027 APOSTROPHE * U+00AD SOFT HYPHEN (SHY) * U+2019 RIGHT SINGLE QUOTATION MARK * (the preferred character for apostrophe) * * D3. A case-ignorable sequence is a sequence of * zero or more case-ignorable characters. */ enum { LOC_ROOT, LOC_TURKISH, LOC_LITHUANIAN }; static int32_t getCaseLocale(const char *locale) { char lang[32]; UErrorCode errorCode; int32_t length; errorCode=U_ZERO_ERROR; length=uloc_getLanguage(locale, lang, sizeof(lang), &errorCode); if(U_FAILURE(errorCode) || length!=2) { return LOC_ROOT; } if( (lang[0]=='t' && lang[1]=='r') || (lang[0]=='a' && lang[1]=='z') ) { return LOC_TURKISH; } else if(lang[0]=='l' && lang[1]=='t') { return LOC_LITHUANIAN; } else { return LOC_ROOT; } } /* Is case-ignorable? */ static U_INLINE UBool isCaseIgnorable(UChar32 c, uint32_t category) { return (FLAG(category)&(_Mn|_Me|_Cf|_Lm|_Sk))!=0 || c==0x27 || c==0xad || c==0x2019; } /* Is this a "cased" character? */ static U_INLINE UBool isCased(UChar32 c, uint32_t category) { /* Lt+Uppercase+Lowercase = Lt+Lu+Ll+Other_Uppercase+Other_Lowercase */ return (FLAG(category)&(_Lt|_Lu|_Ll))!=0 || (u_getUnicodeProperties(c, 1)&(FLAG(UPROPS_UPPERCASE)|FLAG(UPROPS_LOWERCASE)))!=0; } /* Is Soft_Dotted? */ static U_INLINE UBool isSoftDotted(UChar32 c) { return (u_getUnicodeProperties(c, 1)&FLAG(UPROPS_SOFT_DOTTED))!=0; } /* Is followed by {case-ignorable}* cased ? */ static UBool isFollowedByCasedLetter(UCharIterator *iter, int32_t index) { /* This is volatile because AIX 5.1 Visual Age 5.0 in 32-bit mode can't optimize this correctly. It couldn't optimize (1UL<move(iter, index, UITER_ZERO); for(;;) { c=uiter_next32(iter); if(c<0) { break; } GET_PROPS_UNSAFE(c, props); category=GET_CATEGORY(props); if(isCased(c, category)) { return TRUE; /* followed by cased letter */ } if(!isCaseIgnorable(c, category)) { return FALSE; /* not ignorable */ } } return FALSE; /* not followed by cased letter */ } /* Is preceded by cased {case-ignorable}* ? */ static UBool isPrecededByCasedLetter(UCharIterator *iter, int32_t index) { /* This is volatile because AIX 5.1 Visual Age 5.0 in 32-bit mode can't optimize this correctly. It couldn't optimize (1UL<move(iter, index, UITER_ZERO); for(;;) { c=uiter_previous32(iter); if(c<0) { break; } GET_PROPS_UNSAFE(c, props); category=GET_CATEGORY(props); if(isCased(c, category)) { return TRUE; /* preceded by cased letter */ } if(!isCaseIgnorable(c, category)) { return FALSE; /* not ignorable */ } } return FALSE; /* not followed by cased letter */ } /* Is preceded by Soft_Dotted character with no intervening cc=230 ? */ static UBool isPrecededBySoftDotted(UCharIterator *iter, int32_t index) { int32_t c; uint8_t cc; if(iter==NULL) { return FALSE; } iter->move(iter, index, UITER_ZERO); for(;;) { c=uiter_previous32(iter); if(c<0) { break; } if(isSoftDotted(c)) { return TRUE; /* preceded by TYPE_i */ } cc=u_getCombiningClass(c); if(cc==0 || cc==230) { return FALSE; /* preceded by different base character (not TYPE_i), or intervening cc==230 */ } } return FALSE; /* not preceded by TYPE_i */ } /* * See Jitterbug 2344: * The condition After_I for Turkic-lowercasing of U+0307 combining dot above * is checked in ICU 2.0, 2.1, 2.6 but was not in 2.2 & 2.4 because * we made those releases compatible with Unicode 3.2 which had not fixed * a related but in SpecialCasing.txt. * * From the Jitterbug 2344 text: * ... this bug is listed as a Unicode erratum * from 2002-10-31 at http://www.unicode.org/uni2errata/UnicodeErrata.html * * There are two errors in SpecialCasing.txt. * 1. Missing semicolons on two lines. ... [irrelevant for ICU] * 2. An incorrect context definition. Correct as follows: * < 0307; ; 0307; 0307; tr After_Soft_Dotted; # COMBINING DOT ABOVE * < 0307; ; 0307; 0307; az After_Soft_Dotted; # COMBINING DOT ABOVE * --- * > 0307; ; 0307; 0307; tr After_I; # COMBINING DOT ABOVE * > 0307; ; 0307; 0307; az After_I; # COMBINING DOT ABOVE * where the context After_I is defined as: * The last preceding base character was an uppercase I, and there is no * intervening combining character class 230 (ABOVE). * * * Note that SpecialCasing.txt even in Unicode 3.2 described the condition as: * * # When lowercasing, remove dot_above in the sequence I + dot_above, which will turn into i. * # This matches the behavior of the canonically equivalent I-dot_above * * See also the description in this place in older versions of uchar.c (revision 1.100). * * Markus W. Scherer 2003-feb-15 */ /* Is preceded by base character 'I' with no intervening cc=230 ? */ static UBool isPrecededBy_I(UCharIterator *iter, int32_t index) { int32_t c; uint8_t cc; if(iter==NULL) { return FALSE; } iter->move(iter, index, UITER_ZERO); for(;;) { c=uiter_previous32(iter); if(c<0) { break; } if(c==0x49) { return TRUE; /* preceded by I */ } cc=u_getCombiningClass(c); if(cc==0 || cc==230) { return FALSE; /* preceded by different base character (not I), or intervening cc==230 */ } } return FALSE; /* not preceded by I */ } /* Is followed by one or more cc==230 ? */ static UBool isFollowedByMoreAbove(UCharIterator *iter, int32_t index) { int32_t c; uint8_t cc; if(iter==NULL) { return FALSE; } iter->move(iter, index, UITER_ZERO); for(;;) { c=uiter_next32(iter); if(c<0) { break; } cc=u_getCombiningClass(c); if(cc==230) { return TRUE; /* at least one cc==230 following */ } if(cc==0) { return FALSE; /* next base character, no more cc==230 following */ } } return FALSE; /* no more cc==230 following */ } /* Is followed by a dot above (without cc==230 in between) ? */ static UBool isFollowedByDotAbove(UCharIterator *iter, int32_t index) { int32_t c; uint8_t cc; if(iter==NULL) { return FALSE; } iter->move(iter, index, UITER_ZERO); for(;;) { c=uiter_next32(iter); if(c<0) { break; } if(c==0x307) { return TRUE; } cc=u_getCombiningClass(c); if(cc==0 || cc==230) { return FALSE; /* next base character or cc==230 in between */ } } return FALSE; /* no dot above following */ } /* lowercasing -------------------------------------------------------------- */ /* internal, see ustr_imp.h */ U_CAPI int32_t U_EXPORT2 u_internalToLower(UChar32 c, UCharIterator *iter, UChar *dest, int32_t destCapacity, const char *locale) { UChar buffer[8]; uint32_t props; UChar32 result; int32_t i, length; result=c; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(CAT_MASK(props)&(U_GC_LU_MASK|U_GC_LT_MASK)) { result=c+GET_SIGNED_VALUE(props); } } else { const UChar *u; const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe, specialCasing; int32_t minLength; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_SPECIAL_CASING)) { i=EXC_SPECIAL_CASING; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); specialCasing=*pe; /* fill u and length with the case mapping result string */ if(specialCasing&0x80000000) { /* use hardcoded conditions and mappings */ int32_t loc=getCaseLocale(locale), srcIndex= iter!=NULL ? iter->getIndex(iter, UITER_CURRENT) : 0; /* * Test for conditional mappings first * (otherwise the unconditional default mappings are always taken), * then test for characters that have unconditional mappings in SpecialCasing.txt, * then get the UnicodeData.txt mappings. */ if( loc==LOC_LITHUANIAN && /* base characters, find accents above */ (((c==0x49 || c==0x4a || c==0x12e) && isFollowedByMoreAbove(iter, srcIndex)) || /* precomposed with accent above, no need to find one */ (c==0xcc || c==0xcd || c==0x128)) ) { /* # Lithuanian # Lithuanian retains the dot in a lowercase i when followed by accents. # Introduce an explicit dot above when lowercasing capital I's and J's # whenever there are more accents above. # (of the accents used in Lithuanian: grave, acute, tilde above, and ogonek) 0049; 0069 0307; 0049; 0049; lt More_Above; # LATIN CAPITAL LETTER I 004A; 006A 0307; 004A; 004A; lt More_Above; # LATIN CAPITAL LETTER J 012E; 012F 0307; 012E; 012E; lt More_Above; # LATIN CAPITAL LETTER I WITH OGONEK 00CC; 0069 0307 0300; 00CC; 00CC; lt; # LATIN CAPITAL LETTER I WITH GRAVE 00CD; 0069 0307 0301; 00CD; 00CD; lt; # LATIN CAPITAL LETTER I WITH ACUTE 0128; 0069 0307 0303; 0128; 0128; lt; # LATIN CAPITAL LETTER I WITH TILDE */ u=buffer; buffer[1]=0x307; switch(c) { case 0x49: /* LATIN CAPITAL LETTER I */ buffer[0]=0x69; length=2; break; case 0x4a: /* LATIN CAPITAL LETTER J */ buffer[0]=0x6a; length=2; break; case 0x12e: /* LATIN CAPITAL LETTER I WITH OGONEK */ buffer[0]=0x12f; length=2; break; case 0xcc: /* LATIN CAPITAL LETTER I WITH GRAVE */ buffer[0]=0x69; buffer[2]=0x300; length=3; break; case 0xcd: /* LATIN CAPITAL LETTER I WITH ACUTE */ buffer[0]=0x69; buffer[2]=0x301; length=3; break; case 0x128: /* LATIN CAPITAL LETTER I WITH TILDE */ buffer[0]=0x69; buffer[2]=0x303; length=3; break; default: return 0; /* will not occur */ } /* # Turkish and Azeri */ } else if(loc==LOC_TURKISH && c==0x130) { /* # I and i-dotless; I-dot and i are case pairs in Turkish and Azeri # The following rules handle those cases. 0130; 0069; 0130; 0130; tr # LATIN CAPITAL LETTER I WITH DOT ABOVE 0130; 0069; 0130; 0130; az # LATIN CAPITAL LETTER I WITH DOT ABOVE */ result=0x69; goto single; } else if(loc==LOC_TURKISH && c==0x307 && isPrecededBy_I(iter, srcIndex-1)) { /* # When lowercasing, remove dot_above in the sequence I + dot_above, which will turn into i. # This matches the behavior of the canonically equivalent I-dot_above 0307; ; 0307; 0307; tr After_I; # COMBINING DOT ABOVE 0307; ; 0307; 0307; az After_I; # COMBINING DOT ABOVE */ return 0; /* remove the dot (continue without output) */ } else if(loc==LOC_TURKISH && c==0x49 && !isFollowedByDotAbove(iter, srcIndex)) { /* # When lowercasing, unless an I is before a dot_above, it turns into a dotless i. 0049; 0131; 0049; 0049; tr Not_Before_Dot; # LATIN CAPITAL LETTER I 0049; 0131; 0049; 0049; az Not_Before_Dot; # LATIN CAPITAL LETTER I */ result=0x131; goto single; } else if(c==0x130) { /* # Preserve canonical equivalence for I with dot. Turkic is handled below. 0130; 0069 0307; 0130; 0130; # LATIN CAPITAL LETTER I WITH DOT ABOVE */ static const UChar iWithDot[2]={ 0x69, 0x307 }; u=iWithDot; length=2; } else if( c==0x3a3 && !isFollowedByCasedLetter(iter, srcIndex) && isPrecededByCasedLetter(iter, srcIndex-1) ) { /* greek capital sigma maps depending on surrounding cased letters (see SpecialCasing.txt) */ /* # Special case for final form of sigma 03A3; 03C2; 03A3; 03A3; Final_Sigma; # GREEK CAPITAL LETTER SIGMA */ result=0x3c2; /* greek small final sigma */ goto single; } else { /* no known conditional special case mapping, use a normal mapping */ pe=GET_EXCEPTIONS(props); /* restore the initial exception pointer */ firstExceptionValue=*pe; goto notSpecial; } } else { /* get the special case mapping string from the data file */ u=ucharsTable+(specialCasing&0xffff); length=(int32_t)((*u++)&0x1f); } /* copy the result string */ minLength = (length < destCapacity) ? length : destCapacity; i=0; while(idestCapacity) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } return destIndex; } /* uppercasing -------------------------------------------------------------- */ /* internal */ static int32_t u_internalToUpperOrTitle(UChar32 c, UCharIterator *iter, UChar *dest, int32_t destCapacity, const char *locale, UBool upperNotTitle) { uint32_t props; UChar32 result; int32_t i, length; result=c; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(GET_CATEGORY(props)==U_LOWERCASE_LETTER) { result=c-GET_SIGNED_VALUE(props); } } else { const UChar *u; const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe, specialCasing; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_SPECIAL_CASING)) { i=EXC_SPECIAL_CASING; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); specialCasing=*pe; /* fill u and length with the case mapping result string */ if(specialCasing&0x80000000) { /* use hardcoded conditions and mappings */ int32_t loc=getCaseLocale(locale), srcIndex= iter!=NULL ? iter->getIndex(iter, UITER_CURRENT) : 0; if(loc==LOC_TURKISH && c==0x69) { /* # Turkish and Azeri # I and i-dotless; I-dot and i are case pairs in Turkish and Azeri # The following rules handle those cases. # When uppercasing, i turns into a dotted capital I 0069; 0069; 0130; 0130; tr; # LATIN SMALL LETTER I 0069; 0069; 0130; 0130; az; # LATIN SMALL LETTER I */ result=0x130; goto single; } else if(loc==LOC_LITHUANIAN && c==0x307 && isPrecededBySoftDotted(iter, srcIndex-1)) { /* # Lithuanian # Lithuanian retains the dot in a lowercase i when followed by accents. # Remove DOT ABOVE after "i" with upper or titlecase 0307; 0307; ; ; lt After_Soft_Dotted; # COMBINING DOT ABOVE */ return 0; /* remove the dot (continue without output) */ } else { /* no known conditional special case mapping, use a normal mapping */ pe=GET_EXCEPTIONS(props); /* restore the initial exception pointer */ firstExceptionValue=*pe; goto notSpecial; } } else { /* get the special case mapping string from the data file */ u=ucharsTable+(specialCasing&0xffff); length=(int32_t)*u++; /* skip the lowercase result string */ u+=length&0x1f; if(upperNotTitle) { length=(length>>5)&0x1f; } else { /* skip the uppercase result strings too */ u+=(length>>5)&0x1f; length=(length>>10)&0x1f; } } /* copy the result string */ i=0; while(idestCapacity) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } return destIndex; } /* titlecasing -------------------------------------------------------------- */ /* internal, see ustr_imp.h */ U_CAPI int32_t U_EXPORT2 u_internalToTitle(UChar32 c, UCharIterator *iter, UChar *dest, int32_t destCapacity, const char *locale) { return u_internalToUpperOrTitle(c, iter, dest, destCapacity, locale, FALSE); } /* case folding ------------------------------------------------------------- */ /* * Case folding is similar to lowercasing. * The result may be a simple mapping, i.e., a single code point, or * a full mapping, i.e., a string. * If the case folding for a code point is the same as its simple (1:1) lowercase mapping, * then only the lowercase mapping is stored. * * Some special cases are hardcoded because their conditions cannot be * parsed and processed from CaseFolding.txt. * * Unicode 3.2 CaseFolding.txt specifies for its status field: # C: common case folding, common mappings shared by both simple and full mappings. # F: full case folding, mappings that cause strings to grow in length. Multiple characters are separated by spaces. # S: simple case folding, mappings to single characters where different from F. # T: special case for uppercase I and dotted uppercase I # - For non-Turkic languages, this mapping is normally not used. # - For Turkic languages (tr, az), this mapping can be used instead of the normal mapping for these characters. # # Usage: # A. To do a simple case folding, use the mappings with status C + S. # B. To do a full case folding, use the mappings with status C + F. # # The mappings with status T can be used or omitted depending on the desired case-folding # behavior. (The default option is to exclude them.) * Unicode 3.2 has 'T' mappings as follows: 0049; T; 0131; # LATIN CAPITAL LETTER I 0130; T; 0069; # LATIN CAPITAL LETTER I WITH DOT ABOVE * while the default mappings for these code points are: 0049; C; 0069; # LATIN CAPITAL LETTER I 0130; F; 0069 0307; # LATIN CAPITAL LETTER I WITH DOT ABOVE * U+0130 is otherwise lowercased to U+0069 (UnicodeData.txt). * * In case this code is used with CaseFolding.txt from an older version of Unicode * where CaseFolding.txt contains mappings with a status of 'I' that * have the opposite polarity ('I' mappings are included by default but excluded for Turkic), * we must also hardcode the Unicode 3.2 mappings for the code points * with 'I' mappings. * Unicode 3.1.1 has 'I' mappings for U+0130 and U+0131. * Unicode 3.2 has a 'T' mapping for U+0130, and lowercases U+0131 to itself (see UnicodeData.txt). */ /* return the simple case folding mapping for c */ U_CAPI UChar32 U_EXPORT2 u_foldCase(UChar32 c, uint32_t options) { uint32_t props; GET_PROPS(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(CAT_MASK(props)&(U_GC_LU_MASK|U_GC_LT_MASK)) { return c+GET_SIGNED_VALUE(props); } } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_CASE_FOLDING)) { const uint32_t *oldPE=pe; int i=EXC_CASE_FOLDING; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); props=*pe; if(props!=0) { /* return the simple mapping, if there is one */ const UChar *uchars=ucharsTable+(props&0xffff); UChar32 simple; i=0; UTF_NEXT_CHAR_UNSAFE(uchars, i, simple); if(simple!=0) { return simple; } /* fall through to use the lowercase exception value if there is no simple mapping */ pe=oldPE; } else { /* special case folding mappings, hardcoded */ if((options&_FOLD_CASE_OPTIONS_MASK)==U_FOLD_CASE_DEFAULT) { /* default mappings */ if(c==0x49) { /* 0049; C; 0069; # LATIN CAPITAL LETTER I */ return 0x69; } else if(c==0x130) { /* no simple default mapping for U+0130, use UnicodeData.txt */ return 0x69; } } else { /* Turkic mappings */ if(c==0x49) { /* 0049; T; 0131; # LATIN CAPITAL LETTER I */ return 0x131; } else if(c==0x130) { /* 0130; T; 0069; # LATIN CAPITAL LETTER I WITH DOT ABOVE */ return 0x69; } } /* return c itself because there is no special mapping for it */ return c; } } /* not else! - allow to fall through from above */ if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_LOWERCASE)) { int i=EXC_LOWERCASE; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); return (UChar32)*pe; } } return c; /* no mapping - return c itself */ } /* * Issue for canonical caseless match (UAX #21): * Turkic casefolding (using "T" mappings in CaseFolding.txt) does not preserve * canonical equivalence, unlike default-option casefolding. * For example, I-grave and I + grave fold to strings that are not canonically * equivalent. * For more details, see the comment in unorm_compare() in unorm.cpp * and the intermediate prototype changes for Jitterbug 2021. * (For example, revision 1.104 of uchar.c and 1.4 of CaseFolding.txt.) * * This did not get fixed because it appears that it is not possible to fix * it for uppercase and lowercase characters (I-grave vs. i-grave) * together in a way that they still fold to common result strings. */ /* internal, see ustr_imp.h */ U_CAPI int32_t U_EXPORT2 u_internalFoldCase(UChar32 c, UChar *dest, int32_t destCapacity, uint32_t options) { uint32_t props; UChar32 result; int32_t i, length; result=c; GET_PROPS_UNSAFE(c, props); if(!PROPS_VALUE_IS_EXCEPTION(props)) { if(CAT_MASK(props)&(U_GC_LU_MASK|U_GC_LT_MASK)) { /* same as lowercase */ result=c+GET_SIGNED_VALUE(props); } } else { const uint32_t *pe=GET_EXCEPTIONS(props); uint32_t firstExceptionValue=*pe; if(HAVE_EXCEPTION_VALUE(firstExceptionValue, EXC_CASE_FOLDING)) { i=EXC_CASE_FOLDING; ++pe; ADD_EXCEPTION_OFFSET(firstExceptionValue, i, pe); props=*pe; if(props!=0) { /* return the full mapping */ const UChar *uchars=ucharsTable+(props&0xffff)+2; int32_t minLength; length=props>>24; minLength = (length < destCapacity) ? length : destCapacity; /* copy the result string */ i=0; while(idestCapacity) { *pErrorCode=U_BUFFER_OVERFLOW_ERROR; } return destIndex; }