/* *************************************************************************** * Copyright (C) 2008-2014, International Business Machines Corporation * and others. All Rights Reserved. *************************************************************************** * file name: uspoof.cpp * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created on: 2008Feb13 * created by: Andy Heninger * * Unicode Spoof Detection */ #include "unicode/utypes.h" #include "unicode/normalizer2.h" #include "unicode/uspoof.h" #include "unicode/ustring.h" #include "unicode/utf16.h" #include "cmemory.h" #include "cstring.h" #include "identifier_info.h" #include "mutex.h" #include "scriptset.h" #include "uassert.h" #include "ucln_in.h" #include "uspoof_impl.h" #include "umutex.h" #if !UCONFIG_NO_NORMALIZATION U_NAMESPACE_USE // // Static Objects used by the spoof impl, their thread safe initialization and their cleanup. // static UnicodeSet *gInclusionSet = NULL; static UnicodeSet *gRecommendedSet = NULL; static const Normalizer2 *gNfdNormalizer = NULL; static UInitOnce gSpoofInitOnce = U_INITONCE_INITIALIZER; static UBool U_CALLCONV uspoof_cleanup(void) { delete gInclusionSet; gInclusionSet = NULL; delete gRecommendedSet; gRecommendedSet = NULL; gNfdNormalizer = NULL; gSpoofInitOnce.reset(); return TRUE; } static void U_CALLCONV initializeStatics(UErrorCode &status) { static const char *inclusionPat = "[\\u0027\\u002D-\\u002E\\u003A\\u00B7\\u0375\\u058A\\u05F3-\\u05F4" "\\u06FD-\\u06FE\\u0F0B\\u200C-\\u200D\\u2010\\u2019\\u2027\\u30A0\\u30FB]"; gInclusionSet = new UnicodeSet(UnicodeString(inclusionPat, -1, US_INV), status); gInclusionSet->freeze(); // Note: data from http://unicode.org/Public/security/latest/xidmodifications.txt version 7.0.0 // No tooling to generate this from the .txt file, hand extracted with editor macros. // Ultimately, data will be available as character properties, eliminating this. // Note: concatenated string constants do not work with UNICODE_STRING_SIMPLE on all platforms. static const char *recommendedPat = "[\\u0030-\\u0039\\u0041-\\u005A\\u005F\\u0061-\\u007A\\u00C0-\\u00D6\\u00D8-\\u00F6" "\\u00F8-\\u0131\\u0134-\\u013E\\u0141-\\u0148\\u014A-\\u017E\\u01A0-\\u01A1" "\\u01AF-\\u01B0\\u01CD-\\u01DC\\u01DE-\\u01E3\\u01E6-\\u01F0\\u01F4-\\u01F5" "\\u01F8-\\u021B\\u021E-\\u021F\\u0226-\\u0233\\u0259\\u02BB-\\u02BC\\u02EC" "\\u0300-\\u0304\\u0306-\\u030C\\u030F-\\u0311\\u0313-\\u0314\\u031B\\u0323-\\u0328" "\\u032D-\\u032E\\u0330-\\u0331\\u0335\\u0338-\\u0339\\u0342\\u0345\\u037B-\\u037D" "\\u0386\\u0388-\\u038A\\u038C\\u038E-\\u03A1\\u03A3-\\u03CE\\u03FC-\\u045F" "\\u048A-\\u0529\\u052E-\\u052F\\u0531-\\u0556\\u0559\\u0561-\\u0586\\u05B4" "\\u05D0-\\u05EA\\u05F0-\\u05F2\\u0620-\\u063F\\u0641-\\u0655\\u0660-\\u0669" "\\u0670-\\u0672\\u0674\\u0679-\\u068D\\u068F-\\u06D3\\u06D5\\u06E5-\\u06E6" "\\u06EE-\\u06FC\\u06FF\\u0750-\\u07B1\\u08A0-\\u08AC\\u08B2\\u0901-\\u094D" "\\u094F-\\u0950\\u0956-\\u0957\\u0960-\\u0963\\u0966-\\u096F\\u0971-\\u0977" "\\u0979-\\u097F\\u0981-\\u0983\\u0985-\\u098C\\u098F-\\u0990\\u0993-\\u09A8" "\\u09AA-\\u09B0\\u09B2\\u09B6-\\u09B9\\u09BC-\\u09C4\\u09C7-\\u09C8\\u09CB-\\u09CE" "\\u09D7\\u09E0-\\u09E3\\u09E6-\\u09F1\\u0A01-\\u0A03\\u0A05-\\u0A0A\\u0A0F-\\u0A10" "\\u0A13-\\u0A28\\u0A2A-\\u0A30\\u0A32\\u0A35\\u0A38-\\u0A39\\u0A3C\\u0A3E-\\u0A42" "\\u0A47-\\u0A48\\u0A4B-\\u0A4D\\u0A5C\\u0A66-\\u0A74\\u0A81-\\u0A83\\u0A85-\\u0A8D" "\\u0A8F-\\u0A91\\u0A93-\\u0AA8\\u0AAA-\\u0AB0\\u0AB2-\\u0AB3\\u0AB5-\\u0AB9" "\\u0ABC-\\u0AC5\\u0AC7-\\u0AC9\\u0ACB-\\u0ACD\\u0AD0\\u0AE0-\\u0AE3\\u0AE6-\\u0AEF" "\\u0B01-\\u0B03\\u0B05-\\u0B0C\\u0B0F-\\u0B10\\u0B13-\\u0B28\\u0B2A-\\u0B30" "\\u0B32-\\u0B33\\u0B35-\\u0B39\\u0B3C-\\u0B43\\u0B47-\\u0B48\\u0B4B-\\u0B4D" "\\u0B56-\\u0B57\\u0B5F-\\u0B61\\u0B66-\\u0B6F\\u0B71\\u0B82-\\u0B83\\u0B85-\\u0B8A" "\\u0B8E-\\u0B90\\u0B92-\\u0B95\\u0B99-\\u0B9A\\u0B9C\\u0B9E-\\u0B9F\\u0BA3-\\u0BA4" "\\u0BA8-\\u0BAA\\u0BAE-\\u0BB9\\u0BBE-\\u0BC2\\u0BC6-\\u0BC8\\u0BCA-\\u0BCD" "\\u0BD0\\u0BD7\\u0BE6-\\u0BEF\\u0C01-\\u0C03\\u0C05-\\u0C0C\\u0C0E-\\u0C10" "\\u0C12-\\u0C28\\u0C2A-\\u0C33\\u0C35-\\u0C39\\u0C3D-\\u0C44\\u0C46-\\u0C48" "\\u0C4A-\\u0C4D\\u0C55-\\u0C56\\u0C60-\\u0C61\\u0C66-\\u0C6F\\u0C82-\\u0C83" "\\u0C85-\\u0C8C\\u0C8E-\\u0C90\\u0C92-\\u0CA8\\u0CAA-\\u0CB3\\u0CB5-\\u0CB9" "\\u0CBC-\\u0CC4\\u0CC6-\\u0CC8\\u0CCA-\\u0CCD\\u0CD5-\\u0CD6\\u0CE0-\\u0CE3" "\\u0CE6-\\u0CEF\\u0CF1-\\u0CF2\\u0D02-\\u0D03\\u0D05-\\u0D0C\\u0D0E-\\u0D10" "\\u0D12-\\u0D3A\\u0D3D-\\u0D43\\u0D46-\\u0D48\\u0D4A-\\u0D4E\\u0D57\\u0D60-\\u0D61" "\\u0D66-\\u0D6F\\u0D7A-\\u0D7F\\u0D82-\\u0D83\\u0D85-\\u0D8E\\u0D91-\\u0D96" "\\u0D9A-\\u0DA5\\u0DA7-\\u0DB1\\u0DB3-\\u0DBB\\u0DBD\\u0DC0-\\u0DC6\\u0DCA" "\\u0DCF-\\u0DD4\\u0DD6\\u0DD8-\\u0DDE\\u0DF2\\u0E01-\\u0E32\\u0E34-\\u0E3A" "\\u0E40-\\u0E4E\\u0E50-\\u0E59\\u0E81-\\u0E82\\u0E84\\u0E87-\\u0E88\\u0E8A" "\\u0E8D\\u0E94-\\u0E97\\u0E99-\\u0E9F\\u0EA1-\\u0EA3\\u0EA5\\u0EA7\\u0EAA-\\u0EAB" "\\u0EAD-\\u0EB2\\u0EB4-\\u0EB9\\u0EBB-\\u0EBD\\u0EC0-\\u0EC4\\u0EC6\\u0EC8-\\u0ECD" "\\u0ED0-\\u0ED9\\u0EDE-\\u0EDF\\u0F00\\u0F20-\\u0F29\\u0F35\\u0F37\\u0F3E-\\u0F42" "\\u0F44-\\u0F47\\u0F49-\\u0F4C\\u0F4E-\\u0F51\\u0F53-\\u0F56\\u0F58-\\u0F5B" "\\u0F5D-\\u0F68\\u0F6A-\\u0F6C\\u0F71-\\u0F72\\u0F74\\u0F7A-\\u0F80\\u0F82-\\u0F84" "\\u0F86-\\u0F92\\u0F94-\\u0F97\\u0F99-\\u0F9C\\u0F9E-\\u0FA1\\u0FA3-\\u0FA6" "\\u0FA8-\\u0FAB\\u0FAD-\\u0FB8\\u0FBA-\\u0FBC\\u0FC6\\u1000-\\u1049\\u1050-\\u109D" "\\u10C7\\u10CD\\u10D0-\\u10F0\\u10F7-\\u10FA\\u10FD-\\u10FF\\u1200-\\u1248" "\\u124A-\\u124D\\u1250-\\u1256\\u1258\\u125A-\\u125D\\u1260-\\u1288\\u128A-\\u128D" "\\u1290-\\u12B0\\u12B2-\\u12B5\\u12B8-\\u12BE\\u12C0\\u12C2-\\u12C5\\u12C8-\\u12D6" "\\u12D8-\\u1310\\u1312-\\u1315\\u1318-\\u135A\\u135D-\\u135F\\u1380-\\u138F" "\\u1780-\\u17A2\\u17A5-\\u17A7\\u17A9-\\u17B3\\u17B6-\\u17CA\\u17D2\\u17D7" "\\u17DC\\u17E0-\\u17E9\\u1E00-\\u1E99\\u1EBF\\u1F00-\\u1F15\\u1F18-\\u1F1D" "\\u1F20-\\u1F45\\u1F48-\\u1F4D\\u1F50-\\u1F57\\u1F59\\u1F5B\\u1F5D\\u1F5F-\\u1F70" "\\u1F72\\u1F74\\u1F76\\u1F78\\u1F7A\\u1F7C\\u1F80-\\u1FB4\\u1FB6-\\u1FBA" "\\u1FBC\\u1FC2-\\u1FC4\\u1FC6-\\u1FC8\\u1FCA\\u1FCC\\u1FD0-\\u1FD2\\u1FD6-\\u1FDA" "\\u1FE0-\\u1FE2\\u1FE4-\\u1FEA\\u1FEC\\u1FF2-\\u1FF4\\u1FF6-\\u1FF8\\u1FFA" "\\u1FFC\\u2D27\\u2D2D\\u2D80-\\u2D96\\u2DA0-\\u2DA6\\u2DA8-\\u2DAE\\u2DB0-\\u2DB6" "\\u2DB8-\\u2DBE\\u2DC0-\\u2DC6\\u2DC8-\\u2DCE\\u2DD0-\\u2DD6\\u2DD8-\\u2DDE" "\\u3005-\\u3007\\u3041-\\u3096\\u3099-\\u309A\\u309D-\\u309E\\u30A1-\\u30FA" "\\u30FC-\\u30FE\\u3105-\\u312D\\u31A0-\\u31BA\\u3400-\\u4DB5\\u4E00-\\u9FCC" "\\uA660-\\uA661\\uA674-\\uA67B\\uA67F\\uA69F\\uA717-\\uA71F\\uA788\\uA78D-\\uA78E" "\\uA790-\\uA793\\uA7A0-\\uA7AA\\uA7FA\\uA9E7-\\uA9FE\\uAA60-\\uAA76\\uAA7A-\\uAA7F" "\\uAB01-\\uAB06\\uAB09-\\uAB0E\\uAB11-\\uAB16\\uAB20-\\uAB26\\uAB28-\\uAB2E" "\\uAC00-\\uD7A3\\uFA0E-\\uFA0F\\uFA11\\uFA13-\\uFA14\\uFA1F\\uFA21\\uFA23-\\uFA24" "\\uFA27-\\uFA29\\U0001B000-\\U0001B001\\U00020000-\\U0002A6D6\\U0002A700-\\U0002B734" "\\U0002B740-\\U0002B81D]"; gRecommendedSet = new UnicodeSet(UnicodeString(recommendedPat, -1, US_INV), status); gRecommendedSet->freeze(); gNfdNormalizer = Normalizer2::getNFDInstance(status); ucln_i18n_registerCleanup(UCLN_I18N_SPOOF, uspoof_cleanup); } U_CAPI USpoofChecker * U_EXPORT2 uspoof_open(UErrorCode *status) { if (U_FAILURE(*status)) { return NULL; } umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); SpoofImpl *si = new SpoofImpl(SpoofData::getDefault(*status), *status); if (U_FAILURE(*status)) { delete si; si = NULL; } return reinterpret_cast(si); } U_CAPI USpoofChecker * U_EXPORT2 uspoof_openFromSerialized(const void *data, int32_t length, int32_t *pActualLength, UErrorCode *status) { if (U_FAILURE(*status)) { return NULL; } umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); SpoofData *sd = new SpoofData(data, length, *status); SpoofImpl *si = new SpoofImpl(sd, *status); if (U_FAILURE(*status)) { delete sd; delete si; return NULL; } if (sd == NULL || si == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; delete sd; delete si; return NULL; } if (pActualLength != NULL) { *pActualLength = sd->fRawData->fLength; } return reinterpret_cast(si); } U_CAPI USpoofChecker * U_EXPORT2 uspoof_clone(const USpoofChecker *sc, UErrorCode *status) { const SpoofImpl *src = SpoofImpl::validateThis(sc, *status); if (src == NULL) { return NULL; } SpoofImpl *result = new SpoofImpl(*src, *status); // copy constructor if (U_FAILURE(*status)) { delete result; result = NULL; } return reinterpret_cast(result); } U_CAPI void U_EXPORT2 uspoof_close(USpoofChecker *sc) { UErrorCode status = U_ZERO_ERROR; SpoofImpl *This = SpoofImpl::validateThis(sc, status); delete This; } U_CAPI void U_EXPORT2 uspoof_setChecks(USpoofChecker *sc, int32_t checks, UErrorCode *status) { SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return; } // Verify that the requested checks are all ones (bits) that // are acceptable, known values. if (checks & ~(USPOOF_ALL_CHECKS | USPOOF_AUX_INFO)) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } This->fChecks = checks; } U_CAPI int32_t U_EXPORT2 uspoof_getChecks(const USpoofChecker *sc, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return 0; } return This->fChecks; } U_CAPI void U_EXPORT2 uspoof_setRestrictionLevel(USpoofChecker *sc, URestrictionLevel restrictionLevel) { UErrorCode status = U_ZERO_ERROR; SpoofImpl *This = SpoofImpl::validateThis(sc, status); if (This != NULL) { This->fRestrictionLevel = restrictionLevel; } } U_CAPI URestrictionLevel U_EXPORT2 uspoof_getRestrictionLevel(const USpoofChecker *sc) { UErrorCode status = U_ZERO_ERROR; const SpoofImpl *This = SpoofImpl::validateThis(sc, status); if (This == NULL) { return USPOOF_UNRESTRICTIVE; } return This->fRestrictionLevel; } U_CAPI void U_EXPORT2 uspoof_setAllowedLocales(USpoofChecker *sc, const char *localesList, UErrorCode *status) { SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return; } This->setAllowedLocales(localesList, *status); } U_CAPI const char * U_EXPORT2 uspoof_getAllowedLocales(USpoofChecker *sc, UErrorCode *status) { SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return NULL; } return This->getAllowedLocales(*status); } U_CAPI const USet * U_EXPORT2 uspoof_getAllowedChars(const USpoofChecker *sc, UErrorCode *status) { const UnicodeSet *result = uspoof_getAllowedUnicodeSet(sc, status); return result->toUSet(); } U_CAPI const UnicodeSet * U_EXPORT2 uspoof_getAllowedUnicodeSet(const USpoofChecker *sc, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return NULL; } return This->fAllowedCharsSet; } U_CAPI void U_EXPORT2 uspoof_setAllowedChars(USpoofChecker *sc, const USet *chars, UErrorCode *status) { const UnicodeSet *set = UnicodeSet::fromUSet(chars); uspoof_setAllowedUnicodeSet(sc, set, status); } U_CAPI void U_EXPORT2 uspoof_setAllowedUnicodeSet(USpoofChecker *sc, const UnicodeSet *chars, UErrorCode *status) { SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return; } if (chars->isBogus()) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } UnicodeSet *clonedSet = static_cast(chars->clone()); if (clonedSet == NULL || clonedSet->isBogus()) { *status = U_MEMORY_ALLOCATION_ERROR; return; } clonedSet->freeze(); delete This->fAllowedCharsSet; This->fAllowedCharsSet = clonedSet; This->fChecks |= USPOOF_CHAR_LIMIT; } U_CAPI int32_t U_EXPORT2 uspoof_check(const USpoofChecker *sc, const UChar *id, int32_t length, int32_t *position, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return 0; } if (length < -1) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString idStr((length == -1), id, length); // Aliasing constructor. int32_t result = uspoof_checkUnicodeString(sc, idStr, position, status); return result; } U_CAPI int32_t U_EXPORT2 uspoof_checkUTF8(const USpoofChecker *sc, const char *id, int32_t length, int32_t *position, UErrorCode *status) { if (U_FAILURE(*status)) { return 0; } UnicodeString idStr = UnicodeString::fromUTF8(StringPiece(id, length>=0 ? length : uprv_strlen(id))); int32_t result = uspoof_checkUnicodeString(sc, idStr, position, status); return result; } U_CAPI int32_t U_EXPORT2 uspoof_areConfusable(const USpoofChecker *sc, const UChar *id1, int32_t length1, const UChar *id2, int32_t length2, UErrorCode *status) { SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return 0; } if (length1 < -1 || length2 < -1) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString id1Str((length1==-1), id1, length1); // Aliasing constructor UnicodeString id2Str((length2==-1), id2, length2); // Aliasing constructor return uspoof_areConfusableUnicodeString(sc, id1Str, id2Str, status); } U_CAPI int32_t U_EXPORT2 uspoof_areConfusableUTF8(const USpoofChecker *sc, const char *id1, int32_t length1, const char *id2, int32_t length2, UErrorCode *status) { SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return 0; } if (length1 < -1 || length2 < -1) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString id1Str = UnicodeString::fromUTF8(StringPiece(id1, length1>=0? length1 : uprv_strlen(id1))); UnicodeString id2Str = UnicodeString::fromUTF8(StringPiece(id2, length2>=0? length2 : uprv_strlen(id2))); int32_t results = uspoof_areConfusableUnicodeString(sc, id1Str, id2Str, status); return results; } U_CAPI int32_t U_EXPORT2 uspoof_areConfusableUnicodeString(const USpoofChecker *sc, const icu::UnicodeString &id1, const icu::UnicodeString &id2, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return 0; } // // See section 4 of UAX 39 for the algorithm for checking whether two strings are confusable, // and for definitions of the types (single, whole, mixed-script) of confusables. // We only care about a few of the check flags. Ignore the others. // If no tests relavant to this function have been specified, return an error. // TODO: is this really the right thing to do? It's probably an error on the caller's part, // but logically we would just return 0 (no error). if ((This->fChecks & (USPOOF_SINGLE_SCRIPT_CONFUSABLE | USPOOF_MIXED_SCRIPT_CONFUSABLE | USPOOF_WHOLE_SCRIPT_CONFUSABLE)) == 0) { *status = U_INVALID_STATE_ERROR; return 0; } int32_t flagsForSkeleton = This->fChecks & USPOOF_ANY_CASE; int32_t result = 0; IdentifierInfo *identifierInfo = This->getIdentifierInfo(*status); if (U_FAILURE(*status)) { return 0; } identifierInfo->setIdentifier(id1, *status); int32_t id1ScriptCount = identifierInfo->getScriptCount(); int32_t id1FirstScript = identifierInfo->getScripts()->nextSetBit(0); identifierInfo->setIdentifier(id2, *status); int32_t id2ScriptCount = identifierInfo->getScriptCount(); int32_t id2FirstScript = identifierInfo->getScripts()->nextSetBit(0); This->releaseIdentifierInfo(identifierInfo); identifierInfo = NULL; if (This->fChecks & USPOOF_SINGLE_SCRIPT_CONFUSABLE) { UnicodeString id1Skeleton; UnicodeString id2Skeleton; if (id1ScriptCount <= 1 && id2ScriptCount <= 1 && id1FirstScript == id2FirstScript) { flagsForSkeleton |= USPOOF_SINGLE_SCRIPT_CONFUSABLE; uspoof_getSkeletonUnicodeString(sc, flagsForSkeleton, id1, id1Skeleton, status); uspoof_getSkeletonUnicodeString(sc, flagsForSkeleton, id2, id2Skeleton, status); if (id1Skeleton == id2Skeleton) { result |= USPOOF_SINGLE_SCRIPT_CONFUSABLE; } } } if (result & USPOOF_SINGLE_SCRIPT_CONFUSABLE) { // If the two inputs are single script confusable they cannot also be // mixed or whole script confusable, according to the UAX39 definitions. // So we can skip those tests. return result; } // Two identifiers are whole script confusable if each is of a single script // and they are mixed script confusable. UBool possiblyWholeScriptConfusables = id1ScriptCount <= 1 && id2ScriptCount <= 1 && (This->fChecks & USPOOF_WHOLE_SCRIPT_CONFUSABLE); // // Mixed Script Check // if ((This->fChecks & USPOOF_MIXED_SCRIPT_CONFUSABLE) || possiblyWholeScriptConfusables ) { // For getSkeleton(), resetting the USPOOF_SINGLE_SCRIPT_CONFUSABLE flag will get us // the mixed script table skeleton, which is what we want. // The Any Case / Lower Case bit in the skelton flags was set at the top of the function. UnicodeString id1Skeleton; UnicodeString id2Skeleton; flagsForSkeleton &= ~USPOOF_SINGLE_SCRIPT_CONFUSABLE; uspoof_getSkeletonUnicodeString(sc, flagsForSkeleton, id1, id1Skeleton, status); uspoof_getSkeletonUnicodeString(sc, flagsForSkeleton, id2, id2Skeleton, status); if (id1Skeleton == id2Skeleton) { result |= USPOOF_MIXED_SCRIPT_CONFUSABLE; if (possiblyWholeScriptConfusables) { result |= USPOOF_WHOLE_SCRIPT_CONFUSABLE; } } } return result; } U_CAPI int32_t U_EXPORT2 uspoof_checkUnicodeString(const USpoofChecker *sc, const icu::UnicodeString &id, int32_t *position, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { return 0; } int32_t result = 0; IdentifierInfo *identifierInfo = NULL; if ((This->fChecks) & (USPOOF_RESTRICTION_LEVEL | USPOOF_MIXED_NUMBERS)) { identifierInfo = This->getIdentifierInfo(*status); if (U_FAILURE(*status)) { goto cleanupAndReturn; } identifierInfo->setIdentifier(id, *status); identifierInfo->setIdentifierProfile(*This->fAllowedCharsSet); } if ((This->fChecks) & USPOOF_RESTRICTION_LEVEL) { URestrictionLevel idRestrictionLevel = identifierInfo->getRestrictionLevel(*status); if (idRestrictionLevel > This->fRestrictionLevel) { result |= USPOOF_RESTRICTION_LEVEL; } if (This->fChecks & USPOOF_AUX_INFO) { result |= idRestrictionLevel; } } if ((This->fChecks) & USPOOF_MIXED_NUMBERS) { const UnicodeSet *numerics = identifierInfo->getNumerics(); if (numerics->size() > 1) { result |= USPOOF_MIXED_NUMBERS; } // TODO: ICU4J returns the UnicodeSet of the numerics found in the identifier. // We have no easy way to do the same in C. // if (checkResult != null) { // checkResult.numerics = numerics; // } } if (This->fChecks & (USPOOF_CHAR_LIMIT)) { int32_t i; UChar32 c; int32_t length = id.length(); for (i=0; ifAllowedCharsSet->contains(c)) { result |= USPOOF_CHAR_LIMIT; break; } } } if (This->fChecks & (USPOOF_WHOLE_SCRIPT_CONFUSABLE | USPOOF_MIXED_SCRIPT_CONFUSABLE | USPOOF_INVISIBLE)) { // These are the checks that need to be done on NFD input UnicodeString nfdText; gNfdNormalizer->normalize(id, nfdText, *status); int32_t nfdLength = nfdText.length(); if (This->fChecks & USPOOF_INVISIBLE) { // scan for more than one occurence of the same non-spacing mark // in a sequence of non-spacing marks. int32_t i; UChar32 c; UChar32 firstNonspacingMark = 0; UBool haveMultipleMarks = FALSE; UnicodeSet marksSeenSoFar; // Set of combining marks in a single combining sequence. for (i=0; ifChecks & (USPOOF_WHOLE_SCRIPT_CONFUSABLE | USPOOF_MIXED_SCRIPT_CONFUSABLE)) { // The basic test is the same for both whole and mixed script confusables. // Compute the set of scripts that every input character has a confusable in. // For this computation an input character is always considered to be // confusable with itself in its own script. // // If the number of such scripts is two or more, and the input consisted of // characters all from a single script, we have a whole script confusable. // (The two scripts will be the original script and the one that is confusable) // // If the number of such scripts >= one, and the original input contained characters from // more than one script, we have a mixed script confusable. (We can transform // some of the characters, and end up with a visually similar string all in // one script.) if (identifierInfo == NULL) { identifierInfo = This->getIdentifierInfo(*status); if (U_FAILURE(*status)) { goto cleanupAndReturn; } identifierInfo->setIdentifier(id, *status); } int32_t scriptCount = identifierInfo->getScriptCount(); ScriptSet scripts; This->wholeScriptCheck(nfdText, &scripts, *status); int32_t confusableScriptCount = scripts.countMembers(); //printf("confusableScriptCount = %d\n", confusableScriptCount); if ((This->fChecks & USPOOF_WHOLE_SCRIPT_CONFUSABLE) && confusableScriptCount >= 2 && scriptCount == 1) { result |= USPOOF_WHOLE_SCRIPT_CONFUSABLE; } if ((This->fChecks & USPOOF_MIXED_SCRIPT_CONFUSABLE) && confusableScriptCount >= 1 && scriptCount > 1) { result |= USPOOF_MIXED_SCRIPT_CONFUSABLE; } } } cleanupAndReturn: This->releaseIdentifierInfo(identifierInfo); if (position != NULL) { *position = 0; } return result; } U_CAPI int32_t U_EXPORT2 uspoof_getSkeleton(const USpoofChecker *sc, uint32_t type, const UChar *id, int32_t length, UChar *dest, int32_t destCapacity, UErrorCode *status) { SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return 0; } if (length<-1 || destCapacity<0 || (destCapacity==0 && dest!=NULL)) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString idStr((length==-1), id, length); // Aliasing constructor UnicodeString destStr; uspoof_getSkeletonUnicodeString(sc, type, idStr, destStr, status); destStr.extract(dest, destCapacity, *status); return destStr.length(); } U_I18N_API UnicodeString & U_EXPORT2 uspoof_getSkeletonUnicodeString(const USpoofChecker *sc, uint32_t type, const UnicodeString &id, UnicodeString &dest, UErrorCode *status) { const SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return dest; } int32_t tableMask = 0; switch (type) { case 0: tableMask = USPOOF_ML_TABLE_FLAG; break; case USPOOF_SINGLE_SCRIPT_CONFUSABLE: tableMask = USPOOF_SL_TABLE_FLAG; break; case USPOOF_ANY_CASE: tableMask = USPOOF_MA_TABLE_FLAG; break; case USPOOF_SINGLE_SCRIPT_CONFUSABLE | USPOOF_ANY_CASE: tableMask = USPOOF_SA_TABLE_FLAG; break; default: *status = U_ILLEGAL_ARGUMENT_ERROR; return dest; } UnicodeString nfdId; gNfdNormalizer->normalize(id, nfdId, *status); // Apply the skeleton mapping to the NFD normalized input string // Accumulate the skeleton, possibly unnormalized, in a UnicodeString. int32_t inputIndex = 0; UnicodeString skelStr; int32_t normalizedLen = nfdId.length(); for (inputIndex=0; inputIndex < normalizedLen; ) { UChar32 c = nfdId.char32At(inputIndex); inputIndex += U16_LENGTH(c); This->confusableLookup(c, tableMask, skelStr); } gNfdNormalizer->normalize(skelStr, dest, *status); return dest; } U_CAPI int32_t U_EXPORT2 uspoof_getSkeletonUTF8(const USpoofChecker *sc, uint32_t type, const char *id, int32_t length, char *dest, int32_t destCapacity, UErrorCode *status) { SpoofImpl::validateThis(sc, *status); if (U_FAILURE(*status)) { return 0; } if (length<-1 || destCapacity<0 || (destCapacity==0 && dest!=NULL)) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString srcStr = UnicodeString::fromUTF8(StringPiece(id, length>=0 ? length : uprv_strlen(id))); UnicodeString destStr; uspoof_getSkeletonUnicodeString(sc, type, srcStr, destStr, status); if (U_FAILURE(*status)) { return 0; } int32_t lengthInUTF8 = 0; u_strToUTF8(dest, destCapacity, &lengthInUTF8, destStr.getBuffer(), destStr.length(), status); return lengthInUTF8; } U_CAPI int32_t U_EXPORT2 uspoof_serialize(USpoofChecker *sc,void *buf, int32_t capacity, UErrorCode *status) { SpoofImpl *This = SpoofImpl::validateThis(sc, *status); if (This == NULL) { U_ASSERT(U_FAILURE(*status)); return 0; } int32_t dataSize = This->fSpoofData->fRawData->fLength; if (capacity < dataSize) { *status = U_BUFFER_OVERFLOW_ERROR; return dataSize; } uprv_memcpy(buf, This->fSpoofData->fRawData, dataSize); return dataSize; } U_CAPI const USet * U_EXPORT2 uspoof_getInclusionSet(UErrorCode *status) { umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); return gInclusionSet->toUSet(); } U_CAPI const USet * U_EXPORT2 uspoof_getRecommendedSet(UErrorCode *status) { umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); return gRecommendedSet->toUSet(); } U_I18N_API const UnicodeSet * U_EXPORT2 uspoof_getInclusionUnicodeSet(UErrorCode *status) { umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); return gInclusionSet; } U_I18N_API const UnicodeSet * U_EXPORT2 uspoof_getRecommendedUnicodeSet(UErrorCode *status) { umtx_initOnce(gSpoofInitOnce, &initializeStatics, *status); return gRecommendedSet; } #endif // !UCONFIG_NO_NORMALIZATION