/* ******************************************************************************* * Copyright (C) 1996-2003, International Business Machines * Corporation and others. All Rights Reserved. ******************************************************************************* * file name: ucol.cpp * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * Modification history * Date Name Comments * 1996-1999 various members of ICU team maintained C API for collation framework * 02/16/2001 synwee Added internal method getPrevSpecialCE * 03/01/2001 synwee Added maxexpansion functionality. * 03/16/2001 weiv Collation framework is rewritten in C and made UCA compliant */ #include "unicode/utypes.h" #include "uassert.h" #if !UCONFIG_NO_COLLATION #include "unicode/uloc.h" #include "unicode/coll.h" #include "unicode/tblcoll.h" #include "unicode/coleitr.h" #include "unicode/unorm.h" #include "unicode/udata.h" #include "unicode/uchar.h" #include "unicode/caniter.h" #include "ucol_bld.h" #include "ucol_imp.h" #include "ucol_tok.h" #include "ucol_elm.h" #include "bocsu.h" #include "unormimp.h" #include "unorm_it.h" #include "uresimp.h" #include "umutex.h" #include "uhash.h" #include "ucln_in.h" #include "cstring.h" #include "utracimp.h" #ifdef UCOL_DEBUG #include #endif U_NAMESPACE_USE /* added by synwee for trie manipulation*/ #define STAGE_1_SHIFT_ 10 #define STAGE_2_SHIFT_ 4 #define STAGE_2_MASK_AFTER_SHIFT_ 0x3F #define STAGE_3_MASK_ 0xF #define LAST_BYTE_MASK_ 0xFF #define SECOND_LAST_BYTE_SHIFT_ 8 #define ZERO_CC_LIMIT_ 0xC0 // static UCA. There is only one. Collators don't use it. // It is referenced only in ucol_initUCA and ucol_cleanup static UCollator* _staticUCA = NULL; // static pointer to udata memory. Inited in ucol_initUCA // used for cleanup in ucol_cleanup static UDataMemory* UCA_DATA_MEM = NULL; U_CDECL_BEGIN static UBool U_CALLCONV isAcceptableUCA(void * /*context*/, const char * /*type*/, const char * /*name*/, const UDataInfo *pInfo){ /* context, type & name are intentionally not used */ if( pInfo->size>=20 && pInfo->isBigEndian==U_IS_BIG_ENDIAN && pInfo->charsetFamily==U_CHARSET_FAMILY && pInfo->dataFormat[0]==ucaDataInfo.dataFormat[0] && /* dataFormat="UCol" */ pInfo->dataFormat[1]==ucaDataInfo.dataFormat[1] && pInfo->dataFormat[2]==ucaDataInfo.dataFormat[2] && pInfo->dataFormat[3]==ucaDataInfo.dataFormat[3] && pInfo->formatVersion[0]==ucaDataInfo.formatVersion[0] && pInfo->formatVersion[1]>=ucaDataInfo.formatVersion[1]// && //pInfo->formatVersion[1]==ucaDataInfo.formatVersion[1] && //pInfo->formatVersion[2]==ucaDataInfo.formatVersion[2] && // Too harsh //pInfo->formatVersion[3]==ucaDataInfo.formatVersion[3] && // Too harsh ) { UVersionInfo UCDVersion; u_getUnicodeVersion(UCDVersion); if(pInfo->dataVersion[0]==UCDVersion[0] && pInfo->dataVersion[1]==UCDVersion[1]) { // && //pInfo->dataVersion[2]==ucaDataInfo.dataVersion[2] && //pInfo->dataVersion[3]==ucaDataInfo.dataVersion[3]) { return TRUE; } else { return FALSE; } } else { return FALSE; } } static int32_t U_CALLCONV _getFoldingOffset(uint32_t data) { return (int32_t)(data&0xFFFFFF); } U_CDECL_END static inline void IInit_collIterate(const UCollator *collator, const UChar *sourceString, int32_t sourceLen, collIterate *s) { (s)->string = (s)->pos = (UChar *)(sourceString); (s)->origFlags = 0; (s)->flags = 0; if (sourceLen >= 0) { s->flags |= UCOL_ITER_HASLEN; (s)->endp = (UChar *)sourceString+sourceLen; } else { /* change to enable easier checking for end of string for fcdpositon */ (s)->endp = NULL; } (s)->CEpos = (s)->toReturn = (s)->CEs; (s)->writableBuffer = (s)->stackWritableBuffer; (s)->writableBufSize = UCOL_WRITABLE_BUFFER_SIZE; (s)->coll = (collator); (s)->fcdPosition = 0; if(collator->normalizationMode == UCOL_ON) { (s)->flags |= UCOL_ITER_NORM; } if(collator->hiraganaQ == UCOL_ON && collator->strength >= UCOL_QUATERNARY) { (s)->flags |= UCOL_HIRAGANA_Q; } (s)->iterator = NULL; //(s)->iteratorIndex = 0; } U_CAPI void U_EXPORT2 uprv_init_collIterate(const UCollator *collator, const UChar *sourceString, int32_t sourceLen, collIterate *s){ /* Out-of-line version for use from other files. */ IInit_collIterate(collator, sourceString, sourceLen, s); } /** * Backup the state of the collIterate struct data * @param data collIterate to backup * @param backup storage */ static inline void backupState(const collIterate *data, collIterateState *backup) { backup->fcdPosition = data->fcdPosition; backup->flags = data->flags; backup->origFlags = data->origFlags; backup->pos = data->pos; backup->bufferaddress = data->writableBuffer; backup->buffersize = data->writableBufSize; if(data->iterator != NULL) { //backup->iteratorIndex = data->iterator->getIndex(data->iterator, UITER_CURRENT); backup->iteratorIndex = data->iterator->getState(data->iterator); // no we try to fixup if we're using a normalizing iterator and we get UITER_NO_STATE backup->iteratorMove = 0; if(backup->iteratorIndex == UITER_NO_STATE) { while((backup->iteratorIndex = data->iterator->getState(data->iterator)) == UITER_NO_STATE) { backup->iteratorMove++; data->iterator->move(data->iterator, -1, UITER_CURRENT); } data->iterator->move(data->iterator, backup->iteratorMove, UITER_CURRENT); } } } /** * Loads the state into the collIterate struct data * @param data collIterate to backup * @param backup storage * @param forwards boolean to indicate if forwards iteration is used, * false indicates backwards iteration */ static inline void loadState(collIterate *data, const collIterateState *backup, UBool forwards) { UErrorCode status = U_ZERO_ERROR; data->flags = backup->flags; data->origFlags = backup->origFlags; if(data->iterator != NULL) { //data->iterator->move(data->iterator, backup->iteratorIndex, UITER_ZERO); data->iterator->setState(data->iterator, backup->iteratorIndex, &status); if(backup->iteratorMove != 0) { data->iterator->move(data->iterator, backup->iteratorMove, UITER_CURRENT); } } data->pos = backup->pos; if ((data->flags & UCOL_ITER_INNORMBUF) && data->writableBuffer != backup->bufferaddress) { /* this is when a new buffer has been reallocated and we'll have to calculate the new position. note the new buffer has to contain the contents of the old buffer. */ if (forwards) { data->pos = data->writableBuffer + (data->pos - backup->bufferaddress); } else { /* backwards direction */ uint32_t temp = backup->buffersize - (data->pos - backup->bufferaddress); data->pos = data->writableBuffer + (data->writableBufSize - temp); } } if ((data->flags & UCOL_ITER_INNORMBUF) == 0) { /* this is alittle tricky. if we are initially not in the normalization buffer, even if we normalize in the later stage, the data in the buffer will be ignored, since we skip back up to the data string. however if we are already in the normalization buffer, any further normalization will pull data into the normalization buffer and modify the fcdPosition. since we are keeping the data in the buffer for use, the fcdPosition can not be reverted back. arrgghh.... */ data->fcdPosition = backup->fcdPosition; } } /* * collIter_eos() * Checks for a collIterate being positioned at the end of * its source string. * */ static inline UBool collIter_eos(collIterate *s) { if(s->flags & UCOL_USE_ITERATOR) { return !(s->iterator->hasNext(s->iterator)); } if ((s->flags & UCOL_ITER_HASLEN) == 0 && *s->pos != 0) { // Null terminated string, but not at null, so not at end. // Whether in main or normalization buffer doesn't matter. return FALSE; } // String with length. Can't be in normalization buffer, which is always // null termintated. if (s->flags & UCOL_ITER_HASLEN) { return (s->pos == s->endp); } // We are at a null termination, could be either normalization buffer or main string. if ((s->flags & UCOL_ITER_INNORMBUF) == 0) { // At null at end of main string. return TRUE; } // At null at end of normalization buffer. Need to check whether there there are // any characters left in the main buffer. if(s->origFlags & UCOL_USE_ITERATOR) { return !(s->iterator->hasNext(s->iterator)); } else if ((s->origFlags & UCOL_ITER_HASLEN) == 0) { // Null terminated main string. fcdPosition is the 'return' position into main buf. return (*s->fcdPosition == 0); } else { // Main string with an end pointer. return s->fcdPosition == s->endp; } } /* * collIter_bos() * Checks for a collIterate being positioned at the start of * its source string. * */ static inline UBool collIter_bos(collIterate *source) { // if we're going backwards, we need to know whether there is more in the // iterator, even if we are in the side buffer if(source->flags & UCOL_USE_ITERATOR || source->origFlags & UCOL_USE_ITERATOR) { return !source->iterator->hasPrevious(source->iterator); } if (source->pos <= source->string || ((source->flags & UCOL_ITER_INNORMBUF) && *(source->pos - 1) == 0 && source->fcdPosition == NULL)) { return TRUE; } return FALSE; } static inline UBool collIter_SimpleBos(collIterate *source) { // if we're going backwards, we need to know whether there is more in the // iterator, even if we are in the side buffer if(source->flags & UCOL_USE_ITERATOR || source->origFlags & UCOL_USE_ITERATOR) { return !source->iterator->hasPrevious(source->iterator); } if (source->pos == source->string) { return TRUE; } return FALSE; } //return (data->pos == data->string) || /** * Checks and free writable buffer if it is not the original stack buffer * in collIterate. This function does not reassign the writable buffer. * @param data collIterate struct to determine and free the writable buffer */ static inline void freeHeapWritableBuffer(collIterate *data) { if (data->writableBuffer != data->stackWritableBuffer) { uprv_free(data->writableBuffer); } } /****************************************************************************/ /* Following are the open/close functions */ /* */ /****************************************************************************/ static UCollator* tryOpeningFromRules(UResourceBundle *collElem, UErrorCode *status) { int32_t rulesLen = 0; const UChar *rules = ures_getStringByKey(collElem, "Sequence", &rulesLen, status); return ucol_openRules(rules, rulesLen, UCOL_DEFAULT, UCOL_DEFAULT, NULL, status); } U_CAPI UCollator* ucol_open(const char *loc, UErrorCode *status) { UTRACE_ENTRY_OC(UTRACE_UCOL_OPEN); UTRACE_DATA1(UTRACE_INFO, "locale = \"%s\"", loc); UCollator *result = NULL; u_init(status); result = Collator::createUCollator(loc, status); if (result == NULL) { result = ucol_open_internal(loc, status); } UTRACE_EXIT_PTR_STATUS(result, *status); return result; } // API in ucol_imp.h U_CFUNC UCollator* ucol_open_internal(const char *loc, UErrorCode *status) { const UCollator* UCA = ucol_initUCA(status); /* New version */ if(U_FAILURE(*status)) return 0; UCollator *result = NULL; UResourceBundle *b = ures_open(NULL, loc, status); /* we try to find stuff from keyword */ UResourceBundle *collations = ures_getByKey(b, "collations", NULL, status); UResourceBundle *collElem = NULL; char keyBuffer[256]; // if there is a keyword, we pick it up and try to get elements if(!uloc_getKeywordValue(loc, "collation", keyBuffer, 256, status)) { // no keyword. we try to find the default setting, which will give us the keyword value UResourceBundle *defaultColl = ures_getByKeyWithFallback(collations, "default", NULL, status); if(U_SUCCESS(*status)) { int32_t defaultKeyLen = 0; const UChar *defaultKey = ures_getString(defaultColl, &defaultKeyLen, status); u_UCharsToChars(defaultKey, keyBuffer, defaultKeyLen); keyBuffer[defaultKeyLen] = 0; } else { *status = U_INTERNAL_PROGRAM_ERROR; return NULL; } ures_close(defaultColl); } collElem = ures_getByKeyWithFallback(collations, keyBuffer, collElem, status); UResourceBundle *binary = NULL; UErrorCode binaryStatus = U_ZERO_ERROR; if(*status == U_MISSING_RESOURCE_ERROR) { /* We didn't find the tailoring data, we fallback to the UCA */ *status = U_USING_DEFAULT_WARNING; result = ucol_initCollator(UCA->image, result, UCA, status); // if we use UCA, real locale is root result->rb = ures_open(NULL, "", status); result->elements = ures_open(NULL, "", status); if(U_FAILURE(*status)) { goto clean; } ures_close(b); result->hasRealData = FALSE; } else if(U_SUCCESS(*status)) { binary = ures_getByKey(collElem, "%%CollationBin", NULL, &binaryStatus); if(binaryStatus == U_MISSING_RESOURCE_ERROR) { /* we didn't find the binary image, we should use the rules */ binary = NULL; result = tryOpeningFromRules(collElem, status); if(U_FAILURE(*status)) { goto clean; } } else if(U_SUCCESS(*status)) { /* otherwise, we'll pick a collation data that exists */ int32_t len = 0; const uint8_t *inData = ures_getBinary(binary, &len, status); UCATableHeader *colData = (UCATableHeader *)inData; if(uprv_memcmp(colData->UCAVersion, UCA->image->UCAVersion, sizeof(UVersionInfo)) != 0 || uprv_memcmp(colData->UCDVersion, UCA->image->UCDVersion, sizeof(UVersionInfo)) != 0 || colData->version[0] != UCOL_BUILDER_VERSION) { *status = U_DIFFERENT_UCA_VERSION; result = tryOpeningFromRules(collElem, status); } else { if(U_FAILURE(*status)){ goto clean; } if((uint32_t)len > (paddedsize(sizeof(UCATableHeader)) + paddedsize(sizeof(UColOptionSet)))) { result = ucol_initCollator((const UCATableHeader *)inData, result, UCA, status); if(U_FAILURE(*status)){ goto clean; } result->hasRealData = TRUE; } else { result = ucol_initCollator(UCA->image, result, UCA, status); ucol_setOptionsFromHeader(result, (UColOptionSet *)(inData+((const UCATableHeader *)inData)->options), status); if(U_FAILURE(*status)){ goto clean; } result->hasRealData = FALSE; } result->freeImageOnClose = FALSE; } } result->rb = b; result->elements = collElem; } else { /* There is another error, and we're just gonna clean up */ clean: ures_close(b); ures_close(collElem); ures_close(collations); ures_close(binary); return NULL; } result->validLocale = NULL; // default is to use rb info if(loc == NULL) { loc = ures_getLocale(result->rb, status); } result->requestedLocale = (char *)uprv_malloc((uprv_strlen(loc)+1)*sizeof(char)); /* test for NULL */ if (result->requestedLocale == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; ures_close(b); // ??? appears needed ures_close(collElem); ures_close(collations); ures_close(binary); // ??? appears needed return NULL; } uprv_strcpy(result->requestedLocale, loc); ures_close(binary); ures_close(collations); //??? we have to decide on that. Probably affects something :) return result; } U_CAPI void U_EXPORT2 ucol_setReqValidLocales(UCollator *coll, char *requestedLocaleToAdopt, char *validLocaleToAdopt) { if (coll) { if (coll->validLocale) { uprv_free(coll->validLocale); } coll->validLocale = validLocaleToAdopt; if (coll->requestedLocale) { // should always have uprv_free(coll->requestedLocale); } coll->requestedLocale = requestedLocaleToAdopt; } } U_CAPI void U_EXPORT2 ucol_close(UCollator *coll) { UTRACE_ENTRY_OC(UTRACE_UCOL_CLOSE); UTRACE_DATA1(UTRACE_INFO, "coll = %p", coll); if(coll != NULL) { // these are always owned by each UCollator struct, // so we always free them if(coll->validLocale != NULL) { uprv_free(coll->validLocale); } if(coll->requestedLocale != NULL) { uprv_free(coll->requestedLocale); } /* Here, it would be advisable to close: */ /* - UData for UCA (unless we stuff it in the root resb */ /* Again, do we need additional housekeeping... HMMM! */ UTRACE_DATA1(UTRACE_INFO, "coll->freeOnClose: %d", coll->freeOnClose); if(coll->freeOnClose){ /* for safeClone, if freeOnClose is FALSE, don't free the other instance data */ if(coll->freeOptionsOnClose != FALSE) { if(coll->options != NULL) { uprv_free(coll->options); } } if(coll->mapping != NULL) { /*ucmpe32_close(coll->mapping);*/ uprv_free(coll->mapping); } if(coll->rules != NULL && coll->freeRulesOnClose) { uprv_free((UChar *)coll->rules); } if(coll->rb != NULL) { /* pointing to read-only memory */ ures_close(coll->rb); } if(coll->freeImageOnClose == TRUE) { uprv_free((UCATableHeader *)coll->image); } if(coll->elements != NULL) { ures_close(coll->elements); } if(coll->latinOneCEs != NULL) { uprv_free(coll->latinOneCEs); } uprv_free(coll); } } UTRACE_EXIT(); } U_CAPI UCollator* U_EXPORT2 ucol_openRules( const UChar *rules, int32_t rulesLength, UColAttributeValue normalizationMode, UCollationStrength strength, UParseError *parseError, UErrorCode *status) { uint32_t listLen = 0; UColTokenParser src; UColAttributeValue norm; UParseError tErr; if(status == NULL || U_FAILURE(*status)){ return 0; } u_init(status); if (U_FAILURE(*status)) { return NULL; } if(rulesLength < -1 || (rules == NULL && rulesLength != 0)) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } if(rulesLength == -1) { rulesLength = u_strlen(rules); } if(parseError == NULL){ parseError = &tErr; } switch(normalizationMode) { case UCOL_OFF: case UCOL_ON: case UCOL_DEFAULT: norm = normalizationMode; break; default: *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UCollator *UCA = ucol_initUCA(status); if(U_FAILURE(*status)){ return NULL; } ucol_tok_initTokenList(&src, rules, rulesLength, UCA, status); listLen = ucol_tok_assembleTokenList(&src,parseError, status); if(U_FAILURE(*status)) { /* if status is U_ILLEGAL_ARGUMENT_ERROR, src->current points at the offending option */ /* if status is U_INVALID_FORMAT_ERROR, src->current points after the problematic part of the rules */ /* so something might be done here... or on lower level */ #ifdef UCOL_DEBUG if(*status == U_ILLEGAL_ARGUMENT_ERROR) { fprintf(stderr, "bad option starting at offset %i\n", src.current-src.source); } else { fprintf(stderr, "invalid rule just before offset %i\n", src.current-src.source); } #endif ucol_tok_closeTokenList(&src); return NULL; } UCollator *result = NULL; UCATableHeader *table = NULL; if(src.resultLen > 0 || src.removeSet != NULL) { /* we have a set of rules, let's make something of it */ /* also, if we wanted to remove some contractions, we should make a tailoring */ table = ucol_assembleTailoringTable(&src, status); if(U_SUCCESS(*status)) { // builder version table->version[0] = UCOL_BUILDER_VERSION; // no tailoring information on this level table->version[1] = table->version[2] = table->version[3] = 0; // set UCD version u_getUnicodeVersion(table->UCDVersion); // set UCA version uprv_memcpy(table->UCAVersion, UCA->image->UCAVersion, sizeof(UVersionInfo)); result = ucol_initCollator(table, 0, UCA, status); result->hasRealData = TRUE; result->freeImageOnClose = TRUE; } } else { /* no rules, but no error either */ // must be only options // We will init the collator from UCA result = ucol_initCollator(UCA->image, 0, UCA, status); // And set only the options UColOptionSet *opts = (UColOptionSet *)uprv_malloc(sizeof(UColOptionSet)); /* test for NULL */ if (opts == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; goto cleanup; } uprv_memcpy(opts, src.opts, sizeof(UColOptionSet)); ucol_setOptionsFromHeader(result, opts, status); result->freeOptionsOnClose = TRUE; result->hasRealData = FALSE; result->freeImageOnClose = FALSE; } if(U_SUCCESS(*status)) { UChar *newRules; result->dataInfo.dataVersion[0] = UCOL_BUILDER_VERSION; if(rulesLength > 0) { newRules = (UChar *)uprv_malloc((rulesLength+1)*U_SIZEOF_UCHAR); /* test for NULL */ if (newRules == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; goto cleanup; } uprv_memcpy(newRules, rules, rulesLength*U_SIZEOF_UCHAR); newRules[rulesLength]=0; result->rules = newRules; result->rulesLength = rulesLength; result->freeRulesOnClose = TRUE; } result->rb = NULL; result->elements = NULL; result->validLocale = NULL; result->requestedLocale = NULL; ucol_setAttribute(result, UCOL_STRENGTH, strength, status); ucol_setAttribute(result, UCOL_NORMALIZATION_MODE, norm, status); } else { cleanup: if(result != NULL) { ucol_close(result); } else { if(table != NULL) { uprv_free(table); } } result = NULL; } ucol_tok_closeTokenList(&src); return result; } /* This one is currently used by genrb & tests. After constructing from rules (tailoring),*/ /* you should be able to get the binary chunk to write out... Doesn't look very full now */ U_CAPI uint8_t* U_EXPORT2 ucol_cloneRuleData(const UCollator *coll, int32_t *length, UErrorCode *status) { uint8_t *result = NULL; if(U_FAILURE(*status)) { return NULL; } if(coll->hasRealData == TRUE) { *length = coll->image->size; result = (uint8_t *)uprv_malloc(*length); /* test for NULL */ if (result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } uprv_memcpy(result, coll->image, *length); } else { *length = (int32_t)(paddedsize(sizeof(UCATableHeader))+paddedsize(sizeof(UColOptionSet))); result = (uint8_t *)uprv_malloc(*length); /* test for NULL */ if (result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } /* build the UCATableHeader with minimal entries */ /* do not copy the header from the UCA file because its values are wrong! */ /* uprv_memcpy(result, UCA->image, sizeof(UCATableHeader)); */ /* reset everything */ uprv_memset(result, 0, *length); /* set the tailoring-specific values */ UCATableHeader *myData = (UCATableHeader *)result; myData->size = *length; /* offset for the options, the only part of the data that is present after the header */ myData->options = sizeof(UCATableHeader); /* need to always set the expansion value for an upper bound of the options */ myData->expansion = myData->options + sizeof(UColOptionSet); myData->magic = UCOL_HEADER_MAGIC; myData->isBigEndian = U_IS_BIG_ENDIAN; myData->charSetFamily = U_CHARSET_FAMILY; /* copy UCA's version; genrb will override all but the builder version with tailoring data */ uprv_memcpy(myData->version, coll->image->version, sizeof(UVersionInfo)); uprv_memcpy(myData->UCAVersion, coll->image->UCAVersion, sizeof(UVersionInfo)); uprv_memcpy(myData->UCDVersion, coll->image->UCDVersion, sizeof(UVersionInfo)); uprv_memcpy(myData->formatVersion, coll->image->formatVersion, sizeof(UVersionInfo)); myData->jamoSpecial = coll->image->jamoSpecial; /* copy the collator options */ uprv_memcpy(result+paddedsize(sizeof(UCATableHeader)), coll->options, sizeof(UColOptionSet)); } return result; } void ucol_setOptionsFromHeader(UCollator* result, UColOptionSet * opts, UErrorCode *status) { if(U_FAILURE(*status)) { return; } result->caseFirst = (UColAttributeValue)opts->caseFirst; result->caseLevel = (UColAttributeValue)opts->caseLevel; result->frenchCollation = (UColAttributeValue)opts->frenchCollation; result->normalizationMode = (UColAttributeValue)opts->normalizationMode; result->strength = (UColAttributeValue)opts->strength; result->variableTopValue = opts->variableTopValue; result->alternateHandling = (UColAttributeValue)opts->alternateHandling; result->hiraganaQ = (UColAttributeValue)opts->hiraganaQ; result->numericCollation = (UColAttributeValue)opts->numericCollation; result->caseFirstisDefault = TRUE; result->caseLevelisDefault = TRUE; result->frenchCollationisDefault = TRUE; result->normalizationModeisDefault = TRUE; result->strengthisDefault = TRUE; result->variableTopValueisDefault = TRUE; result->hiraganaQisDefault = TRUE; result->numericCollationisDefault = TRUE; ucol_updateInternalState(result, status); result->options = opts; } #if 0 // doesn't look like anybody is using this void ucol_putOptionsToHeader(UCollator* result, UColOptionSet * opts, UErrorCode *status) { if(U_FAILURE(*status)) { return; } opts->caseFirst = result->caseFirst; opts->caseLevel = result->caseLevel; opts->frenchCollation = result->frenchCollation; opts->normalizationMode = result->normalizationMode; opts->strength = result->strength; opts->variableTopValue = result->variableTopValue; opts->alternateHandling = result->alternateHandling; opts->hiraganaQ = result->hiraganaQ; opts->numericCollation = result->numericCollation; } #endif static const uint16_t *fcdTrieIndex=NULL; /** * Approximate determination if a character is at a contraction end. * Guaranteed to be TRUE if a character is at the end of a contraction, * otherwise it is not deterministic. * @param c character to be determined * @param coll collator */ static inline UBool ucol_contractionEndCP(UChar c, const UCollator *coll) { if (UTF_IS_TRAIL(c)) { return TRUE; } if (c < coll->minContrEndCP) { return FALSE; } int32_t hash = c; uint8_t htbyte; if (hash >= UCOL_UNSAFECP_TABLE_SIZE*8) { hash = (hash & UCOL_UNSAFECP_TABLE_MASK) + 256; } htbyte = coll->contrEndCP[hash>>3]; return (((htbyte >> (hash & 7)) & 1) == 1); } /* * i_getCombiningClass() * A fast, at least partly inline version of u_getCombiningClass() * This is a candidate for further optimization. Used heavily * in contraction processing. */ static inline uint8_t i_getCombiningClass(UChar c, const UCollator *coll) { uint8_t sCC = 0; if (c >= 0x300 && ucol_unsafeCP(c, coll)) { sCC = u_getCombiningClass(c); } return sCC; } UCollator* ucol_initCollator(const UCATableHeader *image, UCollator *fillIn, const UCollator *UCA, UErrorCode *status) { UChar c; UCollator *result = fillIn; if(U_FAILURE(*status) || image == NULL) { return NULL; } if(result == NULL) { result = (UCollator *)uprv_malloc(sizeof(UCollator)); if(result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return result; } result->freeOnClose = TRUE; } else { result->freeOnClose = FALSE; } result->image = image; const uint8_t *mapping = (uint8_t*)result->image+result->image->mappingPosition; /*CompactEIntArray *newUCAmapping = ucmpe32_openFromData(&mapping, status);*/ UTrie *newUCAmapping = (UTrie *)uprv_malloc(sizeof(UTrie)); if(newUCAmapping != NULL) { utrie_unserialize(newUCAmapping, mapping, result->image->endExpansionCE - result->image->mappingPosition, status); } else { *status = U_MEMORY_ALLOCATION_ERROR; if(result->freeOnClose == TRUE) { uprv_free(result); result = NULL; } return result; } if(U_SUCCESS(*status)) { result->mapping = newUCAmapping; } else { if(result->freeOnClose == TRUE) { uprv_free(result); result = NULL; } uprv_free(newUCAmapping); return result; } /*result->latinOneMapping = (uint32_t*)((uint8_t*)result->image+result->image->latinOneMapping);*/ result->latinOneMapping = UTRIE_GET32_LATIN1(result->mapping); result->contractionCEs = (uint32_t*)((uint8_t*)result->image+result->image->contractionCEs); result->contractionIndex = (UChar*)((uint8_t*)result->image+result->image->contractionIndex); result->expansion = (uint32_t*)((uint8_t*)result->image+result->image->expansion); result->options = (UColOptionSet*)((uint8_t*)result->image+result->image->options); result->freeOptionsOnClose = FALSE; /* set attributes */ result->caseFirst = (UColAttributeValue)result->options->caseFirst; result->caseLevel = (UColAttributeValue)result->options->caseLevel; result->frenchCollation = (UColAttributeValue)result->options->frenchCollation; result->normalizationMode = (UColAttributeValue)result->options->normalizationMode; result->strength = (UColAttributeValue)result->options->strength; result->variableTopValue = result->options->variableTopValue; result->alternateHandling = (UColAttributeValue)result->options->alternateHandling; result->hiraganaQ = (UColAttributeValue)result->options->hiraganaQ; result->numericCollation = (UColAttributeValue)result->options->numericCollation; result->caseFirstisDefault = TRUE; result->caseLevelisDefault = TRUE; result->frenchCollationisDefault = TRUE; result->normalizationModeisDefault = TRUE; result->strengthisDefault = TRUE; result->variableTopValueisDefault = TRUE; result->alternateHandlingisDefault = TRUE; result->hiraganaQisDefault = TRUE; result->numericCollationisDefault = TRUE; result->scriptOrder = NULL; result->rules = NULL; result->rulesLength = 0; /* get the version info from UCATableHeader and populate the Collator struct*/ result->dataInfo.dataVersion[0] = result->image->version[0]; /* UCA Builder version*/ result->dataInfo.dataVersion[1] = result->image->version[1]; /* UCA Tailoring rules version*/ result->unsafeCP = (uint8_t *)result->image + result->image->unsafeCP; result->minUnsafeCP = 0; for (c=0; c<0x300; c++) { // Find the smallest unsafe char. if (ucol_unsafeCP(c, result)) break; } result->minUnsafeCP = c; result->contrEndCP = (uint8_t *)result->image + result->image->contrEndCP; result->minContrEndCP = 0; for (c=0; c<0x300; c++) { // Find the Contraction-ending char. if (ucol_contractionEndCP(c, result)) break; } result->minContrEndCP = c; /* max expansion tables */ result->endExpansionCE = (uint32_t*)((uint8_t*)result->image + result->image->endExpansionCE); result->lastEndExpansionCE = result->endExpansionCE + result->image->endExpansionCECount - 1; result->expansionCESize = (uint8_t*)result->image + result->image->expansionCESize; if (fcdTrieIndex == NULL) { fcdTrieIndex = unorm_getFCDTrie(status); } //result->errorCode = *status; result->latinOneCEs = NULL; result->latinOneRegenTable = FALSE; result->latinOneFailed = FALSE; result->UCA = UCA; ucol_updateInternalState(result, status); return result; } U_CFUNC UBool ucol_cleanup(void) { if (UCA_DATA_MEM) { udata_close(UCA_DATA_MEM); UCA_DATA_MEM = NULL; } if (_staticUCA) { ucol_close(_staticUCA); _staticUCA = NULL; } return TRUE; } /* new Mark's code */ /** * For generation of Implicit CEs * @author Davis * * Cleaned up so that changes can be made more easily. * Old values: # First Implicit: E26A792D # Last Implicit: E3DC70C0 # First CJK: E0030300 # Last CJK: E0A9DD00 # First CJK_A: E0A9DF00 # Last CJK_A: E0DE3100 */ /* Following is a port of Mark's code for new treatment of implicits. * It is positioned here, since ucol_initUCA need to initialize the * variables below according to the data in the fractional UCA. */ /** * Function used to: * a) collapse the 2 different Han ranges from UCA into one (in the right order), and * b) bump any non-CJK characters by 10FFFF. * The relevant blocks are: * A: 4E00..9FFF; CJK Unified Ideographs * F900..FAFF; CJK Compatibility Ideographs * B: 3400..4DBF; CJK Unified Ideographs Extension A * 20000..XX; CJK Unified Ideographs Extension B (and others later on) * As long as * no new B characters are allocated between 4E00 and FAFF, and * no new A characters are outside of this range, * (very high probability) this simple code will work. * The reordered blocks are: * Block1 is CJK * Block2 is CJK_COMPAT_USED * Block3 is CJK_A * (all contiguous) * Any other CJK gets its normal code point * Any non-CJK gets +10FFFF * When we reorder Block1, we make sure that it is at the very start, * so that it will use a 3-byte form. * Warning: the we only pick up the compatibility characters that are * NOT decomposed, so that block is smaller! */ // CONSTANTS static const UChar32 NON_CJK_OFFSET = 0x110000, UCOL_MAX_INPUT = 0x220001; // 2 * Unicode range + 2 /** * Precomputed by constructor */ static int32_t final3Multiplier = 0, final4Multiplier = 0, final3Count = 0, final4Count = 0, medialCount = 0, min3Primary = 0, min4Primary = 0, max4Primary = 0, minTrail = 0, maxTrail = 0, max3Trail = 0, max4Trail = 0, min4Boundary = 0; static const UChar32 CJK_BASE = 0x4E00, CJK_LIMIT = 0x9FFF+1, CJK_COMPAT_USED_BASE = 0xFA0E, CJK_COMPAT_USED_LIMIT = 0xFA2F+1, CJK_A_BASE = 0x3400, CJK_A_LIMIT = 0x4DBF+1, CJK_B_BASE = 0x20000, CJK_B_LIMIT = 0x2A6DF+1; static UChar32 swapCJK(UChar32 i) { if (i >= CJK_BASE) { if (i < CJK_LIMIT) return i - CJK_BASE; if (i < CJK_COMPAT_USED_BASE) return i + NON_CJK_OFFSET; if (i < CJK_COMPAT_USED_LIMIT) return i - CJK_COMPAT_USED_BASE + (CJK_LIMIT - CJK_BASE); if (i < CJK_B_BASE) return i + NON_CJK_OFFSET; if (i < CJK_B_LIMIT) return i; // non-BMP-CJK return i + NON_CJK_OFFSET; // non-CJK } if (i < CJK_A_BASE) return i + NON_CJK_OFFSET; if (i < CJK_A_LIMIT) return i - CJK_A_BASE + (CJK_LIMIT - CJK_BASE) + (CJK_COMPAT_USED_LIMIT - CJK_COMPAT_USED_BASE); return i + NON_CJK_OFFSET; // non-CJK } U_CAPI UChar32 U_EXPORT2 uprv_uca_getRawFromCodePoint(UChar32 i) { return swapCJK(i)+1; } U_CAPI UChar32 U_EXPORT2 uprv_uca_getCodePointFromRaw(UChar32 i) { i--; UChar32 result = 0; if(i >= NON_CJK_OFFSET) { result = i - NON_CJK_OFFSET; } else if(i >= CJK_B_BASE) { result = i; } else if(i < CJK_A_LIMIT + (CJK_LIMIT - CJK_BASE) + (CJK_COMPAT_USED_LIMIT - CJK_COMPAT_USED_BASE)) { // rest of CJKs, compacted if(i < CJK_LIMIT - CJK_BASE) { result = i + CJK_BASE; } else if(i < (CJK_LIMIT - CJK_BASE) + (CJK_COMPAT_USED_LIMIT - CJK_COMPAT_USED_BASE)) { result = i + CJK_COMPAT_USED_BASE - (CJK_LIMIT - CJK_BASE); } else { result = i + CJK_A_BASE - (CJK_LIMIT - CJK_BASE) - (CJK_COMPAT_USED_LIMIT - CJK_COMPAT_USED_BASE); } } else { result = -1; } return result; } // GET IMPLICIT PRIMARY WEIGHTS // Return value is left justified primary key U_CAPI uint32_t U_EXPORT2 uprv_uca_getImplicitFromRaw(UChar32 cp) { /* if (cp < 0 || cp > UCOL_MAX_INPUT) { throw new IllegalArgumentException("Code point out of range " + Utility.hex(cp)); } */ int32_t last0 = cp - min4Boundary; if (last0 < 0) { int32_t last1 = cp / final3Count; last0 = cp % final3Count; int32_t last2 = last1 / medialCount; last1 %= medialCount; last0 = minTrail + last0*final3Multiplier; // spread out, leaving gap at start last1 = minTrail + last1; // offset last2 = min3Primary + last2; // offset /* if (last2 >= min4Primary) { throw new IllegalArgumentException("4-byte out of range: " + Utility.hex(cp) + ", " + Utility.hex(last2)); } */ return (last2 << 24) + (last1 << 16) + (last0 << 8); } else { int32_t last1 = last0 / final4Count; last0 %= final4Count; int32_t last2 = last1 / medialCount; last1 %= medialCount; int32_t last3 = last2 / medialCount; last2 %= medialCount; last0 = minTrail + last0*final4Multiplier; // spread out, leaving gap at start last1 = minTrail + last1; // offset last2 = minTrail + last2; // offset last3 = min4Primary + last3; // offset /* if (last3 > max4Primary) { throw new IllegalArgumentException("4-byte out of range: " + Utility.hex(cp) + ", " + Utility.hex(last3)); } */ return (last3 << 24) + (last2 << 16) + (last1 << 8) + last0; } } U_CAPI uint32_t U_EXPORT2 uprv_uca_getImplicitPrimary(UChar32 cp) { //if (DEBUG) System.out.println("Incoming: " + Utility.hex(cp)); cp = swapCJK(cp); cp++; // we now have a range of numbers from 0 to 21FFFF. //if (DEBUG) System.out.println("CJK swapped: " + Utility.hex(cp)); return uprv_uca_getImplicitFromRaw(cp); } /** * Converts implicit CE into raw integer ("code point") * @param implicit * @return -1 if illegal format */ U_CAPI UChar32 U_EXPORT2 uprv_uca_getRawFromImplicit(uint32_t implicit) { UChar32 result; UChar32 b3 = implicit & 0xFF; implicit >>= 8; UChar32 b2 = implicit & 0xFF; implicit >>= 8; UChar32 b1 = implicit & 0xFF; implicit >>= 8; UChar32 b0 = implicit & 0xFF; // simple parameter checks if (b0 < min3Primary || b0 > max4Primary || b1 < minTrail || b1 > maxTrail) return -1; // normal offsets b1 -= minTrail; // take care of the final values, and compose if (b0 < min4Primary) { if (b2 < minTrail || b2 > max3Trail || b3 != 0) return -1; b2 -= minTrail; UChar32 remainder = b2 % final3Multiplier; if (remainder != 0) return -1; b0 -= min3Primary; b2 /= final3Multiplier; result = ((b0 * medialCount) + b1) * final3Count + b2; } else { if (b2 < minTrail || b2 > maxTrail || b3 < minTrail || b3 > max4Trail) return -1; b2 -= minTrail; b3 -= minTrail; UChar32 remainder = b3 % final4Multiplier; if (remainder != 0) return -1; b3 /= final4Multiplier; b0 -= min4Primary; result = (((b0 * medialCount) + b1) * medialCount + b2) * final4Count + b3 + min4Boundary; } // final check if (result < 0 || result > UCOL_MAX_INPUT) return -1; return result; } static inline int32_t divideAndRoundUp(int a, int b) { return 1 + (a-1)/b; } /* this function is either called from initUCA or from genUCA before * doing canonical closure for the UCA. */ /** * Set up to generate implicits. * @param minPrimary * @param maxPrimary * @param minTrail final byte * @param maxTrail final byte * @param gap3 the gap we leave for tailoring for 3-byte forms * @param gap4 the gap we leave for tailoring for 4-byte forms */ static void initImplicitConstants(int minPrimary, int maxPrimary, int minTrailIn, int maxTrailIn, int gap3, int primaries3count, UErrorCode *status) { // some simple parameter checks if (minPrimary < 0 || minPrimary >= maxPrimary || maxPrimary > 0xFF) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; }; if (minTrail < 0 || minTrailIn >= maxTrailIn || maxTrailIn > 0xFF) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; }; if (primaries3count < 1) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; }; minTrail = minTrailIn; maxTrail = maxTrailIn; min3Primary = minPrimary; max4Primary = maxPrimary; // compute constants for use later. // number of values we can use in trailing bytes // leave room for empty values between AND above, e.g. if gap = 2 // range 3..7 => +3 -4 -5 -6 -7: so 1 value // range 3..8 => +3 -4 -5 +6 -7 -8: so 2 values // range 3..9 => +3 -4 -5 +6 -7 -8 -9: so 2 values final3Multiplier = gap3 + 1; final3Count = (maxTrail - minTrail + 1) / final3Multiplier; max3Trail = minTrail + (final3Count - 1) * final3Multiplier; // medials can use full range medialCount = (maxTrail - minTrail + 1); // find out how many values fit in each form int32_t threeByteCount = medialCount * final3Count; // now determine where the 3/4 boundary is. // we use 3 bytes below the boundary, and 4 above int32_t primariesAvailable = maxPrimary - minPrimary + 1; int32_t primaries4count = primariesAvailable - primaries3count; int32_t min3ByteCoverage = primaries3count * threeByteCount; min4Primary = minPrimary + primaries3count; min4Boundary = min3ByteCoverage; // Now expand out the multiplier for the 4 bytes, and redo. int32_t totalNeeded = UCOL_MAX_INPUT - min4Boundary; int32_t neededPerPrimaryByte = divideAndRoundUp(totalNeeded, primaries4count); //if (DEBUG) System.out.println("neededPerPrimaryByte: " + neededPerPrimaryByte); int32_t neededPerFinalByte = divideAndRoundUp(neededPerPrimaryByte, medialCount * medialCount); //if (DEBUG) System.out.println("neededPerFinalByte: " + neededPerFinalByte); int32_t gap4 = (maxTrail - minTrail - 1) / neededPerFinalByte; //if (DEBUG) System.out.println("expandedGap: " + gap4); if (gap4 < 1) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } final4Multiplier = gap4 + 1; final4Count = neededPerFinalByte; max4Trail = minTrail + (final4Count - 1) * final4Multiplier; /* if (DEBUG) { System.out.println("final4Count: " + final4Count); for (int counter = 0; counter <= final4Count; ++counter) { int value = minTrail + (1 + counter)*final4Multiplier; System.out.println(counter + "\t" + value + "\t" + Utility.hex(value)); } } */ } /** * Supply parameters for generating implicit CEs */ U_CAPI void U_EXPORT2 uprv_uca_initImplicitConstants(int32_t minPrimary, int32_t maxPrimary, UErrorCode *status) { // 13 is the largest 4-byte gap we can use without getting 2 four-byte forms. initImplicitConstants(minPrimary, maxPrimary, 0x03, 0xFE, 1, 1, status); } /* do not close UCA returned by ucol_initUCA! */ UCollator * ucol_initUCA(UErrorCode *status) { if(U_FAILURE(*status)) { return NULL; } umtx_lock(NULL); UBool f = (_staticUCA == NULL); umtx_unlock(NULL); if(f) { UCollator *newUCA = NULL; UDataMemory *result = udata_openChoice(NULL, UCA_DATA_TYPE, UCA_DATA_NAME, isAcceptableUCA, NULL, status); if(U_FAILURE(*status)) { if (result) { udata_close(result); } uprv_free(newUCA); } if(result != NULL) { /* It looks like sometimes we can fail to find the data file */ newUCA = ucol_initCollator((const UCATableHeader *)udata_getMemory(result), newUCA, newUCA, status); if(U_SUCCESS(*status)){ newUCA->rb = NULL; newUCA->elements = NULL; newUCA->validLocale = NULL; newUCA->requestedLocale = NULL; newUCA->hasRealData = FALSE; // real data lives in .dat file... newUCA->freeImageOnClose = FALSE; umtx_lock(NULL); if(_staticUCA == NULL) { _staticUCA = newUCA; UCA_DATA_MEM = result; result = NULL; newUCA = NULL; } umtx_unlock(NULL); if(newUCA != NULL) { udata_close(result); uprv_free(newUCA); } else { ucln_i18n_registerCleanup(); } // Initalize variables for implicit generation const UCAConstants *UCAconsts = (UCAConstants *)((uint8_t *)_staticUCA->image + _staticUCA->image->UCAConsts); uprv_uca_initImplicitConstants(UCAconsts->UCA_PRIMARY_IMPLICIT_MIN, UCAconsts->UCA_PRIMARY_IMPLICIT_MAX, status); _staticUCA->mapping->getFoldingOffset = _getFoldingOffset; }else{ udata_close(result); uprv_free(newUCA); _staticUCA= NULL; } } } return _staticUCA; } /* collIterNormalize Incremental Normalization happens here. */ /* pick up the range of chars identifed by FCD, */ /* normalize it into the collIterate's writable buffer, */ /* switch the collIterate's state to use the writable buffer. */ /* */ static void collIterNormalize(collIterate *collationSource) { UErrorCode status = U_ZERO_ERROR; int32_t normLen; UChar *srcP = collationSource->pos - 1; /* Start of chars to normalize */ UChar *endP = collationSource->fcdPosition; /* End of region to normalize+1 */ normLen = unorm_decompose(collationSource->writableBuffer, (int32_t)collationSource->writableBufSize, srcP, (int32_t)(endP - srcP), FALSE, 0, &status); if(status == U_BUFFER_OVERFLOW_ERROR || status == U_STRING_NOT_TERMINATED_WARNING) { // reallocate and terminate if(!u_growBufferFromStatic(collationSource->stackWritableBuffer, &collationSource->writableBuffer, (int32_t *)&collationSource->writableBufSize, normLen + 1, 0) ) { #ifdef UCOL_DEBUG fprintf(stderr, "collIterNormalize(), out of memory\n"); #endif return; } status = U_ZERO_ERROR; normLen = unorm_decompose(collationSource->writableBuffer, (int32_t)collationSource->writableBufSize, srcP, (int32_t)(endP - srcP), FALSE, 0, &status); } if (U_FAILURE(status)) { #ifdef UCOL_DEBUG fprintf(stderr, "collIterNormalize(), unorm_decompose() failed, status = %s\n", u_errorName(status)); #endif return; } if(collationSource->writableBuffer != collationSource->stackWritableBuffer) { collationSource->flags |= UCOL_ITER_ALLOCATED; } collationSource->pos = collationSource->writableBuffer; collationSource->origFlags = collationSource->flags; collationSource->flags |= UCOL_ITER_INNORMBUF; collationSource->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN | UCOL_USE_ITERATOR); } // This function takes the iterator and extracts normalized stuff up to the next boundary // It is similar in the end results to the collIterNormalize, but for the cases when we // use an iterator static inline void normalizeIterator(collIterate *collationSource) { UErrorCode status = U_ZERO_ERROR; UBool wasNormalized = FALSE; //int32_t iterIndex = collationSource->iterator->getIndex(collationSource->iterator, UITER_CURRENT); uint32_t iterIndex = collationSource->iterator->getState(collationSource->iterator); int32_t normLen = unorm_next(collationSource->iterator, collationSource->writableBuffer, (int32_t)collationSource->writableBufSize, UNORM_FCD, 0, TRUE, &wasNormalized, &status); if(status == U_BUFFER_OVERFLOW_ERROR || normLen == (int32_t)collationSource->writableBufSize) { // reallocate and terminate if(!u_growBufferFromStatic(collationSource->stackWritableBuffer, &collationSource->writableBuffer, (int32_t *)&collationSource->writableBufSize, normLen + 1, 0) ) { #ifdef UCOL_DEBUG fprintf(stderr, "normalizeIterator(), out of memory\n"); #endif return; } status = U_ZERO_ERROR; //collationSource->iterator->move(collationSource->iterator, iterIndex, UITER_ZERO); collationSource->iterator->setState(collationSource->iterator, iterIndex, &status); normLen = unorm_next(collationSource->iterator, collationSource->writableBuffer, (int32_t)collationSource->writableBufSize, UNORM_FCD, 0, TRUE, &wasNormalized, &status); } // Terminate the buffer - we already checked that it is big enough collationSource->writableBuffer[normLen] = 0; if(collationSource->writableBuffer != collationSource->stackWritableBuffer) { collationSource->flags |= UCOL_ITER_ALLOCATED; } collationSource->pos = collationSource->writableBuffer; collationSource->origFlags = collationSource->flags; collationSource->flags |= UCOL_ITER_INNORMBUF; collationSource->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN | UCOL_USE_ITERATOR); } /* Incremental FCD check and normalize */ /* Called from getNextCE when normalization state is suspect. */ /* When entering, the state is known to be this: */ /* o We are working in the main buffer of the collIterate, not the side */ /* writable buffer. When in the side buffer, normalization mode is always off, */ /* so we won't get here. */ /* o The leading combining class from the current character is 0 or */ /* the trailing combining class of the previous char was zero. */ /* True because the previous call to this function will have always exited */ /* that way, and we get called for every char where cc might be non-zero. */ static inline UBool collIterFCD(collIterate *collationSource) { UChar c, c2; const UChar *srcP, *endP; uint8_t leadingCC; uint8_t prevTrailingCC = 0; uint16_t fcd; UBool needNormalize = FALSE; srcP = collationSource->pos-1; if (collationSource->flags & UCOL_ITER_HASLEN) { endP = collationSource->endp; } else { endP = NULL; } // Get the trailing combining class of the current character. If it's zero, // we are OK. c = *srcP++; /* trie access */ fcd = unorm_getFCD16(fcdTrieIndex, c); if (fcd != 0) { if (UTF_IS_FIRST_SURROGATE(c)) { if ((endP == NULL || srcP != endP) && UTF_IS_SECOND_SURROGATE(c2=*srcP)) { ++srcP; fcd = unorm_getFCD16FromSurrogatePair(fcdTrieIndex, fcd, c2); } else { fcd = 0; } } prevTrailingCC = (uint8_t)(fcd & LAST_BYTE_MASK_); if (prevTrailingCC != 0) { // The current char has a non-zero trailing CC. Scan forward until we find // a char with a leading cc of zero. while (endP == NULL || srcP != endP) { const UChar *savedSrcP = srcP; c = *srcP++; /* trie access */ fcd = unorm_getFCD16(fcdTrieIndex, c); if (fcd != 0 && UTF_IS_FIRST_SURROGATE(c)) { if ((endP == NULL || srcP != endP) && UTF_IS_SECOND_SURROGATE(c2=*srcP)) { ++srcP; fcd = unorm_getFCD16FromSurrogatePair(fcdTrieIndex, fcd, c2); } else { fcd = 0; } } leadingCC = (uint8_t)(fcd >> SECOND_LAST_BYTE_SHIFT_); if (leadingCC == 0) { srcP = savedSrcP; // Hit char that is not part of combining sequence. // back up over it. (Could be surrogate pair!) break; } if (leadingCC < prevTrailingCC) { needNormalize = TRUE; } prevTrailingCC = (uint8_t)(fcd & LAST_BYTE_MASK_); } } } collationSource->fcdPosition = (UChar *)srcP; return needNormalize; } /****************************************************************************/ /* Following are the CE retrieval functions */ /* */ /****************************************************************************/ /* there should be a macro version of this function in the header file */ /* This is the first function that tries to fetch a collation element */ /* If it's not succesfull or it encounters a more difficult situation */ /* some more sofisticated and slower functions are invoked */ static inline uint32_t ucol_IGetNextCE(const UCollator *coll, collIterate *collationSource, UErrorCode *status) { uint32_t order = 0; if (collationSource->CEpos > collationSource->toReturn) { /* Are there any CEs from previous expansions? */ order = *(collationSource->toReturn++); /* if so, return them */ if(collationSource->CEpos == collationSource->toReturn) { collationSource->CEpos = collationSource->toReturn = collationSource->CEs; } return order; } UChar ch = 0; for (;;) /* Loop handles case when incremental normalize switches */ { /* to or from the side buffer / original string, and we */ /* need to start again to get the next character. */ if ((collationSource->flags & (UCOL_ITER_HASLEN | UCOL_ITER_INNORMBUF | UCOL_ITER_NORM | UCOL_HIRAGANA_Q | UCOL_USE_ITERATOR)) == 0) { // The source string is null terminated and we're not working from the side buffer, // and we're not normalizing. This is the fast path. // (We can be in the side buffer for Thai pre-vowel reordering even when not normalizing.) ch = *collationSource->pos++; if (ch != 0) { break; } else { return UCOL_NO_MORE_CES; } } if (collationSource->flags & UCOL_ITER_HASLEN) { // Normal path for strings when length is specified. // (We can't be in side buffer because it is always null terminated.) if (collationSource->pos >= collationSource->endp) { // Ran off of the end of the main source string. We're done. return UCOL_NO_MORE_CES; } ch = *collationSource->pos++; } else if(collationSource->flags & UCOL_USE_ITERATOR) { UChar32 iterCh = collationSource->iterator->next(collationSource->iterator); if(iterCh == U_SENTINEL) { return UCOL_NO_MORE_CES; } ch = (UChar)iterCh; } else { // Null terminated string. ch = *collationSource->pos++; if (ch == 0) { // Ran off end of buffer. if ((collationSource->flags & UCOL_ITER_INNORMBUF) == 0) { // Ran off end of main string. backing up one character. collationSource->pos--; return UCOL_NO_MORE_CES; } else { // Hit null in the normalize side buffer. // Usually this means the end of the normalized data, // except for one odd case: a null followed by combining chars, // which is the case if we are at the start of the buffer. if (collationSource->pos == collationSource->writableBuffer+1) { break; } // Null marked end of side buffer. // Revert to the main string and // loop back to top to try again to get a character. collationSource->pos = collationSource->fcdPosition; collationSource->flags = collationSource->origFlags; continue; } } } if(collationSource->flags&UCOL_HIRAGANA_Q) { if((ch>=0x3040 && ch<=0x3094) || ch == 0x309d || ch == 0x309e) { collationSource->flags |= UCOL_WAS_HIRAGANA; } else { collationSource->flags &= ~UCOL_WAS_HIRAGANA; } } // We've got a character. See if there's any fcd and/or normalization stuff to do. // Note that UCOL_ITER_NORM flag is always zero when we are in the side buffer. if ((collationSource->flags & UCOL_ITER_NORM) == 0) { break; } if (collationSource->fcdPosition >= collationSource->pos) { // An earlier FCD check has already covered the current character. // We can go ahead and process this char. break; } if (ch < ZERO_CC_LIMIT_ ) { // Fast fcd safe path. Trailing combining class == 0. This char is OK. break; } if (ch < NFC_ZERO_CC_BLOCK_LIMIT_) { // We need to peek at the next character in order to tell if we are FCD if ((collationSource->flags & UCOL_ITER_HASLEN) && collationSource->pos >= collationSource->endp) { // We are at the last char of source string. // It is always OK for FCD check. break; } // Not at last char of source string (or we'll check against terminating null). Do the FCD fast test if (*collationSource->pos < NFC_ZERO_CC_BLOCK_LIMIT_) { break; } } // Need a more complete FCD check and possible normalization. if (collIterFCD(collationSource)) { collIterNormalize(collationSource); } if ((collationSource->flags & UCOL_ITER_INNORMBUF) == 0) { // No normalization was needed. Go ahead and process the char we already had. break; } // Some normalization happened. Next loop iteration will pick up a char // from the normalization buffer. } // end for (;;) if (ch <= 0xFF) { /* For latin-1 characters we never need to fall back to the UCA table */ /* because all of the UCA data is replicated in the latinOneMapping array */ order = coll->latinOneMapping[ch]; if (order > UCOL_NOT_FOUND) { order = ucol_prv_getSpecialCE(coll, ch, order, collationSource, status); } } else { order = UTRIE_GET32_FROM_LEAD(coll->mapping, ch); if(order > UCOL_NOT_FOUND) { /* if a CE is special */ order = ucol_prv_getSpecialCE(coll, ch, order, collationSource, status); /* and try to get the special CE */ } if(order == UCOL_NOT_FOUND) { /* We couldn't find a good CE in the tailoring */ /* if we got here, the codepoint MUST be over 0xFF - so we look directly in the trie */ order = UTRIE_GET32_FROM_LEAD(coll->UCA->mapping, ch); if(order > UCOL_NOT_FOUND) { /* UCA also gives us a special CE */ order = ucol_prv_getSpecialCE(coll->UCA, ch, order, collationSource, status); } } } return order; /* return the CE */ } /* ucol_getNextCE, out-of-line version for use from other files. */ U_CAPI uint32_t U_EXPORT2 ucol_getNextCE(const UCollator *coll, collIterate *collationSource, UErrorCode *status) { return ucol_IGetNextCE(coll, collationSource, status); } /** * Incremental previous normalization happens here. Pick up the range of chars * identifed by FCD, normalize it into the collIterate's writable buffer, * switch the collIterate's state to use the writable buffer. * @param data collation iterator data */ static void collPrevIterNormalize(collIterate *data) { UErrorCode status = U_ZERO_ERROR; UChar *pEnd = data->pos; /* End normalize + 1 */ UChar *pStart; uint32_t normLen; UChar *pStartNorm; /* Start normalize */ if (data->fcdPosition == NULL) { pStart = data->string; } else { pStart = data->fcdPosition + 1; } normLen = unorm_normalize(pStart, (pEnd - pStart) + 1, UNORM_NFD, 0, data->writableBuffer, 0, &status); if (data->writableBufSize <= normLen) { freeHeapWritableBuffer(data); data->writableBuffer = (UChar *)uprv_malloc((normLen + 1) * sizeof(UChar)); if(data->writableBuffer == NULL) { // something is wrong here, return return; } data->flags |= UCOL_ITER_ALLOCATED; /* to handle the zero termination */ data->writableBufSize = normLen + 1; } status = U_ZERO_ERROR; /* this puts the null termination infront of the normalized string instead of the end */ pStartNorm = data->writableBuffer + (data->writableBufSize - normLen); *(pStartNorm - 1) = 0; unorm_normalize(pStart, (pEnd - pStart) + 1, UNORM_NFD, 0, pStartNorm, normLen, &status); data->pos = data->writableBuffer + data->writableBufSize; data->origFlags = data->flags; data->flags |= UCOL_ITER_INNORMBUF; data->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); } /** * Incremental FCD check for previous iteration and normalize. Called from * getPrevCE when normalization state is suspect. * When entering, the state is known to be this: * o We are working in the main buffer of the collIterate, not the side * writable buffer. When in the side buffer, normalization mode is always * off, so we won't get here. * o The leading combining class from the current character is 0 or the * trailing combining class of the previous char was zero. * True because the previous call to this function will have always exited * that way, and we get called for every char where cc might be non-zero. * @param data collation iterate struct * @return normalization status, TRUE for normalization to be done, FALSE * otherwise */ static inline UBool collPrevIterFCD(collIterate *data) { const UChar *src, *start; UChar c, c2; uint8_t leadingCC; uint8_t trailingCC = 0; uint16_t fcd; UBool result = FALSE; start = data->string; src = data->pos + 1; /* Get the trailing combining class of the current character. */ c = *--src; if (!UTF_IS_SURROGATE(c)) { fcd = unorm_getFCD16(fcdTrieIndex, c); } else if (UTF_IS_SECOND_SURROGATE(c) && start < src && UTF_IS_FIRST_SURROGATE(c2 = *(src - 1))) { --src; fcd = unorm_getFCD16(fcdTrieIndex, c2); if (fcd != 0) { fcd = unorm_getFCD16FromSurrogatePair(fcdTrieIndex, fcd, c); } } else /* unpaired surrogate */ { fcd = 0; } leadingCC = (uint8_t)(fcd >> SECOND_LAST_BYTE_SHIFT_); if (leadingCC != 0) { /* The current char has a non-zero leading combining class. Scan backward until we find a char with a trailing cc of zero. */ for (;;) { if (start == src) { data->fcdPosition = NULL; return result; } c = *--src; if (!UTF_IS_SURROGATE(c)) { fcd = unorm_getFCD16(fcdTrieIndex, c); } else if (UTF_IS_SECOND_SURROGATE(c) && start < src && UTF_IS_FIRST_SURROGATE(c2 = *(src - 1))) { --src; fcd = unorm_getFCD16(fcdTrieIndex, c2); if (fcd != 0) { fcd = unorm_getFCD16FromSurrogatePair(fcdTrieIndex, fcd, c); } } else /* unpaired surrogate */ { fcd = 0; } trailingCC = (uint8_t)(fcd & LAST_BYTE_MASK_); if (trailingCC == 0) { break; } if (leadingCC < trailingCC) { result = TRUE; } leadingCC = (uint8_t)(fcd >> SECOND_LAST_BYTE_SHIFT_); } } data->fcdPosition = (UChar *)src; return result; } /** gets a character from the string at a given offset * Handles both normal and iterative cases. * No error checking - caller beware! */ inline static UChar peekCharacter(collIterate *source, int32_t offset) { if(source->pos != NULL) { return *(source->pos + offset); } else if(source->iterator != NULL) { if(offset != 0) { source->iterator->move(source->iterator, offset, UITER_CURRENT); UChar toReturn = (UChar)source->iterator->next(source->iterator); source->iterator->move(source->iterator, -offset-1, UITER_CURRENT); return toReturn; } else { return (UChar)source->iterator->current(source->iterator); } } else { return (UChar)U_SENTINEL; } } /** * Determines if we are at the start of the data string in the backwards * collation iterator * @param data collation iterator * @return TRUE if we are at the start */ static inline UBool isAtStartPrevIterate(collIterate *data) { if(data->pos == NULL && data->iterator != NULL) { return !data->iterator->hasPrevious(data->iterator); } //return (collIter_bos(data)) || return (data->pos == data->string) || ((data->flags & UCOL_ITER_INNORMBUF) && *(data->pos - 1) == 0 && data->fcdPosition == NULL); } static inline void goBackOne(collIterate *data) { # if 0 // somehow, it looks like we need to keep iterator synced up // at all times, as above. if(data->pos) { data->pos--; } if(data->iterator) { data->iterator->previous(data->iterator); } #endif if(data->iterator && (data->flags & UCOL_USE_ITERATOR)) { data->iterator->previous(data->iterator); } if(data->pos) { data->pos --; } } /** * Inline function that gets a simple CE. * So what it does is that it will first check the expansion buffer. If the * expansion buffer is not empty, ie the end pointer to the expansion buffer * is different from the string pointer, we return the collation element at the * return pointer and decrement it. * For more complicated CEs it resorts to getComplicatedCE. * @param coll collator data * @param data collation iterator struct * @param status error status */ static inline uint32_t ucol_IGetPrevCE(const UCollator *coll, collIterate *data, UErrorCode *status) { uint32_t result = UCOL_NULLORDER; if (data->toReturn > data->CEs) { data->toReturn --; result = *(data->toReturn); if (data->CEs == data->toReturn) { data->CEpos = data->toReturn; } } else { UChar ch = 0; /* Loop handles case when incremental normalize switches to or from the side buffer / original string, and we need to start again to get the next character. */ for (;;) { if (data->flags & UCOL_ITER_HASLEN) { /* Normal path for strings when length is specified. Not in side buffer because it is always null terminated. */ if (data->pos <= data->string) { /* End of the main source string */ return UCOL_NO_MORE_CES; } data->pos --; ch = *data->pos; } // we are using an iterator to go back. Pray for us! else if (data->flags & UCOL_USE_ITERATOR) { UChar32 iterCh = data->iterator->previous(data->iterator); if(iterCh == U_SENTINEL) { return UCOL_NO_MORE_CES; } else { ch = (UChar)iterCh; } } else { data->pos --; ch = *data->pos; /* we are in the side buffer. */ if (ch == 0) { /* At the start of the normalize side buffer. Go back to string. Because pointer points to the last accessed character, hence we have to increment it by one here. */ if (data->fcdPosition == NULL) { data->pos = data->string; return UCOL_NO_MORE_CES; } else { data->pos = data->fcdPosition + 1; } data->flags = data->origFlags; continue; } } if(data->flags&UCOL_HIRAGANA_Q) { if(ch>=0x3040 && ch<=0x309f) { data->flags |= UCOL_WAS_HIRAGANA; } else { data->flags &= ~UCOL_WAS_HIRAGANA; } } /* * got a character to determine if there's fcd and/or normalization * stuff to do. * if the current character is not fcd. * if current character is at the start of the string * Trailing combining class == 0. * Note if pos is in the writablebuffer, norm is always 0 */ if (ch < ZERO_CC_LIMIT_ || // this should propel us out of the loop in the iterator case (data->flags & UCOL_ITER_NORM) == 0 || (data->fcdPosition != NULL && data->fcdPosition <= data->pos) || data->string == data->pos) { break; } if (ch < NFC_ZERO_CC_BLOCK_LIMIT_) { /* if next character is FCD */ if (data->pos == data->string) { /* First char of string is always OK for FCD check */ break; } /* Not first char of string, do the FCD fast test */ if (*(data->pos - 1) < NFC_ZERO_CC_BLOCK_LIMIT_) { break; } } /* Need a more complete FCD check and possible normalization. */ if (collPrevIterFCD(data)) { collPrevIterNormalize(data); } if ((data->flags & UCOL_ITER_INNORMBUF) == 0) { /* No normalization. Go ahead and process the char. */ break; } /* Some normalization happened. Next loop picks up a char from the normalization buffer. */ } /* attempt to handle contractions, after removal of the backwards contraction */ if (ucol_contractionEndCP(ch, coll) && !isAtStartPrevIterate(data)) { result = ucol_prv_getSpecialPrevCE(coll, ch, UCOL_CONTRACTION, data, status); } else { // TODO: fix me for THAI - I reference *(data->pos-1) if ((data->flags & UCOL_ITER_INNORMBUF) == 0 && /*UCOL_ISTHAIBASECONSONANT(ch) &&*/ // This is from the old specs - we now rearrange unconditionally // makes sure that we're not at the beggining of the string //data->pos > data->string && !collIter_bos(data) && UCOL_ISTHAIPREVOWEL(peekCharacter(data, -1))) //UCOL_ISTHAIPREVOWEL(*(data->pos -1))) { collIterateState entryState; backupState(data, &entryState); // we have to check if the previous character is also Thai // if not, we can just set the result goBackOne(data); if(collIter_bos(data) || !UCOL_ISTHAIPREVOWEL(peekCharacter(data, -1))) { loadState(data, &entryState, FALSE); result = UCOL_THAI; } else { // previous is also reordered // we need to go back as long as they are being reordered // count over the range of reorderable characters and see // if there is an even or odd number of them // if even, we should not reorder. If odd we should reorder. int32_t noReordered = 1; // the one we already detected while(!collIter_bos(data) && UCOL_ISTHAIPREVOWEL(peekCharacter(data, -1))) { noReordered++; goBackOne(data); } if(noReordered & 1) { // odd number of reorderables result = UCOL_THAI; } else { result = UTRIE_GET32_FROM_LEAD(coll->mapping, ch); } loadState(data, &entryState, FALSE); } } else if (ch <= 0xFF) { result = coll->latinOneMapping[ch]; if (result > UCOL_NOT_FOUND) { result = ucol_prv_getSpecialPrevCE(coll, ch, result, data, status); } } else { /*result = ucmpe32_get(coll->mapping, ch);*/ result = UTRIE_GET32_FROM_LEAD(coll->mapping, ch); } if (result > UCOL_NOT_FOUND) { result = ucol_prv_getSpecialPrevCE(coll, ch, result, data, status); } if (result == UCOL_NOT_FOUND) { if (!isAtStartPrevIterate(data) && ucol_contractionEndCP(ch, data->coll)) { result = UCOL_CONTRACTION; } else { /*result = ucmpe32_get(UCA->mapping, ch);*/ result = UTRIE_GET32_FROM_LEAD(coll->UCA->mapping, ch); } if (result > UCOL_NOT_FOUND) { result = ucol_prv_getSpecialPrevCE(coll->UCA, ch, result, data, status); } } } } return result; } /* ucol_getPrevCE, out-of-line version for use from other files. */ U_CAPI uint32_t U_EXPORT2 ucol_getPrevCE(const UCollator *coll, collIterate *data, UErrorCode *status) { return ucol_IGetPrevCE(coll, data, status); } /* this should be connected to special Jamo handling */ U_CAPI uint32_t U_EXPORT2 ucol_getFirstCE(const UCollator *coll, UChar u, UErrorCode *status) { collIterate colIt; uint32_t order; IInit_collIterate(coll, &u, 1, &colIt); order = ucol_IGetNextCE(coll, &colIt, status); /*UCOL_GETNEXTCE(order, coll, colIt, status);*/ return order; } /** * Inserts the argument character into the end of the buffer pushing back the * null terminator. * @param data collIterate struct data * @param pNull pointer to the null termination * @param ch character to be appended * @return the position of the new addition */ static inline UChar * insertBufferEnd(collIterate *data, UChar *pNull, UChar ch) { uint32_t size = data->writableBufSize; UChar *newbuffer; const uint32_t incsize = 5; if ((data->writableBuffer + size) > (pNull + 1)) { *pNull = ch; *(pNull + 1) = 0; return pNull; } /* buffer will always be null terminated at the end. giving extra space since it is likely that more characters will be added. */ size += incsize; newbuffer = (UChar *)uprv_malloc(sizeof(UChar) * size); if(newbuffer != NULL) { // something wrong, but no status uprv_memcpy(newbuffer, data->writableBuffer, data->writableBufSize * sizeof(UChar)); freeHeapWritableBuffer(data); data->writableBufSize = size; data->writableBuffer = newbuffer; newbuffer = newbuffer + data->writableBufSize; *newbuffer = ch; *(newbuffer + 1) = 0; } return newbuffer; } /** * Inserts the argument string into the end of the buffer pushing back the * null terminator. * @param data collIterate struct data * @param pNull pointer to the null termination * @param string to be appended * @param length of the string to be appended * @return the position of the new addition */ static inline UChar * insertBufferEnd(collIterate *data, UChar *pNull, UChar *str, int32_t length) { uint32_t size = pNull - data->writableBuffer; UChar *newbuffer; if (data->writableBuffer + data->writableBufSize > pNull + length + 1) { uprv_memcpy(pNull, str, length * sizeof(UChar)); *(pNull + length) = 0; return pNull; } /* buffer will always be null terminated at the end. giving extra space since it is likely that more characters will be added. */ newbuffer = (UChar *)uprv_malloc(sizeof(UChar) * (size + length + 1)); if(newbuffer != NULL) { uprv_memcpy(newbuffer, data->writableBuffer, size * sizeof(UChar)); uprv_memcpy(newbuffer + size, str, length * sizeof(UChar)); freeHeapWritableBuffer(data); data->writableBufSize = size + length + 1; data->writableBuffer = newbuffer; } return newbuffer; } /** * Special normalization function for contraction in the forwards iterator. * This normalization sequence will place the current character at source->pos * and its following normalized sequence into the buffer. * The fcd position, pos will be changed. * pos will now point to positions in the buffer. * Flags will be changed accordingly. * @param data collation iterator data */ static inline void normalizeNextContraction(collIterate *data) { UChar *buffer = data->writableBuffer; uint32_t buffersize = data->writableBufSize; uint32_t strsize; UErrorCode status = U_ZERO_ERROR; /* because the pointer points to the next character */ UChar *pStart = data->pos - 1; UChar *pEnd; uint32_t normLen; UChar *pStartNorm; if ((data->flags & UCOL_ITER_INNORMBUF) == 0) { *data->writableBuffer = *(pStart - 1); strsize = 1; } else { strsize = u_strlen(data->writableBuffer); } pEnd = data->fcdPosition; normLen = unorm_normalize(pStart, pEnd - pStart, UNORM_NFD, 0, buffer, 0, &status); if (buffersize <= normLen + strsize) { uint32_t size = strsize + normLen + 1; UChar *temp = (UChar *)uprv_malloc(size * sizeof(UChar)); if(temp != NULL) { uprv_memcpy(temp, buffer, sizeof(UChar) * strsize); freeHeapWritableBuffer(data); data->writableBuffer = temp; data->writableBufSize = size; data->flags |= UCOL_ITER_ALLOCATED; } } status = U_ZERO_ERROR; pStartNorm = buffer + strsize; /* null-termination will be added here */ unorm_normalize(pStart, pEnd - pStart, UNORM_NFD, 0, pStartNorm, normLen + 1, &status); data->pos = data->writableBuffer + strsize; data->origFlags = data->flags; data->flags |= UCOL_ITER_INNORMBUF; data->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); } /** * Contraction character management function that returns the next character * for the forwards iterator. * Does nothing if the next character is in buffer and not the first character * in it. * Else it checks next character in data string to see if it is normalizable. * If it is not, the character is simply copied into the buffer, else * the whole normalized substring is copied into the buffer, including the * current character. * @param data collation element iterator data * @return next character */ static inline UChar getNextNormalizedChar(collIterate *data) { UChar nextch; UChar ch; // Here we need to add the iterator code. One problem is the way // end of string is handled. If we just return next char, it could // be the sentinel. Most of the cases already check for this, but we // need to be sure. if ((data->flags & (UCOL_ITER_NORM | UCOL_ITER_INNORMBUF)) == 0 ) { /* if no normalization and not in buffer. */ if(data->flags & UCOL_USE_ITERATOR) { return (UChar)data->iterator->next(data->iterator); } else { return *(data->pos ++); } } //if (data->flags & UCOL_ITER_NORM && data->flags & UCOL_USE_ITERATOR) { //normalizeIterator(data); //} UChar *pEndWritableBuffer = NULL; UBool innormbuf = (UBool)(data->flags & UCOL_ITER_INNORMBUF); if ((innormbuf && *data->pos != 0) || (data->fcdPosition != NULL && !innormbuf && data->pos < data->fcdPosition)) { /* if next character is in normalized buffer, no further normalization is required */ return *(data->pos ++); } if (data->flags & UCOL_ITER_HASLEN) { /* in data string */ if (data->pos + 1 == data->endp) { return *(data->pos ++); } } else { if (innormbuf) { // inside the normalization buffer, but at the end // (since we encountered zero). This means, in the // case we're using char iterator, that we need to // do another round of normalization. //if(data->origFlags & UCOL_USE_ITERATOR) { // we need to restore original flags, // otherwise, we'll lose them //data->flags = data->origFlags; //normalizeIterator(data); //return *(data->pos++); //} else { /* in writable buffer, at this point fcdPosition can not be pointing to the end of the data string. see contracting tag. */ if(data->fcdPosition) { if (*(data->fcdPosition + 1) == 0 || data->fcdPosition + 1 == data->endp) { /* at the end of the string, dump it into the normalizer */ data->pos = insertBufferEnd(data, data->pos, *(data->fcdPosition)) + 1; return *(data->fcdPosition ++); } pEndWritableBuffer = data->pos; data->pos = data->fcdPosition; } else if(data->origFlags & UCOL_USE_ITERATOR) { // if we are here, we're using a normalizing iterator. // we should just continue further. data->flags = data->origFlags; data->pos = NULL; return (UChar)data->iterator->next(data->iterator); } //} } else { if (*(data->pos + 1) == 0) { return *(data->pos ++); } } } ch = *data->pos ++; nextch = *data->pos; /* * if the current character is not fcd. * Trailing combining class == 0. */ if ((data->fcdPosition == NULL || data->fcdPosition < data->pos) && (nextch >= NFC_ZERO_CC_BLOCK_LIMIT_ || ch >= NFC_ZERO_CC_BLOCK_LIMIT_)) { /* Need a more complete FCD check and possible normalization. normalize substring will be appended to buffer */ if (collIterFCD(data)) { normalizeNextContraction(data); return *(data->pos ++); } else if (innormbuf) { /* fcdposition shifted even when there's no normalization, if we don't input the rest into this, we'll get the wrong position when we reach the end of the writableBuffer */ int32_t length = data->fcdPosition - data->pos + 1; data->pos = insertBufferEnd(data, pEndWritableBuffer, data->pos - 1, length); return *(data->pos ++); } } if (innormbuf) { /* no normalization is to be done hence only one character will be appended to the buffer. */ data->pos = insertBufferEnd(data, pEndWritableBuffer, ch) + 1; } /* points back to the pos in string */ return ch; } /** * Function to copy the buffer into writableBuffer and sets the fcd position to * the correct position * @param source data string source * @param buffer character buffer * @param tempdb current position in buffer that has been used up */ static inline void setDiscontiguosAttribute(collIterate *source, UChar *buffer, UChar *tempdb) { /* okay confusing part here. to ensure that the skipped characters are considered later, we need to place it in the appropriate position in the normalization buffer and reassign the pos pointer. simple case if pos reside in string, simply copy to normalization buffer and fcdposition = pos, pos = start of normalization buffer. if pos in normalization buffer, we'll insert the copy infront of pos and point pos to the start of the normalization buffer. why am i doing these copies? well, so that the whole chunk of codes in the getNextCE, ucol_prv_getSpecialCE does not require any changes, which be really painful. */ uint32_t length = u_strlen(buffer);; if (source->flags & UCOL_ITER_INNORMBUF) { u_strcpy(tempdb, source->pos); } else { source->fcdPosition = source->pos; source->origFlags = source->flags; source->flags |= UCOL_ITER_INNORMBUF; source->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN | UCOL_USE_ITERATOR); } if (length >= source->writableBufSize) { freeHeapWritableBuffer(source); source->writableBuffer = (UChar *)uprv_malloc((length + 1) * sizeof(UChar)); if(source->writableBuffer == NULL) { return; } source->writableBufSize = length; } u_strcpy(source->writableBuffer, buffer); source->pos = source->writableBuffer; } /** * Function to get the discontiguos collation element within the source. * Note this function will set the position to the appropriate places. * @param coll current collator used * @param source data string source * @param constart index to the start character in the contraction table * @return discontiguos collation element offset */ static uint32_t getDiscontiguous(const UCollator *coll, collIterate *source, const UChar *constart) { /* source->pos currently points to the second combining character after the start character */ UChar *temppos = source->pos; UChar buffer[4*UCOL_MAX_BUFFER]; UChar *tempdb = buffer; const UChar *tempconstart = constart; uint8_t tempflags = source->flags; UBool multicontraction = FALSE; UChar *tempbufferpos = 0; collIterateState discState; backupState(source, &discState); //*tempdb = *(source->pos - 1); *tempdb = peekCharacter(source, -1); tempdb ++; while (TRUE) { UChar *UCharOffset; UChar schar, tchar; uint32_t result; if (((source->flags & UCOL_ITER_HASLEN) && source->pos >= source->endp) || (peekCharacter(source, 0) == 0 && //|| (*source->pos == 0 && ((source->flags & UCOL_ITER_INNORMBUF) == 0 || source->fcdPosition == NULL || source->fcdPosition == source->endp || *(source->fcdPosition) == 0 || u_getCombiningClass(*(source->fcdPosition)) == 0)) || /* end of string in null terminated string or stopped by a null character, note fcd does not always point to a base character after the discontiguos change */ u_getCombiningClass(peekCharacter(source, 0)) == 0) { //u_getCombiningClass(*(source->pos)) == 0) { //constart = (UChar *)coll->image + getContractOffset(CE); if (multicontraction) { *tempbufferpos = 0; source->pos = temppos - 1; setDiscontiguosAttribute(source, buffer, tempdb); return *(coll->contractionCEs + (tempconstart - coll->contractionIndex)); } constart = tempconstart; break; } UCharOffset = (UChar *)(tempconstart + 1); /* skip the backward offset*/ schar = getNextNormalizedChar(source); while (schar > (tchar = *UCharOffset)) { UCharOffset++; } if (schar != tchar) { /* not the correct codepoint. we stuff the current codepoint into the discontiguos buffer and try the next character */ *tempdb = schar; tempdb ++; continue; } else { if (u_getCombiningClass(schar) == u_getCombiningClass(peekCharacter(source, -2))) { //u_getCombiningClass(*(source->pos - 2))) { *tempdb = schar; tempdb ++; continue; } result = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); } *tempdb = 0; if (result == UCOL_NOT_FOUND) { break; } else if (isContraction(result)) { /* this is a multi-contraction*/ tempconstart = (UChar *)coll->image + getContractOffset(result); if (*(coll->contractionCEs + (constart - coll->contractionIndex)) != UCOL_NOT_FOUND) { multicontraction = TRUE; temppos = source->pos + 1; tempbufferpos = buffer + u_strlen(buffer); } } else { setDiscontiguosAttribute(source, buffer, tempdb); return result; } } /* no problems simply reverting just like that, if we are in string before getting into this function, points back to string hence no problem. if we are in normalization buffer before getting into this function, since we'll never use another normalization within this function, we know that fcdposition points to a base character. the normalization buffer never change, hence this revert works. */ loadState(source, &discState, TRUE); goBackOne(source); //source->pos = temppos - 1; source->flags = tempflags; return *(coll->contractionCEs + (constart - coll->contractionIndex)); } static inline UBool isNonChar(UChar32 cp) { if ((cp & 0xFFFE) == 0xFFFE || (0xFDD0 <= cp && cp <= 0xFDEF) || (0xD800 <= cp && cp <= 0xDFFF)) { return TRUE; } return FALSE; } /* now uses Mark's getImplicitPrimary code */ static inline uint32_t getImplicit(UChar32 cp, collIterate *collationSource) { if(isNonChar(cp)) { return 0; } uint32_t r = uprv_uca_getImplicitPrimary(cp); *(collationSource->CEpos++) = ((r & 0x0000FFFF)<<16) | 0x000000C0; return (r & UCOL_PRIMARYMASK) | 0x00000505; // This was 'order' } /** * Inserts the argument character into the front of the buffer replacing the * front null terminator. * @param data collation element iterator data * @param pNull pointer to the null terminator * @param ch character to be appended * @return positon of added character */ static inline UChar * insertBufferFront(collIterate *data, UChar *pNull, UChar ch) { uint32_t size = data->writableBufSize; UChar *end; UChar *newbuffer; const uint32_t incsize = 5; if (pNull > data->writableBuffer + 1) { *pNull = ch; *(pNull - 1) = 0; return pNull; } /* buffer will always be null terminated infront. giving extra space since it is likely that more characters will be added. */ size += incsize; newbuffer = (UChar *)uprv_malloc(sizeof(UChar) * size); if(newbuffer == NULL) { return NULL; } end = newbuffer + incsize; uprv_memcpy(end, data->writableBuffer, data->writableBufSize * sizeof(UChar)); *end = ch; *(end - 1) = 0; freeHeapWritableBuffer(data); data->writableBufSize = size; data->writableBuffer = newbuffer; return end; } /** * Special normalization function for contraction in the previous iterator. * This normalization sequence will place the current character at source->pos * and its following normalized sequence into the buffer. * The fcd position, pos will be changed. * pos will now point to positions in the buffer. * Flags will be changed accordingly. * @param data collation iterator data */ static inline void normalizePrevContraction(collIterate *data) { UChar *buffer = data->writableBuffer; uint32_t buffersize = data->writableBufSize; uint32_t nulltermsize; UErrorCode status = U_ZERO_ERROR; UChar *pEnd = data->pos + 1; /* End normalize + 1 */ UChar *pStart; uint32_t normLen; UChar *pStartNorm; if (data->flags & UCOL_ITER_HASLEN) { /* normalization buffer not used yet, we'll pull down the next character into the end of the buffer */ *(buffer + (buffersize - 1)) = *(data->pos + 1); nulltermsize = buffersize - 1; } else { nulltermsize = buffersize; UChar *temp = buffer + (nulltermsize - 1); while (*(temp --) != 0) { nulltermsize --; } } /* Start normalize */ if (data->fcdPosition == NULL) { pStart = data->string; } else { pStart = data->fcdPosition + 1; } normLen = unorm_normalize(pStart, pEnd - pStart, UNORM_NFD, 0, buffer, 0, &status); if (nulltermsize <= normLen) { uint32_t size = buffersize - nulltermsize + normLen + 1; UChar *temp = (UChar *)uprv_malloc(size * sizeof(UChar)); if(temp != NULL) { nulltermsize = normLen + 1; uprv_memcpy(temp + normLen, buffer, sizeof(UChar) * (buffersize - nulltermsize)); freeHeapWritableBuffer(data); data->writableBuffer = temp; data->writableBufSize = size; } } status = U_ZERO_ERROR; /* this puts the null termination infront of the normalized string instead of the end */ pStartNorm = buffer + (nulltermsize - normLen); *(pStartNorm - 1) = 0; unorm_normalize(pStart, pEnd - pStart, UNORM_NFD, 0, pStartNorm, normLen, &status); data->pos = data->writableBuffer + nulltermsize; data->origFlags = data->flags; data->flags |= UCOL_ITER_INNORMBUF; data->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); } /** * Contraction character management function that returns the previous character * for the backwards iterator. * Does nothing if the previous character is in buffer and not the first * character in it. * Else it checks previous character in data string to see if it is * normalizable. * If it is not, the character is simply copied into the buffer, else * the whole normalized substring is copied into the buffer, including the * current character. * @param data collation element iterator data * @return previous character */ static inline UChar getPrevNormalizedChar(collIterate *data) { UChar prevch; UChar ch; UChar *start; UBool innormbuf = (UBool)(data->flags & UCOL_ITER_INNORMBUF); UChar *pNull = NULL; if ((data->flags & (UCOL_ITER_NORM | UCOL_ITER_INNORMBUF)) == 0 || (innormbuf && *(data->pos - 1) != 0)) { /* if no normalization. if previous character is in normalized buffer, no further normalization is required */ if(data->flags & UCOL_USE_ITERATOR) { data->iterator->move(data->iterator, -1, UITER_CURRENT); return (UChar)data->iterator->next(data->iterator); } else { return *(data->pos - 1); } } start = data->pos; if (data->flags & UCOL_ITER_HASLEN) { /* in data string */ if ((start - 1) == data->string) { return *(start - 1); } start --; ch = *start; prevch = *(start - 1); } else { /* in writable buffer, at this point fcdPosition can not be NULL. see contracting tag. */ if (data->fcdPosition == data->string) { /* at the start of the string, just dump it into the normalizer */ insertBufferFront(data, data->pos - 1, *(data->fcdPosition)); data->fcdPosition = NULL; return *(data->pos - 1); } pNull = data->pos - 1; start = data->fcdPosition; ch = *start; prevch = *(start - 1); } /* * if the current character is not fcd. * Trailing combining class == 0. */ if (data->fcdPosition > start && (ch >= NFC_ZERO_CC_BLOCK_LIMIT_ || prevch >= NFC_ZERO_CC_BLOCK_LIMIT_)) { /* Need a more complete FCD check and possible normalization. normalize substring will be appended to buffer */ UChar *backuppos = data->pos; data->pos = start; if (collPrevIterFCD(data)) { normalizePrevContraction(data); return *(data->pos - 1); } data->pos = backuppos; data->fcdPosition ++; } if (innormbuf) { /* no normalization is to be done hence only one character will be appended to the buffer. */ insertBufferFront(data, pNull, ch); data->fcdPosition --; } return ch; } /* This function handles the special CEs like contractions, expansions, surrogates, Thai */ /* It is called by getNextCE */ uint32_t ucol_prv_getSpecialCE(const UCollator *coll, UChar ch, uint32_t CE, collIterate *source, UErrorCode *status) { collIterateState entryState; backupState(source, &entryState); UChar32 cp = ch; for (;;) { // This loop will repeat only in the case of contractions, and only when a contraction // is found and the first CE resulting from that contraction is itself a special // (an expansion, for example.) All other special CE types are fully handled the // first time through, and the loop exits. const uint32_t *CEOffset = NULL; switch(getCETag(CE)) { case NOT_FOUND_TAG: /* This one is not found, and we'll let somebody else bother about it... no more games */ return CE; case SURROGATE_TAG: /* we encountered a leading surrogate. We shall get the CE by using the following code unit */ /* two things can happen here: next code point can be a trailing surrogate - we will use it */ /* to retrieve the CE, or it is not a trailing surrogate (or the string is done). In that case */ /* we return 0 (completely ignorable - per UCA specification */ { UChar trail; collIterateState state; backupState(source, &state); if (collIter_eos(source) || !(UTF16_IS_TRAIL((trail = getNextNormalizedChar(source))))) { // we chould have stepped one char forward and it might have turned that it // was not a trail surrogate. In that case, we have to backup. loadState(source, &state, TRUE); return 0; } else { /* TODO: CE contain the data from the previous CE + the mask. It should at least be unmasked */ CE = UTRIE_GET32_FROM_OFFSET_TRAIL(coll->mapping, CE&0xFFFFFF, trail); if(CE == UCOL_NOT_FOUND) { // there are tailored surrogates in this block, but not this one. // We need to backup loadState(source, &state, TRUE); return CE; } // calculate the supplementary code point value, if surrogate was not tailored cp = ((((uint32_t)ch)<<10UL)+(trail)-(((uint32_t)0xd800<<10UL)+0xdc00-0x10000)); } } break; case THAI_TAG: /* Thai/Lao reordering */ if (((source->flags) & UCOL_ITER_INNORMBUF) /* Already Swapped || */ || collIter_eos(source)) /* At end of string. No swap possible */ { // Treat Thai as a length one expansion */ CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); /* find the offset to expansion table */ CE = *CEOffset++; } else { // Move the prevowel and the following base Consonant into the normalization buffer // with their order swapped // Note: this operation might activate the normalization buffer. We have to check for // that and act accordingly. UChar thCh = getNextNormalizedChar(source); UChar32 cp = 0; if(U16_IS_LEAD(thCh)) { if(!collIter_eos(source)) { collIterateState thaiState; backupState(source, &thaiState); UChar trailCh = getNextNormalizedChar(source); if(U16_IS_TRAIL(trailCh)) { cp = U16_GET_SUPPLEMENTARY(thCh, trailCh); } else { loadState(source, &thaiState, TRUE); cp = (UChar32)thCh; } } else { cp = (UChar32)thCh; } } else { cp = (UChar32)thCh; } // Now we have the character that needs to be decomposed // if the normalizing buffer was not used, we can just use our structure and be happy. if((source->flags & UCOL_ITER_INNORMBUF) == 0) { // decompose into writable buffer int32_t decompLen = unorm_getDecomposition(cp, FALSE, &(source->writableBuffer[1]), UCOL_WRITABLE_BUFFER_SIZE-1); if(decompLen < 0) { decompLen = -decompLen; } // reorder Thai and the character after it if(decompLen >= 2 && U16_IS_LEAD(source->writableBuffer[1]) && U16_IS_TRAIL(source->writableBuffer[2])) { source->writableBuffer[0] = source->writableBuffer[1]; source->writableBuffer[1] = source->writableBuffer[2]; source->writableBuffer[2] = ch; } else { source->writableBuffer[0] = source->writableBuffer[1]; source->writableBuffer[1] = ch; } // zero terminate, since normalization buffer is always zero terminated source->writableBuffer[decompLen+1] = 0; // we added the prevowel if(source->pos) { source->fcdPosition = source->pos; // Indicate where to continue in main input string // after exhausting the writableBuffer } source->pos = source->writableBuffer; source->origFlags = source->flags; source->flags |= UCOL_ITER_INNORMBUF; source->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN | UCOL_USE_ITERATOR); } else { // stuff is already normalized... what to do here??? // if we are in the normalization buffer, thCh must be in it // prove by contradiction // if thCh is not in the normalization buffer, // that means that trailCh is the normalization buffer // that means that trailCh is a trail surrogate by the above // bounding if block, this is a contradiction because there // are no characters at the moment that decomposes to an // unmatched surrogate. qed. if (cp >= 0x10000) { source->writableBuffer[0] = source->writableBuffer[1]; source->writableBuffer[1] = source->writableBuffer[2]; source->writableBuffer[2] = ch; } else { source->writableBuffer[0] = source->writableBuffer[1]; source->writableBuffer[1] = ch; } source->pos = source->writableBuffer; } CE = ucol_IGetNextCE(coll, source, status); // UCOL_IGNORABLE; } break; case SPEC_PROC_TAG: { // Special processing is getting a CE that is preceded by a certain prefix // Currently this is only needed for optimizing Japanese length and iteration marks. // When we encouter a special processing tag, we go backwards and try to see if // we have a match. // Contraction tables are used - so the whole process is not unlike contraction. // prefix data is stored backwards in the table. const UChar *UCharOffset; UChar schar, tchar; collIterateState prefixState; backupState(source, &prefixState); loadState(source, &entryState, TRUE); goBackOne(source); // We want to look at the point where we entered - actually one // before that... for(;;) { // This loop will run once per source string character, for as long as we // are matching a potential contraction sequence // First we position ourselves at the begining of contraction sequence const UChar *ContractionStart = UCharOffset = (UChar *)coll->image+getContractOffset(CE); if (collIter_bos(source)) { CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); break; } schar = getPrevNormalizedChar(source); goBackOne(source); while(schar > (tchar = *UCharOffset)) { /* since the contraction codepoints should be ordered, we skip all that are smaller */ UCharOffset++; } if (schar == tchar) { // Found the source string char in the table. // Pick up the corresponding CE from the table. CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); } else { // if there is a completely ignorable code point in the middle of // a prefix, we need to act as if it's not there // assumption: 'real' noncharacters (*fffe, *ffff, fdd0-fdef are set to zero) // lone surrogates cannot be set to zero as it would break other processing uint32_t isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, schar); // it's easy for BMP code points if(isZeroCE == 0) { continue; } else if(UTF_IS_TRAIL(schar) || UTF_IS_LEAD(schar)) { // for supplementary code points, we have to check the next one // situations where we are going to ignore // 1. beginning of the string: schar is a lone surrogate // 2. schar is a lone surrogate // 3. schar is a trail surrogate in a valid surrogate sequence // that is explicitly set to zero. if (!collIter_bos(source)) { UChar lead; if(UTF_IS_LEAD(lead = getPrevNormalizedChar(source))) { isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, lead); if(getCETag(isZeroCE) == SURROGATE_TAG) { uint32_t finalCE = UTRIE_GET32_FROM_OFFSET_TRAIL(coll->mapping, isZeroCE&0xFFFFFF, schar); if(finalCE == 0) { // this is a real, assigned completely ignorable code point goBackOne(source); continue; } } } else { // lone surrogate, completely ignorable continue; } } else { // lone surrogate at the beggining, completely ignorable continue; } } // Source string char was not in the table. // We have not found the prefix. CE = *(coll->contractionCEs + (ContractionStart - coll->contractionIndex)); } if(!isPrefix(CE)) { // The source string char was in the contraction table, and the corresponding // CE is not a prefix CE. We found the prefix, break // out of loop, this CE will end up being returned. This is the normal // way out of prefix handling when the source actually contained // the prefix. break; } } if(CE != UCOL_NOT_FOUND) { // we found something and we can merilly continue loadState(source, &prefixState, TRUE); if(source->origFlags & UCOL_USE_ITERATOR) { source->flags = source->origFlags; } } else { // prefix search was a failure, we have to backup all the way to the start loadState(source, &entryState, TRUE); } break; } case CONTRACTION_TAG: { /* This should handle contractions */ collIterateState state; backupState(source, &state); uint32_t firstCE = UCOL_NOT_FOUND; const UChar *UCharOffset; UChar schar, tchar; for (;;) { /* This loop will run once per source string character, for as long as we */ /* are matching a potential contraction sequence */ /* First we position ourselves at the begining of contraction sequence */ const UChar *ContractionStart = UCharOffset = (UChar *)coll->image+getContractOffset(CE); if (collIter_eos(source)) { // Ran off the end of the source string. CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); // So we'll pick whatever we have at the point... if (CE == UCOL_NOT_FOUND) { // back up the source over all the chars we scanned going into this contraction. CE = firstCE; loadState(source, &state, TRUE); if(source->origFlags & UCOL_USE_ITERATOR) { source->flags = source->origFlags; } } break; } uint8_t maxCC = (uint8_t)(*(UCharOffset)&0xFF); /*get the discontiguos stuff */ /* skip the backward offset, see above */ uint8_t allSame = (uint8_t)(*(UCharOffset++)>>8); schar = getNextNormalizedChar(source); while(schar > (tchar = *UCharOffset)) { /* since the contraction codepoints should be ordered, we skip all that are smaller */ UCharOffset++; } if (schar == tchar) { // Found the source string char in the contraction table. // Pick up the corresponding CE from the table. CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); } else { // if there is a completely ignorable code point in the middle of // contraction, we need to act as if it's not there uint32_t isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, schar); // it's easy for BMP code points if(isZeroCE == 0) { continue; } else if(UTF_IS_LEAD(schar)) { if(!collIter_eos(source)) { backupState(source, &state); UChar trail = getNextNormalizedChar(source); if(UTF_IS_TRAIL(trail)) { // do stuff with trail if(getCETag(isZeroCE) == SURROGATE_TAG) { uint32_t finalCE = UTRIE_GET32_FROM_OFFSET_TRAIL(coll->mapping, isZeroCE&0xFFFFFF, trail); if(finalCE == 0) { continue; } } } else { // broken surrogate sequence, thus completely ignorable loadState(source, &state, TRUE); continue; } loadState(source, &state, TRUE); } else { // no more characters, so broken surrogate pair... // this contraction will ultimately fail, but not because of us continue; } } // else if(UTF_IS_LEAD(schar)) // Source string char was not in contraction table. // Unless we have a discontiguous contraction, we have finished // with this contraction. uint8_t sCC; if (schar < 0x300 || maxCC == 0 || (sCC = i_getCombiningClass(schar, coll)) == 0 || sCC>maxCC || (allSame != 0 && sCC == maxCC) || collIter_eos(source)) { // Contraction can not be discontiguous. goBackOne(source); // back up the source string by one, // because the character we just looked at was // not part of the contraction. */ CE = *(coll->contractionCEs + (ContractionStart - coll->contractionIndex)); } else { // // Contraction is possibly discontiguous. // Scan more of source string looking for a match // UChar tempchar; /* find the next character if schar is not a base character and we are not yet at the end of the string */ tempchar = getNextNormalizedChar(source); goBackOne(source); if (i_getCombiningClass(tempchar, coll) == 0) { goBackOne(source); /* Spit out the last char of the string, wasn't tasty enough */ CE = *(coll->contractionCEs + (ContractionStart - coll->contractionIndex)); } else { CE = getDiscontiguous(coll, source, ContractionStart); } } } // else after if(schar == tchar) if(CE == UCOL_NOT_FOUND) { /* The Source string did not match the contraction that we were checking. */ /* Back up the source position to undo the effects of having partially */ /* scanned through what ultimately proved to not be a contraction. */ loadState(source, &state, TRUE); CE = firstCE; break; } if(!isContraction(CE)) { // The source string char was in the contraction table, and the corresponding // CE is not a contraction CE. We completed the contraction, break // out of loop, this CE will end up being returned. This is the normal // way out of contraction handling when the source actually contained // the contraction. break; } // The source string char was in the contraction table, and the corresponding // CE is IS a contraction CE. We will continue looping to check the source // string for the remaining chars in the contraction. uint32_t tempCE = *(coll->contractionCEs + (ContractionStart - coll->contractionIndex)); if(tempCE != UCOL_NOT_FOUND) { // We have scanned a a section of source string for which there is a // CE from the contraction table. Remember the CE and scan position, so // that we can return to this point if further scanning fails to // match a longer contraction sequence. firstCE = tempCE; goBackOne(source); backupState(source, &state); getNextNormalizedChar(source); // Another way to do this is: //collIterateState tempState; //backupState(source, &tempState); //goBackOne(source); //backupState(source, &state); //loadState(source, &tempState, TRUE); // The problem is that for incomplete contractions we have to remember the previous // position. Before, the only thing I needed to do was state.pos--; // After iterator introduction and especially after introduction of normalizing // iterators, it became much more difficult to decrease the saved state. // I'm not yet sure which of the two methods above is faster. } } // for(;;) break; } // case CONTRACTION_TAG: case LONG_PRIMARY_TAG: { *(source->CEpos++) = ((CE & 0xFF)<<24)|UCOL_CONTINUATION_MARKER; CE = ((CE & 0xFFFF00) << 8) | (UCOL_BYTE_COMMON << 8) | UCOL_BYTE_COMMON; return CE; } case EXPANSION_TAG: { /* This should handle expansion. */ /* NOTE: we can encounter both continuations and expansions in an expansion! */ /* I have to decide where continuations are going to be dealt with */ uint32_t size; uint32_t i; /* general counter */ CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); /* find the offset to expansion table */ size = getExpansionCount(CE); CE = *CEOffset++; if(size != 0) { /* if there are less than 16 elements in expansion, we don't terminate */ for(i = 1; iCEpos++) = *CEOffset++; } } else { /* else, we do */ while(*CEOffset != 0) { *(source->CEpos++) = *CEOffset++; } } return CE; } case DIGIT_TAG: { /* We do a check to see if we want to collate digits as numbers; if so we generate a custom collation key. Otherwise we pull out the value stored in the expansion table. */ uint32_t size; uint32_t i; /* general counter */ collIterateState digitState; if (source->coll->numericCollation == UCOL_ON){ UChar32 char32 = 0; uint32_t digIndx = 0; uint32_t endIndex = 0; uint32_t trailingZeroIndex = 0; uint32_t primWeight = 0; int32_t digVal = 0; uint8_t collateVal = 0; UBool nonZeroValReached = FALSE; uint8_t *numTempBuf; uint8_t stackNumTempBuf[UCOL_MAX_BUFFER]; // I just need a temporary place to store my generated CEs. uint32_t numTempBufSize = UCOL_MAX_BUFFER; numTempBuf = stackNumTempBuf; /* We parse the source string until we hit a char that's NOT a digit. Use this u_charDigitValue. This might be slow because we have to handle surrogates... */ /* if (U16_IS_LEAD(ch)){ if (!collIter_eos(source)) { backupState(source, &digitState); UChar trail = getNextNormalizedChar(source); if(U16_IS_TRAIL(trail)) { char32 = U16_GET_SUPPLEMENTARY(ch, trail); } else { loadState(source, &digitState, TRUE); char32 = ch; } } else { char32 = ch; } } else { char32 = ch; } digVal = u_charDigitValue(char32); */ digVal = u_charDigitValue(cp); // if we have arrived here, we have // already processed possible supplementaries that trigered the digit tag - // all supplementaries are marked in the UCA. /* We pad a zero in front of the first element anyways. This takes care of the (probably) most common case where people are sorting things followed by a single digit */ digIndx++; for(;;){ // Make sure we have enough space. if (digIndx >= ((numTempBufSize - 2) * 2) + 1) { numTempBufSize *= 2; if (numTempBuf == stackNumTempBuf){ numTempBuf = (uint8_t *)uprv_malloc(sizeof(uint8_t) * numTempBufSize); uprv_memcpy(numTempBuf, stackNumTempBuf, UCOL_MAX_BUFFER); }else uprv_realloc(numTempBuf, numTempBufSize); } // Skipping over leading zeroes. if (digVal != 0 || nonZeroValReached){ if (digVal != 0 && !nonZeroValReached) nonZeroValReached = TRUE; /* We parse the digit string into base 100 numbers (this fits into a byte). We only add to the buffer in twos, thus if we are parsing an odd character, that serves as the 'tens' digit while the if we are parsing an even one, that is the 'ones' digit. We dumped the parsed base 100 value (collateVal) into a buffer. We multiply each collateVal by 2 (to give us room) and add 5 (to avoid overlapping magic CE byte values). The last byte we subtract 1 to ensure it is less than all the other bytes. */ if (digIndx % 2 == 1){ collateVal += (uint8_t)digVal; // We don't enter the low-order-digit case unless we've already seen // the high order, or for the first digit, which is always non-zero. if (collateVal != 0) trailingZeroIndex = 0; numTempBuf[(digIndx/2) + 2] = collateVal*2 + 6; collateVal = 0; } else{ // We drop the collation value into the buffer so if we need to do // a "front patch" we don't have to check to see if we're hitting the // last element. collateVal = (uint8_t)(digVal * 10); // Check for trailing zeroes. if (collateVal == 0) { if (!trailingZeroIndex) trailingZeroIndex = (digIndx/2) + 2; } else trailingZeroIndex = 0; numTempBuf[(digIndx/2) + 2] = collateVal*2 + 6; } digIndx++; } // Get next character. if (!collIter_eos(source)){ ch = getNextNormalizedChar(source); if (U16_IS_LEAD(ch)){ if (!collIter_eos(source)) { backupState(source, &digitState); UChar trail = getNextNormalizedChar(source); if(U16_IS_TRAIL(trail)) { char32 = U16_GET_SUPPLEMENTARY(ch, trail); } else { loadState(source, &digitState, TRUE); char32 = ch; } } } else { char32 = ch; } if ((digVal = u_charDigitValue(char32)) == -1){ // Resetting position to point to the next unprocessed char. We // overshot it when doing our test/set for numbers. if (char32 > 0xFFFF) { // For surrogates. loadState(source, &digitState, TRUE); //goBackOne(source); } goBackOne(source); break; } } else { break; } } if (nonZeroValReached == FALSE){ digIndx = 2; numTempBuf[2] = 6; } endIndex = trailingZeroIndex ? trailingZeroIndex : ((digIndx/2) + 2) ; if (digIndx % 2 != 0){ /* We missed a value. Since digIndx isn't even, stuck too many values into the buffer (this is what we get for padding the first byte with a zero). "Front-patch" now by pushing all nybbles forward. Doing it this way ensures that at least 50% of the time (statistically speaking) we'll only be doing a single pass and optimizes for strings with single digits. I'm just assuming that's the more common case. */ for(i = 2; i < endIndex; i++){ numTempBuf[i] = (((((numTempBuf[i] - 6)/2) % 10) * 10) + (((numTempBuf[i+1])-6)/2) / 10) * 2 + 6; } --digIndx; } // Subtract one off of the last byte. numTempBuf[endIndex-1] -= 1; /* We want to skip over the first two slots in the buffer. The first slot is reserved for the header byte 0x1B. The second slot is for the sign/exponent byte: 0x80 + (decimalPos/2) & 7f. */ numTempBuf[0] = 0x1B; numTempBuf[1] = (uint8_t)(0x80 + ((digIndx/2) & 0x7F)); // Now transfer the collation key to our collIterate struct. // The total size for our collation key is endIndx bumped up to the next largest even value divided by two. size = ((endIndex+1) & ~1)/2; CE = (((numTempBuf[0] << 8) | numTempBuf[1]) << UCOL_PRIMARYORDERSHIFT) | //Primary weight (UCOL_BYTE_COMMON << UCOL_SECONDARYORDERSHIFT) | // Secondary weight UCOL_BYTE_COMMON; // Tertiary weight. i = 2; // Reset the index into the buffer. while(i < endIndex) { primWeight = numTempBuf[i++] << 8; if ( i < endIndex) primWeight |= numTempBuf[i++]; *(source->CEpos++) = (primWeight << UCOL_PRIMARYORDERSHIFT) | UCOL_CONTINUATION_MARKER; } if (numTempBuf != stackNumTempBuf) uprv_free(numTempBuf); } else { // no numeric mode, we'll just switch to whatever we stashed and continue CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); /* find the offset to expansion table */ CE = *CEOffset++; break; #if 0 CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); /* find the offset to expansion table */ size = getExpansionCount(CE); CE = *CEOffset++; if(size != 0) { /* if there are less than 16 elements in expansion, we don't terminate */ for(i = 1; iCEpos++) = *CEOffset++; } } else { /* else, we do */ while(*CEOffset != 0) { *(source->CEpos++) = *CEOffset++; } } #endif } return CE; } /* various implicits optimization */ // TODO: remove CJK_IMPLICIT_TAG completely - handled by the getImplicit case CJK_IMPLICIT_TAG: /* 0x3400-0x4DB5, 0x4E00-0x9FA5, 0xF900-0xFA2D*/ //return getImplicit(cp, source, 0x04000000); return getImplicit(cp, source); case IMPLICIT_TAG: /* everything that is not defined otherwise */ /* UCA is filled with these. Tailorings are NOT_FOUND */ //return getImplicit(cp, source, 0); return getImplicit(cp, source); case TRAIL_SURROGATE_TAG: /* DC00-DFFF*/ return 0; /* broken surrogate sequence */ case LEAD_SURROGATE_TAG: /* D800-DBFF*/ UChar nextChar; if( source->flags & UCOL_USE_ITERATOR) { if(U_IS_TRAIL(nextChar = (UChar)source->iterator->current(source->iterator))) { cp = U16_GET_SUPPLEMENTARY(ch, nextChar); source->iterator->next(source->iterator); return getImplicit(cp, source); } else { return 0; } } else if((((source->flags & UCOL_ITER_HASLEN) == 0 ) || (source->posendp)) && U_IS_TRAIL((nextChar=*source->pos))) { cp = U16_GET_SUPPLEMENTARY(ch, nextChar); source->pos++; return getImplicit(cp, source); } else { return 0; /* completely ignorable */ } case HANGUL_SYLLABLE_TAG: /* AC00-D7AF*/ { const uint32_t SBase = 0xAC00, LBase = 0x1100, VBase = 0x1161, TBase = 0x11A7; //const uint32_t LCount = 19; const uint32_t VCount = 21; const uint32_t TCount = 28; //const uint32_t NCount = VCount * TCount; // 588 //const uint32_t SCount = LCount * NCount; // 11172 uint32_t L = ch - SBase; // divide into pieces uint32_t T = L % TCount; // we do it in this order since some compilers can do % and / in one operation L /= TCount; uint32_t V = L % VCount; L /= VCount; // offset them L += LBase; V += VBase; T += TBase; // return the first CE, but first put the rest into the expansion buffer if (!source->coll->image->jamoSpecial) { // FAST PATH /**(source->CEpos++) = ucmpe32_get(UCA->mapping, V);*/ /**(source->CEpos++) = UTRIE_GET32_FROM_LEAD(UCA->mapping, V);*/ *(source->CEpos++) = UTRIE_GET32_FROM_LEAD(coll->mapping, V); if (T != TBase) { /**(source->CEpos++) = ucmpe32_get(UCA->mapping, T);*/ /**(source->CEpos++) = UTRIE_GET32_FROM_LEAD(UCA->mapping, T);*/ *(source->CEpos++) = UTRIE_GET32_FROM_LEAD(coll->mapping, T); } /*return ucmpe32_get(UCA->mapping, L);*/ // return first one /*return UTRIE_GET32_FROM_LEAD(UCA->mapping, L);*/ return UTRIE_GET32_FROM_LEAD(coll->mapping, L); } else { // Jamo is Special // Since Hanguls pass the FCD check, it is // guaranteed that we won't be in // the normalization buffer if something like this happens // However, if we are using a uchar iterator and normalization // is ON, the Hangul that lead us here is going to be in that // normalization buffer. Here we want to restore the uchar // iterator state and pull out of the normalization buffer if(source->iterator != NULL && source->flags & UCOL_ITER_INNORMBUF) { source->flags = source->origFlags; // restore the iterator source->pos = NULL; } // Move Jamos into normalization buffer source->writableBuffer[0] = (UChar)L; source->writableBuffer[1] = (UChar)V; if (T != TBase) { source->writableBuffer[2] = (UChar)T; source->writableBuffer[3] = 0; } else { source->writableBuffer[2] = 0; } source->fcdPosition = source->pos; // Indicate where to continue in main input string // after exhausting the writableBuffer source->pos = source->writableBuffer; source->origFlags = source->flags; source->flags |= UCOL_ITER_INNORMBUF; source->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); return(UCOL_IGNORABLE); } } case CHARSET_TAG: /* not yet implemented */ /* probably after 1.8 */ return UCOL_NOT_FOUND; default: *status = U_INTERNAL_PROGRAM_ERROR; CE=0; break; } if (CE <= UCOL_NOT_FOUND) break; } return CE; } /* now uses Mark's getImplicitPrimary code */ static inline uint32_t getPrevImplicit(UChar32 cp, collIterate *collationSource) { if(isNonChar(cp)) { return 0; } uint32_t r = uprv_uca_getImplicitPrimary(cp); *(collationSource->CEpos++) = (r & UCOL_PRIMARYMASK) | 0x00000505; collationSource->toReturn = collationSource->CEpos; return ((r & 0x0000FFFF)<<16) | 0x000000C0; } /** * This function handles the special CEs like contractions, expansions, * surrogates, Thai. * It is called by both getPrevCE */ uint32_t ucol_prv_getSpecialPrevCE(const UCollator *coll, UChar ch, uint32_t CE, collIterate *source, UErrorCode *status) { const uint32_t *CEOffset = NULL; UChar *UCharOffset = NULL; UChar schar; const UChar *constart = NULL; uint32_t size; UChar buffer[UCOL_MAX_BUFFER]; uint32_t *endCEBuffer; UChar *strbuffer; int32_t noChars = 0; for(;;) { /* the only ces that loops are thai and contractions */ switch (getCETag(CE)) { case NOT_FOUND_TAG: /* this tag always returns */ return CE; case SURROGATE_TAG: /* This is a surrogate pair */ /* essentialy an engaged lead surrogate. */ /* if you have encountered it here, it means that a */ /* broken sequence was encountered and this is an error */ return 0; case THAI_TAG: if ((source->flags & UCOL_ITER_INNORMBUF) || /* Already Swapped || */ source->string == source->pos || /* At start of string.|| */ /* previous char not Thai prevowel */ /*UCOL_ISTHAIBASECONSONANT(*(source->pos)) == FALSE ||*/ // This is from the old specs - we now rearrange unconditionally UCOL_ISTHAIPREVOWEL(peekCharacter(source, -1)) == FALSE) //UCOL_ISTHAIPREVOWEL(*(source->pos - 1)) == FALSE) { /* Treat Thai as a length one expansion */ /* find the offset to expansion table */ CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); CE = *CEOffset ++; } else { /* Move the prevowel and the following base Consonant into the normalization buffer with their order swapped */ UChar32 cp = (UChar32)peekCharacter(source, 0); UBool reorder = TRUE; int32_t decompLen = unorm_getDecomposition(cp, FALSE, source->writableBuffer, UCOL_WRITABLE_BUFFER_SIZE-1); if(decompLen < 0) { decompLen = -decompLen; // there was no decomposition } else { // we need to check if we will hit a contraction trigger because of decomposition int32_t i = decompLen; for(i = 0; i < decompLen; i++) { if(ucol_contractionEndCP(source->writableBuffer[i], coll)) { reorder = FALSE; } } } UChar *tempbuffer = source->writableBuffer + (source->writableBufSize - 1); uprv_memcpy(tempbuffer-decompLen + 1, source->writableBuffer, sizeof(UChar)*decompLen); if(reorder) { *(tempbuffer - decompLen) = *(tempbuffer - decompLen + 1); *(tempbuffer - decompLen + 1) = peekCharacter(source, -1); } else { *(tempbuffer - decompLen) = peekCharacter(source, -1); } *(tempbuffer - decompLen - 1) = 0; /* UChar *tempbuffer = source->writableBuffer + (source->writableBufSize - 1); *(tempbuffer - 2) = 0; *(tempbuffer - 1) = peekCharacter(source, 0); *(tempbuffer) = peekCharacter(source, -1); */ /* Indicate where to continue in main input string after exhausting the writableBuffer */ if (source->pos - 1 == source->string) { source->fcdPosition = NULL; } else { source->fcdPosition = source->pos-2; } source->pos = tempbuffer+1; // we're doing predecrement, right? source->origFlags = source->flags; source->flags |= UCOL_ITER_INNORMBUF; source->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); //CE = UCOL_IGNORABLE; return(UCOL_IGNORABLE); } break; case SPEC_PROC_TAG: { // Special processing is getting a CE that is preceded by a certain prefix // Currently this is only needed for optimizing Japanese length and iteration marks. // When we encouter a special processing tag, we go backwards and try to see if // we have a match. // Contraction tables are used - so the whole process is not unlike contraction. // prefix data is stored backwards in the table. const UChar *UCharOffset; UChar schar, tchar; collIterateState prefixState; backupState(source, &prefixState); for(;;) { // This loop will run once per source string character, for as long as we // are matching a potential contraction sequence // First we position ourselves at the begining of contraction sequence const UChar *ContractionStart = UCharOffset = (UChar *)coll->image+getContractOffset(CE); if (collIter_bos(source)) { CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); break; } schar = getPrevNormalizedChar(source); goBackOne(source); while(schar > (tchar = *UCharOffset)) { /* since the contraction codepoints should be ordered, we skip all that are smaller */ UCharOffset++; } if (schar == tchar) { // Found the source string char in the table. // Pick up the corresponding CE from the table. CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); } else { // if there is a completely ignorable code point in the middle of // a prefix, we need to act as if it's not there // assumption: 'real' noncharacters (*fffe, *ffff, fdd0-fdef are set to zero) // lone surrogates cannot be set to zero as it would break other processing uint32_t isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, schar); // it's easy for BMP code points if(isZeroCE == 0) { continue; } else if(UTF_IS_TRAIL(schar) || UTF_IS_LEAD(schar)) { // for supplementary code points, we have to check the next one // situations where we are going to ignore // 1. beginning of the string: schar is a lone surrogate // 2. schar is a lone surrogate // 3. schar is a trail surrogate in a valid surrogate sequence // that is explicitly set to zero. if (!collIter_bos(source)) { UChar lead; if(UTF_IS_LEAD(lead = getPrevNormalizedChar(source))) { isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, lead); if(getCETag(isZeroCE) == SURROGATE_TAG) { uint32_t finalCE = UTRIE_GET32_FROM_OFFSET_TRAIL(coll->mapping, isZeroCE&0xFFFFFF, schar); if(finalCE == 0) { // this is a real, assigned completely ignorable code point goBackOne(source); continue; } } } else { // lone surrogate, completely ignorable continue; } } else { // lone surrogate at the beggining, completely ignorable continue; } } // Source string char was not in the table. // We have not found the prefix. CE = *(coll->contractionCEs + (ContractionStart - coll->contractionIndex)); } if(!isPrefix(CE)) { // The source string char was in the contraction table, and the corresponding // CE is not a prefix CE. We found the prefix, break // out of loop, this CE will end up being returned. This is the normal // way out of prefix handling when the source actually contained // the prefix. break; } } loadState(source, &prefixState, TRUE); break; } case CONTRACTION_TAG: /* to ensure that the backwards and forwards iteration matches, we take the current region of most possible match and pass it through the forward iteration. this will ensure that the obstinate problem of overlapping contractions will not occur. */ schar = peekCharacter(source, 0); constart = (UChar *)coll->image + getContractOffset(CE); if (isAtStartPrevIterate(source) /* commented away contraction end checks after adding the checks in getPrevCE */) { /* start of string or this is not the end of any contraction */ CE = *(coll->contractionCEs + (constart - coll->contractionIndex)); break; } strbuffer = buffer; UCharOffset = strbuffer + (UCOL_MAX_BUFFER - 1); *(UCharOffset --) = 0; noChars = 0; // have to swap thai characters while (ucol_unsafeCP(schar, coll) || UCOL_ISTHAIPREVOWEL(peekCharacter(source, -1))) { // we might have ended here after trying to reorder Thai, but seeing that there are unsafe points // in the backward processing *(UCharOffset) = schar; noChars++; UCharOffset --; schar = getPrevNormalizedChar(source); goBackOne(source); // TODO: when we exhaust the contraction buffer, // it needs to get reallocated. The problem is // that the size depends on the string which is // not iterated over. However, since we're travelling // backwards, we already had to set the iterator at // the end - so we might as well know where we are? if (UCharOffset + 1 == buffer) { /* we have exhausted the buffer */ int32_t newsize = 0; if(source->pos) { // actually dealing with a position newsize = source->pos - source->string + 1; } else { // iterator newsize = 4 * UCOL_MAX_BUFFER; } strbuffer = (UChar *)uprv_malloc(sizeof(UChar) * (newsize + UCOL_MAX_BUFFER)); /* test for NULL */ if (strbuffer == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return UCOL_NO_MORE_CES; } UCharOffset = strbuffer + newsize; uprv_memcpy(UCharOffset, buffer, UCOL_MAX_BUFFER * sizeof(UChar)); UCharOffset --; } if ((source->pos && (source->pos == source->string || ((source->flags & UCOL_ITER_INNORMBUF) && *(source->pos - 1) == 0 && source->fcdPosition == NULL))) || (source->iterator && !source->iterator->hasPrevious(source->iterator))) { break; } } /* adds the initial base character to the string */ *(UCharOffset) = schar; noChars++; /* a new collIterate is used to simplify things, since using the current collIterate will mean that the forward and backwards iteration will share and change the same buffers. we don't want to get into that. */ collIterate temp; //IInit_collIterate(coll, UCharOffset, -1, &temp); IInit_collIterate(coll, UCharOffset, noChars, &temp); temp.flags &= ~UCOL_ITER_NORM; CE = ucol_IGetNextCE(coll, &temp, status); endCEBuffer = source->CEs + UCOL_EXPAND_CE_BUFFER_SIZE; while (CE != UCOL_NO_MORE_CES) { *(source->CEpos ++) = CE; if (source->CEpos == endCEBuffer) { /* ran out of CE space, bail. there's no guarantee of the right character position after this bail*/ *status = U_BUFFER_OVERFLOW_ERROR; source->CEpos = source->CEs; freeHeapWritableBuffer(&temp); if (strbuffer != buffer) { uprv_free(strbuffer); } return UCOL_NULLORDER; } CE = ucol_IGetNextCE(coll, &temp, status); } freeHeapWritableBuffer(&temp); if (strbuffer != buffer) { uprv_free(strbuffer); } source->toReturn = source->CEpos - 1; if (source->toReturn == source->CEs) { source->CEpos = source->CEs; } return *(source->toReturn); case LONG_PRIMARY_TAG: { *(source->CEpos++) = ((CE & 0xFFFF00) << 8) | (UCOL_BYTE_COMMON << 8) | UCOL_BYTE_COMMON; *(source->CEpos++) = ((CE & 0xFF)<<24)|UCOL_CONTINUATION_MARKER; source->toReturn = source->CEpos - 1; return *(source->toReturn); } case EXPANSION_TAG: /* this tag always returns */ /* This should handle expansion. NOTE: we can encounter both continuations and expansions in an expansion! I have to decide where continuations are going to be dealt with */ /* find the offset to expansion table */ CEOffset = (uint32_t *)coll->image + getExpansionOffset(CE); size = getExpansionCount(CE); if (size != 0) { /* if there are less than 16 elements in expansion, we don't terminate */ uint32_t count; for (count = 0; count < size; count++) { *(source->CEpos ++) = *CEOffset++; } } else { /* else, we do */ while (*CEOffset != 0) { *(source->CEpos ++) = *CEOffset ++; } } source->toReturn = source->CEpos - 1; // in case of one element expansion, we // want to immediately return CEpos if(source->toReturn == source->CEs) { source->CEpos = source->CEs; } return *(source->toReturn); case DIGIT_TAG: { /* We do a check to see if we want to collate digits as numbers; if so we generate a custom collation key. Otherwise we pull out the value stored in the expansion table. */ //uint32_t size; uint32_t i; /* general counter */ collIterateState state; if (source->coll->numericCollation == UCOL_ON){ UChar32 char32 = 0; uint32_t digIndx = 0; uint32_t endIndex = 0; uint32_t leadingZeroIndex = 0; uint32_t primWeight = 0; int32_t digVal = 0; uint8_t collateVal = 0; UBool nonZeroValReached = FALSE; uint8_t *numTempBuf; uint8_t stackNumTempBuf[UCOL_MAX_BUFFER]; // I just need a temporary place to store my generated CEs. uint32_t numTempBufSize = UCOL_MAX_BUFFER; numTempBuf = stackNumTempBuf; /* We parse the source string until we hit a char that's NOT a digit. Use this u_charDigitValue. This might be slow because we have to handle surrogates... */ if (U16_IS_TRAIL (ch)){ if (!collIter_bos(source)){ UChar lead = getPrevNormalizedChar(source); if(U16_IS_LEAD(lead)) { char32 = U16_GET_SUPPLEMENTARY(lead,ch); goBackOne(source); } else { char32 = ch; } } else { char32 = ch; } } else { char32 = ch; } digVal = u_charDigitValue(char32); for(;;){ // Make sure we have enough space. if (digIndx >= ((numTempBufSize - 2) * 2) + 1) { numTempBufSize *= 2; if (numTempBuf == stackNumTempBuf){ numTempBuf = (uint8_t *)uprv_malloc(sizeof(uint8_t) * numTempBufSize); uprv_memcpy(numTempBuf, stackNumTempBuf, UCOL_MAX_BUFFER); }else uprv_realloc(numTempBuf, numTempBufSize); } // Skipping over "trailing" zeroes but we still add to digIndx. if (digVal != 0 || nonZeroValReached){ if (digVal != 0 && !nonZeroValReached) nonZeroValReached = TRUE; /* We parse the digit string into base 100 numbers (this fits into a byte). We only add to the buffer in twos, thus if we are parsing an odd character, that serves as the 'tens' digit while the if we are parsing an even one, that is the 'ones' digit. We dumped the parsed base 100 value (collateVal) into a buffer. We multiply each collateVal by 2 (to give us room) and add 5 (to avoid overlapping magic CE byte values). The last byte we subtract 1 to ensure it is less than all the other bytes. Since we're doing in this reverse we want to put the first digit encountered into the ones place and the second digit encountered into the tens place. */ if (digIndx % 2 == 1){ collateVal += (uint8_t)(digVal * 10); // This removes leading zeroes. if (collateVal == 0 && !leadingZeroIndex) leadingZeroIndex = ((digIndx-1)/2) + 2; else if (leadingZeroIndex) leadingZeroIndex = 0; numTempBuf[((digIndx-1)/2) + 2] = collateVal*2 + 6; collateVal = 0; } else{ collateVal = (uint8_t)digVal; } } digIndx++; if (!collIter_bos(source)){ ch = getPrevNormalizedChar(source); //goBackOne(source); if (U16_IS_TRAIL(ch)){ backupState(source, &state); if (!collIter_bos(source)) { goBackOne(source); UChar lead = getPrevNormalizedChar(source); if(U16_IS_LEAD(lead)) { char32 = U16_GET_SUPPLEMENTARY(lead,ch); } else { loadState(source, &state, FALSE); char32 = ch; } } } else char32 = ch; if ((digVal = u_charDigitValue(char32)) == -1){ if (char32 > 0xFFFF) {// For surrogates. loadState(source, &state, FALSE); } // Don't need to "reverse" the goBackOne call, // as this points to the next position to process.. //if (char32 > 0xFFFF) // For surrogates. //getNextNormalizedChar(source); break; } goBackOne(source); }else break; } if (nonZeroValReached == FALSE){ digIndx = 2; numTempBuf[2] = 6; } if (digIndx % 2 != 0){ if (collateVal == 0 && leadingZeroIndex == 0) { // This removes the leading 0 in a odd number sequence of // numbers e.g. avery001 leadingZeroIndex = ((digIndx - 1) >> 1) + 2; } else { // this is not a leading 0, we add it in numTempBuf[((digIndx)/2) + 2] = collateVal*2 + 6; digIndx += 1; } } endIndex = leadingZeroIndex ? leadingZeroIndex : ((digIndx/2) + 2) ; digIndx = ((endIndex - 2) << 1) + 1; // removing initial zeros // Subtract one off of the last byte. Really the first byte here, but it's reversed... numTempBuf[2] -= 1; /* We want to skip over the first two slots in the buffer. The first slot is reserved for the header byte 0x1B. The second slot is for the sign/exponent byte: 0x80 + (decimalPos/2) & 7f. */ numTempBuf[0] = 0x1B; numTempBuf[1] = (uint8_t)(0x80 + ((digIndx/2) & 0x7F)); // Now transfer the collation key to our collIterate struct. // The total size for our collation key is endIndx bumped up to the next largest even value divided by two. //size = ((endIndex+1) & ~1)/2; *(source->CEpos++) = (((numTempBuf[0] << 8) | numTempBuf[1]) << UCOL_PRIMARYORDERSHIFT) | //Primary weight (UCOL_BYTE_COMMON << UCOL_SECONDARYORDERSHIFT) | // Secondary weight UCOL_BYTE_COMMON; // Tertiary weight. i = endIndex - 1; // Reset the index into the buffer. while(i >= 2) { primWeight = numTempBuf[i--] << 8; if ( i >= 2) primWeight |= numTempBuf[i--]; *(source->CEpos++) = (primWeight << UCOL_PRIMARYORDERSHIFT) | UCOL_CONTINUATION_MARKER; } if (numTempBuf != stackNumTempBuf) uprv_free(numTempBuf); source->toReturn = source->CEpos -1; return *(source->toReturn); } else { CEOffset = (uint32_t *)coll->image + getExpansionOffset(CE); CE = *(CEOffset++); break; #if 0 /* find the offset to expansion table */ CEOffset = (uint32_t *)coll->image + getExpansionOffset(CE); size = getExpansionCount(CE); if (size != 0) { /* if there are less than 16 elements in expansion, we don't terminate */ uint32_t count; for (count = 0; count < size; count++) { *(source->CEpos ++) = *CEOffset++; } } else { /* else, we do */ while (*CEOffset != 0) { *(source->CEpos ++) = *CEOffset ++; } } source->toReturn = source->CEpos - 1; // in case of one element expansion, we // want to immediately return CEpos if(source->toReturn == source->CEs) { source->CEpos = source->CEs; } return *(source->toReturn); #endif } } case HANGUL_SYLLABLE_TAG: /* AC00-D7AF*/ { const uint32_t SBase = 0xAC00, LBase = 0x1100, VBase = 0x1161, TBase = 0x11A7; //const uint32_t LCount = 19; const uint32_t VCount = 21; const uint32_t TCount = 28; //const uint32_t NCount = VCount * TCount; /* 588 */ //const uint32_t SCount = LCount * NCount; /* 11172 */ uint32_t L = ch - SBase; /* divide into pieces. we do it in this order since some compilers can do % and / in one operation */ uint32_t T = L % TCount; L /= TCount; uint32_t V = L % VCount; L /= VCount; /* offset them */ L += LBase; V += VBase; T += TBase; /* return the first CE, but first put the rest into the expansion buffer */ if (!source->coll->image->jamoSpecial) { /**(source->CEpos ++) = ucmpe32_get(UCA->mapping, L);*/ /**(source->CEpos++) = UTRIE_GET32_FROM_LEAD(UCA->mapping, L);*/ *(source->CEpos++) = UTRIE_GET32_FROM_LEAD(coll->mapping, L); /**(source->CEpos ++) = ucmpe32_get(UCA->mapping, V);*/ /**(source->CEpos++) = UTRIE_GET32_FROM_LEAD(UCA->mapping, V);*/ *(source->CEpos++) = UTRIE_GET32_FROM_LEAD(coll->mapping, V); if (T != TBase) /**(source->CEpos ++) = ucmpe32_get(UCA->mapping, T);*/ /**(source->CEpos++) = UTRIE_GET32_FROM_LEAD(UCA->mapping, T);*/ *(source->CEpos++) = UTRIE_GET32_FROM_LEAD(coll->mapping, T); source->toReturn = source->CEpos - 1; return *(source->toReturn); } else { // Since Hanguls pass the FCD check, it is // guaranteed that we won't be in // the normalization buffer if something like this happens // Move Jamos into normalization buffer /* Move the Jamos into the normalization buffer */ UChar *tempbuffer = source->writableBuffer + (source->writableBufSize - 1); *(tempbuffer) = 0; if (T != TBase) { *(tempbuffer - 1) = (UChar)T; *(tempbuffer - 2) = (UChar)V; *(tempbuffer - 3) = (UChar)L; *(tempbuffer - 4) = 0; } else { *(tempbuffer - 1) = (UChar)V; *(tempbuffer - 2) = (UChar)L; *(tempbuffer - 3) = 0; } /* Indicate where to continue in main input string after exhausting the writableBuffer */ if (source->pos == source->string) { source->fcdPosition = NULL; } else { source->fcdPosition = source->pos-1; } source->pos = tempbuffer; source->origFlags = source->flags; source->flags |= UCOL_ITER_INNORMBUF; source->flags &= ~(UCOL_ITER_NORM | UCOL_ITER_HASLEN); return(UCOL_IGNORABLE); } } case LEAD_SURROGATE_TAG: /* D800-DBFF*/ return 0; /* broken surrogate sequence */ case TRAIL_SURROGATE_TAG: /* DC00-DFFF*/ { UChar32 cp = 0; UChar prevChar; UChar *prev; if (isAtStartPrevIterate(source)) { /* we are at the start of the string, wrong place to be at */ return 0; } if (source->pos != source->writableBuffer) { prev = source->pos - 1; } else { prev = source->fcdPosition; } prevChar = *prev; /* Handles Han and Supplementary characters here.*/ if (UTF_IS_FIRST_SURROGATE(prevChar)) { cp = ((((uint32_t)prevChar)<<10UL)+(ch)-(((uint32_t)0xd800<<10UL)+0xdc00-0x10000)); source->pos = prev; } else { return 0; /* completely ignorable */ } return getPrevImplicit(cp, source); } // TODO: Remove CJK implicits as they are handled by the getImplicitPrimary function case CJK_IMPLICIT_TAG: /* 0x3400-0x4DB5, 0x4E00-0x9FA5, 0xF900-0xFA2D*/ return getPrevImplicit(ch, source); case IMPLICIT_TAG: /* everything that is not defined otherwise */ return getPrevImplicit(ch, source); /* UCA is filled with these. Tailorings are NOT_FOUND */ /* not yet implemented */ case CHARSET_TAG: /* this tag always returns */ /* probably after 1.8 */ return UCOL_NOT_FOUND; default: /* this tag always returns */ *status = U_INTERNAL_PROGRAM_ERROR; CE=0; break; } if (CE <= UCOL_NOT_FOUND) { break; } } return CE; } /* This should really be a macro */ /* However, it is used only when stack buffers are not sufficiently big, and then we're messed up performance wise */ /* anyway */ static uint8_t *reallocateBuffer(uint8_t **secondaries, uint8_t *secStart, uint8_t *second, uint32_t *secSize, uint32_t newSize, UErrorCode *status) { #ifdef UCOL_DEBUG fprintf(stderr, "."); #endif uint8_t *newStart = NULL; uint32_t offset = *secondaries-secStart; if(secStart==second) { newStart=(uint8_t*)uprv_malloc(newSize); if(newStart==NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } uprv_memcpy(newStart, secStart, *secondaries-secStart); } else { newStart=(uint8_t*)uprv_realloc(secStart, newSize); if(newStart==NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } } *secondaries=newStart+offset; *secSize=newSize; return newStart; } /* This should really be a macro */ /* This function is used to reverse parts of a buffer. We need this operation when doing continuation */ /* secondaries in French */ /* void uprv_ucol_reverse_buffer(uint8_t *start, uint8_t *end) { uint8_t temp; while(start0 && src1[src1Length-1]!=0) || src2==NULL || src2Length<-2 || src2Length==0 || (src2Length>0 && src2[src2Length-1]!=0) || destCapacity<0 || (destCapacity>0 && dest==NULL) ) { /* error, attempt to write a zero byte and return 0 */ if(dest!=NULL && destCapacity>0) { *dest=0; } return 0; } /* check lengths and capacity */ if(src1Length<0) { src1Length=(int32_t)uprv_strlen((const char *)src1)+1; } if(src2Length<0) { src2Length=(int32_t)uprv_strlen((const char *)src2)+1; } destLength=src1Length+src2Length-1; if(destLength>destCapacity) { /* the merged sort key does not fit into the destination */ return destLength; } /* merge the sort keys with the same number of levels */ while(*src1!=0 && *src2!=0) { /* while both have another level */ /* copy level from src1 not including 00 or 01 */ while((b=*src1)>=2) { ++src1; *dest++=b; } /* add a 02 merge separator */ *dest++=2; /* copy level from src2 not including 00 or 01 */ while((b=*src2)>=2) { ++src2; *dest++=b; } /* if both sort keys have another level, then add a 01 level separator and continue */ if(*src1==1 && *src2==1) { ++src1; ++src2; *dest++=1; } } /* * here, at least one sort key is finished now, but the other one * might have some contents left from containing more levels; * that contents is just appended to the result */ if(*src1!=0) { /* src1 is not finished, therefore *src2==0, and src1 is appended */ src2=src1; } /* append src2, "the other, unfinished sort key" */ uprv_strcpy((char *)dest, (const char *)src2); /* trust that neither sort key contained illegally embedded zero bytes */ return destLength; } /* sortkey API */ U_CAPI int32_t U_EXPORT2 ucol_getSortKey(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t *result, int32_t resultLength) { UTRACE_ENTRY(UTRACE_UCOL_GET_SORTKEY); if (UTRACE_LEVEL(UTRACE_VERBOSE)) { int32_t actualSrcLen = sourceLength; if (actualSrcLen==-1 && source!=NULL) { actualSrcLen = u_strlen(source); } UTRACE_DATA3(UTRACE_VERBOSE, "coll=%p, source string = %vh ", coll, source, actualSrcLen); } UErrorCode status = U_ZERO_ERROR; int32_t keySize = 0; if(source != NULL) { // source == NULL is actually an error situation, but we would need to // have an error code to return it. Until we introduce a new // API, it stays like this /* this uses the function pointer that is set in updateinternalstate */ /* currently, there are two funcs: */ /*ucol_calcSortKey(...);*/ /*ucol_calcSortKeySimpleTertiary(...);*/ keySize = coll->sortKeyGen(coll, source, sourceLength, &result, resultLength, FALSE, &status); //((UCollator *)coll)->errorCode = status; /*semantically const */ } UTRACE_DATA2(UTRACE_VERBOSE, "Sort Key = %vb", result, keySize); UTRACE_EXIT_STATUS(status); return keySize; } /* this function is called by the C++ API for sortkey generation */ U_CFUNC int32_t ucol_getSortKeyWithAllocation(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **pResult, UErrorCode *pErrorCode) { *pResult = 0; return coll->sortKeyGen(coll, source, sourceLength, pResult, 0, TRUE, pErrorCode); } #define UCOL_FSEC_BUF_SIZE 256 /* This function tries to get the size of a sortkey. It will be invoked if the size of resulting buffer is 0 */ /* or if we run out of space while making a sortkey and want to return ASAP */ int32_t ucol_getSortKeySize(const UCollator *coll, collIterate *s, int32_t currentSize, UColAttributeValue strength, int32_t len) { UErrorCode status = U_ZERO_ERROR; const UCAConstants *UCAconsts = (UCAConstants *)((uint8_t *)coll->UCA->image + coll->image->UCAConsts); uint8_t compareSec = (uint8_t)((strength >= UCOL_SECONDARY)?0:0xFF); uint8_t compareTer = (uint8_t)((strength >= UCOL_TERTIARY)?0:0xFF); uint8_t compareQuad = (uint8_t)((strength >= UCOL_QUATERNARY)?0:0xFF); UBool compareIdent = (strength == UCOL_IDENTICAL); UBool doCase = (coll->caseLevel == UCOL_ON); UBool shifted = (coll->alternateHandling == UCOL_SHIFTED); //UBool qShifted = shifted && (compareQuad == 0); UBool doHiragana = (coll->hiraganaQ == UCOL_ON) && (compareQuad == 0); UBool isFrenchSec = (coll->frenchCollation == UCOL_ON) && (compareSec == 0); uint8_t fSecsBuff[UCOL_FSEC_BUF_SIZE]; uint8_t *fSecs = fSecsBuff; uint32_t fSecsLen = 0, fSecsMaxLen = UCOL_FSEC_BUF_SIZE; uint8_t *frenchStartPtr = NULL, *frenchEndPtr = NULL; uint32_t variableTopValue = coll->variableTopValue; uint8_t UCOL_COMMON_BOT4 = (uint8_t)((coll->variableTopValue>>8)+1); if(doHiragana) { UCOL_COMMON_BOT4++; /* allocate one more space for hiragana */ } uint8_t UCOL_BOT_COUNT4 = (uint8_t)(0xFF - UCOL_COMMON_BOT4); uint32_t order = UCOL_NO_MORE_CES; uint8_t primary1 = 0; uint8_t primary2 = 0; uint8_t secondary = 0; uint8_t tertiary = 0; int32_t caseShift = 0; uint32_t c2 = 0, c3 = 0, c4 = 0; /* variables for compression */ uint8_t caseSwitch = coll->caseSwitch; uint8_t tertiaryMask = coll->tertiaryMask; uint8_t tertiaryCommon = coll->tertiaryCommon; UBool wasShifted = FALSE; UBool notIsContinuation = FALSE; uint8_t leadPrimary = 0; for(;;) { order = ucol_IGetNextCE(coll, s, &status); if(order == UCOL_NO_MORE_CES) { break; } if(order == 0) { continue; } notIsContinuation = !isContinuation(order); if(notIsContinuation) { tertiary = (uint8_t)((order & UCOL_BYTE_SIZE_MASK)); } else { tertiary = (uint8_t)((order & UCOL_REMOVE_CONTINUATION)); } secondary = (uint8_t)((order >>= 8) & UCOL_BYTE_SIZE_MASK); primary2 = (uint8_t)((order >>= 8) & UCOL_BYTE_SIZE_MASK); primary1 = (uint8_t)(order >> 8); if(shifted && ((notIsContinuation && order <= variableTopValue && primary1 > 0) || (!notIsContinuation && wasShifted)) || (wasShifted && primary1 == 0)) { /* amendment to the UCA says that primary ignorables */ /* and other ignorables should be removed if following a shifted code point */ if(primary1 == 0) { /* if we were shifted and we got an ignorable code point */ /* we should just completely ignore it */ continue; } if(compareQuad == 0) { if(c4 > 0) { currentSize += (c2/UCOL_BOT_COUNT4)+1; c4 = 0; } currentSize++; if(primary2 != 0) { currentSize++; } } wasShifted = TRUE; } else { wasShifted = FALSE; /* Note: This code assumes that the table is well built i.e. not having 0 bytes where they are not supposed to be. */ /* Usually, we'll have non-zero primary1 & primary2, except in cases of LatinOne and friends, when primary2 will */ /* calculate sortkey size */ if(primary1 != UCOL_IGNORABLE) { if(notIsContinuation) { if(leadPrimary == primary1) { currentSize++; } else { if(leadPrimary != 0) { currentSize++; } if(primary2 == UCOL_IGNORABLE) { /* one byter, not compressed */ currentSize++; leadPrimary = 0; } else if(primary1 (UCOL_RESET_TOP_VALUE>>24) && primary1 < (UCOL_NEXT_TOP_VALUE>>24))) { (primary1 > (*UCAconsts->UCA_LAST_NON_VARIABLE>>24) && primary1 < (*UCAconsts->UCA_FIRST_IMPLICIT>>24))) { /* not compressible */ leadPrimary = 0; currentSize+=2; } else { /* compress */ leadPrimary = primary1; currentSize+=2; } } } else { /* we are in continuation, so we're gonna add primary to the key don't care about compression */ currentSize++; if(primary2 != UCOL_IGNORABLE) { currentSize++; } } } if(secondary > compareSec) { /* I think that != 0 test should be != IGNORABLE */ if(!isFrenchSec){ if (secondary == UCOL_COMMON2 && notIsContinuation) { c2++; } else { if(c2 > 0) { if (secondary > UCOL_COMMON2) { // not necessary for 4th level. currentSize += (c2/(uint32_t)UCOL_TOP_COUNT2)+1; } else { currentSize += (c2/(uint32_t)UCOL_BOT_COUNT2)+1; } c2 = 0; } currentSize++; } } else { fSecs[fSecsLen++] = secondary; if(fSecsLen == fSecsMaxLen) { if(fSecs == fSecsBuff) { fSecs = (uint8_t *)uprv_malloc(2*fSecsLen); } else { fSecs = (uint8_t *)uprv_realloc(fSecs, 2*fSecsLen); } if(fSecs == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return -1; } fSecsMaxLen *= 2; } if(notIsContinuation) { if (frenchStartPtr != NULL) { /* reverse secondaries from frenchStartPtr up to frenchEndPtr */ uprv_ucol_reverse_buffer(uint8_t, frenchStartPtr, frenchEndPtr); frenchStartPtr = NULL; } } else { if (frenchStartPtr == NULL) { frenchStartPtr = fSecs+fSecsLen-2; } frenchEndPtr = fSecs+fSecsLen-1; } } } if(doCase) { if (caseShift == 0) { currentSize++; caseShift = UCOL_CASE_SHIFT_START; } if((tertiary&0x3F) > 0 && notIsContinuation) { caseShift--; if((tertiary &0xC0) != 0) { if (caseShift == 0) { currentSize++; caseShift = UCOL_CASE_SHIFT_START; } caseShift--; } } } else { if(notIsContinuation) { tertiary ^= caseSwitch; } } tertiary &= tertiaryMask; if(tertiary > compareTer) { /* I think that != 0 test should be != IGNORABLE */ if (tertiary == tertiaryCommon && notIsContinuation) { c3++; } else { if(c3 > 0) { if((tertiary > tertiaryCommon && tertiaryCommon == UCOL_COMMON3_NORMAL) || (tertiary <= tertiaryCommon && tertiaryCommon == UCOL_COMMON3_UPPERFIRST)) { currentSize += (c3/(uint32_t)coll->tertiaryTopCount)+1; } else { currentSize += (c3/(uint32_t)coll->tertiaryBottomCount)+1; } c3 = 0; } currentSize++; } } if(/*qShifted*/(compareQuad==0) && notIsContinuation) { if(s->flags & UCOL_WAS_HIRAGANA) { // This was Hiragana and we need to note it if(c4>0) { // Close this part currentSize += (c4/UCOL_BOT_COUNT4)+1; c4 = 0; } currentSize++; // Add the Hiragana } else { // This wasn't Hiragana, so we can continue adding stuff c4++; } } } } if(!isFrenchSec){ if(c2 > 0) { currentSize += (c2/(uint32_t)UCOL_BOT_COUNT2)+((c2%(uint32_t)UCOL_BOT_COUNT2 != 0)?1:0); } } else { uint32_t i = 0; if(frenchStartPtr != NULL) { uprv_ucol_reverse_buffer(uint8_t, frenchStartPtr, frenchEndPtr); } for(i = 0; i 0) { if (secondary > UCOL_COMMON2) { // not necessary for 4th level. currentSize += (c2/(uint32_t)UCOL_TOP_COUNT2)+((c2%(uint32_t)UCOL_TOP_COUNT2 != 0)?1:0); } else { currentSize += (c2/(uint32_t)UCOL_BOT_COUNT2)+((c2%(uint32_t)UCOL_BOT_COUNT2 != 0)?1:0); } c2 = 0; } currentSize++; } } if(c2 > 0) { currentSize += (c2/(uint32_t)UCOL_BOT_COUNT2)+((c2%(uint32_t)UCOL_BOT_COUNT2 != 0)?1:0); } if(fSecs != fSecsBuff) { uprv_free(fSecs); } } if(c3 > 0) { currentSize += (c3/(uint32_t)coll->tertiaryBottomCount) + ((c3%(uint32_t)coll->tertiaryBottomCount != 0)?1:0); } if(c4 > 0 && compareQuad == 0) { currentSize += (c4/(uint32_t)UCOL_BOT_COUNT4)+((c4%(uint32_t)UCOL_BOT_COUNT4 != 0)?1:0); } if(compareIdent) { currentSize += u_lengthOfIdenticalLevelRun(s->string, len); } return currentSize; } static inline void doCaseShift(uint8_t **cases, uint32_t &caseShift) { if (caseShift == 0) { *(*cases)++ = UCOL_CASE_BYTE_START; caseShift = UCOL_CASE_SHIFT_START; } } // Adds a value to the buffer if it's safe to add. Increments the number of added values, so that we // know how many values we wanted to add, even if we didn't add them all static inline void addWithIncrement(uint8_t *&primaries, uint8_t *limit, uint32_t &size, const uint8_t value) { size++; if(primaries < limit) { *(primaries)++ = value; } } // Packs the secondary buffer when processing French locale. Adds the terminator. static inline uint8_t *packFrench(uint8_t *primaries, uint8_t *primEnd, uint8_t *secondaries, uint32_t *secsize, uint8_t *frenchStartPtr, uint8_t *frenchEndPtr) { uint8_t secondary; int32_t count2 = 0; uint32_t i = 0, size = 0; // we use i here since the key size already accounts for terminators, so we'll discard the increment addWithIncrement(primaries, primEnd, i, UCOL_LEVELTERMINATOR); /* If there are any unresolved continuation secondaries, reverse them here so that we can reverse the whole secondary thing */ if(frenchStartPtr != NULL) { uprv_ucol_reverse_buffer(uint8_t, frenchStartPtr, frenchEndPtr); } for(i = 0; i<*secsize; i++) { secondary = *(secondaries-i-1); /* This is compression code. */ if (secondary == UCOL_COMMON2) { ++count2; } else { if (count2 > 0) { if (secondary > UCOL_COMMON2) { // not necessary for 4th level. while (count2 > UCOL_TOP_COUNT2) { addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_TOP2 - UCOL_TOP_COUNT2)); count2 -= (uint32_t)UCOL_TOP_COUNT2; } addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_TOP2 - (count2-1))); } else { while (count2 > UCOL_BOT_COUNT2) { addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2)); count2 -= (uint32_t)UCOL_BOT_COUNT2; } addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_BOT2 + (count2-1))); } count2 = 0; } addWithIncrement(primaries, primEnd, size, secondary); } } if (count2 > 0) { while (count2 > UCOL_BOT_COUNT2) { addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2)); count2 -= (uint32_t)UCOL_BOT_COUNT2; } addWithIncrement(primaries, primEnd, size, (uint8_t)(UCOL_COMMON_BOT2 + (count2-1))); } *secsize = size; return primaries; } /* This is the sortkey work horse function */ U_CFUNC int32_t U_CALLCONV ucol_calcSortKey(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **result, uint32_t resultLength, UBool allocateSKBuffer, UErrorCode *status) { const UCAConstants *UCAconsts = (UCAConstants *)((uint8_t *)coll->UCA->image + coll->image->UCAConsts); uint32_t i = 0; /* general purpose counter */ /* Stack allocated buffers for buffers we use */ uint8_t prim[UCOL_PRIMARY_MAX_BUFFER], second[UCOL_SECONDARY_MAX_BUFFER], tert[UCOL_TERTIARY_MAX_BUFFER], caseB[UCOL_CASE_MAX_BUFFER], quad[UCOL_QUAD_MAX_BUFFER]; uint8_t *primaries = *result, *secondaries = second, *tertiaries = tert, *cases = caseB, *quads = quad; if(U_FAILURE(*status)) { return 0; } if(primaries == NULL && allocateSKBuffer == TRUE) { primaries = *result = prim; resultLength = UCOL_PRIMARY_MAX_BUFFER; } uint32_t secSize = UCOL_SECONDARY_MAX_BUFFER, terSize = UCOL_TERTIARY_MAX_BUFFER, caseSize = UCOL_CASE_MAX_BUFFER, quadSize = UCOL_QUAD_MAX_BUFFER; uint32_t sortKeySize = 1; /* it is always \0 terminated */ UChar normBuffer[UCOL_NORMALIZATION_MAX_BUFFER]; UChar *normSource = normBuffer; int32_t normSourceLen = UCOL_NORMALIZATION_MAX_BUFFER; int32_t len = (sourceLength == -1 ? u_strlen(source) : sourceLength); UColAttributeValue strength = coll->strength; uint8_t compareSec = (uint8_t)((strength >= UCOL_SECONDARY)?0:0xFF); uint8_t compareTer = (uint8_t)((strength >= UCOL_TERTIARY)?0:0xFF); uint8_t compareQuad = (uint8_t)((strength >= UCOL_QUATERNARY)?0:0xFF); UBool compareIdent = (strength == UCOL_IDENTICAL); UBool doCase = (coll->caseLevel == UCOL_ON); UBool isFrenchSec = (coll->frenchCollation == UCOL_ON) && (compareSec == 0); UBool shifted = (coll->alternateHandling == UCOL_SHIFTED); //UBool qShifted = shifted && (compareQuad == 0); UBool doHiragana = (coll->hiraganaQ == UCOL_ON) && (compareQuad == 0); const uint8_t *scriptOrder = coll->scriptOrder; uint32_t variableTopValue = coll->variableTopValue; // TODO: UCOL_COMMON_BOT4 should be a function of qShifted. If we have no // qShifted, we don't need to set UCOL_COMMON_BOT4 so high. uint8_t UCOL_COMMON_BOT4 = (uint8_t)((coll->variableTopValue>>8)+1); uint8_t UCOL_HIRAGANA_QUAD = 0; if(doHiragana) { UCOL_HIRAGANA_QUAD=UCOL_COMMON_BOT4++; /* allocate one more space for hiragana, value for hiragana */ } uint8_t UCOL_BOT_COUNT4 = (uint8_t)(0xFF - UCOL_COMMON_BOT4); /* support for special features like caselevel and funky secondaries */ uint8_t *frenchStartPtr = NULL; uint8_t *frenchEndPtr = NULL; uint32_t caseShift = 0; sortKeySize += ((compareSec?0:1) + (compareTer?0:1) + (doCase?1:0) + /*(qShifted?1:0)*/(compareQuad?0:1) + (compareIdent?1:0)); /* If we need to normalize, we'll do it all at once at the beginning! */ UNormalizationMode normMode; if(compareIdent) { normMode = UNORM_NFD; } else if(coll->normalizationMode != UCOL_OFF) { normMode = UNORM_FCD; } else { normMode = UNORM_NONE; } if(normMode != UNORM_NONE && UNORM_YES != unorm_quickCheck(source, len, normMode, status)) { len = unorm_internalNormalize(normSource, normSourceLen, source, len, normMode, FALSE, status); if(*status == U_BUFFER_OVERFLOW_ERROR) { normSourceLen = len; normSource = (UChar *)uprv_malloc(len*U_SIZEOF_UCHAR); if(normSource == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } *status = U_ZERO_ERROR; len = unorm_internalNormalize(normSource, normSourceLen, source, len, normMode, FALSE, status); } if(U_FAILURE(*status)) { return 0; } source = normSource; } collIterate s; IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } if(resultLength == 0 || primaries == NULL) { int32_t keyLen = ucol_getSortKeySize(coll, &s, sortKeySize, strength, len); if(normSource != normBuffer) { uprv_free(normSource); } return keyLen; } uint8_t *primarySafeEnd = primaries + resultLength - 2; uint32_t minBufferSize = UCOL_MAX_BUFFER; uint8_t *primStart = primaries; uint8_t *secStart = secondaries; uint8_t *terStart = tertiaries; uint8_t *caseStart = cases; uint8_t *quadStart = quads; uint32_t order = 0; uint8_t primary1 = 0; uint8_t primary2 = 0; uint8_t secondary = 0; uint8_t tertiary = 0; uint8_t caseSwitch = coll->caseSwitch; uint8_t tertiaryMask = coll->tertiaryMask; int8_t tertiaryAddition = (int8_t)coll->tertiaryAddition; uint8_t tertiaryTop = coll->tertiaryTop; uint8_t tertiaryBottom = coll->tertiaryBottom; uint8_t tertiaryCommon = coll->tertiaryCommon; uint8_t caseBits = 0; UBool finished = FALSE; UBool wasShifted = FALSE; UBool notIsContinuation = FALSE; uint32_t prevBuffSize = 0; uint32_t count2 = 0, count3 = 0, count4 = 0; uint8_t leadPrimary = 0; for(;;) { for(i=prevBuffSize; i>= 8) & UCOL_BYTE_SIZE_MASK); primary2 = (uint8_t)((order >>= 8) & UCOL_BYTE_SIZE_MASK); primary1 = (uint8_t)(order >> 8); if(notIsContinuation) { if(scriptOrder != NULL) { primary1 = scriptOrder[primary1]; } } if(shifted && ((notIsContinuation && order <= variableTopValue && primary1 > 0) || (!notIsContinuation && wasShifted)) || (wasShifted && primary1 == 0)) { /* amendment to the UCA says that primary ignorables */ /* and other ignorables should be removed if following a shifted code point */ if(primary1 == 0) { /* if we were shifted and we got an ignorable code point */ /* we should just completely ignore it */ continue; } if(compareQuad == 0) { if(count4 > 0) { while (count4 > UCOL_BOT_COUNT4) { *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + UCOL_BOT_COUNT4); count4 -= UCOL_BOT_COUNT4; } *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + (count4-1)); count4 = 0; } /* We are dealing with a variable and we're treating them as shifted */ /* This is a shifted ignorable */ if(primary1 != 0) { /* we need to check this since we could be in continuation */ *quads++ = primary1; } if(primary2 != 0) { *quads++ = primary2; } } wasShifted = TRUE; } else { wasShifted = FALSE; /* Note: This code assumes that the table is well built i.e. not having 0 bytes where they are not supposed to be. */ /* Usually, we'll have non-zero primary1 & primary2, except in cases of LatinOne and friends, when primary2 will */ /* regular and simple sortkey calc */ if(primary1 != UCOL_IGNORABLE) { if(notIsContinuation) { if(leadPrimary == primary1) { *primaries++ = primary2; } else { if(leadPrimary != 0) { *primaries++ = (uint8_t)((primary1 > leadPrimary) ? UCOL_BYTE_UNSHIFTED_MAX : UCOL_BYTE_UNSHIFTED_MIN); } if(primary2 == UCOL_IGNORABLE) { /* one byter, not compressed */ *primaries++ = primary1; leadPrimary = 0; } else if(primary1 (*UCAconsts->UCA_LAST_NON_VARIABLE>>24) && primary1 < (*UCAconsts->UCA_FIRST_IMPLICIT>>24))) { /* not compressible */ leadPrimary = 0; *primaries++ = primary1; *primaries++ = primary2; } else { /* compress */ *primaries++ = leadPrimary = primary1; *primaries++ = primary2; } } } else { /* we are in continuation, so we're gonna add primary to the key don't care about compression */ *primaries++ = primary1; if(primary2 != UCOL_IGNORABLE) { *primaries++ = primary2; /* second part */ } } } if(secondary > compareSec) { if(!isFrenchSec) { /* This is compression code. */ if (secondary == UCOL_COMMON2 && notIsContinuation) { ++count2; } else { if (count2 > 0) { if (secondary > UCOL_COMMON2) { // not necessary for 4th level. while (count2 > UCOL_TOP_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_TOP2 - UCOL_TOP_COUNT2); count2 -= (uint32_t)UCOL_TOP_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_TOP2 - (count2-1)); } else { while (count2 > UCOL_BOT_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2); count2 -= (uint32_t)UCOL_BOT_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + (count2-1)); } count2 = 0; } *secondaries++ = secondary; } } else { *secondaries++ = secondary; /* Do the special handling for French secondaries */ /* We need to get continuation elements and do intermediate restore */ /* abc1c2c3de with french secondaries need to be edc1c2c3ba NOT edc3c2c1ba */ if(notIsContinuation) { if (frenchStartPtr != NULL) { /* reverse secondaries from frenchStartPtr up to frenchEndPtr */ uprv_ucol_reverse_buffer(uint8_t, frenchStartPtr, frenchEndPtr); frenchStartPtr = NULL; } } else { if (frenchStartPtr == NULL) { frenchStartPtr = secondaries - 2; } frenchEndPtr = secondaries-1; } } } if(doCase) { doCaseShift(&cases, caseShift); if(notIsContinuation) { caseBits = (uint8_t)(tertiary & 0xC0); if(tertiary != 0) { if(coll->caseFirst == UCOL_UPPER_FIRST) { if((caseBits & 0xC0) == 0) { *(cases-1) |= 1 << (--caseShift); } else { *(cases-1) |= 0 << (--caseShift); /* second bit */ doCaseShift(&cases, caseShift); *(cases-1) |= ((caseBits>>6)&1) << (--caseShift); } } else { if((caseBits & 0xC0) == 0) { *(cases-1) |= 0 << (--caseShift); } else { *(cases-1) |= 1 << (--caseShift); /* second bit */ doCaseShift(&cases, caseShift); *(cases-1) |= ((caseBits>>7)&1) << (--caseShift); } } } } } else { if(notIsContinuation) { tertiary ^= caseSwitch; } } tertiary &= tertiaryMask; if(tertiary > compareTer) { /* This is compression code. */ /* sequence size check is included in the if clause */ if (tertiary == tertiaryCommon && notIsContinuation) { ++count3; } else { if((tertiary > tertiaryCommon && tertiaryCommon == UCOL_COMMON3_NORMAL) || (tertiary <= tertiaryCommon && tertiaryCommon == UCOL_COMMON3_UPPERFIRST)) { tertiary += tertiaryAddition; } if (count3 > 0) { if ((tertiary > tertiaryCommon)) { while (count3 > coll->tertiaryTopCount) { *tertiaries++ = (uint8_t)(tertiaryTop - coll->tertiaryTopCount); count3 -= (uint32_t)coll->tertiaryTopCount; } *tertiaries++ = (uint8_t)(tertiaryTop - (count3-1)); } else { while (count3 > coll->tertiaryBottomCount) { *tertiaries++ = (uint8_t)(tertiaryBottom + coll->tertiaryBottomCount); count3 -= (uint32_t)coll->tertiaryBottomCount; } *tertiaries++ = (uint8_t)(tertiaryBottom + (count3-1)); } count3 = 0; } *tertiaries++ = tertiary; } } if(/*qShifted*/(compareQuad==0) && notIsContinuation) { if(s.flags & UCOL_WAS_HIRAGANA) { // This was Hiragana and we need to note it if(count4>0) { // Close this part while (count4 > UCOL_BOT_COUNT4) { *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + UCOL_BOT_COUNT4); count4 -= UCOL_BOT_COUNT4; } *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + (count4-1)); count4 = 0; } *quads++ = UCOL_HIRAGANA_QUAD; // Add the Hiragana } else { // This wasn't Hiragana, so we can continue adding stuff count4++; } } } if(primaries > primarySafeEnd) { /* We have stepped over the primary buffer */ if(allocateSKBuffer == FALSE) { /* need to save our butts if we cannot reallocate */ IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, strength, len); *status = U_BUFFER_OVERFLOW_ERROR; finished = TRUE; break; } else { /* It's much nicer if we can actually reallocate */ int32_t sks = sortKeySize+(primaries - primStart)+(secondaries - secStart)+(tertiaries - terStart)+(cases-caseStart)+(quads-quadStart); primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sks, status); if(U_SUCCESS(*status)) { *result = primStart; primarySafeEnd = primStart + resultLength - 2; } else { IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, strength, len); finished = TRUE; break; } } } } if(finished) { break; } else { prevBuffSize = minBufferSize; secStart = reallocateBuffer(&secondaries, secStart, second, &secSize, 2*secSize, status); terStart = reallocateBuffer(&tertiaries, terStart, tert, &terSize, 2*terSize, status); caseStart = reallocateBuffer(&cases, caseStart, caseB, &caseSize, 2*caseSize, status); quadStart = reallocateBuffer(&quads, quadStart, quad, &quadSize, 2*quadSize, status); minBufferSize *= 2; if(U_FAILURE(*status)) { // if we cannot reallocate buffers, we can at least give the sortkey size IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, strength, len); break; } } } /* Here, we are generally done with processing */ /* bailing out would not be too productive */ if(U_SUCCESS(*status)) { sortKeySize += (primaries - primStart); /* we have done all the CE's, now let's put them together to form a key */ if(compareSec == 0) { if (count2 > 0) { while (count2 > UCOL_BOT_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2); count2 -= (uint32_t)UCOL_BOT_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + (count2-1)); } uint32_t secsize = secondaries-secStart; if(!isFrenchSec) { // Regular situation, we know the length of secondaries sortKeySize += secsize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, secStart, secsize); primaries += secsize; } else { if(allocateSKBuffer == TRUE) { /* need to save our butts if we cannot reallocate */ primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, secStart, secsize); primaries += secsize; } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } } else { // French secondary is on. We will need to pack French. packFrench will add the level terminator uint8_t *newPrim = packFrench(primaries, primStart+resultLength, secondaries, &secsize, frenchStartPtr, frenchEndPtr); sortKeySize += secsize; if(sortKeySize <= resultLength) { // if we managed to pack fine primaries = newPrim; // update the primary pointer } else { // overflow, need to reallocate and redo if(allocateSKBuffer == TRUE) { /* need to save our butts if we cannot reallocate */ primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { primaries = packFrench(primaries, primStart+resultLength, secondaries, &secsize, frenchStartPtr, frenchEndPtr); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } } } if(doCase) { uint32_t casesize = cases - caseStart; sortKeySize += casesize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, caseStart, casesize); primaries += casesize; } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, caseStart, casesize); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } } if(compareTer == 0) { if (count3 > 0) { if (coll->tertiaryCommon != UCOL_COMMON_BOT3) { while (count3 >= coll->tertiaryTopCount) { *tertiaries++ = (uint8_t)(tertiaryTop - coll->tertiaryTopCount); count3 -= (uint32_t)coll->tertiaryTopCount; } *tertiaries++ = (uint8_t)(tertiaryTop - count3); } else { while (count3 > coll->tertiaryBottomCount) { *tertiaries++ = (uint8_t)(tertiaryBottom + coll->tertiaryBottomCount); count3 -= (uint32_t)coll->tertiaryBottomCount; } *tertiaries++ = (uint8_t)(tertiaryBottom + (count3-1)); } } uint32_t tersize = tertiaries - terStart; sortKeySize += tersize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, terStart, tersize); primaries += tersize; } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, terStart, tersize); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } if(compareQuad == 0/*qShifted == TRUE*/) { if(count4 > 0) { while (count4 > UCOL_BOT_COUNT4) { *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + UCOL_BOT_COUNT4); count4 -= UCOL_BOT_COUNT4; } *quads++ = (uint8_t)(UCOL_COMMON_BOT4 + (count4-1)); } uint32_t quadsize = quads - quadStart; sortKeySize += quadsize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, quadStart, quadsize); primaries += quadsize; } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, quadStart, quadsize); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } } if(compareIdent) { sortKeySize += u_lengthOfIdenticalLevelRun(s.string, len); if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; primaries += u_writeIdenticalLevelRun(s.string, len, primaries); } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; u_writeIdenticalLevelRun(s.string, len, primaries); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } } } *(primaries++) = '\0'; } if(terStart != tert) { uprv_free(terStart); uprv_free(secStart); uprv_free(caseStart); uprv_free(quadStart); } if(normSource != normBuffer) { uprv_free(normSource); } if(allocateSKBuffer == TRUE) { *result = (uint8_t*)uprv_malloc(sortKeySize); /* test for NULL */ if (*result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return sortKeySize; } uprv_memcpy(*result, primStart, sortKeySize); if(primStart != prim) { uprv_free(primStart); } } return sortKeySize; } U_CFUNC int32_t U_CALLCONV ucol_calcSortKeySimpleTertiary(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **result, uint32_t resultLength, UBool allocateSKBuffer, UErrorCode *status) { U_ALIGN_CODE(16); const UCAConstants *UCAconsts = (UCAConstants *)((uint8_t *)coll->UCA->image + coll->image->UCAConsts); uint32_t i = 0; /* general purpose counter */ /* Stack allocated buffers for buffers we use */ uint8_t prim[UCOL_PRIMARY_MAX_BUFFER], second[UCOL_SECONDARY_MAX_BUFFER], tert[UCOL_TERTIARY_MAX_BUFFER]; uint8_t *primaries = *result, *secondaries = second, *tertiaries = tert; if(U_FAILURE(*status)) { return 0; } if(primaries == NULL && allocateSKBuffer == TRUE) { primaries = *result = prim; resultLength = UCOL_PRIMARY_MAX_BUFFER; } uint32_t secSize = UCOL_SECONDARY_MAX_BUFFER, terSize = UCOL_TERTIARY_MAX_BUFFER; uint32_t sortKeySize = 3; /* it is always \0 terminated plus separators for secondary and tertiary */ UChar normBuffer[UCOL_NORMALIZATION_MAX_BUFFER]; UChar *normSource = normBuffer; int32_t normSourceLen = UCOL_NORMALIZATION_MAX_BUFFER; int32_t len = sourceLength; /* If we need to normalize, we'll do it all at once at the beginning! */ if(coll->normalizationMode != UCOL_OFF && UNORM_YES != unorm_quickCheck(source, len, UNORM_FCD, status)) { len = unorm_internalNormalize(normSource, normSourceLen, source, len, UNORM_FCD, FALSE, status); if(*status == U_BUFFER_OVERFLOW_ERROR) { normSourceLen = len; normSource = (UChar *)uprv_malloc(len*U_SIZEOF_UCHAR); if(normSource == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } *status = U_ZERO_ERROR; len = unorm_internalNormalize(normSource, normSourceLen, source, len, UNORM_FCD, FALSE, status); } if(U_FAILURE(*status)) { return 0; } source = normSource; } collIterate s; IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } if(resultLength == 0 || primaries == NULL) { int32_t t = ucol_getSortKeySize(coll, &s, sortKeySize, coll->strength, len); if(normSource != normBuffer) { uprv_free(normSource); } return t; } uint8_t *primarySafeEnd = primaries + resultLength - 2; uint32_t minBufferSize = UCOL_MAX_BUFFER; uint8_t *primStart = primaries; uint8_t *secStart = secondaries; uint8_t *terStart = tertiaries; uint32_t order = 0; uint8_t primary1 = 0; uint8_t primary2 = 0; uint8_t secondary = 0; uint8_t tertiary = 0; uint8_t caseSwitch = coll->caseSwitch; uint8_t tertiaryMask = coll->tertiaryMask; int8_t tertiaryAddition = (int8_t)coll->tertiaryAddition; uint8_t tertiaryTop = coll->tertiaryTop; uint8_t tertiaryBottom = coll->tertiaryBottom; uint8_t tertiaryCommon = coll->tertiaryCommon; uint32_t prevBuffSize = 0; UBool finished = FALSE; UBool notIsContinuation = FALSE; uint32_t count2 = 0, count3 = 0; uint8_t leadPrimary = 0; for(;;) { for(i=prevBuffSize; i>= 8) & UCOL_BYTE_SIZE_MASK); primary2 = (uint8_t)((order >>= 8) & UCOL_BYTE_SIZE_MASK); primary1 = (uint8_t)(order >> 8); /* Note: This code assumes that the table is well built i.e. not having 0 bytes where they are not supposed to be. */ /* Usually, we'll have non-zero primary1 & primary2, except in cases of LatinOne and friends, when primary2 will */ /* be zero with non zero primary1. primary3 is different than 0 only for long primaries - see above. */ /* regular and simple sortkey calc */ if(primary1 != UCOL_IGNORABLE) { if(notIsContinuation) { if(leadPrimary == primary1) { *primaries++ = primary2; } else { if(leadPrimary != 0) { *primaries++ = (uint8_t)((primary1 > leadPrimary) ? UCOL_BYTE_UNSHIFTED_MAX : UCOL_BYTE_UNSHIFTED_MIN); } if(primary2 == UCOL_IGNORABLE) { /* one byter, not compressed */ *primaries++ = primary1; leadPrimary = 0; } else if(primary1 (UCOL_RESET_TOP_VALUE>>24) && primary1 < (UCOL_NEXT_TOP_VALUE>>24))) (primary1 > (*UCAconsts->UCA_LAST_NON_VARIABLE>>24) && primary1 < (*UCAconsts->UCA_FIRST_IMPLICIT>>24))) { /* not compressible */ leadPrimary = 0; *primaries++ = primary1; *primaries++ = primary2; } else { /* compress */ *primaries++ = leadPrimary = primary1; *primaries++ = primary2; } } } else { /* we are in continuation, so we're gonna add primary to the key don't care about compression */ *primaries++ = primary1; if(primary2 != UCOL_IGNORABLE) { *primaries++ = primary2; /* second part */ } } } if(secondary > 0) { /* I think that != 0 test should be != IGNORABLE */ /* This is compression code. */ if (secondary == UCOL_COMMON2 && notIsContinuation) { ++count2; } else { if (count2 > 0) { if (secondary > UCOL_COMMON2) { // not necessary for 4th level. while (count2 > UCOL_TOP_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_TOP2 - UCOL_TOP_COUNT2); count2 -= (uint32_t)UCOL_TOP_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_TOP2 - (count2-1)); } else { while (count2 > UCOL_BOT_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2); count2 -= (uint32_t)UCOL_BOT_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + (count2-1)); } count2 = 0; } *secondaries++ = secondary; } } if(notIsContinuation) { tertiary ^= caseSwitch; } if(tertiary > 0) { /* This is compression code. */ /* sequence size check is included in the if clause */ if (tertiary == tertiaryCommon && notIsContinuation) { ++count3; } else { if(tertiary > tertiaryCommon && tertiaryCommon == UCOL_COMMON3_NORMAL) { tertiary += tertiaryAddition; } else if (tertiary <= tertiaryCommon && tertiaryCommon == UCOL_COMMON3_UPPERFIRST) { tertiary -= tertiaryAddition; } if (count3 > 0) { if ((tertiary > tertiaryCommon)) { while (count3 > coll->tertiaryTopCount) { *tertiaries++ = (uint8_t)(tertiaryTop - coll->tertiaryTopCount); count3 -= (uint32_t)coll->tertiaryTopCount; } *tertiaries++ = (uint8_t)(tertiaryTop - (count3-1)); } else { while (count3 > coll->tertiaryBottomCount) { *tertiaries++ = (uint8_t)(tertiaryBottom + coll->tertiaryBottomCount); count3 -= (uint32_t)coll->tertiaryBottomCount; } *tertiaries++ = (uint8_t)(tertiaryBottom + (count3-1)); } count3 = 0; } *tertiaries++ = tertiary; } } if(primaries > primarySafeEnd) { /* We have stepped over the primary buffer */ if(allocateSKBuffer == FALSE) { /* need to save our butts if we cannot reallocate */ IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, coll->strength, len); *status = U_BUFFER_OVERFLOW_ERROR; finished = TRUE; break; } else { /* It's much nicer if we can actually reallocate */ int32_t sks = sortKeySize+(primaries - primStart)+(secondaries - secStart)+(tertiaries - terStart); primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sks, status); if(U_SUCCESS(*status)) { *result = primStart; primarySafeEnd = primStart + resultLength - 2; } else { IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, coll->strength, len); finished = TRUE; break; } } } } if(finished) { break; } else { prevBuffSize = minBufferSize; secStart = reallocateBuffer(&secondaries, secStart, second, &secSize, 2*secSize, status); terStart = reallocateBuffer(&tertiaries, terStart, tert, &terSize, 2*terSize, status); minBufferSize *= 2; if(U_FAILURE(*status)) { // if we cannot reallocate buffers, we can at least give the sortkey size IInit_collIterate(coll, (UChar *)source, len, &s); if(source == normSource) { s.flags &= ~UCOL_ITER_NORM; } sortKeySize = ucol_getSortKeySize(coll, &s, sortKeySize, coll->strength, len); break; } } } if(U_SUCCESS(*status)) { sortKeySize += (primaries - primStart); /* we have done all the CE's, now let's put them together to form a key */ if (count2 > 0) { while (count2 > UCOL_BOT_COUNT2) { *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + UCOL_BOT_COUNT2); count2 -= (uint32_t)UCOL_BOT_COUNT2; } *secondaries++ = (uint8_t)(UCOL_COMMON_BOT2 + (count2-1)); } uint32_t secsize = secondaries-secStart; sortKeySize += secsize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, secStart, secsize); primaries += secsize; } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *(primaries++) = UCOL_LEVELTERMINATOR; *result = primStart; uprv_memcpy(primaries, secStart, secsize); } } else { *status = U_BUFFER_OVERFLOW_ERROR; } } if (count3 > 0) { if (coll->tertiaryCommon != UCOL_COMMON3_NORMAL) { while (count3 >= coll->tertiaryTopCount) { *tertiaries++ = (uint8_t)(tertiaryTop - coll->tertiaryTopCount); count3 -= (uint32_t)coll->tertiaryTopCount; } *tertiaries++ = (uint8_t)(tertiaryTop - count3); } else { while (count3 > coll->tertiaryBottomCount) { *tertiaries++ = (uint8_t)(tertiaryBottom + coll->tertiaryBottomCount); count3 -= (uint32_t)coll->tertiaryBottomCount; } *tertiaries++ = (uint8_t)(tertiaryBottom + (count3-1)); } } uint32_t tersize = tertiaries - terStart; sortKeySize += tersize; if(sortKeySize <= resultLength) { *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, terStart, tersize); primaries += tersize; } else { if(allocateSKBuffer == TRUE) { primStart = reallocateBuffer(&primaries, *result, prim, &resultLength, 2*sortKeySize, status); if(U_SUCCESS(*status)) { *result = primStart; *(primaries++) = UCOL_LEVELTERMINATOR; uprv_memcpy(primaries, terStart, tersize); } } else { *status = U_MEMORY_ALLOCATION_ERROR; } } *(primaries++) = '\0'; } if(terStart != tert) { uprv_free(terStart); uprv_free(secStart); } if(normSource != normBuffer) { uprv_free(normSource); } if(allocateSKBuffer == TRUE) { *result = (uint8_t*)uprv_malloc(sortKeySize); /* test for NULL */ if (*result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return sortKeySize; } uprv_memcpy(*result, primStart, sortKeySize); if(primStart != prim) { uprv_free(primStart); } } return sortKeySize; } static inline UBool isShiftedCE(uint32_t CE, uint32_t LVT, UBool *wasShifted) { UBool notIsContinuation = !isContinuation(CE); uint8_t primary1 = (uint8_t)((CE >> 24) & 0xFF); if(LVT && ((notIsContinuation && (CE & 0xFFFF0000)<= LVT && primary1 > 0) || (!notIsContinuation && *wasShifted)) || (*wasShifted && primary1 == 0)) { /* amendment to the UCA says that primary ignorables */ // The stuff below should probably be in the sortkey code... maybe not... if(primary1 != 0) { /* if we were shifted and we got an ignorable code point */ /* we should just completely ignore it */ *wasShifted = TRUE; //continue; } //*wasShifted = TRUE; return TRUE; } else { *wasShifted = FALSE; return FALSE; } } static inline void terminatePSKLevel(int32_t level, int32_t maxLevel, int32_t &i, uint8_t *dest) { if(level < maxLevel) { dest[i++] = UCOL_LEVELTERMINATOR; } else { dest[i++] = 0; } } /** enumeration of level identifiers for partial sort key generation */ enum { UCOL_PSK_PRIMARY = 0, UCOL_PSK_SECONDARY = 1, UCOL_PSK_CASE = 2, UCOL_PSK_TERTIARY = 3, UCOL_PSK_QUATERNARY = 4, UCOL_PSK_QUIN = 5, /** This is an extra level, not used - but we have three bits to blow */ UCOL_PSK_IDENTICAL = 6, UCOL_PSK_NULL = 7, /** level for the end of sort key. Will just produce zeros */ UCOL_PSK_LIMIT }; /** collation state enum. *_SHIFT value is how much to shift right * to get the state piece to the right. *_MASK value should be * ANDed with the shifted state. This data is stored in state[1] * field. */ enum { UCOL_PSK_LEVEL_SHIFT = 0, /** level identificator. stores an enum value from above */ UCOL_PSK_LEVEL_MASK = 7, /** three bits */ UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_SHIFT = 3, /** number of bytes of primary or quaternary already written */ UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_MASK = 1, /** can be only 0 or 1, since we get up to two bytes from primary or quaternary * This field is also used to denote that the French secondary level is finished */ UCOL_PSK_WAS_SHIFTED_SHIFT = 4,/** was the last value shifted */ UCOL_PSK_WAS_SHIFTED_MASK = 1, /** can be 0 or 1 (Boolean) */ UCOL_PSK_USED_FRENCH_SHIFT = 5,/** how many French bytes have we already written */ UCOL_PSK_USED_FRENCH_MASK = 3, /** up to 4 bytes. See comment just below */ /** When we do French we need to reverse secondary values. However, continuations * need to stay the same. So if you had abc1c2c3de, you need to have edc1c2c3ba */ UCOL_PSK_USED_ELEMENTS_SHIFT = 7, UCOL_PSK_USED_ELEMENTS_MASK = 0x3FF, UCOL_PSK_ITER_SKIP_SHIFT = 17, UCOL_PSK_ITER_SKIP_MASK = 0x7FFF }; /** main sortkey part procedure. On the first call, * you should pass in a collator, an iterator, empty state * state[0] == state[1] == 0, a buffer to hold results * number of bytes you need and an error code pointer. * Make sure your buffer is big enough to hold the wanted * number of sortkey bytes. I don't check. * The only meaningful status you can get back is * U_BUFFER_OVERFLOW_ERROR, which basically means that you * have been dealt a raw deal and that you probably won't * be able to use partial sortkey generation for this * particular combination of string and collator. This * is highly unlikely, but you should still check the error code. * Any other status means that you're not in a sane situation * anymore. After the first call, preserve state values and * use them on subsequent calls to obtain more bytes of a sortkey. * Use until the number of bytes written is smaller than the requested * number of bytes. Generated sortkey is not compatible with the * one generated by ucol_getSortKey, as we don't do any compression. * However, levels are still terminated by a 1 (one) and the sortkey * is terminated by a 0 (zero). Identical level is the same as in the * regular sortkey - internal bocu-1 implementation is used. * For curious, although you cannot do much about this, here is * the structure of state words. * state[0] - iterator state. Depends on the iterator implementation, * but allows the iterator to continue where it stopped in * the last iteration. * state[1] - collation processing state. Here is the distribution * of the bits: * 0, 1, 2 - level of the sortkey - primary, secondary, case, tertiary * quaternary, quin (we don't use this one), identical and * null (producing only zeroes - first one to terminate the * sortkey and subsequent to fill the buffer). * 3 - byte count. Number of bytes written on the primary level. * 4 - was shifted. Whether the previous iteration finished in the * shifted state. * 5, 6 - French continuation bytes written. See the comment in the enum * 7..16 - Used elements. Number of CEs that were already used from the * expansion buffer or number of bytes from a bocu sequence on * the identical level. * 17..31 - iterator skip. Number of move operations iterator needs to * skip from the current state in order to continue. This is used * only if normalization is turned on, since the normalizing iterator * can return undefined state, which means that it's in the middle * of normalizing sequence. */ U_CAPI int32_t U_EXPORT2 ucol_nextSortKeyPart(const UCollator *coll, UCharIterator *iter, uint32_t state[2], uint8_t *dest, int32_t count, UErrorCode *status) { /* error checking */ if(status==NULL || U_FAILURE(*status)) { return 0; } UTRACE_ENTRY(UTRACE_UCOL_NEXTSORTKEYPART); if( coll==NULL || iter==NULL || state==NULL || count<0 || (count>0 && dest==NULL) ) { *status=U_ILLEGAL_ARGUMENT_ERROR; } UTRACE_DATA6(UTRACE_VERBOSE, "coll=%p, iter=%p, state=%d %d, dest=%p, count=%d", coll, iter, state[0], state[1], dest, count); if(count==0) { /* nothing to do */ UTRACE_EXIT_VALUE(0); return 0; } /** Setting up situation according to the state we got from the previous iteration */ // The state of the iterator from the previous invocation uint32_t iterState = state[0]; // Has the last iteration ended in the shifted state UBool wasShifted = ((state[1] >> UCOL_PSK_WAS_SHIFTED_SHIFT) & UCOL_PSK_WAS_SHIFTED_MASK)?TRUE:FALSE; // What is the current level of the sortkey? int32_t level= (state[1] >> UCOL_PSK_LEVEL_SHIFT) & UCOL_PSK_LEVEL_MASK; // Have we written only one byte from a two byte primary in the previous iteration? // Also on secondary level - have we finished with the French secondary? int32_t byteCountOrFrenchDone = (state[1] >> UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_SHIFT) & UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_MASK; // number of bytes in the continuation buffer for French int32_t usedFrench = (state[1] >> UCOL_PSK_USED_FRENCH_SHIFT) & UCOL_PSK_USED_FRENCH_MASK; // Skip the CEs that we got from an extraction // and delivered in the previous call int32_t usedElements = (state[1] >> UCOL_PSK_USED_ELEMENTS_SHIFT) & UCOL_PSK_USED_ELEMENTS_MASK; // Number of times to skip because the iterator returned // UITER_NO_STATE when it was stopped in the last iteration, so we had to save the // last valid state. int32_t iterSkips = (state[1] >> UCOL_PSK_ITER_SKIP_SHIFT) & UCOL_PSK_ITER_SKIP_MASK; /** values that depend on the collator attributes */ // strength of the collator. int32_t strength = ucol_getAttribute(coll, UCOL_STRENGTH, status); // maximal level of the partial sortkey. Need to take whether case level is done int32_t maxLevel = 0; if(strength < UCOL_TERTIARY) { if(ucol_getAttribute(coll, UCOL_CASE_LEVEL, status) == UCOL_ON) { maxLevel = UCOL_PSK_CASE; } else { maxLevel = strength; } } else { if(strength == UCOL_TERTIARY) { maxLevel = UCOL_PSK_TERTIARY; } else if(strength == UCOL_QUATERNARY) { maxLevel = UCOL_PSK_QUATERNARY; } else { // identical maxLevel = UCOL_IDENTICAL; } } // value for the quaternary level if Hiragana is encountered. Used for JIS X 4061 collation uint8_t UCOL_HIRAGANA_QUAD = (ucol_getAttribute(coll, UCOL_HIRAGANA_QUATERNARY_MODE, status) == UCOL_ON)?0xFE:0xFF; // Boundary value that decides whether a CE is shifted or not uint32_t LVT = (coll->alternateHandling == UCOL_SHIFTED)?(coll->variableTopValue<<16):0; // Are we doing French collation? UBool doingFrench = (ucol_getAttribute(coll, UCOL_FRENCH_COLLATION, status) == UCOL_ON); /** initializing the collation state */ UBool notIsContinuation = FALSE; uint32_t CE = UCOL_NO_MORE_CES; collIterate s; IInit_collIterate(coll, NULL, -1, &s); s.iterator = iter; s.flags |= UCOL_USE_ITERATOR; // This variable tells us whether we have produced some other levels in this iteration // before we moved to the identical level. In that case, we need to switch the // type of the iterator. UBool doingIdenticalFromStart = FALSE; // Normalizing iterator // The division for the array length may truncate the array size to // a little less than UNORM_ITER_SIZE, but that size is dimensioned too high // for all platforms anyway. UAlignedMemory stackNormIter[UNORM_ITER_SIZE/sizeof(UAlignedMemory)]; UNormIterator *normIter = NULL; // If the normalization is turned on for the collator and we are below identical level // we will use a FCD normalizing iterator if(ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, status) == UCOL_ON && level < UCOL_PSK_IDENTICAL) { normIter = unorm_openIter(stackNormIter, sizeof(stackNormIter), status); s.iterator = unorm_setIter(normIter, iter, UNORM_FCD, status); s.flags &= ~UCOL_ITER_NORM; if(U_FAILURE(*status)) { UTRACE_EXIT_STATUS(*status); return 0; } } else if(level == UCOL_PSK_IDENTICAL) { // for identical level, we need a NFD iterator. We need to instantiate it here, since we // will be updating the state - and this cannot be done on an ordinary iterator. normIter = unorm_openIter(stackNormIter, sizeof(stackNormIter), status); s.iterator = unorm_setIter(normIter, iter, UNORM_NFD, status); s.flags &= ~UCOL_ITER_NORM; if(U_FAILURE(*status)) { UTRACE_EXIT_STATUS(*status); return 0; } doingIdenticalFromStart = TRUE; } // This is the tentative new state of the iterator. The problem // is that the iterator might return an undefined state, in // which case we should save the last valid state and increase // the iterator skip value. uint32_t newState = 0; // First, we set the iterator to the last valid position // from the last iteration. This was saved in state[0]. if(iterState == 0) { /* initial state */ if(level == UCOL_PSK_SECONDARY && doingFrench && !byteCountOrFrenchDone) { s.iterator->move(s.iterator, 0, UITER_LIMIT); } else { s.iterator->move(s.iterator, 0, UITER_START); } } else { /* reset to previous state */ s.iterator->setState(s.iterator, iterState, status); if(U_FAILURE(*status)) { UTRACE_EXIT_STATUS(*status); return 0; } } // Then, we may have to move more, if the normalizing iterator // was going through a normalizing sequence. if(iterSkips) { // if we are on secondary level AND we do French, we need to go backward instead of forward if(level == UCOL_PSK_SECONDARY && doingFrench) { s.iterator->move(s.iterator, -iterSkips, UITER_CURRENT); } else { s.iterator->move(s.iterator, iterSkips, UITER_CURRENT); } } // Number of expansion CEs that were already consumed in the // previous iteration for the last code point processed. We // want to clean out the expansion buffer, so that we can // get correct CEs. This value is persistent over iterations, // since we can have several iterations on the one expansion // buffer. int32_t consumedExpansionCEs = usedElements; // Number of bytes already writted from a bocsu sequence. Since // the longes bocsu sequence is 4 long, this can be up to 3. It // shares the state field with consumedExpansionCEs value, since // they cannot simultanously appear on the same level int32_t bocsuBytesUsed = 0; // Clean out the expansion buffer unless we are on // identical level. In that case we use this field // to store the number of bytes already written // from the previous bocsu sequence. if(level < UCOL_PSK_IDENTICAL && usedElements != 0) { while(usedElements-->0) { // If we're doing French and we are on the secondary level, // we go backwards. if(level == UCOL_PSK_SECONDARY && doingFrench) { CE = ucol_IGetPrevCE(coll, &s, status); } else { CE = ucol_IGetNextCE(coll, &s, status); } if(CE==UCOL_NO_MORE_CES) { /* should not happen */ *status=U_INTERNAL_PROGRAM_ERROR; UTRACE_EXIT_STATUS(*status); return 0; } } } else { bocsuBytesUsed = usedElements; } // This variable prevents the adjusting of iterator // skip variable when we are the first time on a // level. I hope there is a better way to do it, but // I could not think of it. UBool firstTimeOnLevel = TRUE; // French secondary needs to know whether the iterator state of zero came from previous level OR // from a new invocation... UBool wasDoingPrimary = FALSE; // Case level is kind of goofy. This variable tells us that // we are still not done with the case level. UBool dontAdvanceIteratorBecauseWeNeedALevelTerminator = FALSE; // destination buffer byte counter. When this guy // gets to count, we're done with the iteration int32_t i = 0; // used to count the zero bytes written after we // have finished with the sort key int32_t j = 0; // Hm.... I think we're ready to plunge in. Basic story is as following: // we have a fall through case based on level. This is used for initial // positioning on iteration start. Every level processor contains a // for(;;) which will be broken when we exhaust all the CEs. Other // way to exit is a goto saveState, which happens when we have filled // out our buffer. switch(level) { case UCOL_PSK_PRIMARY: wasDoingPrimary = TRUE; for(;;) { if(i==count) { goto saveState; } // We should save the state only if we // are sure that we are done with the // previous iterator state if(consumedExpansionCEs == 0 && byteCountOrFrenchDone == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel && !byteCountOrFrenchDone) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetNextCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); byteCountOrFrenchDone=0; // Restart the iteration an move to the // second level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_SECONDARY; break; } if(!isShiftedCE(CE, LVT, &wasShifted)) { CE >>= UCOL_PRIMARYORDERSHIFT; /* get primary */ if(CE != 0) { if(byteCountOrFrenchDone == 0) { // get the second byte of primary dest[i++]=(uint8_t)(CE >> 8); } else { byteCountOrFrenchDone = 0; } if((CE &=0xff)!=0) { if(i==count) { /* overflow */ byteCountOrFrenchDone=1; goto saveState; } dest[i++]=(uint8_t)CE; } } } if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { // s.pos != NULL means there is a normalization buffer in effect // in iterative case, this means that we are doing Thai (maybe discontiguos) consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { // maybe it is the end of Thai - we have to have // an extra skip iterSkips++; } } /* fall through to next level */ case UCOL_PSK_SECONDARY: if(strength >= UCOL_SECONDARY) { if(!doingFrench) { for(;;) { if(i == count) { goto saveState; } // We should save the state only if we // are sure that we are done with the // previous iterator state if(consumedExpansionCEs == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetNextCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); byteCountOrFrenchDone=0; // Restart the iteration an move to the // second level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_CASE; break; } if(!isShiftedCE(CE, LVT, &wasShifted)) { CE >>= 8; /* get secondary */ if(CE != 0) { dest[i++]=(uint8_t)CE; } } if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { iterSkips++; } } } else { // French secondary processing uint8_t frenchBuff[UCOL_MAX_BUFFER]; int32_t frenchIndex = 0; // Here we are going backwards. // If the iterator is at the beggining, it should be // moved to end. if(wasDoingPrimary) { s.iterator->move(s.iterator, 0, UITER_LIMIT); } for(;;) { if(i == count) { goto saveState; } if(consumedExpansionCEs == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetPrevCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); byteCountOrFrenchDone=0; // Restart the iteration an move to the next level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_CASE; break; } if(isContinuation(CE)) { // if it's a continuation, we want to save it and // reverse when we get a first non-continuation CE. CE >>= 8; frenchBuff[frenchIndex++] = (uint8_t)CE; } else if(!isShiftedCE(CE, LVT, &wasShifted)) { CE >>= 8; /* get secondary */ if(!frenchIndex) { if(CE != 0) { dest[i++]=(uint8_t)CE; } } else { frenchBuff[frenchIndex++] = (uint8_t)CE; frenchIndex -= usedFrench; usedFrench = 0; while(i < count && frenchIndex) { dest[i++] = frenchBuff[--frenchIndex]; usedFrench++; } } } if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { iterSkips++; } } } } else { level = UCOL_PSK_CASE; } /* fall through to next level */ case UCOL_PSK_CASE: if(ucol_getAttribute(coll, UCOL_CASE_LEVEL, status) == UCOL_ON) { uint32_t caseShift = UCOL_CASE_SHIFT_START; uint8_t caseByte = UCOL_CASE_BYTE_START; uint8_t caseBits = 0; for(;;) { if(i == count) { goto saveState; } // We should save the state only if we // are sure that we are done with the // previous iterator state if(consumedExpansionCEs == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetNextCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // On the case level we might have an unfinished // case byte. Add one if it's started. if(caseShift != UCOL_CASE_SHIFT_START) { dest[i++] = caseByte; } // This is kind of tricky - situation where // we need to keep the iterator in the old // state, but don't need to bring anything // to the next invocation if(i < count) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); // Restart the iteration and move to the // next level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_TERTIARY; } else { dontAdvanceIteratorBecauseWeNeedALevelTerminator = TRUE; } break; } if(!isShiftedCE(CE, LVT, &wasShifted)) { if(!isContinuation(CE)) { CE = (uint8_t)(CE & UCOL_BYTE_SIZE_MASK); caseBits = (uint8_t)(CE & 0xC0); // this copies the case level logic from the // sort key generation code if(CE != 0) { if(coll->caseFirst == UCOL_UPPER_FIRST) { if((caseBits & 0xC0) == 0) { caseByte |= 1 << (--caseShift); } else { caseByte |= 0 << (--caseShift); /* second bit */ if(caseShift == 0) { dest[i++] = caseByte; caseShift = UCOL_CASE_SHIFT_START; caseByte = UCOL_CASE_BYTE_START; } caseByte |= ((caseBits>>6)&1) << (--caseShift); } } else { if((caseBits & 0xC0) == 0) { caseByte |= 0 << (--caseShift); } else { caseByte |= 1 << (--caseShift); /* second bit */ if(caseShift == 0) { dest[i++] = caseByte; caseShift = UCOL_CASE_SHIFT_START; caseByte = UCOL_CASE_BYTE_START; } caseByte |= ((caseBits>>7)&1) << (--caseShift); } } } } } // Not sure this is correct for the case level - revisit if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { iterSkips++; } } } else { level = UCOL_PSK_TERTIARY; } /* fall through to next level */ case UCOL_PSK_TERTIARY: if(strength >= UCOL_TERTIARY) { for(;;) { if(i == count) { goto saveState; } // We should save the state only if we // are sure that we are done with the // previous iterator state if(consumedExpansionCEs == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetNextCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); byteCountOrFrenchDone=0; // Restart the iteration an move to the // second level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_QUATERNARY; break; } if(!isShiftedCE(CE, LVT, &wasShifted)) { notIsContinuation = !isContinuation(CE); if(notIsContinuation) { CE = (uint8_t)(CE & UCOL_BYTE_SIZE_MASK); CE ^= coll->caseSwitch; CE &= coll->tertiaryMask; } else { CE = (uint8_t)((CE & UCOL_REMOVE_CONTINUATION)); } if(CE != 0) { dest[i++]=(uint8_t)CE; } } if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { iterSkips++; } } } else { // if we're not doing tertiary // skip to the end level = UCOL_PSK_NULL; } /* fall through to next level */ case UCOL_PSK_QUATERNARY: if(strength >= UCOL_QUATERNARY) { for(;;) { if(i == count) { goto saveState; } // We should save the state only if we // are sure that we are done with the // previous iterator state if(consumedExpansionCEs == 0) { newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { if(!firstTimeOnLevel) { iterSkips++; } } } firstTimeOnLevel = FALSE; CE = ucol_IGetNextCE(coll, &s, status); if(CE==UCOL_NO_MORE_CES) { // Add the level separator terminatePSKLevel(level, maxLevel, i, dest); //dest[i++] = UCOL_LEVELTERMINATOR; byteCountOrFrenchDone=0; // Restart the iteration an move to the // second level s.iterator->move(s.iterator, 0, UITER_START); level = UCOL_PSK_QUIN; break; } if(isShiftedCE(CE, LVT, &wasShifted)) { CE >>= 16; /* get primary */ if(CE != 0) { if(byteCountOrFrenchDone == 0) { dest[i++]=(uint8_t)(CE >> 8); } else { byteCountOrFrenchDone = 0; } if((CE &=0xff)!=0) { if(i==count) { /* overflow */ byteCountOrFrenchDone=1; goto saveState; } dest[i++]=(uint8_t)CE; } } } else { notIsContinuation = !isContinuation(CE); if(notIsContinuation) { if(s.flags & UCOL_WAS_HIRAGANA) { // This was Hiragana and we need to note it dest[i++] = UCOL_HIRAGANA_QUAD; } else { dest[i++] = 0xFF; } } } if(s.CEpos - s.toReturn || (s.pos && *s.pos != 0)) { consumedExpansionCEs++; } else { consumedExpansionCEs = 0; } if(s.pos && *s.pos == 0) { iterSkips++; } } } else { // if we're not doing quaternary // skip to the end level = UCOL_PSK_NULL; } /* fall through to next level */ case UCOL_PSK_QUIN: level = UCOL_PSK_IDENTICAL; /* fall through to next level */ case UCOL_PSK_IDENTICAL: if(strength >= UCOL_IDENTICAL) { UChar32 first, second; int32_t bocsuBytesWritten = 0; // We always need to do identical on // the NFD form of the string. if(normIter == NULL) { // we arrived from the level below and // normalization was not turned on. // therefore, we need to make a fresh NFD iterator normIter = unorm_openIter(stackNormIter, sizeof(stackNormIter), status); s.iterator = unorm_setIter(normIter, iter, UNORM_NFD, status); } else if(!doingIdenticalFromStart) { // there is an iterator, but we did some other levels. // therefore, we have a FCD iterator - need to make // a NFD one. // normIter being at the beginning does not guarantee // that the underlying iterator is at the beginning iter->move(iter, 0, UITER_START); s.iterator = unorm_setIter(normIter, iter, UNORM_NFD, status); } // At this point we have a NFD iterator that is positioned // in the right place if(U_FAILURE(*status)) { UTRACE_EXIT_STATUS(*status); return 0; } first = uiter_previous32(s.iterator); // maybe we're at the start of the string if(first == U_SENTINEL) { first = 0; } else { uiter_next32(s.iterator); } j = 0; for(;;) { if(i == count) { if(j+1 < bocsuBytesWritten) { bocsuBytesUsed = j+1; } goto saveState; } // On identical level, we will always save // the state if we reach this point, since // we don't depend on getNextCE for content // all the content is in our buffer and we // already either stored the full buffer OR // otherwise we won't arrive here. newState = s.iterator->getState(s.iterator); if(newState != UITER_NO_STATE) { iterState = newState; iterSkips = 0; } else { iterSkips++; } uint8_t buff[4]; second = uiter_next32(s.iterator); // end condition for identical level if(second == U_SENTINEL) { terminatePSKLevel(level, maxLevel, i, dest); level = UCOL_PSK_NULL; break; } bocsuBytesWritten = u_writeIdenticalLevelRunTwoChars(first, second, buff); first = second; j = 0; if(bocsuBytesUsed != 0) { while(bocsuBytesUsed-->0) { j++; } } while(i < count && j < bocsuBytesWritten) { dest[i++] = buff[j++]; } } } else { level = UCOL_PSK_NULL; } /* fall through to next level */ case UCOL_PSK_NULL: j = i; while(jgetState(s.iterator))!= UITER_NO_STATE) { state[0] = s.iterator->getState(s.iterator); iterSkips = 0; } else { state[0] = iterState; iterSkips++; } } // Store the number of elements processed. On CE levels, this is // the number of expansion CEs processed. On identical level, this // is the number of bocsu bytes written. if(level < UCOL_PSK_IDENTICAL) { if((consumedExpansionCEs & UCOL_PSK_USED_ELEMENTS_MASK) != consumedExpansionCEs) { *status = U_INDEX_OUTOFBOUNDS_ERROR; } state[1] = (consumedExpansionCEs & UCOL_PSK_USED_ELEMENTS_MASK) << UCOL_PSK_USED_ELEMENTS_SHIFT; } else { if((bocsuBytesUsed & UCOL_PSK_USED_ELEMENTS_MASK) != bocsuBytesUsed) { *status = U_INDEX_OUTOFBOUNDS_ERROR; } state[1] = (bocsuBytesUsed & UCOL_PSK_USED_ELEMENTS_MASK) << UCOL_PSK_USED_ELEMENTS_SHIFT; } // Next we put in the level of comparison state[1] |= ((level & UCOL_PSK_LEVEL_MASK) << UCOL_PSK_LEVEL_SHIFT); // If we are doing French, we need to store whether we have just finished the French level if(level == UCOL_PSK_SECONDARY && doingFrench) { state[1] |= (((state[0] == 0) & UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_MASK) << UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_SHIFT); } else { state[1] |= ((byteCountOrFrenchDone & UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_MASK) << UCOL_PSK_BYTE_COUNT_OR_FRENCH_DONE_SHIFT); } // Was the latest CE shifted if(wasShifted) { state[1] |= 1 << UCOL_PSK_WAS_SHIFTED_SHIFT; } // Check for iterSkips overflow if((iterSkips & UCOL_PSK_ITER_SKIP_MASK) != iterSkips) { *status = U_INDEX_OUTOFBOUNDS_ERROR; } // Store iterSkips state[1] |= ((iterSkips & UCOL_PSK_ITER_SKIP_MASK) << UCOL_PSK_ITER_SKIP_SHIFT); // Check for French overflow if((usedFrench & UCOL_PSK_USED_FRENCH_MASK) != usedFrench) { *status = U_INDEX_OUTOFBOUNDS_ERROR; } // Store number of bytes written in the French secondary continuation sequence state[1] |= ((usedFrench & UCOL_PSK_USED_FRENCH_MASK) << UCOL_PSK_USED_FRENCH_SHIFT); // If we have used normalizing iterator, get rid of it if(normIter != NULL) { unorm_closeIter(normIter); } // Return number of meaningful sortkey bytes. UTRACE_DATA4(UTRACE_VERBOSE, "dest = %vb, state=%d %d", dest,i, state[0], state[1]); UTRACE_EXIT_VALUE(i); return i; } /** * Produce a bound for a given sortkey and a number of levels. */ U_CAPI int32_t U_EXPORT2 ucol_getBound(const uint8_t *source, int32_t sourceLength, UColBoundMode boundType, uint32_t noOfLevels, uint8_t *result, int32_t resultLength, UErrorCode *status) { // consistency checks if(status == NULL || U_FAILURE(*status)) { return 0; } if(source == NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } int32_t sourceIndex = 0; // Scan the string until we skip enough of the key OR reach the end of the key do { sourceIndex++; if(source[sourceIndex] == UCOL_LEVELTERMINATOR) { noOfLevels--; } } while (noOfLevels > 0 && (source[sourceIndex] != 0 || sourceIndex < sourceLength)); if((source[sourceIndex] == 0 || sourceIndex == sourceLength) && noOfLevels > 0) { *status = U_SORT_KEY_TOO_SHORT_WARNING; } // READ ME: this code assumes that the values for boundType // enum will not changes. They are set so that the enum value // corresponds to the number of extra bytes each bound type // needs. if(result != NULL && resultLength >= sourceIndex+boundType) { uprv_memcpy(result, source, sourceIndex); switch(boundType) { // Lower bound just gets terminated. No extra bytes case UCOL_BOUND_LOWER: // = 0 break; // Upper bound needs one extra byte case UCOL_BOUND_UPPER: // = 1 result[sourceIndex++] = 2; break; // Upper long bound needs two extra bytes case UCOL_BOUND_UPPER_LONG: // = 2 result[sourceIndex++] = 0xFF; result[sourceIndex++] = 0xFF; break; default: *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } result[sourceIndex++] = 0; return sourceIndex; } else { return sourceIndex+boundType+1; } } static inline void uprv_appendByteToHexString(char *dst, uint8_t val) { uint32_t len = (uint32_t)uprv_strlen(dst); *(dst+len) = T_CString_itosOffset((val >> 4)); *(dst+len+1) = T_CString_itosOffset((val & 0xF)); *(dst+len+2) = 0; } /* this function makes a string with representation of a sortkey */ U_CAPI char* U_EXPORT2 ucol_sortKeyToString(const UCollator *coll, const uint8_t *sortkey, char *buffer, uint32_t *len) { int32_t strength = UCOL_PRIMARY; uint32_t res_size = 0; UBool doneCase = FALSE; char *current = buffer; const uint8_t *currentSk = sortkey; uprv_strcpy(current, "["); while(strength <= UCOL_QUATERNARY && strength <= coll->strength) { if(strength > UCOL_PRIMARY) { uprv_strcat(current, " . "); } while(*currentSk != 0x01 && *currentSk != 0x00) { /* print a level */ uprv_appendByteToHexString(current, *currentSk++); uprv_strcat(current, " "); } if(coll->caseLevel == UCOL_ON && strength == UCOL_SECONDARY && doneCase == FALSE) { doneCase = TRUE; } else if(coll->caseLevel == UCOL_OFF || doneCase == TRUE || strength != UCOL_SECONDARY) { strength ++; } uprv_appendByteToHexString(current, *currentSk++); /* This should print '01' */ if(strength == UCOL_QUATERNARY && coll->alternateHandling == UCOL_NON_IGNORABLE) { break; } } if(coll->strength == UCOL_IDENTICAL) { uprv_strcat(current, " . "); while(*currentSk != 0) { uprv_appendByteToHexString(current, *currentSk++); uprv_strcat(current, " "); } uprv_appendByteToHexString(current, *currentSk++); } uprv_strcat(current, "]"); if(res_size > *len) { return NULL; } return buffer; } /****************************************************************************/ /* Following are the functions that deal with the properties of a collator */ /* there are new APIs and some compatibility APIs */ /****************************************************************************/ static inline void ucol_addLatinOneEntry(UCollator *coll, UChar ch, uint32_t CE, int32_t *primShift, int32_t *secShift, int32_t *terShift) { uint8_t primary1 = 0, primary2 = 0, secondary = 0, tertiary = 0; UBool reverseSecondary = FALSE; if(!isContinuation(CE)) { tertiary = (uint8_t)((CE & coll->tertiaryMask)); tertiary ^= coll->caseSwitch; reverseSecondary = TRUE; } else { tertiary = (uint8_t)((CE & UCOL_REMOVE_CONTINUATION)); tertiary &= UCOL_REMOVE_CASE; reverseSecondary = FALSE; } secondary = (uint8_t)((CE >>= 8) & UCOL_BYTE_SIZE_MASK); primary2 = (uint8_t)((CE >>= 8) & UCOL_BYTE_SIZE_MASK); primary1 = (uint8_t)(CE >> 8); if(primary1 != 0) { coll->latinOneCEs[ch] |= (primary1 << *primShift); *primShift -= 8; } if(primary2 != 0) { if(*primShift < 0) { coll->latinOneCEs[ch] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[coll->latinOneTableLen+ch] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[2*coll->latinOneTableLen+ch] = UCOL_BAIL_OUT_CE; return; } coll->latinOneCEs[ch] |= (primary2 << *primShift); *primShift -= 8; } if(secondary != 0) { if(reverseSecondary && coll->frenchCollation == UCOL_ON) { // reverse secondary coll->latinOneCEs[coll->latinOneTableLen+ch] >>= 8; // make space for secondary coll->latinOneCEs[coll->latinOneTableLen+ch] |= (secondary << 24); } else { // normal case coll->latinOneCEs[coll->latinOneTableLen+ch] |= (secondary << *secShift); } *secShift -= 8; } if(tertiary != 0) { coll->latinOneCEs[2*coll->latinOneTableLen+ch] |= (tertiary << *terShift); *terShift -= 8; } } static inline UBool ucol_resizeLatinOneTable(UCollator *coll, int32_t size, UErrorCode *status) { uint32_t *newTable = (uint32_t *)uprv_malloc(size*sizeof(uint32_t)*3); if(newTable == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; coll->latinOneFailed = TRUE; return FALSE; } int32_t sizeToCopy = ((sizelatinOneTableLen)?size:coll->latinOneTableLen)*sizeof(uint32_t); uprv_memset(newTable, 0, size*sizeof(uint32_t)*3); uprv_memcpy(newTable, coll->latinOneCEs, sizeToCopy); uprv_memcpy(newTable+size, coll->latinOneCEs+coll->latinOneTableLen, sizeToCopy); uprv_memcpy(newTable+2*size, coll->latinOneCEs+2*coll->latinOneTableLen, sizeToCopy); coll->latinOneTableLen = size; uprv_free(coll->latinOneCEs); coll->latinOneCEs = newTable; return TRUE; } static UBool ucol_setUpLatinOne(UCollator *coll, UErrorCode *status) { UBool result = TRUE; if(coll->latinOneCEs == NULL) { coll->latinOneCEs = (uint32_t *)uprv_malloc(sizeof(uint32_t)*UCOL_LATINONETABLELEN*3); if(coll->latinOneCEs == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return FALSE; } coll->latinOneTableLen = UCOL_LATINONETABLELEN; } UChar ch = 0; UCollationElements *it = ucol_openElements(coll, &ch, 1, status); uprv_memset(coll->latinOneCEs, 0, sizeof(uint32_t)*coll->latinOneTableLen*3); int32_t primShift = 24, secShift = 24, terShift = 24; uint32_t CE = 0; int32_t contractionOffset = UCOL_ENDOFLATINONERANGE+1; // TODO: make safe if you get more than you wanted... for(ch = 0; ch <= UCOL_ENDOFLATINONERANGE; ch++) { primShift = 24; secShift = 24; terShift = 24; if(ch < 0x100) { CE = coll->latinOneMapping[ch]; } else { CE = UTRIE_GET32_FROM_LEAD(coll->mapping, ch); if(CE == UCOL_NOT_FOUND) { CE = UTRIE_GET32_FROM_LEAD(coll->UCA->mapping, ch); } } if(CE < UCOL_NOT_FOUND) { ucol_addLatinOneEntry(coll, ch, CE, &primShift, &secShift, &terShift); } else { switch (getCETag(CE)) { case EXPANSION_TAG: ucol_setText(it, &ch, 1, status); while((int32_t)(CE = ucol_next(it, status)) != UCOL_NULLORDER) { if(primShift < 0 || secShift < 0 || terShift < 0) { coll->latinOneCEs[ch] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[coll->latinOneTableLen+ch] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[2*coll->latinOneTableLen+ch] = UCOL_BAIL_OUT_CE; break; } ucol_addLatinOneEntry(coll, ch, CE, &primShift, &secShift, &terShift); } break; case CONTRACTION_TAG: // here is the trick // F2 is contraction. We do something very similar to contractions // but have two indices, one in the real contraction table and the // other to where we stuffed things. This hopes that we don't have // many contractions (this should work for latin-1 tables). { if((CE & 0x00FFF000) != 0) { *status = U_UNSUPPORTED_ERROR; return FALSE; } const UChar *UCharOffset = (UChar *)coll->image+getContractOffset(CE); CE |= (contractionOffset & 0xFFF) << 12; // insert the offset in latin-1 table coll->latinOneCEs[ch] = CE; coll->latinOneCEs[coll->latinOneTableLen+ch] = CE; coll->latinOneCEs[2*coll->latinOneTableLen+ch] = CE; // We're going to jump into contraction table, pick the elements // and use them do { CE = *(coll->contractionCEs + (UCharOffset - coll->contractionIndex)); if(CE > UCOL_NOT_FOUND && getCETag(CE) == EXPANSION_TAG) { uint32_t size; uint32_t i; /* general counter */ uint32_t *CEOffset = (uint32_t *)coll->image+getExpansionOffset(CE); /* find the offset to expansion table */ size = getExpansionCount(CE); //CE = *CEOffset++; if(size != 0) { /* if there are less than 16 elements in expansion, we don't terminate */ for(i = 0; ilatinOneCEs[(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[2*coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; break; } ucol_addLatinOneEntry(coll, (UChar)contractionOffset, *CEOffset++, &primShift, &secShift, &terShift); } } else { /* else, we do */ while(*CEOffset != 0) { if(primShift < 0 || secShift < 0 || terShift < 0) { coll->latinOneCEs[(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[2*coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; break; } ucol_addLatinOneEntry(coll, (UChar)contractionOffset, *CEOffset++, &primShift, &secShift, &terShift); } } contractionOffset++; } else if(CE < UCOL_NOT_FOUND) { ucol_addLatinOneEntry(coll, (UChar)contractionOffset++, CE, &primShift, &secShift, &terShift); } else { coll->latinOneCEs[(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; coll->latinOneCEs[2*coll->latinOneTableLen+(UChar)contractionOffset] = UCOL_BAIL_OUT_CE; contractionOffset++; } UCharOffset++; primShift = 24; secShift = 24; terShift = 24; if(contractionOffset == coll->latinOneTableLen) { // we need to reallocate if(!ucol_resizeLatinOneTable(coll, 2*coll->latinOneTableLen, status)) { return FALSE; } } } while(*UCharOffset != 0xFFFF); } break; default: coll->latinOneFailed = TRUE; result = FALSE; break; } } } ucol_closeElements(it); // compact table if(contractionOffset < coll->latinOneTableLen) { if(!ucol_resizeLatinOneTable(coll, contractionOffset, status)) { return FALSE; } } return result; } void ucol_updateInternalState(UCollator *coll, UErrorCode *status) { if(U_SUCCESS(*status)) { if(coll->caseFirst == UCOL_UPPER_FIRST) { coll->caseSwitch = UCOL_CASE_SWITCH; } else { coll->caseSwitch = UCOL_NO_CASE_SWITCH; } if(coll->caseLevel == UCOL_ON || coll->caseFirst == UCOL_OFF) { coll->tertiaryMask = UCOL_REMOVE_CASE; coll->tertiaryCommon = UCOL_COMMON3_NORMAL; coll->tertiaryAddition = UCOL_FLAG_BIT_MASK_CASE_SW_OFF; coll->tertiaryTop = UCOL_COMMON_TOP3_CASE_SW_OFF; coll->tertiaryBottom = UCOL_COMMON_BOT3; } else { coll->tertiaryMask = UCOL_KEEP_CASE; coll->tertiaryAddition = UCOL_FLAG_BIT_MASK_CASE_SW_ON; if(coll->caseFirst == UCOL_UPPER_FIRST) { coll->tertiaryCommon = UCOL_COMMON3_UPPERFIRST; coll->tertiaryTop = UCOL_COMMON_TOP3_CASE_SW_UPPER; coll->tertiaryBottom = UCOL_COMMON_BOTTOM3_CASE_SW_UPPER; } else { coll->tertiaryCommon = UCOL_COMMON3_NORMAL; coll->tertiaryTop = UCOL_COMMON_TOP3_CASE_SW_LOWER; coll->tertiaryBottom = UCOL_COMMON_BOTTOM3_CASE_SW_LOWER; } } /* Set the compression values */ uint8_t tertiaryTotal = (uint8_t)(coll->tertiaryTop - UCOL_COMMON_BOT3-1); coll->tertiaryTopCount = (uint8_t)(UCOL_PROPORTION3*tertiaryTotal); /* we multilply double with int, but need only int */ coll->tertiaryBottomCount = (uint8_t)(tertiaryTotal - coll->tertiaryTopCount); if(coll->caseLevel == UCOL_OFF && coll->strength == UCOL_TERTIARY && coll->frenchCollation == UCOL_OFF && coll->alternateHandling == UCOL_NON_IGNORABLE) { coll->sortKeyGen = ucol_calcSortKeySimpleTertiary; } else { coll->sortKeyGen = ucol_calcSortKey; } if(coll->caseLevel == UCOL_OFF && coll->strength <= UCOL_TERTIARY && coll->alternateHandling == UCOL_NON_IGNORABLE && !coll->latinOneFailed) { if(coll->latinOneCEs == NULL || coll->latinOneRegenTable) { if(ucol_setUpLatinOne(coll, status)) { // if we succeed in building latin1 table, we'll use it //fprintf(stderr, "F"); coll->latinOneUse = TRUE; } else { coll->latinOneUse = FALSE; } if(*status == U_UNSUPPORTED_ERROR) { *status = U_ZERO_ERROR; } } else { // latin1Table exists and it doesn't need to be regenerated, just use it coll->latinOneUse = TRUE; } } else { coll->latinOneUse = FALSE; } } } U_CAPI uint32_t U_EXPORT2 ucol_setVariableTop(UCollator *coll, const UChar *varTop, int32_t len, UErrorCode *status) { if(U_FAILURE(*status) || coll == NULL) { return 0; } if(len == -1) { len = u_strlen(varTop); } if(len == 0) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } collIterate s; IInit_collIterate(coll, varTop, len, &s); uint32_t CE = ucol_IGetNextCE(coll, &s, status); /* here we check if we have consumed all characters */ /* you can put in either one character or a contraction */ /* you shouldn't put more... */ if(s.pos != s.endp || CE == UCOL_NO_MORE_CES) { *status = U_CE_NOT_FOUND_ERROR; return 0; } uint32_t nextCE = ucol_IGetNextCE(coll, &s, status); if(isContinuation(nextCE) && (nextCE & UCOL_PRIMARYMASK) != 0) { *status = U_PRIMARY_TOO_LONG_ERROR; return 0; } coll->variableTopValue = (CE & UCOL_PRIMARYMASK)>>16; return CE & UCOL_PRIMARYMASK; } U_CAPI uint32_t U_EXPORT2 ucol_getVariableTop(const UCollator *coll, UErrorCode *status) { if(U_FAILURE(*status) || coll == NULL) { return 0; } return coll->variableTopValue<<16; } U_CAPI void U_EXPORT2 ucol_restoreVariableTop(UCollator *coll, const uint32_t varTop, UErrorCode *status) { if(U_FAILURE(*status) || coll == NULL) { return; } coll->variableTopValue = (varTop & UCOL_PRIMARYMASK)>>16; } /* Attribute setter API */ U_CAPI void U_EXPORT2 ucol_setAttribute(UCollator *coll, UColAttribute attr, UColAttributeValue value, UErrorCode *status) { if(U_FAILURE(*status) || coll == NULL) { return; } UColAttributeValue oldFrench = coll->frenchCollation; UColAttributeValue oldCaseFirst = coll->caseFirst; switch(attr) { case UCOL_NUMERIC_COLLATION: /* sort substrings of digits as numbers */ if(value == UCOL_ON) { coll->numericCollation = UCOL_ON; coll->numericCollationisDefault = FALSE; } else if (value == UCOL_OFF) { coll->numericCollation = UCOL_OFF; coll->numericCollationisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->numericCollationisDefault = TRUE; coll->numericCollation = (UColAttributeValue)coll->options->numericCollation; } else { *status = U_ILLEGAL_ARGUMENT_ERROR; } break; case UCOL_HIRAGANA_QUATERNARY_MODE: /* special quaternary values for Hiragana */ if(value == UCOL_ON) { coll->hiraganaQ = UCOL_ON; coll->hiraganaQisDefault = FALSE; } else if (value == UCOL_OFF) { coll->hiraganaQ = UCOL_OFF; coll->hiraganaQisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->hiraganaQisDefault = TRUE; coll->hiraganaQ = (UColAttributeValue)coll->options->hiraganaQ; } else { *status = U_ILLEGAL_ARGUMENT_ERROR; } break; case UCOL_FRENCH_COLLATION: /* attribute for direction of secondary weights*/ if(value == UCOL_ON) { coll->frenchCollation = UCOL_ON; coll->frenchCollationisDefault = FALSE; } else if (value == UCOL_OFF) { coll->frenchCollation = UCOL_OFF; coll->frenchCollationisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->frenchCollationisDefault = TRUE; coll->frenchCollation = (UColAttributeValue)coll->options->frenchCollation; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_ALTERNATE_HANDLING: /* attribute for handling variable elements*/ if(value == UCOL_SHIFTED) { coll->alternateHandling = UCOL_SHIFTED; coll->alternateHandlingisDefault = FALSE; } else if (value == UCOL_NON_IGNORABLE) { coll->alternateHandling = UCOL_NON_IGNORABLE; coll->alternateHandlingisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->alternateHandlingisDefault = TRUE; coll->alternateHandling = (UColAttributeValue)coll->options->alternateHandling ; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_CASE_FIRST: /* who goes first, lower case or uppercase */ if(value == UCOL_LOWER_FIRST) { coll->caseFirst = UCOL_LOWER_FIRST; coll->caseFirstisDefault = FALSE; } else if (value == UCOL_UPPER_FIRST) { coll->caseFirst = UCOL_UPPER_FIRST; coll->caseFirstisDefault = FALSE; } else if (value == UCOL_OFF) { coll->caseFirst = UCOL_OFF; coll->caseFirstisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->caseFirst = (UColAttributeValue)coll->options->caseFirst; coll->caseFirstisDefault = TRUE; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_CASE_LEVEL: /* do we have an extra case level */ if(value == UCOL_ON) { coll->caseLevel = UCOL_ON; coll->caseLevelisDefault = FALSE; } else if (value == UCOL_OFF) { coll->caseLevel = UCOL_OFF; coll->caseLevelisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->caseLevel = (UColAttributeValue)coll->options->caseLevel; coll->caseLevelisDefault = TRUE; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_NORMALIZATION_MODE: /* attribute for normalization */ if(value == UCOL_ON) { coll->normalizationMode = UCOL_ON; coll->normalizationModeisDefault = FALSE; } else if (value == UCOL_OFF) { coll->normalizationMode = UCOL_OFF; coll->normalizationModeisDefault = FALSE; } else if (value == UCOL_DEFAULT) { coll->normalizationModeisDefault = TRUE; coll->normalizationMode = (UColAttributeValue)coll->options->normalizationMode; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_STRENGTH: /* attribute for strength */ if (value == UCOL_DEFAULT) { coll->strengthisDefault = TRUE; coll->strength = (UColAttributeValue)coll->options->strength; } else if (value <= UCOL_IDENTICAL) { coll->strengthisDefault = FALSE; coll->strength = value; } else { *status = U_ILLEGAL_ARGUMENT_ERROR ; } break; case UCOL_ATTRIBUTE_COUNT: default: *status = U_ILLEGAL_ARGUMENT_ERROR; break; } if(oldFrench != coll->frenchCollation || oldCaseFirst != coll->caseFirst) { coll->latinOneRegenTable = TRUE; } else { coll->latinOneRegenTable = FALSE; } ucol_updateInternalState(coll, status); } U_CAPI UColAttributeValue U_EXPORT2 ucol_getAttribute(const UCollator *coll, UColAttribute attr, UErrorCode *status) { if(U_FAILURE(*status) || coll == NULL) { return UCOL_DEFAULT; } switch(attr) { case UCOL_NUMERIC_COLLATION: return coll->numericCollation; case UCOL_HIRAGANA_QUATERNARY_MODE: return coll->hiraganaQ; case UCOL_FRENCH_COLLATION: /* attribute for direction of secondary weights*/ return coll->frenchCollation; case UCOL_ALTERNATE_HANDLING: /* attribute for handling variable elements*/ return coll->alternateHandling; case UCOL_CASE_FIRST: /* who goes first, lower case or uppercase */ return coll->caseFirst; case UCOL_CASE_LEVEL: /* do we have an extra case level */ return coll->caseLevel; case UCOL_NORMALIZATION_MODE: /* attribute for normalization */ return coll->normalizationMode; case UCOL_STRENGTH: /* attribute for strength */ return coll->strength; case UCOL_ATTRIBUTE_COUNT: default: *status = U_ILLEGAL_ARGUMENT_ERROR; break; } return UCOL_DEFAULT; } U_CAPI void U_EXPORT2 ucol_setStrength( UCollator *coll, UCollationStrength strength) { UErrorCode status = U_ZERO_ERROR; ucol_setAttribute(coll, UCOL_STRENGTH, strength, &status); } U_CAPI UCollationStrength U_EXPORT2 ucol_getStrength(const UCollator *coll) { UErrorCode status = U_ZERO_ERROR; return ucol_getAttribute(coll, UCOL_STRENGTH, &status); } /****************************************************************************/ /* Following are misc functions */ /* there are new APIs and some compatibility APIs */ /****************************************************************************/ U_CAPI UCollator* U_EXPORT2 ucol_safeClone(const UCollator *coll, void *stackBuffer, int32_t * pBufferSize, UErrorCode *status) { UCollator * localCollator; int32_t bufferSizeNeeded = (int32_t)sizeof(UCollator); char *stackBufferChars = (char *)stackBuffer; if (status == NULL || U_FAILURE(*status)){ return 0; } if ((stackBuffer && !pBufferSize) || !coll){ *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } /* Pointers on 64-bit platforms need to be aligned * on a 64-bit boundry in memory. */ if (U_ALIGNMENT_OFFSET(stackBuffer) != 0) { int32_t offsetUp = (int32_t)U_ALIGNMENT_OFFSET_UP(stackBufferChars); *pBufferSize -= offsetUp; stackBufferChars += offsetUp; } stackBuffer = (void *)stackBufferChars; if (stackBuffer && *pBufferSize <= 0){ /* 'preflighting' request - set needed size into *pBufferSize */ *pBufferSize = bufferSizeNeeded; return 0; } if (!stackBuffer || *pBufferSize < bufferSizeNeeded) { /* allocate one here...*/ int32_t length; const UChar * rules = ucol_getRules(coll, &length); localCollator = ucol_openRules(rules, length, ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, status), ucol_getStrength(coll), NULL, status); if (U_SUCCESS(*status)) { *status = U_SAFECLONE_ALLOCATED_WARNING; } } else { localCollator = (UCollator *)stackBuffer; uprv_memcpy(localCollator, coll, sizeof(UCollator)); localCollator->freeOnClose = FALSE; localCollator->requestedLocale = NULL; // zero copies of pointers localCollator->validLocale = NULL; } return localCollator; } U_CAPI int32_t U_EXPORT2 ucol_getRulesEx(const UCollator *coll, UColRuleOption delta, UChar *buffer, int32_t bufferLen) { UErrorCode status = U_ZERO_ERROR; int32_t len = 0; int32_t UCAlen = 0; const UChar* ucaRules = 0; const UChar *rules = ucol_getRules(coll, &len); if(delta == UCOL_FULL_RULES) { /* take the UCA rules and append real rules at the end */ /* UCA rules will be probably coming from the root RB */ ucaRules = ures_getStringByKey(coll->rb,"%%UCARULES",&UCAlen,&status); } if(U_FAILURE(status)) { return 0; } if(buffer!=0 && bufferLen>0){ *buffer=0; if(UCAlen > 0) { u_memcpy(buffer, ucaRules, uprv_min(UCAlen, bufferLen)); } if(len > 0 && bufferLen > UCAlen) { u_memcpy(buffer+UCAlen, rules, uprv_min(len, bufferLen-UCAlen)); } } return u_terminateUChars(buffer, bufferLen, len+UCAlen, &status); } static const UChar _NUL = 0; U_CAPI const UChar* U_EXPORT2 ucol_getRules( const UCollator *coll, int32_t *length) { if(coll->rules != NULL) { *length = coll->rulesLength; return coll->rules; } else { UErrorCode status = U_ZERO_ERROR; if(coll->elements != NULL) { if(U_SUCCESS(status)) { /*Semantic const */ ((UCollator *)coll)->rules = ures_getStringByKey(coll->elements, "Sequence", length, &status); ((UCollator *)coll)->rulesLength = *length; ((UCollator *)coll)->freeRulesOnClose = FALSE; return coll->rules; } } *length = 0; return &_NUL; } } U_CAPI int32_t U_EXPORT2 ucol_getDisplayName( const char *objLoc, const char *dispLoc, UChar *result, int32_t resultLength, UErrorCode *status) { if(U_FAILURE(*status)) return -1; UnicodeString dst; if(!(result==NULL && resultLength==0)) { // NULL destination for pure preflighting: empty dummy string // otherwise, alias the destination buffer dst.setTo(result, 0, resultLength); } Collator::getDisplayName(Locale(objLoc), Locale(dispLoc), dst); return dst.extract(result, resultLength, *status); } U_CAPI const char* U_EXPORT2 ucol_getAvailable(int32_t index) { return uloc_getAvailable(index); } U_CAPI int32_t U_EXPORT2 ucol_countAvailable() { return uloc_countAvailable(); } U_CAPI void U_EXPORT2 ucol_getVersion(const UCollator* coll, UVersionInfo versionInfo) { /* RunTime version */ uint8_t rtVersion = UCOL_RUNTIME_VERSION; /* Builder version*/ uint8_t bdVersion = coll->image->version[0]; /* Charset Version. Need to get the version from cnv files * makeconv should populate cnv files with version and * an api has to be provided in ucnv.h to obtain this version */ uint8_t csVersion = 0; /* combine the version info */ uint16_t cmbVersion = (uint16_t)((rtVersion<<11) | (bdVersion<<6) | (csVersion)); /* Tailoring rules */ versionInfo[0] = (uint8_t)(cmbVersion>>8); versionInfo[1] = (uint8_t)cmbVersion; versionInfo[2] = coll->image->version[1]; versionInfo[3] = coll->UCA->image->UCAVersion[0]; } /* This internal API checks whether a character is tailored or not */ U_CAPI UBool U_EXPORT2 ucol_isTailored(const UCollator *coll, const UChar u, UErrorCode *status) { uint32_t CE = UCOL_NOT_FOUND; const UChar *ContractionStart = NULL; if(U_SUCCESS(*status) && coll != NULL) { if(coll == coll->UCA) { return FALSE; } else if(u < 0x100) { /* latin-1 */ CE = coll->latinOneMapping[u]; if(CE == coll->UCA->latinOneMapping[u]) { return FALSE; } } else { /* regular */ /*CE = ucmpe32_get(coll->mapping, u);*/ CE = UTRIE_GET32_FROM_LEAD(coll->mapping, u); } if(isContraction(CE)) { ContractionStart = (UChar *)coll->image+getContractOffset(CE); CE = *(coll->contractionCEs + (ContractionStart- coll->contractionIndex)); } if(CE == UCOL_NOT_FOUND) { return FALSE; } else { return TRUE; } } else { return FALSE; } } /****************************************************************************/ /* Following are the string compare functions */ /* */ /****************************************************************************/ /* ucol_checkIdent internal function. Does byte level string compare. */ /* Used by strcoll if strength == identical and strings */ /* are otherwise equal. Moved out-of-line because this */ /* is a rare case. */ /* */ /* Comparison must be done on NFD normalized strings. */ /* FCD is not good enough. */ /* */ /* TODO: make an incremental NFD Comparison function, which could */ /* be of general use */ static UCollationResult ucol_checkIdent(collIterate *sColl, collIterate *tColl, UBool normalize, UErrorCode *status) { // TODO: When we have an UChar iterator, we need to access the whole string. One // useful modification would be a UChar iterator extract API, since reset next next... // is not optimal. // TODO: Handle long strings. Do the same in compareUsingSortKeys. // When we arrive here, we can have normal strings or UCharIterators. Currently they are both // of same type, but that doesn't really mean that it will stay that way. // The division for the array length may truncate the array size to // a little less than UNORM_ITER_SIZE, but that size is dimensioned too high // for all platforms anyway. UAlignedMemory stackNormIter1[UNORM_ITER_SIZE/sizeof(UAlignedMemory)]; UAlignedMemory stackNormIter2[UNORM_ITER_SIZE/sizeof(UAlignedMemory)]; //UChar sStackBuf[256], tStackBuf[256]; //int32_t sBufSize = 256, tBufSize = 256; int32_t comparison; int32_t sLen = 0; UChar *sBuf = NULL; int32_t tLen = 0; UChar *tBuf = NULL; UBool freeSBuf = FALSE, freeTBuf = FALSE; if (sColl->flags & UCOL_USE_ITERATOR) { UNormIterator *sNIt = NULL, *tNIt = NULL; sNIt = unorm_openIter(stackNormIter1, sizeof(stackNormIter1), status); tNIt = unorm_openIter(stackNormIter2, sizeof(stackNormIter2), status); sColl->iterator->move(sColl->iterator, 0, UITER_START); tColl->iterator->move(tColl->iterator, 0, UITER_START); UCharIterator *sIt = unorm_setIter(sNIt, sColl->iterator, UNORM_NFD, status); UCharIterator *tIt = unorm_setIter(tNIt, tColl->iterator, UNORM_NFD, status); comparison = u_strCompareIter(sIt, tIt, TRUE); unorm_closeIter(sNIt); unorm_closeIter(tNIt); } else { sLen = (sColl->flags & UCOL_ITER_HASLEN) ? sColl->endp - sColl->string : -1; sBuf = sColl->string; tLen = (tColl->flags & UCOL_ITER_HASLEN) ? tColl->endp - tColl->string : -1; tBuf = tColl->string; if (normalize) { *status = U_ZERO_ERROR; if (unorm_quickCheck(sBuf, sLen, UNORM_NFD, status) != UNORM_YES) { sLen = unorm_decompose(sColl->writableBuffer, (int32_t)sColl->writableBufSize, sBuf, sLen, FALSE, 0, status); if(*status == U_BUFFER_OVERFLOW_ERROR) { if(!u_growBufferFromStatic(sColl->stackWritableBuffer, &sColl->writableBuffer, (int32_t *)&sColl->writableBufSize, sLen, 0) ) { *status = U_MEMORY_ALLOCATION_ERROR; return UCOL_LESS; /* TODO set *status = U_MEMORY_ALLOCATION_ERROR; */ } *status = U_ZERO_ERROR; sLen = unorm_decompose(sColl->writableBuffer, (int32_t)sColl->writableBufSize, sBuf, sLen, FALSE, 0, status); } if(freeSBuf) { uprv_free(sBuf); freeSBuf = FALSE; } sBuf = sColl->writableBuffer; if (sBuf != sColl->stackWritableBuffer) { sColl->flags |= UCOL_ITER_ALLOCATED; } } *status = U_ZERO_ERROR; if (unorm_quickCheck(tBuf, tLen, UNORM_NFD, status) != UNORM_YES) { tLen = unorm_decompose(tColl->writableBuffer, (int32_t)tColl->writableBufSize, tBuf, tLen, FALSE, 0, status); if(*status == U_BUFFER_OVERFLOW_ERROR) { if(!u_growBufferFromStatic(tColl->stackWritableBuffer, &tColl->writableBuffer, (int32_t *)&tColl->writableBufSize, tLen, 0) ) { *status = U_MEMORY_ALLOCATION_ERROR; return UCOL_LESS; /* TODO set *status = U_MEMORY_ALLOCATION_ERROR; */ } *status = U_ZERO_ERROR; tLen = unorm_decompose(tColl->writableBuffer, (int32_t)tColl->writableBufSize, tBuf, tLen, FALSE, 0, status); } if(freeTBuf) { uprv_free(tBuf); freeTBuf = FALSE; } tBuf = tColl->writableBuffer; if (tBuf != tColl->stackWritableBuffer) { tColl->flags |= UCOL_ITER_ALLOCATED; } } } if (sLen == -1 && tLen == -1) { comparison = u_strcmpCodePointOrder(sBuf, tBuf); } else { if (sLen == -1) { sLen = u_strlen(sBuf); } if (tLen == -1) { tLen = u_strlen(tBuf); } comparison = u_memcmpCodePointOrder(sBuf, tBuf, uprv_min(sLen, tLen)); if (comparison == 0) { comparison = sLen - tLen; } } } if (comparison < 0) { return UCOL_LESS; } else if (comparison == 0) { return UCOL_EQUAL; } else /* comparison > 0 */ { return UCOL_GREATER; } } /* CEBuf - A struct and some inline functions to handle the saving */ /* of CEs in a buffer within ucol_strcoll */ #define UCOL_CEBUF_SIZE 512 typedef struct ucol_CEBuf { uint32_t *buf; uint32_t *endp; uint32_t *pos; uint32_t localArray[UCOL_CEBUF_SIZE]; } ucol_CEBuf; static inline void UCOL_INIT_CEBUF(ucol_CEBuf *b) { (b)->buf = (b)->pos = (b)->localArray; (b)->endp = (b)->buf + UCOL_CEBUF_SIZE; }; static void ucol_CEBuf_Expand(ucol_CEBuf *b, collIterate *ci) { uint32_t oldSize; uint32_t newSize; uint32_t *newBuf; ci->flags |= UCOL_ITER_ALLOCATED; oldSize = b->pos - b->buf; newSize = oldSize * 2; newBuf = (uint32_t *)uprv_malloc(newSize * sizeof(uint32_t)); if(newBuf != NULL) { uprv_memcpy(newBuf, b->buf, oldSize * sizeof(uint32_t)); if (b->buf != b->localArray) { uprv_free(b->buf); } b->buf = newBuf; b->endp = b->buf + newSize; b->pos = b->buf + oldSize; } } static inline void UCOL_CEBUF_PUT(ucol_CEBuf *b, uint32_t ce, collIterate *ci) { if (b->pos == b->endp) { ucol_CEBuf_Expand(b, ci); } *(b)->pos++ = ce; }; /* This is a trick string compare function that goes in and uses sortkeys to compare */ /* It is used when compare gets in trouble and needs to bail out */ static UCollationResult ucol_compareUsingSortKeys(collIterate *sColl, collIterate *tColl) { uint8_t sourceKey[UCOL_MAX_BUFFER], targetKey[UCOL_MAX_BUFFER]; uint8_t *sourceKeyP = sourceKey; uint8_t *targetKeyP = targetKey; int32_t sourceKeyLen = UCOL_MAX_BUFFER, targetKeyLen = UCOL_MAX_BUFFER; const UCollator *coll = sColl->coll; UChar *source = NULL; UChar *target = NULL; UChar sStackBuf[256], tStackBuf[256]; int32_t sourceLength = (sColl->flags&UCOL_ITER_HASLEN)?(sColl->endp-sColl->string):-1; int32_t targetLength = (tColl->flags&UCOL_ITER_HASLEN)?(tColl->endp-tColl->string):-1; // TODO: Handle long strings. Do the same in ucol_checkIdent. if(sColl->flags & UCOL_USE_ITERATOR) { sColl->iterator->move(sColl->iterator, 0, UITER_START); tColl->iterator->move(tColl->iterator, 0, UITER_START); source = sStackBuf; UChar *sBufp = source; target = tStackBuf; UChar *tBufp = target; while(sColl->iterator->hasNext(sColl->iterator)) { *sBufp++ = (UChar)sColl->iterator->next(sColl->iterator); } while(tColl->iterator->hasNext(tColl->iterator)) { *tBufp++ = (UChar)tColl->iterator->next(tColl->iterator); } sourceLength = sBufp - source; targetLength = tBufp - target; } else { // no iterators sourceLength = (sColl->flags&UCOL_ITER_HASLEN)?(sColl->endp-sColl->string):-1; targetLength = (tColl->flags&UCOL_ITER_HASLEN)?(tColl->endp-tColl->string):-1; source = sColl->string; target = tColl->string; } sourceKeyLen = ucol_getSortKey(coll, source, sourceLength, sourceKeyP, sourceKeyLen); if(sourceKeyLen > UCOL_MAX_BUFFER) { sourceKeyP = (uint8_t*)uprv_malloc(sourceKeyLen*sizeof(uint8_t)); if(sourceKeyP != NULL) { sourceKeyLen = ucol_getSortKey(coll, source, sourceLength, sourceKeyP, sourceKeyLen); } } targetKeyLen = ucol_getSortKey(coll, target, targetLength, targetKeyP, targetKeyLen); if(targetKeyLen > UCOL_MAX_BUFFER) { targetKeyP = (uint8_t*)uprv_malloc(targetKeyLen*sizeof(uint8_t)); if(targetKeyP != NULL) { targetKeyLen = ucol_getSortKey(coll, target, targetLength, targetKeyP, targetKeyLen); } } int32_t result = uprv_strcmp((const char*)sourceKeyP, (const char*)targetKeyP); if(sourceKeyP != sourceKey) { uprv_free(sourceKeyP); } if(targetKeyP != targetKey) { uprv_free(targetKeyP); } if(result<0) { return UCOL_LESS; } else if(result>0) { return UCOL_GREATER; } else { return UCOL_EQUAL; } } static inline UCollationResult ucol_strcollRegular( collIterate *sColl, collIterate *tColl, // const UCollator *coll, // const UChar *source, // int32_t sourceLength, // const UChar *target, // int32_t targetLength, UErrorCode *status) { U_ALIGN_CODE(16); const UCollator *coll = sColl->coll; // setting up the collator parameters UColAttributeValue strength = coll->strength; UBool initialCheckSecTer = (strength >= UCOL_SECONDARY); UBool checkSecTer = initialCheckSecTer; UBool checkTertiary = (strength >= UCOL_TERTIARY); UBool checkQuad = (strength >= UCOL_QUATERNARY); UBool checkIdent = (strength == UCOL_IDENTICAL); UBool checkCase = (coll->caseLevel == UCOL_ON); UBool isFrenchSec = (coll->frenchCollation == UCOL_ON) && checkSecTer; UBool shifted = (coll->alternateHandling == UCOL_SHIFTED); UBool qShifted = shifted && checkQuad; UBool doHiragana = (coll->hiraganaQ == UCOL_ON) && checkQuad; if(doHiragana && shifted) { return (ucol_compareUsingSortKeys(sColl, tColl)); } uint8_t caseSwitch = coll->caseSwitch; uint8_t tertiaryMask = coll->tertiaryMask; // This is the lowest primary value that will not be ignored if shifted uint32_t LVT = (shifted)?(coll->variableTopValue<<16):0; UCollationResult result = UCOL_EQUAL; UCollationResult hirResult = UCOL_EQUAL; // Preparing the CE buffers. They will be filled during the primary phase ucol_CEBuf sCEs; ucol_CEBuf tCEs; UCOL_INIT_CEBUF(&sCEs); UCOL_INIT_CEBUF(&tCEs); uint32_t secS = 0, secT = 0; uint32_t sOrder=0, tOrder=0; // Non shifted primary processing is quite simple if(!shifted) { for(;;) { // We fetch CEs until we hit a non ignorable primary or end. do { // We get the next CE sOrder = ucol_IGetNextCE(coll, sColl, status); // Stuff it in the buffer UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); // And keep just the primary part. sOrder &= UCOL_PRIMARYMASK; } while(sOrder == 0); // see the comments on the above block do { tOrder = ucol_IGetNextCE(coll, tColl, status); UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); tOrder &= UCOL_PRIMARYMASK; } while(tOrder == 0); // if both primaries are the same if(sOrder == tOrder) { // and there are no more CEs, we advance to the next level if(sOrder == UCOL_NO_MORE_CES_PRIMARY) { break; } if(doHiragana && hirResult == UCOL_EQUAL) { if((sColl->flags & UCOL_WAS_HIRAGANA) != (tColl->flags & UCOL_WAS_HIRAGANA)) { hirResult = ((sColl->flags & UCOL_WAS_HIRAGANA) > (tColl->flags & UCOL_WAS_HIRAGANA)) ? UCOL_LESS:UCOL_GREATER; } } } else { // if two primaries are different, we are done result = (sOrder < tOrder) ? UCOL_LESS: UCOL_GREATER; goto commonReturn; } } // no primary difference... do the rest from the buffers } else { // shifted - do a slightly more complicated processing :) for(;;) { UBool sInShifted = FALSE; UBool tInShifted = FALSE; // This version of code can be refactored. However, it seems easier to understand this way. // Source loop. Sam as the target loop. for(;;) { sOrder = ucol_IGetNextCE(coll, sColl, status); if(sOrder == UCOL_NO_MORE_CES) { UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); break; } else if(sOrder == 0 || (sInShifted && (sOrder & UCOL_PRIMARYMASK) == 0)) { /* UCA amendment - ignore ignorables that follow shifted code points */ continue; } else if(isContinuation(sOrder)) { if((sOrder & UCOL_PRIMARYMASK) > 0) { /* There is primary value */ if(sInShifted) { sOrder = (sOrder & UCOL_PRIMARYMASK) | 0xC0; /* preserve interesting continuation */ UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); continue; } else { UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); break; } } else { /* Just lower level values */ if(sInShifted) { continue; } else { UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); continue; } } } else { /* regular */ if((sOrder & UCOL_PRIMARYMASK) > LVT) { UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); break; } else { if((sOrder & UCOL_PRIMARYMASK) > 0) { sInShifted = TRUE; sOrder &= UCOL_PRIMARYMASK; UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); continue; } else { UCOL_CEBUF_PUT(&sCEs, sOrder, sColl); sInShifted = FALSE; continue; } } } } sOrder &= UCOL_PRIMARYMASK; sInShifted = FALSE; for(;;) { tOrder = ucol_IGetNextCE(coll, tColl, status); if(tOrder == UCOL_NO_MORE_CES) { UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); break; } else if(tOrder == 0 || (tInShifted && (tOrder & UCOL_PRIMARYMASK) == 0)) { /* UCA amendment - ignore ignorables that follow shifted code points */ continue; } else if(isContinuation(tOrder)) { if((tOrder & UCOL_PRIMARYMASK) > 0) { /* There is primary value */ if(tInShifted) { tOrder = (tOrder & UCOL_PRIMARYMASK) | 0xC0; /* preserve interesting continuation */ UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); continue; } else { UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); break; } } else { /* Just lower level values */ if(tInShifted) { continue; } else { UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); continue; } } } else { /* regular */ if((tOrder & UCOL_PRIMARYMASK) > LVT) { UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); break; } else { if((tOrder & UCOL_PRIMARYMASK) > 0) { tInShifted = TRUE; tOrder &= UCOL_PRIMARYMASK; UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); continue; } else { UCOL_CEBUF_PUT(&tCEs, tOrder, tColl); tInShifted = FALSE; continue; } } } } tOrder &= UCOL_PRIMARYMASK; tInShifted = FALSE; if(sOrder == tOrder) { /* if(doHiragana && hirResult == UCOL_EQUAL) { if((sColl.flags & UCOL_WAS_HIRAGANA) != (tColl.flags & UCOL_WAS_HIRAGANA)) { hirResult = ((sColl.flags & UCOL_WAS_HIRAGANA) > (tColl.flags & UCOL_WAS_HIRAGANA)) ? UCOL_LESS:UCOL_GREATER; } } */ if(sOrder == UCOL_NO_MORE_CES_PRIMARY) { break; } else { sOrder = 0; tOrder = 0; continue; } } else { result = (sOrder < tOrder) ? UCOL_LESS : UCOL_GREATER; goto commonReturn; } } /* no primary difference... do the rest from the buffers */ } /* now, we're gonna reexamine collected CEs */ uint32_t *sCE; uint32_t *tCE; /* This is the secondary level of comparison */ if(checkSecTer) { if(!isFrenchSec) { /* normal */ sCE = sCEs.buf; tCE = tCEs.buf; for(;;) { while (secS == 0) { secS = *(sCE++) & UCOL_SECONDARYMASK; } while(secT == 0) { secT = *(tCE++) & UCOL_SECONDARYMASK; } if(secS == secT) { if(secS == UCOL_NO_MORE_CES_SECONDARY) { break; } else { secS = 0; secT = 0; continue; } } else { result = (secS < secT) ? UCOL_LESS : UCOL_GREATER; goto commonReturn; } } } else { /* do the French */ uint32_t *sCESave = NULL; uint32_t *tCESave = NULL; sCE = sCEs.pos-2; /* this could also be sCEs-- if needs to be optimized */ tCE = tCEs.pos-2; for(;;) { while (secS == 0 && sCE >= sCEs.buf) { if(sCESave == 0) { secS = *(sCE--); if(isContinuation(secS)) { while(isContinuation(secS = *(sCE--))); /* after this, secS has the start of continuation, and sCEs points before that */ sCESave = sCE; /* we save it, so that we know where to come back AND that we need to go forward */ sCE+=2; /* need to point to the first continuation CP */ /* However, now you can just continue doing stuff */ } } else { secS = *(sCE++); if(!isContinuation(secS)) { /* This means we have finished with this cont */ sCE = sCESave; /* reset the pointer to before continuation */ sCESave = 0; continue; } } secS &= UCOL_SECONDARYMASK; /* remove the continuation bit */ } while(secT == 0 && tCE >= tCEs.buf) { if(tCESave == 0) { secT = *(tCE--); if(isContinuation(secT)) { while(isContinuation(secT = *(tCE--))); /* after this, secS has the start of continuation, and sCEs points before that */ tCESave = tCE; /* we save it, so that we know where to come back AND that we need to go forward */ tCE+=2; /* need to point to the first continuation CP */ /* However, now you can just continue doing stuff */ } } else { secT = *(tCE++); if(!isContinuation(secT)) { /* This means we have finished with this cont */ tCE = tCESave; /* reset the pointer to before continuation */ tCESave = 0; continue; } } secT &= UCOL_SECONDARYMASK; /* remove the continuation bit */ } if(secS == secT) { if(secS == UCOL_NO_MORE_CES_SECONDARY || (sCE < sCEs.buf && tCE < tCEs.buf)) { break; } else { secS = 0; secT = 0; continue; } } else { result = (secS < secT) ? UCOL_LESS : UCOL_GREATER; goto commonReturn; } } } } /* doing the case bit */ if(checkCase) { sCE = sCEs.buf; tCE = tCEs.buf; for(;;) { while((secS & UCOL_REMOVE_CASE) == 0) { if(!isContinuation(*sCE++)) { secS =*(sCE-1) & UCOL_TERT_CASE_MASK; secS ^= caseSwitch; } else { secS = 0; } } while((secT & UCOL_REMOVE_CASE) == 0) { if(!isContinuation(*tCE++)) { secT = *(tCE-1) & UCOL_TERT_CASE_MASK; secT ^= caseSwitch; } else { secT = 0; } } if((secS & UCOL_CASE_BIT_MASK) < (secT & UCOL_CASE_BIT_MASK)) { result = UCOL_LESS; goto commonReturn; } else if((secS & UCOL_CASE_BIT_MASK) > (secT & UCOL_CASE_BIT_MASK)) { result = UCOL_GREATER; goto commonReturn; } if((secS & UCOL_REMOVE_CASE) == UCOL_NO_MORE_CES_TERTIARY || (secT & UCOL_REMOVE_CASE) == UCOL_NO_MORE_CES_TERTIARY ) { break; } else { secS = 0; secT = 0; } } } /* Tertiary level */ if(checkTertiary) { secS = 0; secT = 0; sCE = sCEs.buf; tCE = tCEs.buf; for(;;) { while((secS & UCOL_REMOVE_CASE) == 0) { secS = *(sCE++) & tertiaryMask; if(!isContinuation(secS)) { secS ^= caseSwitch; } else { secS &= UCOL_REMOVE_CASE; } } while((secT & UCOL_REMOVE_CASE) == 0) { secT = *(tCE++) & tertiaryMask; if(!isContinuation(secT)) { secT ^= caseSwitch; } else { secT &= UCOL_REMOVE_CASE; } } if(secS == secT) { if((secS & UCOL_REMOVE_CASE) == 1) { break; } else { secS = 0; secT = 0; continue; } } else { result = (secS < secT) ? UCOL_LESS : UCOL_GREATER; goto commonReturn; } } } if(qShifted /*checkQuad*/) { UBool sInShifted = TRUE; UBool tInShifted = TRUE; secS = 0; secT = 0; sCE = sCEs.buf; tCE = tCEs.buf; for(;;) { while(secS == 0 && secS != UCOL_NO_MORE_CES || (isContinuation(secS) && !sInShifted)) { secS = *(sCE++); if(isContinuation(secS)) { if(!sInShifted) { continue; } } else if(secS > LVT || (secS & UCOL_PRIMARYMASK) == 0) { /* non continuation */ secS = UCOL_PRIMARYMASK; sInShifted = FALSE; } else { sInShifted = TRUE; } } secS &= UCOL_PRIMARYMASK; while(secT == 0 && secT != UCOL_NO_MORE_CES || (isContinuation(secT) && !tInShifted)) { secT = *(tCE++); if(isContinuation(secT)) { if(!tInShifted) { continue; } } else if(secT > LVT || (secT & UCOL_PRIMARYMASK) == 0) { secT = UCOL_PRIMARYMASK; tInShifted = FALSE; } else { tInShifted = TRUE; } } secT &= UCOL_PRIMARYMASK; if(secS == secT) { if(secS == UCOL_NO_MORE_CES_PRIMARY) { break; } else { secS = 0; secT = 0; continue; } } else { result = (secS < secT) ? UCOL_LESS : UCOL_GREATER; goto commonReturn; } } } else if(doHiragana && hirResult != UCOL_EQUAL) { // If we're fine on quaternaries, we might be different // on Hiragana. This, however, might fail us in shifted. result = hirResult; goto commonReturn; } /* For IDENTICAL comparisons, we use a bitwise character comparison */ /* as a tiebreaker if all else is equal. */ /* Getting here should be quite rare - strings are not identical - */ /* that is checked first, but compared == through all other checks. */ if(checkIdent) { //result = ucol_checkIdent(&sColl, &tColl, coll->normalizationMode == UCOL_ON); result = ucol_checkIdent(sColl, tColl, TRUE, status); } commonReturn: if ((sColl->flags | tColl->flags) & UCOL_ITER_ALLOCATED) { freeHeapWritableBuffer(sColl); freeHeapWritableBuffer(tColl); if (sCEs.buf != sCEs.localArray ) { uprv_free(sCEs.buf); } if (tCEs.buf != tCEs.localArray ) { uprv_free(tCEs.buf); } } return result; } static inline uint32_t ucol_getLatinOneContraction(const UCollator *coll, int32_t strength, uint32_t CE, const UChar *s, int32_t *index, int32_t len) { const UChar *UCharOffset = (UChar *)coll->image+getContractOffset(CE&0xFFF); int32_t latinOneOffset = (CE & 0x00FFF000) >> 12; int32_t offset = 1; UChar schar = 0, tchar = 0; for(;;) { if(len == -1) { if(s[*index] == 0) { // end of string return(coll->latinOneCEs[strength*coll->latinOneTableLen+latinOneOffset]); } else { schar = s[*index]; } } else { if(*index == len) { return(coll->latinOneCEs[strength*coll->latinOneTableLen+latinOneOffset]); } else { schar = s[*index]; } } while(schar > (tchar = *(UCharOffset+offset))) { /* since the contraction codepoints should be ordered, we skip all that are smaller */ offset++; } if (schar == tchar) { (*index)++; return(coll->latinOneCEs[strength*coll->latinOneTableLen+latinOneOffset+offset]); } else { if(schar & 0xFF00 /*> UCOL_ENDOFLATIN1RANGE*/) { return UCOL_BAIL_OUT_CE; } // skip completely ignorables uint32_t isZeroCE = UTRIE_GET32_FROM_LEAD(coll->mapping, schar); if(isZeroCE == 0) { // we have to ignore completely ignorables (*index)++; continue; } return(coll->latinOneCEs[strength*coll->latinOneTableLen+latinOneOffset]); } } } /** * This is a fast strcoll, geared towards text in Latin-1. * It supports contractions of size two, French secondaries * and case switching. You can use it with strengths primary * to tertiary. It does not support shifted and case level. * It relies on the table build by setupLatin1Table. If it * doesn't understand something, it will go to the regular * strcoll. */ static inline UCollationResult ucol_strcollUseLatin1( const UCollator *coll, const UChar *source, int32_t sLen, const UChar *target, int32_t tLen, UErrorCode *status) { U_ALIGN_CODE(16); int32_t strength = coll->strength; int32_t sIndex = 0, tIndex = 0; UChar sChar = 0, tChar = 0; uint32_t sOrder=0, tOrder=0; UBool endOfSource = FALSE, endOfTarget = FALSE; uint32_t *elements = coll->latinOneCEs; UBool haveContractions = FALSE; // if we have contractions in our string // we cannot do French secondary // Do the primary level for(;;) { while(sOrder==0) { // this loop skips primary ignorables // sOrder=getNextlatinOneCE(source); if(sLen==-1) { // handling zero terminated strings sChar=source[sIndex++]; if(sChar==0) { endOfSource = TRUE; break; } } else { // handling strings with known length if(sIndex==sLen) { endOfSource = TRUE; break; } sChar=source[sIndex++]; } if(sChar&0xFF00) { // if we encounter non-latin-1, we bail out (sChar > 0xFF, but this is faster on win32) //fprintf(stderr, "R"); goto returnRegular; //return ucol_strcollRegular(coll, source, sLen, target, tLen, status); } sOrder = elements[sChar]; if(sOrder >= UCOL_NOT_FOUND) { // if we got a special // specials can basically be either contractions or bail-out signs. If we get anything // else, we'll bail out anywasy if(getCETag(sOrder) == CONTRACTION_TAG) { sOrder = ucol_getLatinOneContraction(coll, UCOL_PRIMARY, sOrder, source, &sIndex, sLen); haveContractions = TRUE; // if there are contractions, we cannot do French secondary // However, if there are contractions in the table, but we always use just one char, // we might be able to do French. This should be checked out. } if(sOrder >= UCOL_NOT_FOUND /*== UCOL_BAIL_OUT_CE*/) { //fprintf(stderr, "S"); goto returnRegular; //return ucol_strcollRegular(coll, source, sLen, target, tLen, status); } } } while(tOrder==0) { // this loop skips primary ignorables // tOrder=getNextlatinOneCE(target); if(tLen==-1) { // handling zero terminated strings tChar=target[tIndex++]; if(tChar==0) { if(endOfSource) { // this is different than source loop, // as we already know that source loop is done here, // so we can either finish the primary loop if both // strings are done or anounce the result if only // target is done. Same below. goto endOfPrimLoop; } else { return UCOL_GREATER; } } } else { // handling strings with known length if(tIndex==tLen) { if(endOfSource) { goto endOfPrimLoop; } else { return UCOL_GREATER; } } tChar=target[tIndex++]; } if(tChar&0xFF00) { // if we encounter non-latin-1, we bail out (sChar > 0xFF, but this is faster on win32) //fprintf(stderr, "R"); goto returnRegular; //return ucol_strcollRegular(coll, source, sLen, target, tLen, status); } tOrder = elements[tChar]; if(tOrder >= UCOL_NOT_FOUND) { // Handling specials, see the comments for source if(getCETag(tOrder) == CONTRACTION_TAG) { tOrder = ucol_getLatinOneContraction(coll, UCOL_PRIMARY, tOrder, target, &tIndex, tLen); haveContractions = TRUE; } if(tOrder >= UCOL_NOT_FOUND /*== UCOL_BAIL_OUT_CE*/) { //fprintf(stderr, "S"); goto returnRegular; //return ucol_strcollRegular(coll, source, sLen, target, tLen, status); } } } if(endOfSource) { // source is finished, but target is not, say the result. return UCOL_LESS; } if(sOrder == tOrder) { // if we have same CEs, we continue the loop sOrder = 0; tOrder = 0; continue; } else { // compare current top bytes if(((sOrder^tOrder)&0xFF000000)!=0) { // top bytes differ, return difference if(sOrder < tOrder) { return UCOL_LESS; } else if(sOrder > tOrder) { return UCOL_GREATER; } // instead of return (int32_t)(sOrder>>24)-(int32_t)(tOrder>>24); // since we must return enum value } // top bytes match, continue with following bytes sOrder<<=8; tOrder<<=8; } } endOfPrimLoop: // after primary loop, we definitely know the sizes of strings, // so we set it and use simpler loop for secondaries and tertiaries sLen = sIndex; tLen = tIndex; if(strength >= UCOL_SECONDARY) { // adjust the table beggining elements += coll->latinOneTableLen; endOfSource = FALSE; endOfTarget = FALSE; if(coll->frenchCollation == UCOL_OFF) { // non French // This loop is a simplified copy of primary loop // at this point we know that whole strings are latin-1, so we don't // check for that. We also know that we only have contractions as // specials. sIndex = 0; tIndex = 0; for(;;) { while(sOrder==0) { if(sIndex==sLen) { endOfSource = TRUE; break; } sChar=source[sIndex++]; sOrder = elements[sChar]; if(sOrder > UCOL_NOT_FOUND) { sOrder = ucol_getLatinOneContraction(coll, UCOL_SECONDARY, sOrder, source, &sIndex, sLen); } } while(tOrder==0) { if(tIndex==tLen) { if(endOfSource) { goto endOfSecLoop; } else { return UCOL_GREATER; } } tChar=target[tIndex++]; tOrder = elements[tChar]; if(tOrder > UCOL_NOT_FOUND) { tOrder = ucol_getLatinOneContraction(coll, UCOL_SECONDARY, tOrder, target, &tIndex, tLen); } } if(endOfSource) { return UCOL_LESS; } if(sOrder == tOrder) { sOrder = 0; tOrder = 0; continue; } else { // see primary loop for comments on this if(((sOrder^tOrder)&0xFF000000)!=0) { if(sOrder < tOrder) { return UCOL_LESS; } else if(sOrder > tOrder) { return UCOL_GREATER; } } sOrder<<=8; tOrder<<=8; } } } else { // French if(haveContractions) { // if we have contractions, we have to bail out // since we don't really know how to handle them here goto returnRegular; //return ucol_strcollRegular(coll, source, sLen, target, tLen, status); } // For French, we go backwards sIndex = sLen; tIndex = tLen; for(;;) { while(sOrder==0) { if(sIndex==0) { endOfSource = TRUE; break; } sChar=source[--sIndex]; sOrder = elements[sChar]; // don't even look for contractions } while(tOrder==0) { if(tIndex==0) { if(endOfSource) { goto endOfSecLoop; } else { return UCOL_GREATER; } } tChar=target[--tIndex]; tOrder = elements[tChar]; // don't even look for contractions } if(endOfSource) { return UCOL_LESS; } if(sOrder == tOrder) { sOrder = 0; tOrder = 0; continue; } else { // see the primary loop for comments if(((sOrder^tOrder)&0xFF000000)!=0) { if(sOrder < tOrder) { return UCOL_LESS; } else if(sOrder > tOrder) { return UCOL_GREATER; } } sOrder<<=8; tOrder<<=8; } } } } endOfSecLoop: if(strength >= UCOL_TERTIARY) { // tertiary loop is the same as secondary (except no French) elements += coll->latinOneTableLen; sIndex = 0; tIndex = 0; endOfSource = FALSE; endOfTarget = FALSE; for(;;) { while(sOrder==0) { if(sIndex==sLen) { endOfSource = TRUE; break; } sChar=source[sIndex++]; sOrder = elements[sChar]; if(sOrder > UCOL_NOT_FOUND) { sOrder = ucol_getLatinOneContraction(coll, UCOL_TERTIARY, sOrder, source, &sIndex, sLen); } } while(tOrder==0) { if(tIndex==tLen) { if(endOfSource) { return UCOL_EQUAL; // if both strings are at the end, they are equal } else { return UCOL_GREATER; } } tChar=target[tIndex++]; tOrder = elements[tChar]; if(tOrder > UCOL_NOT_FOUND) { tOrder = ucol_getLatinOneContraction(coll, UCOL_TERTIARY, tOrder, target, &tIndex, tLen); } } if(endOfSource) { return UCOL_LESS; } if(sOrder == tOrder) { sOrder = 0; tOrder = 0; continue; } else { if(((sOrder^tOrder)&0xff000000)!=0) { if(sOrder < tOrder) { return UCOL_LESS; } else if(sOrder > tOrder) { return UCOL_GREATER; } } sOrder<<=8; tOrder<<=8; } } } return UCOL_EQUAL; returnRegular: // Preparing the context objects for iterating over strings collIterate sColl, tColl; IInit_collIterate(coll, source, sLen, &sColl); IInit_collIterate(coll, target, tLen, &tColl); return ucol_strcollRegular(&sColl, &tColl, status); } U_CAPI UCollationResult U_EXPORT2 ucol_strcollIter( const UCollator *coll, UCharIterator *sIter, UCharIterator *tIter, UErrorCode *status) { if(!status || U_FAILURE(*status)) { return UCOL_EQUAL; } UTRACE_ENTRY(UTRACE_UCOL_STRCOLLITER); UTRACE_DATA3(UTRACE_VERBOSE, "coll=%p, sIter=%p, tIter=%p", coll, sIter, tIter); if (sIter == tIter) { UTRACE_EXIT_VALUE_STATUS(UCOL_EQUAL, *status) return UCOL_EQUAL; } if(sIter == NULL || tIter == NULL || coll == NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; UTRACE_EXIT_VALUE_STATUS(UCOL_EQUAL, *status) return UCOL_EQUAL; } UCollationResult result = UCOL_EQUAL; // Preparing the context objects for iterating over strings collIterate sColl, tColl; // The division for the array length may truncate the array size to // a little less than UNORM_ITER_SIZE, but that size is dimensioned too high // for all platforms anyway. UAlignedMemory stackNormIter1[UNORM_ITER_SIZE/sizeof(UAlignedMemory)]; UAlignedMemory stackNormIter2[UNORM_ITER_SIZE/sizeof(UAlignedMemory)]; UNormIterator *sNormIter = NULL, *tNormIter = NULL; IInit_collIterate(coll, NULL, -1, &sColl); sColl.iterator = sIter; sColl.flags |= UCOL_USE_ITERATOR; IInit_collIterate(coll, NULL, -1, &tColl); tColl.flags |= UCOL_USE_ITERATOR; tColl.iterator = tIter; if(ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, status) == UCOL_ON) { sNormIter = unorm_openIter(stackNormIter1, sizeof(stackNormIter1), status); sColl.iterator = unorm_setIter(sNormIter, sIter, UNORM_FCD, status); sColl.flags &= ~UCOL_ITER_NORM; tNormIter = unorm_openIter(stackNormIter2, sizeof(stackNormIter2), status); tColl.iterator = unorm_setIter(tNormIter, tIter, UNORM_FCD, status); tColl.flags &= ~UCOL_ITER_NORM; } UChar32 sChar = U_SENTINEL, tChar = U_SENTINEL; while((sChar = sColl.iterator->next(sColl.iterator)) == (tChar = tColl.iterator->next(tColl.iterator))) { if(UCOL_ISTHAIPREVOWEL(sChar)) { break; } if(sChar == U_SENTINEL) { result = UCOL_EQUAL; goto end_compare; } } if(sChar == U_SENTINEL) { tChar = tColl.iterator->previous(tColl.iterator); } if(tChar == U_SENTINEL) { sChar = sColl.iterator->previous(sColl.iterator); } sChar = sColl.iterator->previous(sColl.iterator); tChar = tColl.iterator->previous(tColl.iterator); if (ucol_unsafeCP((UChar)sChar, coll) || ucol_unsafeCP((UChar)tChar, coll)) { // We are stopped in the middle of a contraction. // Scan backwards through the == part of the string looking for the start of the contraction. // It doesn't matter which string we scan, since they are the same in this region. do { sChar = sColl.iterator->previous(sColl.iterator); tChar = tColl.iterator->previous(tColl.iterator); } while (sChar != U_SENTINEL && ucol_unsafeCP((UChar)sChar, coll)); } if(U_SUCCESS(*status)) { result = ucol_strcollRegular(&sColl, &tColl, status); } end_compare: if(sNormIter || tNormIter) { unorm_closeIter(sNormIter); unorm_closeIter(tNormIter); } UTRACE_EXIT_VALUE_STATUS(result, *status) return result; } /* */ /* ucol_strcoll Main public API string comparison function */ /* */ U_CAPI UCollationResult U_EXPORT2 ucol_strcoll( const UCollator *coll, const UChar *source, int32_t sourceLength, const UChar *target, int32_t targetLength) { U_ALIGN_CODE(16); UTRACE_ENTRY(UTRACE_UCOL_STRCOLL); if (UTRACE_LEVEL(UTRACE_VERBOSE)) { UTRACE_DATA3(UTRACE_VERBOSE, "coll=%p, source=%p, target=%p", coll, source, target); UTRACE_DATA2(UTRACE_VERBOSE, "source string = %vh ", source, sourceLength); UTRACE_DATA2(UTRACE_VERBOSE, "target string = %vh ", target, targetLength); } UErrorCode status = U_ZERO_ERROR; if(source == NULL || target == NULL) { // do not crash, but return. Should have // status argument to return error. UTRACE_EXIT_VALUE(UTRACE_UCOL_STRCOLL); return UCOL_EQUAL; } collIterate sColl, tColl; /* Scan the strings. Find: */ /* The length of any leading portion that is equal */ /* Whether they are exactly equal. (in which case we just return) */ const UChar *pSrc = source; const UChar *pTarg = target; int32_t equalLength; if (sourceLength == -1 && targetLength == -1) { // Both strings are null terminated. // Check for them being the same string, and scan through // any leading equal portion. if (source==target) { UTRACE_EXIT_VALUE(UCOL_EQUAL); return UCOL_EQUAL; } for (;;) { if ( *pSrc != *pTarg || *pSrc == 0) { break; } if(UCOL_ISTHAIPREVOWEL(*pSrc)) { break; } pSrc++; pTarg++; } if (*pSrc == 0 && *pTarg == 0) { UTRACE_EXIT_VALUE(UCOL_EQUAL); return UCOL_EQUAL; } equalLength = pSrc - source; } else { // One or both strings has an explicit length. /* check if source and target are same strings */ if (source==target && sourceLength==targetLength) { UTRACE_EXIT_VALUE(UCOL_EQUAL); return UCOL_EQUAL; } const UChar *pSrcEnd = source + sourceLength; const UChar *pTargEnd = target + targetLength; // Scan while the strings are bitwise ==, or until one is exhausted. for (;;) { if (pSrc == pSrcEnd || pTarg == pTargEnd) { break; } if ((*pSrc == 0 && sourceLength == -1) || (*pTarg == 0 && targetLength == -1)) { break; } if (*pSrc != *pTarg) { break; } if(UCOL_ISTHAIPREVOWEL(*pSrc)) { // they are the same here, so any will do break; } pSrc++; pTarg++; } equalLength = pSrc - source; // If we made it all the way through both strings, we are done. They are == if ((pSrc ==pSrcEnd || (pSrcEnd 0) { /* There is an identical portion at the beginning of the two strings. */ /* If the identical portion ends within a contraction or a comibining */ /* character sequence, back up to the start of that sequence. */ pSrc = source + equalLength; /* point to the first differing chars */ pTarg = target + equalLength; if (pSrc != source+sourceLength && ucol_unsafeCP(*pSrc, coll) || pTarg != target+targetLength && ucol_unsafeCP(*pTarg, coll)) { // We are stopped in the middle of a contraction. // Scan backwards through the == part of the string looking for the start of the contraction. // It doesn't matter which string we scan, since they are the same in this region. do { equalLength--; pSrc--; } while (equalLength>0 && ucol_unsafeCP(*pSrc, coll)); } source += equalLength; target += equalLength; if (sourceLength > 0) { sourceLength -= equalLength; } if (targetLength > 0) { targetLength -= equalLength; } } UCollationResult returnVal; if(!coll->latinOneUse || (sourceLength > 0 && *source&0xff00) || (targetLength > 0 && *target&0xff00)) { // Preparing the context objects for iterating over strings IInit_collIterate(coll, source, sourceLength, &sColl); IInit_collIterate(coll, target, targetLength, &tColl); returnVal = ucol_strcollRegular(&sColl, &tColl, &status); } else { returnVal = ucol_strcollUseLatin1(coll, source, sourceLength, target, targetLength, &status); } UTRACE_EXIT_VALUE(returnVal); return returnVal; } /* convenience function for comparing strings */ U_CAPI UBool U_EXPORT2 ucol_greater( const UCollator *coll, const UChar *source, int32_t sourceLength, const UChar *target, int32_t targetLength) { return (ucol_strcoll(coll, source, sourceLength, target, targetLength) == UCOL_GREATER); } /* convenience function for comparing strings */ U_CAPI UBool U_EXPORT2 ucol_greaterOrEqual( const UCollator *coll, const UChar *source, int32_t sourceLength, const UChar *target, int32_t targetLength) { return (ucol_strcoll(coll, source, sourceLength, target, targetLength) != UCOL_LESS); } /* convenience function for comparing strings */ U_CAPI UBool U_EXPORT2 ucol_equal( const UCollator *coll, const UChar *source, int32_t sourceLength, const UChar *target, int32_t targetLength) { return (ucol_strcoll(coll, source, sourceLength, target, targetLength) == UCOL_EQUAL); } /* returns the locale name the collation data comes from */ U_CAPI const char * U_EXPORT2 ucol_getLocale(const UCollator *coll, ULocDataLocaleType type, UErrorCode *status) { return ucol_getLocaleByType(coll, type, status); } U_CAPI const char * U_EXPORT2 ucol_getLocaleByType(const UCollator *coll, ULocDataLocaleType type, UErrorCode *status) { const char *result = NULL; if(status == NULL || U_FAILURE(*status)) { return NULL; } UTRACE_ENTRY(UTRACE_UCOL_GETLOCALE); UTRACE_DATA1(UTRACE_INFO, "coll=%p", coll); switch(type) { case ULOC_ACTUAL_LOCALE: // validLocale is set only if service registration has explicitly set the // requested and valid locales. if this is the case, the actual locale // is considered to be the valid locale. if (coll->validLocale != NULL) { result = coll->validLocale; } else if(coll->elements != NULL) { result = ures_getLocale(coll->elements, status); } break; case ULOC_VALID_LOCALE: if (coll->validLocale != NULL) { result = coll->validLocale; } else if(coll->rb != NULL) { result = ures_getLocale(coll->rb, status); } break; case ULOC_REQUESTED_LOCALE: result = coll->requestedLocale; break; default: *status = U_ILLEGAL_ARGUMENT_ERROR; } UTRACE_DATA1(UTRACE_INFO, "result = %s", result); UTRACE_EXIT_STATUS(*status); return result; } U_CAPI USet * U_EXPORT2 ucol_getTailoredSet(const UCollator *coll, UErrorCode *status) { if(status == NULL || U_FAILURE(*status)) { return NULL; } if(coll == NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; } UParseError parseError; UColTokenParser src; int32_t rulesLen = 0; const UChar *rules = ucol_getRules(coll, &rulesLen); const UChar *current = NULL; UBool startOfRules = TRUE; // we internally use the C++ class, for the following reasons: // 1. we need to utilize canonical iterator, which is a C++ only class // 2. canonical iterator returns UnicodeStrings - USet cannot take them // 3. USet is internally really UnicodeSet, C is just a wrapper UnicodeSet *tailored = new UnicodeSet(); UnicodeString pattern; CanonicalIterator it("", *status); // The idea is to tokenize the rule set. For each non-reset token, // we add all the canonicaly equivalent FCD sequences ucol_tok_initTokenList(&src, rules, rulesLen, coll->UCA, status); while ((current = ucol_tok_parseNextToken(&src, startOfRules, &parseError, status)) != NULL) { startOfRules = FALSE; if(src.parsedToken.strength != UCOL_TOK_RESET) { const UChar *stuff = src.source+(src.parsedToken.charsOffset); it.setSource(UnicodeString(stuff, src.parsedToken.charsLen), *status); pattern = it.next(); while(!pattern.isBogus()) { if(Normalizer::quickCheck(pattern, UNORM_FCD, *status) != UNORM_NO) { tailored->add(pattern); } pattern = it.next(); } } } ucol_tok_closeTokenList(&src); return (USet *)tailored; } U_CAPI UBool U_EXPORT2 ucol_equals(const UCollator *source, const UCollator *target) { UErrorCode status = U_ZERO_ERROR; // if pointers are equal, collators are equal if(source == target) { return TRUE; } int32_t i = 0, j = 0; // if any of attributes are different, collators are not equal for(i = 0; i < UCOL_ATTRIBUTE_COUNT; i++) { if(ucol_getAttribute(source, (UColAttribute)i, &status) != ucol_getAttribute(target, (UColAttribute)i, &status) || U_FAILURE(status)) { return FALSE; } } int32_t sourceRulesLen = 0, targetRulesLen = 0; const UChar *sourceRules = ucol_getRules(source, &sourceRulesLen); const UChar *targetRules = ucol_getRules(target, &targetRulesLen); if(sourceRulesLen == targetRulesLen && u_strncmp(sourceRules, targetRules, sourceRulesLen) == 0) { // all the attributes are equal and the rules are equal - collators are equal return(TRUE); } // hard part, need to construct tree from rules and see if they yield the same tailoring UBool result = TRUE; UParseError parseError; UColTokenParser sourceParser, targetParser; int32_t sourceListLen = 0, targetListLen = 0; ucol_tok_initTokenList(&sourceParser, sourceRules, sourceRulesLen, source->UCA, &status); ucol_tok_initTokenList(&targetParser, targetRules, targetRulesLen, target->UCA, &status); sourceListLen = ucol_tok_assembleTokenList(&sourceParser, &parseError, &status); targetListLen = ucol_tok_assembleTokenList(&targetParser, &parseError, &status); if(sourceListLen != targetListLen) { // different number of resets result = FALSE; } else { UColToken *sourceReset = NULL, *targetReset = NULL; UChar *sourceResetString = NULL, *targetResetString = NULL; int32_t sourceStringLen = 0, targetStringLen = 0; for(i = 0; i < sourceListLen; i++) { sourceReset = sourceParser.lh[i].reset; sourceResetString = sourceParser.source+(sourceReset->source & 0xFFFFFF); sourceStringLen = sourceReset->source >> 24; for(j = 0; j < sourceListLen; j++) { targetReset = targetParser.lh[j].reset; targetResetString = targetParser.source+(targetReset->source & 0xFFFFFF); targetStringLen = targetReset->source >> 24; if(sourceStringLen == targetStringLen && (u_strncmp(sourceResetString, targetResetString, sourceStringLen) == 0)) { sourceReset = sourceParser.lh[i].first; targetReset = targetParser.lh[j].first; while(sourceReset != NULL && targetReset != NULL) { sourceResetString = sourceParser.source+(sourceReset->source & 0xFFFFFF); sourceStringLen = sourceReset->source >> 24; targetResetString = targetParser.source+(targetReset->source & 0xFFFFFF); targetStringLen = targetReset->source >> 24; if(sourceStringLen != targetStringLen || (u_strncmp(sourceResetString, targetResetString, sourceStringLen) != 0)) { result = FALSE; goto returnResult; } // probably also need to check the expansions if(sourceReset->expansion) { if(!targetReset->expansion) { result = FALSE; goto returnResult; } else { // compare expansions sourceResetString = sourceParser.source+(sourceReset->expansion& 0xFFFFFF); sourceStringLen = sourceReset->expansion >> 24; targetResetString = targetParser.source+(targetReset->expansion & 0xFFFFFF); targetStringLen = targetReset->expansion >> 24; if(sourceStringLen != targetStringLen || (u_strncmp(sourceResetString, targetResetString, sourceStringLen) != 0)) { result = FALSE; goto returnResult; } } } else { if(targetReset->expansion) { result = FALSE; goto returnResult; } } sourceReset = sourceReset->next; targetReset = targetReset->next; } if(sourceReset != targetReset) { // at least one is not NULL // there are more tailored elements in one list result = FALSE; goto returnResult; } break; } } // couldn't find the reset anchor, so the collators are not equal if(j == sourceListLen) { result = FALSE; goto returnResult; } } } returnResult: ucol_tok_closeTokenList(&sourceParser); ucol_tok_closeTokenList(&targetParser); return result; } U_CAPI void U_EXPORT2 ucol_getUCAVersion(const UCollator* coll, UVersionInfo info) { if(coll) { uprv_memcpy(info, coll->UCA->image->UCAVersion, sizeof(UVersionInfo)); } } #endif /* #if !UCONFIG_NO_COLLATION */