/* ******************************************************************************* * Copyright (C) 2007-2011, International Business Machines Corporation and * others. All Rights Reserved. ******************************************************************************* * * File PLURRULE.CPP * * Modification History: * * Date Name Description ******************************************************************************* */ #include "unicode/utypes.h" #include "unicode/localpointer.h" #include "unicode/plurrule.h" #include "unicode/ures.h" #include "cmemory.h" #include "cstring.h" #include "hash.h" #include "mutex.h" #include "patternprops.h" #include "plurrule_impl.h" #include "putilimp.h" #include "ucln_in.h" #include "uhash.h" #include "ustrfmt.h" #include "locutil.h" #if !UCONFIG_NO_FORMATTING U_NAMESPACE_BEGIN // shared by all instances when lazy-initializing samples static UMTX pluralMutex; #define ARRAY_SIZE(array) (int32_t)(sizeof array / sizeof array[0]) static const UChar PLURAL_KEYWORD_OTHER[]={LOW_O,LOW_T,LOW_H,LOW_E,LOW_R,0}; static const UChar PLURAL_DEFAULT_RULE[]={LOW_O,LOW_T,LOW_H,LOW_E,LOW_R,COLON,SPACE,LOW_N,0}; static const UChar PK_IN[]={LOW_I,LOW_N,0}; static const UChar PK_NOT[]={LOW_N,LOW_O,LOW_T,0}; static const UChar PK_IS[]={LOW_I,LOW_S,0}; static const UChar PK_MOD[]={LOW_M,LOW_O,LOW_D,0}; static const UChar PK_AND[]={LOW_A,LOW_N,LOW_D,0}; static const UChar PK_OR[]={LOW_O,LOW_R,0}; static const UChar PK_VAR_N[]={LOW_N,0}; static const UChar PK_WITHIN[]={LOW_W,LOW_I,LOW_T,LOW_H,LOW_I,LOW_N,0}; UOBJECT_DEFINE_RTTI_IMPLEMENTATION(PluralRules) UOBJECT_DEFINE_RTTI_IMPLEMENTATION(PluralKeywordEnumeration) PluralRules::PluralRules(UErrorCode& status) : UObject(), mRules(NULL), mParser(NULL), mSamples(NULL), mSampleInfo(NULL), mSampleInfoCount(0) { if (U_FAILURE(status)) { return; } mParser = new RuleParser(); if (mParser==NULL) { status = U_MEMORY_ALLOCATION_ERROR; } } PluralRules::PluralRules(const PluralRules& other) : UObject(other), mRules(NULL), mParser(NULL), mSamples(NULL), mSampleInfo(NULL), mSampleInfoCount(0) { *this=other; } PluralRules::~PluralRules() { delete mRules; delete mParser; uprv_free(mSamples); uprv_free(mSampleInfo); } PluralRules* PluralRules::clone() const { return new PluralRules(*this); } PluralRules& PluralRules::operator=(const PluralRules& other) { if (this != &other) { delete mRules; if (other.mRules==NULL) { mRules = NULL; } else { mRules = new RuleChain(*other.mRules); } delete mParser; mParser = new RuleParser(); uprv_free(mSamples); mSamples = NULL; uprv_free(mSampleInfo); mSampleInfo = NULL; mSampleInfoCount = 0; } return *this; } PluralRules* U_EXPORT2 PluralRules::createRules(const UnicodeString& description, UErrorCode& status) { RuleChain rules; if (U_FAILURE(status)) { return NULL; } PluralRules *newRules = new PluralRules(status); if ( (newRules != NULL)&& U_SUCCESS(status) ) { newRules->parseDescription((UnicodeString &)description, rules, status); if (U_SUCCESS(status)) { newRules->addRules(rules); } } if (U_FAILURE(status)) { delete newRules; return NULL; } else { return newRules; } } PluralRules* U_EXPORT2 PluralRules::createDefaultRules(UErrorCode& status) { return createRules(PLURAL_DEFAULT_RULE, status); } PluralRules* U_EXPORT2 PluralRules::forLocale(const Locale& locale, UErrorCode& status) { RuleChain rChain; if (U_FAILURE(status)) { return NULL; } PluralRules *newObj = new PluralRules(status); if (newObj==NULL || U_FAILURE(status)) { delete newObj; return NULL; } UnicodeString locRule = newObj->getRuleFromResource(locale, status); if ((locRule.length() != 0) && U_SUCCESS(status)) { newObj->parseDescription(locRule, rChain, status); if (U_SUCCESS(status)) { newObj->addRules(rChain); } } if (U_FAILURE(status)||(locRule.length() == 0)) { // use default plural rule status = U_ZERO_ERROR; UnicodeString defRule = UnicodeString(PLURAL_DEFAULT_RULE); newObj->parseDescription(defRule, rChain, status); newObj->addRules(rChain); } return newObj; } UnicodeString PluralRules::select(int32_t number) const { if (mRules == NULL) { return PLURAL_DEFAULT_RULE; } else { return mRules->select(number); } } UnicodeString PluralRules::select(double number) const { if (mRules == NULL) { return PLURAL_DEFAULT_RULE; } else { return mRules->select(number); } } StringEnumeration* PluralRules::getKeywords(UErrorCode& status) const { if (U_FAILURE(status)) return NULL; StringEnumeration* nameEnumerator = new PluralKeywordEnumeration(mRules, status); if (U_FAILURE(status)) { delete nameEnumerator; return NULL; } return nameEnumerator; } double PluralRules::getUniqueKeywordValue(const UnicodeString& keyword) { double val; UErrorCode status = U_ZERO_ERROR; int32_t count = getSamplesInternal(keyword, &val, 1, FALSE, status); return count == 1 ? val : UPLRULES_NO_UNIQUE_VALUE; } int32_t PluralRules::getAllKeywordValues(const UnicodeString &keyword, double *dest, int32_t destCapacity, UErrorCode& error) { return getSamplesInternal(keyword, dest, destCapacity, FALSE, error); } int32_t PluralRules::getSamples(const UnicodeString &keyword, double *dest, int32_t destCapacity, UErrorCode& status) { return getSamplesInternal(keyword, dest, destCapacity, TRUE, status); } int32_t PluralRules::getSamplesInternal(const UnicodeString &keyword, double *dest, int32_t destCapacity, UBool includeUnlimited, UErrorCode& status) { initSamples(status); if (U_FAILURE(status)) { return -1; } if (destCapacity < 0 || (dest == NULL && destCapacity > 0)) { status = U_ILLEGAL_ARGUMENT_ERROR; return -1; } int32_t index = getKeywordIndex(keyword, status); if (index == -1) { return 0; } const int32_t LIMIT_MASK = 0x1 << 31; if (!includeUnlimited) { if ((mSampleInfo[index] & LIMIT_MASK) == 0) { return -1; } } int32_t start = index == 0 ? 0 : mSampleInfo[index - 1] & ~LIMIT_MASK; int32_t limit = mSampleInfo[index] & ~LIMIT_MASK; int32_t len = limit - start; if (len <= destCapacity) { destCapacity = len; } else if (includeUnlimited) { len = destCapacity; // no overflow, and don't report more than we copy } else { status = U_BUFFER_OVERFLOW_ERROR; return len; } for (int32_t i = 0; i < destCapacity; ++i, ++start) { dest[i] = mSamples[start]; } return len; } UBool PluralRules::isKeyword(const UnicodeString& keyword) const { if ( keyword == PLURAL_KEYWORD_OTHER ) { return true; } else { if (mRules==NULL) { return false; } else { return mRules->isKeyword(keyword); } } } UnicodeString PluralRules::getKeywordOther() const { return PLURAL_KEYWORD_OTHER; } UBool PluralRules::operator==(const PluralRules& other) const { int32_t limit; const UnicodeString *ptrKeyword; UErrorCode status= U_ZERO_ERROR; if ( this == &other ) { return TRUE; } LocalPointer myKeywordList(getKeywords(status)); LocalPointer otherKeywordList(other.getKeywords(status)); if (U_FAILURE(status)) { return FALSE; } if (myKeywordList->count(status)!=otherKeywordList->count(status)) { return FALSE; } myKeywordList->reset(status); while ((ptrKeyword=myKeywordList->snext(status))!=NULL) { if (!other.isKeyword(*ptrKeyword)) { return FALSE; } } otherKeywordList->reset(status); while ((ptrKeyword=otherKeywordList->snext(status))!=NULL) { if (!this->isKeyword(*ptrKeyword)) { return FALSE; } } if (U_FAILURE(status)) { return FALSE; } if ((limit=this->getRepeatLimit()) != other.getRepeatLimit()) { return FALSE; } UnicodeString myKeyword, otherKeyword; for (int32_t i=0; iselect(i); otherKeyword = other.select(i); if (myKeyword!=otherKeyword) { return FALSE; } } return TRUE; } void PluralRules::parseDescription(UnicodeString& data, RuleChain& rules, UErrorCode &status) { int32_t ruleIndex=0; UnicodeString token; tokenType type; tokenType prevType=none; RuleChain *ruleChain=NULL; AndConstraint *curAndConstraint=NULL; OrConstraint *orNode=NULL; RuleChain *lastChain=NULL; if (U_FAILURE(status)) { return; } UnicodeString ruleData = data.toLower(); while (ruleIndex< ruleData.length()) { mParser->getNextToken(ruleData, &ruleIndex, token, type, status); if (U_FAILURE(status)) { return; } mParser->checkSyntax(prevType, type, status); if (U_FAILURE(status)) { return; } switch (type) { case tAnd: curAndConstraint = curAndConstraint->add(); break; case tOr: lastChain = &rules; while (lastChain->next !=NULL) { lastChain = lastChain->next; } orNode=lastChain->ruleHeader; while (orNode->next != NULL) { orNode = orNode->next; } orNode->next= new OrConstraint(); orNode=orNode->next; orNode->next=NULL; curAndConstraint = orNode->add(); break; case tIs: curAndConstraint->rangeHigh=-1; break; case tNot: curAndConstraint->notIn=TRUE; break; case tIn: curAndConstraint->rangeHigh=PLURAL_RANGE_HIGH; curAndConstraint->integerOnly = TRUE; break; case tWithin: curAndConstraint->rangeHigh=PLURAL_RANGE_HIGH; break; case tNumber: if ( (curAndConstraint->op==AndConstraint::MOD)&& (curAndConstraint->opNum == -1 ) ) { curAndConstraint->opNum=getNumberValue(token); } else { if (curAndConstraint->rangeLow == -1) { curAndConstraint->rangeLow=getNumberValue(token); } else { curAndConstraint->rangeHigh=getNumberValue(token); } } break; case tMod: curAndConstraint->op=AndConstraint::MOD; break; case tKeyword: if (ruleChain==NULL) { ruleChain = &rules; } else { while (ruleChain->next!=NULL){ ruleChain=ruleChain->next; } ruleChain=ruleChain->next=new RuleChain(); } orNode = ruleChain->ruleHeader = new OrConstraint(); curAndConstraint = orNode->add(); ruleChain->keyword = token; break; default: break; } prevType=type; } } int32_t PluralRules::getNumberValue(const UnicodeString& token) const { int32_t i; char digits[128]; i = token.extract(0, token.length(), digits, ARRAY_SIZE(digits), US_INV); digits[i]='\0'; return((int32_t)atoi(digits)); } void PluralRules::getNextLocale(const UnicodeString& localeData, int32_t* curIndex, UnicodeString& localeName) { int32_t i=*curIndex; localeName.remove(); while (i< localeData.length()) { if ( (localeData.charAt(i)!= SPACE) && (localeData.charAt(i)!= COMMA) ) { break; } i++; } while (i< localeData.length()) { if ( (localeData.charAt(i)== SPACE) || (localeData.charAt(i)== COMMA) ) { break; } localeName+=localeData.charAt(i++); } *curIndex=i; } int32_t PluralRules::getRepeatLimit() const { if (mRules!=NULL) { return mRules->getRepeatLimit(); } else { return 0; } } int32_t PluralRules::getKeywordIndex(const UnicodeString& keyword, UErrorCode& status) const { if (U_SUCCESS(status)) { int32_t n = 0; RuleChain* rc = mRules; while (rc != NULL) { if (rc->ruleHeader != NULL) { if (rc->keyword == keyword) { return n; } ++n; } rc = rc->next; } if (keyword == PLURAL_KEYWORD_OTHER) { return n; } } return -1; } typedef struct SampleRecord { int32_t ruleIndex; double value; } SampleRecord; void PluralRules::initSamples(UErrorCode& status) { if (U_FAILURE(status)) { return; } Mutex lock(&pluralMutex); if (mSamples) { return; } // Note, the original design let you have multiple rules with the same keyword. But // we don't use that in our data and existing functions in this implementation don't // fully support it (for example, the returned keywords is a list and not a set). // // So I don't support this here either. If you ask for samples, or for all values, // you will get information about the first rule with that keyword, not all rules with // that keyword. int32_t maxIndex = 0; int32_t otherIndex = -1; // the value -1 will indicate we added 'other' at end RuleChain* rc = mRules; while (rc != NULL) { if (rc->ruleHeader != NULL) { if (otherIndex == -1 && rc->keyword == PLURAL_KEYWORD_OTHER) { otherIndex = maxIndex; } ++maxIndex; } rc = rc->next; } if (otherIndex == -1) { ++maxIndex; } LocalMemory newSampleInfo; if (NULL == newSampleInfo.allocateInsteadAndCopy(maxIndex)) { status = U_MEMORY_ALLOCATION_ERROR; return; } const int32_t LIMIT_MASK = 0x1 << 31; rc = mRules; int32_t n = 0; while (rc != NULL) { if (rc->ruleHeader != NULL) { newSampleInfo[n++] = rc->ruleHeader->isLimited() ? LIMIT_MASK : 0; } rc = rc->next; } if (otherIndex == -1) { newSampleInfo[maxIndex - 1] = 0; // unlimited } MaybeStackArray newSamples; int32_t sampleCount = 0; int32_t limit = getRepeatLimit() * MAX_SAMPLES * 2; if (limit < 10) { limit = 10; } for (int i = 0, keywordsRemaining = maxIndex; keywordsRemaining > 0 && i < limit; ++i) { double val = i / 2.0; n = 0; rc = mRules; int32_t found = -1; while (rc != NULL) { if (rc->ruleHeader != NULL) { if (rc->ruleHeader->isFulfilled(val)) { found = n; break; } ++n; } rc = rc->next; } if (found == -1) { // 'other'. If there is an 'other' rule, the rule set is bad since nothing // should leak through, but we don't bother to report that here. found = otherIndex == -1 ? maxIndex - 1 : otherIndex; } if (newSampleInfo[found] == MAX_SAMPLES) { // limit flag not set continue; } newSampleInfo[found] += 1; // won't impact limit flag if (sampleCount == newSamples.getCapacity()) { int32_t newCapacity = sampleCount < 20 ? 128 : sampleCount * 2; if (NULL == newSamples.resize(newCapacity, sampleCount)) { status = U_MEMORY_ALLOCATION_ERROR; return; } } newSamples[sampleCount].ruleIndex = found; newSamples[sampleCount].value = val; ++sampleCount; if (newSampleInfo[found] == MAX_SAMPLES) { // limit flag not set --keywordsRemaining; } } // sort the values by index, leaving order otherwise unchanged // this is just a selection sort for simplicity LocalMemory values; if (NULL == values.allocateInsteadAndCopy(sampleCount)) { status = U_MEMORY_ALLOCATION_ERROR; return; } for (int i = 0, j = 0; i < maxIndex; ++i) { for (int k = 0; k < sampleCount; ++k) { if (newSamples[k].ruleIndex == i) { values[j++] = newSamples[k].value; } } } // convert array of mask/lengths to array of mask/limits limit = 0; for (int i = 0; i < maxIndex; ++i) { int32_t info = newSampleInfo[i]; int32_t len = info & ~LIMIT_MASK; limit += len; // if a rule is 'unlimited' but has fewer than MAX_SAMPLES samples, // it's not really unlimited, so mark it as limited int32_t mask = len < MAX_SAMPLES ? LIMIT_MASK : info & LIMIT_MASK; newSampleInfo[i] = limit | mask; } // ok, we've got good data mSamples = values.orphan(); mSampleInfo = newSampleInfo.orphan(); mSampleInfoCount = maxIndex; } void PluralRules::addRules(RuleChain& rules) { RuleChain *newRule = new RuleChain(rules); this->mRules=newRule; newRule->setRepeatLimit(); } UnicodeString PluralRules::getRuleFromResource(const Locale& locale, UErrorCode& errCode) { UnicodeString emptyStr; if (U_FAILURE(errCode)) { return emptyStr; } UResourceBundle *rb=ures_openDirect(NULL, "plurals", &errCode); if(U_FAILURE(errCode)) { /* total failure, not even root could be opened */ return emptyStr; } UResourceBundle *locRes=ures_getByKey(rb, "locales", NULL, &errCode); if(U_FAILURE(errCode)) { ures_close(rb); return emptyStr; } int32_t resLen=0; const char *curLocaleName=locale.getName(); const UChar* s = ures_getStringByKey(locRes, curLocaleName, &resLen, &errCode); if (s == NULL) { // Check parent locales. UErrorCode status = U_ZERO_ERROR; char parentLocaleName[ULOC_FULLNAME_CAPACITY]; const char *curLocaleName=locale.getName(); int32_t localeNameLen=0; uprv_strcpy(parentLocaleName, curLocaleName); while ((localeNameLen=uloc_getParent(parentLocaleName, parentLocaleName, ULOC_FULLNAME_CAPACITY, &status)) > 0) { resLen=0; s = ures_getStringByKey(locRes, parentLocaleName, &resLen, &status); if (s != NULL) { errCode = U_ZERO_ERROR; break; } status = U_ZERO_ERROR; } } if (s==NULL) { ures_close(locRes); ures_close(rb); return emptyStr; } char setKey[256]; UChar result[256]; u_UCharsToChars(s, setKey, resLen + 1); // printf("\n PluralRule: %s\n", setKey); UResourceBundle *ruleRes=ures_getByKey(rb, "rules", NULL, &errCode); if(U_FAILURE(errCode)) { ures_close(locRes); ures_close(rb); return emptyStr; } resLen=0; UResourceBundle *setRes = ures_getByKey(ruleRes, setKey, NULL, &errCode); if (U_FAILURE(errCode)) { ures_close(ruleRes); ures_close(locRes); ures_close(rb); return emptyStr; } int32_t numberKeys = ures_getSize(setRes); char *key=NULL; int32_t len=0; for(int32_t i=0; iop = other.op; this->opNum=other.opNum; this->rangeLow=other.rangeLow; this->rangeHigh=other.rangeHigh; this->integerOnly=other.integerOnly; this->notIn=other.notIn; if (other.next==NULL) { this->next=NULL; } else { this->next = new AndConstraint(*other.next); } } AndConstraint::~AndConstraint() { if (next!=NULL) { delete next; } } UBool AndConstraint::isFulfilled(double number) { UBool result=TRUE; double value=number; // arrrrrrgh if ((rangeHigh == -1 || integerOnly) && number != uprv_floor(number)) { return notIn; } if ( op == MOD ) { value = (int32_t)value % opNum; } if ( rangeHigh == -1 ) { if ( rangeLow == -1 ) { result = TRUE; // empty rule } else { if ( value == rangeLow ) { result = TRUE; } else { result = FALSE; } } } else { if ((rangeLow <= value) && (value <= rangeHigh)) { if (integerOnly) { if ( value != (int32_t)value) { result = FALSE; } else { result = TRUE; } } else { result = TRUE; } } else { result = FALSE; } } if (notIn) { return !result; } else { return result; } } UBool AndConstraint::isLimited() { return (rangeHigh == -1 || integerOnly) && !notIn && op != MOD; } int32_t AndConstraint::updateRepeatLimit(int32_t maxLimit) { if ( op == MOD ) { return uprv_max(opNum, maxLimit); } else { if ( rangeHigh == -1 ) { return uprv_max(rangeLow, maxLimit); } else{ return uprv_max(rangeHigh, maxLimit); } } } AndConstraint* AndConstraint::add() { this->next = new AndConstraint(); return this->next; } OrConstraint::OrConstraint() { childNode=NULL; next=NULL; } OrConstraint::OrConstraint(const OrConstraint& other) { if ( other.childNode == NULL ) { this->childNode = NULL; } else { this->childNode = new AndConstraint(*(other.childNode)); } if (other.next == NULL ) { this->next = NULL; } else { this->next = new OrConstraint(*(other.next)); } } OrConstraint::~OrConstraint() { if (childNode!=NULL) { delete childNode; } if (next!=NULL) { delete next; } } AndConstraint* OrConstraint::add() { OrConstraint *curOrConstraint=this; { while (curOrConstraint->next!=NULL) { curOrConstraint = curOrConstraint->next; } curOrConstraint->next = NULL; curOrConstraint->childNode = new AndConstraint(); } return curOrConstraint->childNode; } UBool OrConstraint::isFulfilled(double number) { OrConstraint* orRule=this; UBool result=FALSE; while (orRule!=NULL && !result) { result=TRUE; AndConstraint* andRule = orRule->childNode; while (andRule!=NULL && result) { result = andRule->isFulfilled(number); andRule=andRule->next; } orRule = orRule->next; } return result; } UBool OrConstraint::isLimited() { for (OrConstraint *orc = this; orc != NULL; orc = orc->next) { UBool result = FALSE; for (AndConstraint *andc = orc->childNode; andc != NULL; andc = andc->next) { if (andc->isLimited()) { result = TRUE; break; } } if (result == FALSE) { return FALSE; } } return TRUE; } RuleChain::RuleChain() { ruleHeader=NULL; next = NULL; repeatLimit=0; } RuleChain::RuleChain(const RuleChain& other) { this->repeatLimit = other.repeatLimit; this->keyword=other.keyword; if (other.ruleHeader != NULL) { this->ruleHeader = new OrConstraint(*(other.ruleHeader)); } else { this->ruleHeader = NULL; } if (other.next != NULL ) { this->next = new RuleChain(*other.next); } else { this->next = NULL; } } RuleChain::~RuleChain() { if (next != NULL) { delete next; } if ( ruleHeader != NULL ) { delete ruleHeader; } } UnicodeString RuleChain::select(double number) const { if ( ruleHeader != NULL ) { if (ruleHeader->isFulfilled(number)) { return keyword; } } if ( next != NULL ) { return next->select(number); } else { return PLURAL_KEYWORD_OTHER; } } void RuleChain::dumpRules(UnicodeString& result) { UChar digitString[16]; if ( ruleHeader != NULL ) { result += keyword; OrConstraint* orRule=ruleHeader; while ( orRule != NULL ) { AndConstraint* andRule=orRule->childNode; while ( andRule != NULL ) { if ( (andRule->op==AndConstraint::NONE) && (andRule->rangeHigh==-1) ) { result += UNICODE_STRING_SIMPLE(" n is "); if (andRule->notIn) { result += UNICODE_STRING_SIMPLE("not "); } uprv_itou(digitString,16, andRule->rangeLow,10,0); result += UnicodeString(digitString); } else { if (andRule->op==AndConstraint::MOD) { result += UNICODE_STRING_SIMPLE(" n mod "); uprv_itou(digitString,16, andRule->opNum,10,0); result += UnicodeString(digitString); } else { result += UNICODE_STRING_SIMPLE(" n "); } if (andRule->rangeHigh==-1) { if (andRule->notIn) { result += UNICODE_STRING_SIMPLE(" is not "); uprv_itou(digitString,16, andRule->rangeLow,10,0); result += UnicodeString(digitString); } else { result += UNICODE_STRING_SIMPLE(" is "); uprv_itou(digitString,16, andRule->rangeLow,10,0); result += UnicodeString(digitString); } } else { if (andRule->notIn) { if ( andRule->integerOnly ) { result += UNICODE_STRING_SIMPLE(" not in "); } else { result += UNICODE_STRING_SIMPLE(" not within "); } uprv_itou(digitString,16, andRule->rangeLow,10,0); result += UnicodeString(digitString); result += UNICODE_STRING_SIMPLE(" .. "); uprv_itou(digitString,16, andRule->rangeHigh,10,0); result += UnicodeString(digitString); } else { if ( andRule->integerOnly ) { result += UNICODE_STRING_SIMPLE(" in "); } else { result += UNICODE_STRING_SIMPLE(" within "); } uprv_itou(digitString,16, andRule->rangeLow,10,0); result += UnicodeString(digitString); result += UNICODE_STRING_SIMPLE(" .. "); uprv_itou(digitString,16, andRule->rangeHigh,10,0); } } } if ( (andRule=andRule->next) != NULL) { result += PK_AND; } } if ( (orRule = orRule->next) != NULL ) { result += PK_OR; } } } if ( next != NULL ) { next->dumpRules(result); } } int32_t RuleChain::getRepeatLimit () { return repeatLimit; } void RuleChain::setRepeatLimit () { int32_t limit=0; if ( next != NULL ) { next->setRepeatLimit(); limit = next->repeatLimit; } if ( ruleHeader != NULL ) { OrConstraint* orRule=ruleHeader; while ( orRule != NULL ) { AndConstraint* andRule=orRule->childNode; while ( andRule != NULL ) { limit = andRule->updateRepeatLimit(limit); andRule = andRule->next; } orRule = orRule->next; } } repeatLimit = limit; } UErrorCode RuleChain::getKeywords(int32_t capacityOfKeywords, UnicodeString* keywords, int32_t& arraySize) const { if ( arraySize < capacityOfKeywords-1 ) { keywords[arraySize++]=keyword; } else { return U_BUFFER_OVERFLOW_ERROR; } if ( next != NULL ) { return next->getKeywords(capacityOfKeywords, keywords, arraySize); } else { return U_ZERO_ERROR; } } UBool RuleChain::isKeyword(const UnicodeString& keywordParam) const { if ( keyword == keywordParam ) { return TRUE; } if ( next != NULL ) { return next->isKeyword(keywordParam); } else { return FALSE; } } RuleParser::RuleParser() { } RuleParser::~RuleParser() { } void RuleParser::checkSyntax(tokenType prevType, tokenType curType, UErrorCode &status) { if (U_FAILURE(status)) { return; } switch(prevType) { case none: case tSemiColon: if (curType!=tKeyword) { status = U_UNEXPECTED_TOKEN; } break; case tVariableN : if (curType != tIs && curType != tMod && curType != tIn && curType != tNot && curType != tWithin) { status = U_UNEXPECTED_TOKEN; } break; case tZero: case tOne: case tTwo: case tFew: case tMany: case tOther: case tKeyword: if (curType != tColon) { status = U_UNEXPECTED_TOKEN; } break; case tColon : if (curType != tVariableN) { status = U_UNEXPECTED_TOKEN; } break; case tIs: if ( curType != tNumber && curType != tNot) { status = U_UNEXPECTED_TOKEN; } break; case tNot: if (curType != tNumber && curType != tIn && curType != tWithin) { status = U_UNEXPECTED_TOKEN; } break; case tMod: case tDot: case tIn: case tWithin: case tAnd: case tOr: if (curType != tNumber && curType != tVariableN) { status = U_UNEXPECTED_TOKEN; } break; case tNumber: if (curType != tDot && curType != tSemiColon && curType != tIs && curType != tNot && curType != tIn && curType != tWithin && curType != tAnd && curType != tOr) { status = U_UNEXPECTED_TOKEN; } break; default: status = U_UNEXPECTED_TOKEN; break; } } void RuleParser::getNextToken(const UnicodeString& ruleData, int32_t *ruleIndex, UnicodeString& token, tokenType& type, UErrorCode &status) { int32_t curIndex= *ruleIndex; UChar ch; tokenType prevType=none; if (U_FAILURE(status)) { return; } while (curIndex=ruleData.length() ) { if ( (type == tLetter)||(type == tNumber) ) { token=UnicodeString(ruleData, *ruleIndex, curIndex-*ruleIndex); getKeyType(token, type, status); if (U_FAILURE(status)) { return; } } *ruleIndex = ruleData.length(); } } UBool RuleParser::inRange(UChar ch, tokenType& type) { if ((ch>=CAP_A) && (ch<=CAP_Z)) { // we assume all characters are in lower case already. return FALSE; } if ((ch>=LOW_A) && (ch<=LOW_Z)) { type = tLetter; return TRUE; } if ((ch>=U_ZERO) && (ch<=U_NINE)) { type = tNumber; return TRUE; } switch (ch) { case COLON: type = tColon; return TRUE; case SPACE: type = tSpace; return TRUE; case SEMI_COLON: type = tSemiColon; return TRUE; case DOT: type = tDot; return TRUE; default : type = none; return FALSE; } } void RuleParser::getKeyType(const UnicodeString& token, tokenType& keyType, UErrorCode &status) { if (U_FAILURE(status)) { return; } if ( keyType==tNumber) { } else if (token==PK_VAR_N) { keyType = tVariableN; } else if (token==PK_IS) { keyType = tIs; } else if (token==PK_AND) { keyType = tAnd; } else if (token==PK_IN) { keyType = tIn; } else if (token==PK_WITHIN) { keyType = tWithin; } else if (token==PK_NOT) { keyType = tNot; } else if (token==PK_MOD) { keyType = tMod; } else if (token==PK_OR) { keyType = tOr; } else if ( isValidKeyword(token) ) { keyType = tKeyword; } else { status = U_UNEXPECTED_TOKEN; } } UBool RuleParser::isValidKeyword(const UnicodeString& token) { return PatternProps::isIdentifier(token.getBuffer(), token.length()); } PluralKeywordEnumeration::PluralKeywordEnumeration(RuleChain *header, UErrorCode& status) : pos(0), fKeywordNames(status) { if (U_FAILURE(status)) { return; } fKeywordNames.setDeleter(uhash_deleteUObject); UBool addKeywordOther=TRUE; RuleChain *node=header; while(node!=NULL) { fKeywordNames.addElement(new UnicodeString(node->keyword), status); if (U_FAILURE(status)) { return; } if (node->keyword == PLURAL_KEYWORD_OTHER) { addKeywordOther= FALSE; } node=node->next; } if (addKeywordOther) { fKeywordNames.addElement(new UnicodeString(PLURAL_KEYWORD_OTHER), status); } } const UnicodeString* PluralKeywordEnumeration::snext(UErrorCode& status) { if (U_SUCCESS(status) && pos < fKeywordNames.size()) { return (const UnicodeString*)fKeywordNames.elementAt(pos++); } return NULL; } void PluralKeywordEnumeration::reset(UErrorCode& /*status*/) { pos=0; } int32_t PluralKeywordEnumeration::count(UErrorCode& /*status*/) const { return fKeywordNames.size(); } PluralKeywordEnumeration::~PluralKeywordEnumeration() { } U_NAMESPACE_END #endif /* #if !UCONFIG_NO_FORMATTING */ //eof