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nest-open-source / nest-learning-thermostat / 5.0 / icu / refs/heads/master / . / icu / source / i18n / plurrule.cpp
blob: 666c827702a1d2b60a897bf6610dbd3895d51c2a [file] [log] [blame]
/*
*******************************************************************************
* Copyright (C) 2007-2009, International Business Machines Corporation and
* others. All Rights Reserved.
*******************************************************************************
*
* File PLURRULE.CPP
*
* Modification History:
*
* Date Name Description
*******************************************************************************
*/
#include "unicode/uniset.h"
#include "unicode/utypes.h"
#include "unicode/ures.h"
#include "unicode/plurrule.h"
#include "cmemory.h"
#include "cstring.h"
#include "hash.h"
#include "mutex.h"
#include "plurrule_impl.h"
#include "putilimp.h"
#include "ucln_in.h"
#include "ustrfmt.h"
#include "locutil.h"
/*
// TODO(claireho): remove stdio
#include "stdio.h"
*/
#if !UCONFIG_NO_FORMATTING
U_NAMESPACE_BEGIN
#define ARRAY_SIZE(array) (int32_t)(sizeof array / sizeof array[0])
static const UChar PLURAL_KEYWORD_ZERO[] = {LOW_Z,LOW_E,LOW_R,LOW_O, 0};
static const UChar PLURAL_KEYWORD_ONE[]={LOW_O,LOW_N,LOW_E,0};
static const UChar PLURAL_KEYWORD_TWO[]={LOW_T,LOW_W,LOW_O,0};
static const UChar PLURAL_KEYWORD_FEW[]={LOW_F,LOW_E,LOW_W,0};
static const UChar PLURAL_KEYWORD_MANY[]={LOW_M,LOW_A,LOW_N,LOW_Y,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)
{
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(new RuleParser())
{
*this=other;
}
PluralRules::~PluralRules() {
delete mRules;
delete mParser;
}
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();
}
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)) {
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)) return NULL;
return nameEnumerator;
}
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;
UBool sameList = TRUE;
const UnicodeString *ptrKeyword;
UErrorCode status= U_ZERO_ERROR;
if ( this == &other ) {
return TRUE;
}
StringEnumeration* myKeywordList = getKeywords(status);
if (U_FAILURE(status)) {
return FALSE;
}
StringEnumeration* otherKeywordList =other.getKeywords(status);
if (U_FAILURE(status)) {
return FALSE;
}
if (myKeywordList->count(status)!=otherKeywordList->count(status) ||
U_FAILURE(status)) {
sameList = FALSE;
}
else {
myKeywordList->reset(status);
if (U_FAILURE(status)) {
return FALSE;
}
while (sameList && (ptrKeyword=myKeywordList->snext(status))!=NULL) {
if (U_FAILURE(status) || !other.isKeyword(*ptrKeyword)) {
sameList = FALSE;
}
}
otherKeywordList->reset(status);
if (U_FAILURE(status)) {
return FALSE;
}
while (sameList && (ptrKeyword=otherKeywordList->snext(status))!=NULL) {
if (U_FAILURE(status)) {
return FALSE;
}
if (!this->isKeyword(*ptrKeyword)) {
sameList = FALSE;
}
}
delete myKeywordList;
delete otherKeywordList;
if (!sameList) {
return FALSE;
}
}
if ((limit=this->getRepeatLimit()) != other.getRepeatLimit()) {
return FALSE;
}
UnicodeString myKeyword, otherKeyword;
for (int32_t i=0; i<limit; ++i) {
myKeyword = this->select(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;
}
}
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; i<numberKeys; ++i) {
int32_t keyLen;
resLen=0;
s=ures_getNextString(setRes, &resLen, (const char**)&key, &errCode);
keyLen = (int32_t)uprv_strlen(key);
u_charsToUChars(key, result+len, keyLen);
len += keyLen;
result[len++]=COLON;
uprv_memcpy(result+len, s, resLen*sizeof(UChar));
len += resLen;
result[len++]=SEMI_COLON;
}
result[len++]=0;
u_UCharsToChars(result, setKey, len);
// printf(" Rule: %s\n", setKey);
ures_close(setRes);
ures_close(ruleRes);
ures_close(locRes);
ures_close(rb);
return UnicodeString(result);
}
AndConstraint::AndConstraint() {
op = AndConstraint::NONE;
opNum=-1;
rangeLow=-1;
rangeHigh=-1;
notIn=FALSE;
integerOnly=FALSE;
next=NULL;
}
AndConstraint::AndConstraint(const AndConstraint& other) {
this->op = 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;
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;
}
}
int32_t
AndConstraint::updateRepeatLimit(int32_t maxLimit) {
if ( op == MOD ) {
return uprv_max(opNum, maxLimit);
}
else {
if ( rangeHigh == -1 ) {
return(rangeLow>maxLimit? rangeLow : maxLimit);
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;
}
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() {
UErrorCode err=U_ZERO_ERROR;
const UnicodeString idStart=UNICODE_STRING_SIMPLE("[[a-z]]");
const UnicodeString idContinue=UNICODE_STRING_SIMPLE("[[a-z][A-Z][_][0-9]]");
idStartFilter = new UnicodeSet(idStart, err);
idContinueFilter = new UnicodeSet(idContinue, err);
}
RuleParser::~RuleParser() {
delete idStartFilter;
delete idContinueFilter;
}
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()) {
ch = ruleData.charAt(curIndex);
if ( !inRange(ch, type) ) {
status = U_ILLEGAL_CHARACTER;
return;
}
switch (type) {
case tSpace:
if ( *ruleIndex != curIndex ) { // letter
token=UnicodeString(ruleData, *ruleIndex, curIndex-*ruleIndex);
*ruleIndex=curIndex;
type=prevType;
getKeyType(token, type, status);
return;
}
else {
*ruleIndex=*ruleIndex+1;
}
break; // consective space
case tColon:
case tSemiColon:
if ( *ruleIndex != curIndex ) {
token=UnicodeString(ruleData, *ruleIndex, curIndex-*ruleIndex);
*ruleIndex=curIndex;
type=prevType;
getKeyType(token, type, status);
return;
}
else {
*ruleIndex=curIndex+1;
return;
}
case tLetter:
if ((type==prevType)||(prevType==none)) {
prevType=type;
break;
}
break;
case tNumber:
if ((type==prevType)||(prevType==none)) {
prevType=type;
break;
}
else {
*ruleIndex=curIndex+1;
return;
}
case tDot:
if (prevType==none) { // first dot
prevType=type;
continue;
}
else {
if ( *ruleIndex != curIndex ) {
token=UnicodeString(ruleData, *ruleIndex, curIndex-*ruleIndex);
*ruleIndex=curIndex; // letter
type=prevType;
getKeyType(token, type, status);
return;
}
else { // two consective dots
*ruleIndex=curIndex+2;
return;
}
}
break;
default:
status = U_UNEXPECTED_TOKEN;
return;
}
curIndex++;
}
if ( 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) {
if ( token.length()==0 ) {
return FALSE;
}
if ( idStartFilter->contains(token.charAt(0) )==TRUE ) {
int32_t i;
for (i=1; i< token.length(); i++) {
if (idContinueFilter->contains(token.charAt(i))== FALSE) {
return FALSE;
}
}
return TRUE;
}
else {
return FALSE;
}
}
PluralKeywordEnumeration::PluralKeywordEnumeration(RuleChain *header, UErrorCode& status) :
fKeywordNames(status)
{
RuleChain *node=header;
UBool addKeywordOther=true;
if (U_FAILURE(status)) {
return;
}
pos=0;
fKeywordNames.removeAllElements();
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);
if (U_FAILURE(status)) {
return;
}
}
}
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() {
UnicodeString *s;
for (int32_t i=0; i<fKeywordNames.size(); ++i) {
if ((s=(UnicodeString *)fKeywordNames.elementAt(i))!=NULL) {
delete s;
}
}
}
U_NAMESPACE_END
#endif /* #if !UCONFIG_NO_FORMATTING */
//eof