// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /******************************************************************************* * Copyright (C) 2008-2016, International Business Machines Corporation and * others. All Rights Reserved. ******************************************************************************* * * File DTITVFMT.CPP * ******************************************************************************* */ #include "utypeinfo.h" // for 'typeid' to work #include "unicode/dtitvfmt.h" #if !UCONFIG_NO_FORMATTING //TODO: put in compilation //#define DTITVFMT_DEBUG 1 #include "unicode/calendar.h" #include "unicode/dtptngen.h" #include "unicode/dtitvinf.h" #include "unicode/simpleformatter.h" #include "cmemory.h" #include "cstring.h" #include "dtitv_impl.h" #include "mutex.h" #include "uresimp.h" #include "formattedval_impl.h" #ifdef DTITVFMT_DEBUG #include #endif U_NAMESPACE_BEGIN #ifdef DTITVFMT_DEBUG #define PRINTMESG(msg) { std::cout << "(" << __FILE__ << ":" << __LINE__ << ") " << msg << "\n"; } #endif static const UChar gDateFormatSkeleton[][11] = { //yMMMMEEEEd {LOW_Y, CAP_M, CAP_M, CAP_M, CAP_M, CAP_E, CAP_E, CAP_E, CAP_E, LOW_D, 0}, //yMMMMd {LOW_Y, CAP_M, CAP_M, CAP_M, CAP_M, LOW_D, 0}, //yMMMd {LOW_Y, CAP_M, CAP_M, CAP_M, LOW_D, 0}, //yMd {LOW_Y, CAP_M, LOW_D, 0} }; static const char gCalendarTag[] = "calendar"; static const char gGregorianTag[] = "gregorian"; static const char gDateTimePatternsTag[] = "DateTimePatterns"; // latestFirst: static const UChar gLaterFirstPrefix[] = {LOW_L, LOW_A, LOW_T, LOW_E, LOW_S,LOW_T, CAP_F, LOW_I, LOW_R, LOW_S, LOW_T, COLON}; // earliestFirst: static const UChar gEarlierFirstPrefix[] = {LOW_E, LOW_A, LOW_R, LOW_L, LOW_I, LOW_E, LOW_S, LOW_T, CAP_F, LOW_I, LOW_R, LOW_S, LOW_T, COLON}; class FormattedDateIntervalData : public FormattedValueFieldPositionIteratorImpl { public: FormattedDateIntervalData(UErrorCode& status) : FormattedValueFieldPositionIteratorImpl(5, status) {} virtual ~FormattedDateIntervalData(); }; FormattedDateIntervalData::~FormattedDateIntervalData() = default; UPRV_FORMATTED_VALUE_SUBCLASS_AUTO_IMPL(FormattedDateInterval) UOBJECT_DEFINE_RTTI_IMPLEMENTATION(DateIntervalFormat) // Mutex, protects access to fDateFormat, fFromCalendar and fToCalendar. // Needed because these data members are modified by const methods of DateIntervalFormat. static UMutex gFormatterMutex; DateIntervalFormat* U_EXPORT2 DateIntervalFormat::createInstance(const UnicodeString& skeleton, UErrorCode& status) { return createInstance(skeleton, Locale::getDefault(), status); } DateIntervalFormat* U_EXPORT2 DateIntervalFormat::createInstance(const UnicodeString& skeleton, const Locale& locale, UErrorCode& status) { #ifdef DTITVFMT_DEBUG char result[1000]; char result_1[1000]; char mesg[2000]; skeleton.extract(0, skeleton.length(), result, "UTF-8"); UnicodeString pat; ((SimpleDateFormat*)dtfmt)->toPattern(pat); pat.extract(0, pat.length(), result_1, "UTF-8"); sprintf(mesg, "skeleton: %s; pattern: %s\n", result, result_1); PRINTMESG(mesg) #endif DateIntervalInfo* dtitvinf = new DateIntervalInfo(locale, status); if (dtitvinf == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; return nullptr; } return create(locale, dtitvinf, &skeleton, status); } DateIntervalFormat* U_EXPORT2 DateIntervalFormat::createInstance(const UnicodeString& skeleton, const DateIntervalInfo& dtitvinf, UErrorCode& status) { return createInstance(skeleton, Locale::getDefault(), dtitvinf, status); } DateIntervalFormat* U_EXPORT2 DateIntervalFormat::createInstance(const UnicodeString& skeleton, const Locale& locale, const DateIntervalInfo& dtitvinf, UErrorCode& status) { DateIntervalInfo* ptn = dtitvinf.clone(); return create(locale, ptn, &skeleton, status); } DateIntervalFormat::DateIntervalFormat() : fInfo(nullptr), fDateFormat(nullptr), fFromCalendar(nullptr), fToCalendar(nullptr), fLocale(Locale::getRoot()), fDatePattern(nullptr), fTimePattern(nullptr), fDateTimeFormat(nullptr) {} DateIntervalFormat::DateIntervalFormat(const DateIntervalFormat& itvfmt) : Format(itvfmt), fInfo(nullptr), fDateFormat(nullptr), fFromCalendar(nullptr), fToCalendar(nullptr), fLocale(itvfmt.fLocale), fDatePattern(nullptr), fTimePattern(nullptr), fDateTimeFormat(nullptr) { *this = itvfmt; } DateIntervalFormat& DateIntervalFormat::operator=(const DateIntervalFormat& itvfmt) { if ( this != &itvfmt ) { delete fDateFormat; delete fInfo; delete fFromCalendar; delete fToCalendar; delete fDatePattern; delete fTimePattern; delete fDateTimeFormat; { Mutex lock(&gFormatterMutex); if ( itvfmt.fDateFormat ) { fDateFormat = itvfmt.fDateFormat->clone(); } else { fDateFormat = nullptr; } if ( itvfmt.fFromCalendar ) { fFromCalendar = itvfmt.fFromCalendar->clone(); } else { fFromCalendar = nullptr; } if ( itvfmt.fToCalendar ) { fToCalendar = itvfmt.fToCalendar->clone(); } else { fToCalendar = nullptr; } } if ( itvfmt.fInfo ) { fInfo = itvfmt.fInfo->clone(); } else { fInfo = nullptr; } fSkeleton = itvfmt.fSkeleton; int8_t i; for ( i = 0; i< DateIntervalInfo::kIPI_MAX_INDEX; ++i ) { fIntervalPatterns[i] = itvfmt.fIntervalPatterns[i]; } fLocale = itvfmt.fLocale; fDatePattern = (itvfmt.fDatePattern)? itvfmt.fDatePattern->clone(): nullptr; fTimePattern = (itvfmt.fTimePattern)? itvfmt.fTimePattern->clone(): nullptr; fDateTimeFormat = (itvfmt.fDateTimeFormat)? itvfmt.fDateTimeFormat->clone(): nullptr; } return *this; } DateIntervalFormat::~DateIntervalFormat() { delete fInfo; delete fDateFormat; delete fFromCalendar; delete fToCalendar; delete fDatePattern; delete fTimePattern; delete fDateTimeFormat; } DateIntervalFormat* DateIntervalFormat::clone() const { return new DateIntervalFormat(*this); } UBool DateIntervalFormat::operator==(const Format& other) const { if (typeid(*this) != typeid(other)) {return FALSE;} const DateIntervalFormat* fmt = (DateIntervalFormat*)&other; if (this == fmt) {return TRUE;} if (!Format::operator==(other)) {return FALSE;} if ((fInfo != fmt->fInfo) && (fInfo == nullptr || fmt->fInfo == nullptr)) {return FALSE;} if (fInfo && fmt->fInfo && (*fInfo != *fmt->fInfo )) {return FALSE;} { Mutex lock(&gFormatterMutex); if (fDateFormat != fmt->fDateFormat && (fDateFormat == nullptr || fmt->fDateFormat == nullptr)) {return FALSE;} if (fDateFormat && fmt->fDateFormat && (*fDateFormat != *fmt->fDateFormat)) {return FALSE;} } // note: fFromCalendar and fToCalendar hold no persistent state, and therefore do not participate in operator ==. // fDateFormat has the master calendar for the DateIntervalFormat. if (fSkeleton != fmt->fSkeleton) {return FALSE;} if (fDatePattern != fmt->fDatePattern && (fDatePattern == nullptr || fmt->fDatePattern == nullptr)) {return FALSE;} if (fDatePattern && fmt->fDatePattern && (*fDatePattern != *fmt->fDatePattern)) {return FALSE;} if (fTimePattern != fmt->fTimePattern && (fTimePattern == nullptr || fmt->fTimePattern == nullptr)) {return FALSE;} if (fTimePattern && fmt->fTimePattern && (*fTimePattern != *fmt->fTimePattern)) {return FALSE;} if (fDateTimeFormat != fmt->fDateTimeFormat && (fDateTimeFormat == nullptr || fmt->fDateTimeFormat == nullptr)) {return FALSE;} if (fDateTimeFormat && fmt->fDateTimeFormat && (*fDateTimeFormat != *fmt->fDateTimeFormat)) {return FALSE;} if (fLocale != fmt->fLocale) {return FALSE;} for (int32_t i = 0; i< DateIntervalInfo::kIPI_MAX_INDEX; ++i ) { if (fIntervalPatterns[i].firstPart != fmt->fIntervalPatterns[i].firstPart) {return FALSE;} if (fIntervalPatterns[i].secondPart != fmt->fIntervalPatterns[i].secondPart ) {return FALSE;} if (fIntervalPatterns[i].laterDateFirst != fmt->fIntervalPatterns[i].laterDateFirst) {return FALSE;} } return TRUE; } UnicodeString& DateIntervalFormat::format(const Formattable& obj, UnicodeString& appendTo, FieldPosition& fieldPosition, UErrorCode& status) const { if ( U_FAILURE(status) ) { return appendTo; } if ( obj.getType() == Formattable::kObject ) { const UObject* formatObj = obj.getObject(); const DateInterval* interval = dynamic_cast(formatObj); if (interval != nullptr) { return format(interval, appendTo, fieldPosition, status); } } status = U_ILLEGAL_ARGUMENT_ERROR; return appendTo; } UnicodeString& DateIntervalFormat::format(const DateInterval* dtInterval, UnicodeString& appendTo, FieldPosition& fieldPosition, UErrorCode& status) const { if ( U_FAILURE(status) ) { return appendTo; } if (fDateFormat == nullptr || fInfo == nullptr) { status = U_INVALID_STATE_ERROR; return appendTo; } FieldPositionOnlyHandler handler(fieldPosition); handler.setAcceptFirstOnly(TRUE); int8_t ignore; Mutex lock(&gFormatterMutex); return formatIntervalImpl(*dtInterval, appendTo, ignore, handler, status); } FormattedDateInterval DateIntervalFormat::formatToValue( const DateInterval& dtInterval, UErrorCode& status) const { if (U_FAILURE(status)) { return FormattedDateInterval(status); } // LocalPointer only sets OOM status if U_SUCCESS is true. LocalPointer result(new FormattedDateIntervalData(status), status); if (U_FAILURE(status)) { return FormattedDateInterval(status); } UnicodeString string; int8_t firstIndex; auto handler = result->getHandler(status); handler.setCategory(UFIELD_CATEGORY_DATE); { Mutex lock(&gFormatterMutex); formatIntervalImpl(dtInterval, string, firstIndex, handler, status); } handler.getError(status); result->appendString(string, status); if (U_FAILURE(status)) { return FormattedDateInterval(status); } // Compute the span fields and sort them into place: if (firstIndex != -1) { result->addOverlapSpans(UFIELD_CATEGORY_DATE_INTERVAL_SPAN, firstIndex, status); if (U_FAILURE(status)) { return FormattedDateInterval(status); } result->sort(); } return FormattedDateInterval(result.orphan()); } UnicodeString& DateIntervalFormat::format(Calendar& fromCalendar, Calendar& toCalendar, UnicodeString& appendTo, FieldPosition& pos, UErrorCode& status) const { FieldPositionOnlyHandler handler(pos); handler.setAcceptFirstOnly(TRUE); int8_t ignore; Mutex lock(&gFormatterMutex); return formatImpl(fromCalendar, toCalendar, appendTo, ignore, handler, status); } FormattedDateInterval DateIntervalFormat::formatToValue( Calendar& fromCalendar, Calendar& toCalendar, UErrorCode& status) const { if (U_FAILURE(status)) { return FormattedDateInterval(status); } // LocalPointer only sets OOM status if U_SUCCESS is true. LocalPointer result(new FormattedDateIntervalData(status), status); if (U_FAILURE(status)) { return FormattedDateInterval(status); } UnicodeString string; int8_t firstIndex; auto handler = result->getHandler(status); handler.setCategory(UFIELD_CATEGORY_DATE); { Mutex lock(&gFormatterMutex); formatImpl(fromCalendar, toCalendar, string, firstIndex, handler, status); } handler.getError(status); result->appendString(string, status); if (U_FAILURE(status)) { return FormattedDateInterval(status); } // Compute the span fields and sort them into place: if (firstIndex != -1) { result->addOverlapSpans(UFIELD_CATEGORY_DATE_INTERVAL_SPAN, firstIndex, status); result->sort(); } return FormattedDateInterval(result.orphan()); } UnicodeString& DateIntervalFormat::formatIntervalImpl( const DateInterval& dtInterval, UnicodeString& appendTo, int8_t& firstIndex, FieldPositionHandler& fphandler, UErrorCode& status) const { if (U_FAILURE(status)) { return appendTo; } if (fFromCalendar == nullptr || fToCalendar == nullptr) { status = U_INVALID_STATE_ERROR; return appendTo; } fFromCalendar->setTime(dtInterval.getFromDate(), status); fToCalendar->setTime(dtInterval.getToDate(), status); return formatImpl(*fFromCalendar, *fToCalendar, appendTo, firstIndex, fphandler, status); } UnicodeString& DateIntervalFormat::formatImpl(Calendar& fromCalendar, Calendar& toCalendar, UnicodeString& appendTo, int8_t& firstIndex, FieldPositionHandler& fphandler, UErrorCode& status) const { if ( U_FAILURE(status) ) { return appendTo; } // Initialize firstIndex to -1 (single date, no range) firstIndex = -1; // not support different calendar types and time zones //if ( fromCalendar.getType() != toCalendar.getType() ) { if ( !fromCalendar.isEquivalentTo(toCalendar) ) { status = U_ILLEGAL_ARGUMENT_ERROR; return appendTo; } // First, find the largest different calendar field. UCalendarDateFields field = UCAL_FIELD_COUNT; if ( fromCalendar.get(UCAL_ERA,status) != toCalendar.get(UCAL_ERA,status)) { field = UCAL_ERA; } else if ( fromCalendar.get(UCAL_YEAR, status) != toCalendar.get(UCAL_YEAR, status) ) { field = UCAL_YEAR; } else if ( fromCalendar.get(UCAL_MONTH, status) != toCalendar.get(UCAL_MONTH, status) ) { field = UCAL_MONTH; } else if ( fromCalendar.get(UCAL_DATE, status) != toCalendar.get(UCAL_DATE, status) ) { field = UCAL_DATE; } else if ( fromCalendar.get(UCAL_AM_PM, status) != toCalendar.get(UCAL_AM_PM, status) ) { field = UCAL_AM_PM; } else if ( fromCalendar.get(UCAL_HOUR, status) != toCalendar.get(UCAL_HOUR, status) ) { field = UCAL_HOUR; } else if ( fromCalendar.get(UCAL_MINUTE, status) != toCalendar.get(UCAL_MINUTE, status) ) { field = UCAL_MINUTE; } else if ( fromCalendar.get(UCAL_SECOND, status) != toCalendar.get(UCAL_SECOND, status) ) { field = UCAL_SECOND; } else if ( fromCalendar.get(UCAL_MILLISECOND, status) != toCalendar.get(UCAL_MILLISECOND, status) ) { field = UCAL_MILLISECOND; } if ( U_FAILURE(status) ) { return appendTo; } if ( field == UCAL_FIELD_COUNT ) { /* ignore the millisecond etc. small fields' difference. * use single date when all the above are the same. */ return fDateFormat->_format(fromCalendar, appendTo, fphandler, status); } UBool fromToOnSameDay = (field==UCAL_AM_PM || field==UCAL_HOUR || field==UCAL_MINUTE || field==UCAL_SECOND || field==UCAL_MILLISECOND); // following call should not set wrong status, // all the pass-in fields are valid till here int32_t itvPtnIndex = DateIntervalInfo::calendarFieldToIntervalIndex(field, status); const PatternInfo& intervalPattern = fIntervalPatterns[itvPtnIndex]; if ( intervalPattern.firstPart.isEmpty() && intervalPattern.secondPart.isEmpty() ) { if ( fDateFormat->isFieldUnitIgnored(field) ) { /* the largest different calendar field is small than * the smallest calendar field in pattern, * return single date format. */ return fDateFormat->_format(fromCalendar, appendTo, fphandler, status); } return fallbackFormat(fromCalendar, toCalendar, fromToOnSameDay, appendTo, firstIndex, fphandler, status); } // If the first part in interval pattern is empty, // the 2nd part of it saves the full-pattern used in fall-back. // For a 'real' interval pattern, the first part will never be empty. if ( intervalPattern.firstPart.isEmpty() ) { // fall back UnicodeString originalPattern; fDateFormat->toPattern(originalPattern); fDateFormat->applyPattern(intervalPattern.secondPart); appendTo = fallbackFormat(fromCalendar, toCalendar, fromToOnSameDay, appendTo, firstIndex, fphandler, status); fDateFormat->applyPattern(originalPattern); return appendTo; } Calendar* firstCal; Calendar* secondCal; if ( intervalPattern.laterDateFirst ) { firstCal = &toCalendar; secondCal = &fromCalendar; firstIndex = 1; } else { firstCal = &fromCalendar; secondCal = &toCalendar; firstIndex = 0; } // break the interval pattern into 2 parts, // first part should not be empty, UnicodeString originalPattern; fDateFormat->toPattern(originalPattern); fDateFormat->applyPattern(intervalPattern.firstPart); fDateFormat->_format(*firstCal, appendTo, fphandler, status); if ( !intervalPattern.secondPart.isEmpty() ) { fDateFormat->applyPattern(intervalPattern.secondPart); fDateFormat->_format(*secondCal, appendTo, fphandler, status); } fDateFormat->applyPattern(originalPattern); return appendTo; } void DateIntervalFormat::parseObject(const UnicodeString& /* source */, Formattable& /* result */, ParsePosition& /* parse_pos */) const { // parseObject(const UnicodeString&, Formattable&, UErrorCode&) const // will set status as U_INVALID_FORMAT_ERROR if // parse_pos is still 0 } const DateIntervalInfo* DateIntervalFormat::getDateIntervalInfo() const { return fInfo; } void DateIntervalFormat::setDateIntervalInfo(const DateIntervalInfo& newItvPattern, UErrorCode& status) { delete fInfo; fInfo = new DateIntervalInfo(newItvPattern); if (fInfo == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; } // Delete patterns that get reset by initializePattern delete fDatePattern; fDatePattern = nullptr; delete fTimePattern; fTimePattern = nullptr; delete fDateTimeFormat; fDateTimeFormat = nullptr; if (fDateFormat) { initializePattern(status); } } const DateFormat* DateIntervalFormat::getDateFormat() const { return fDateFormat; } void DateIntervalFormat::adoptTimeZone(TimeZone* zone) { if (fDateFormat != nullptr) { fDateFormat->adoptTimeZone(zone); } // The fDateFormat has the master calendar for the DateIntervalFormat and has // ownership of any adopted TimeZone; fFromCalendar and fToCalendar are internal // work clones of that calendar (and should not also be given ownership of the // adopted TimeZone). if (fFromCalendar) { fFromCalendar->setTimeZone(*zone); } if (fToCalendar) { fToCalendar->setTimeZone(*zone); } } void DateIntervalFormat::setTimeZone(const TimeZone& zone) { if (fDateFormat != nullptr) { fDateFormat->setTimeZone(zone); } // The fDateFormat has the master calendar for the DateIntervalFormat; // fFromCalendar and fToCalendar are internal work clones of that calendar. if (fFromCalendar) { fFromCalendar->setTimeZone(zone); } if (fToCalendar) { fToCalendar->setTimeZone(zone); } } const TimeZone& DateIntervalFormat::getTimeZone() const { if (fDateFormat != nullptr) { Mutex lock(&gFormatterMutex); return fDateFormat->getTimeZone(); } // If fDateFormat is nullptr (unexpected), create default timezone. return *(TimeZone::createDefault()); } DateIntervalFormat::DateIntervalFormat(const Locale& locale, DateIntervalInfo* dtItvInfo, const UnicodeString* skeleton, UErrorCode& status) : fInfo(nullptr), fDateFormat(nullptr), fFromCalendar(nullptr), fToCalendar(nullptr), fLocale(locale), fDatePattern(nullptr), fTimePattern(nullptr), fDateTimeFormat(nullptr) { LocalPointer info(dtItvInfo, status); LocalPointer dtfmt(static_cast( DateFormat::createInstanceForSkeleton(*skeleton, locale, status)), status); if (U_FAILURE(status)) { return; } if ( skeleton ) { fSkeleton = *skeleton; } fInfo = info.orphan(); fDateFormat = dtfmt.orphan(); if ( fDateFormat->getCalendar() ) { fFromCalendar = fDateFormat->getCalendar()->clone(); fToCalendar = fDateFormat->getCalendar()->clone(); } initializePattern(status); } DateIntervalFormat* U_EXPORT2 DateIntervalFormat::create(const Locale& locale, DateIntervalInfo* dtitvinf, const UnicodeString* skeleton, UErrorCode& status) { DateIntervalFormat* f = new DateIntervalFormat(locale, dtitvinf, skeleton, status); if ( f == nullptr ) { status = U_MEMORY_ALLOCATION_ERROR; delete dtitvinf; } else if ( U_FAILURE(status) ) { // safe to delete f, although nothing acutally is saved delete f; f = 0; } return f; } /** * Initialize interval patterns locale to this formatter * * This code is a bit complicated since * 1. the interval patterns saved in resource bundle files are interval * patterns based on date or time only. * It does not have interval patterns based on both date and time. * Interval patterns on both date and time are algorithm generated. * * For example, it has interval patterns on skeleton "dMy" and "hm", * but it does not have interval patterns on skeleton "dMyhm". * * The rule to genearte interval patterns for both date and time skeleton are * 1) when the year, month, or day differs, concatenate the two original * expressions with a separator between, * For example, interval pattern from "Jan 10, 2007 10:10 am" * to "Jan 11, 2007 10:10am" is * "Jan 10, 2007 10:10 am - Jan 11, 2007 10:10am" * * 2) otherwise, present the date followed by the range expression * for the time. * For example, interval pattern from "Jan 10, 2007 10:10 am" * to "Jan 10, 2007 11:10am" is * "Jan 10, 2007 10:10 am - 11:10am" * * 2. even a pattern does not request a certion calendar field, * the interval pattern needs to include such field if such fields are * different between 2 dates. * For example, a pattern/skeleton is "hm", but the interval pattern * includes year, month, and date when year, month, and date differs. * * @param status output param set to success/failure code on exit * @stable ICU 4.0 */ void DateIntervalFormat::initializePattern(UErrorCode& status) { if ( U_FAILURE(status) ) { return; } const Locale& locale = fDateFormat->getSmpFmtLocale(); if ( fSkeleton.isEmpty() ) { UnicodeString fullPattern; fDateFormat->toPattern(fullPattern); #ifdef DTITVFMT_DEBUG char result[1000]; char result_1[1000]; char mesg[2000]; fSkeleton.extract(0, fSkeleton.length(), result, "UTF-8"); sprintf(mesg, "in getBestSkeleton: fSkeleton: %s; \n", result); PRINTMESG(mesg) #endif // fSkeleton is already set by createDateIntervalInstance() // or by createInstance(UnicodeString skeleton, .... ) fSkeleton = DateTimePatternGenerator::staticGetSkeleton( fullPattern, status); if ( U_FAILURE(status) ) { return; } } // initialize the fIntervalPattern ordering int8_t i; for ( i = 0; i < DateIntervalInfo::kIPI_MAX_INDEX; ++i ) { fIntervalPatterns[i].laterDateFirst = fInfo->getDefaultOrder(); } /* Check whether the skeleton is a combination of date and time. * For the complication reason 1 explained above. */ UnicodeString dateSkeleton; UnicodeString timeSkeleton; UnicodeString normalizedTimeSkeleton; UnicodeString normalizedDateSkeleton; /* the difference between time skeleton and normalizedTimeSkeleton are: * 1. (Formerly, normalized time skeleton folded 'H' to 'h'; no longer true) * 2. 'a' is omitted in normalized time skeleton. * 3. there is only one appearance for 'h' or 'H', 'm','v', 'z' in normalized * time skeleton * * The difference between date skeleton and normalizedDateSkeleton are: * 1. both 'y' and 'd' appear only once in normalizeDateSkeleton * 2. 'E' and 'EE' are normalized into 'EEE' * 3. 'MM' is normalized into 'M' */ getDateTimeSkeleton(fSkeleton, dateSkeleton, normalizedDateSkeleton, timeSkeleton, normalizedTimeSkeleton); #ifdef DTITVFMT_DEBUG char result[1000]; char result_1[1000]; char mesg[2000]; fSkeleton.extract(0, fSkeleton.length(), result, "UTF-8"); sprintf(mesg, "in getBestSkeleton: fSkeleton: %s; \n", result); PRINTMESG(mesg) #endif // move this up here since we need it for fallbacks if ( timeSkeleton.length() > 0 && dateSkeleton.length() > 0 ) { // Need the Date/Time pattern for concatenation of the date // with the time interval. // The date/time pattern ( such as {0} {1} ) is saved in // calendar, that is why need to get the CalendarData here. LocalUResourceBundlePointer dateTimePatternsRes(ures_open(nullptr, locale.getBaseName(), &status)); ures_getByKey(dateTimePatternsRes.getAlias(), gCalendarTag, dateTimePatternsRes.getAlias(), &status); ures_getByKeyWithFallback(dateTimePatternsRes.getAlias(), gGregorianTag, dateTimePatternsRes.getAlias(), &status); ures_getByKeyWithFallback(dateTimePatternsRes.getAlias(), gDateTimePatternsTag, dateTimePatternsRes.getAlias(), &status); int32_t dateTimeFormatLength; const UChar* dateTimeFormat = ures_getStringByIndex( dateTimePatternsRes.getAlias(), (int32_t)DateFormat::kDateTime, &dateTimeFormatLength, &status); if ( U_SUCCESS(status) && dateTimeFormatLength >= 3 ) { fDateTimeFormat = new UnicodeString(dateTimeFormat, dateTimeFormatLength); if (fDateTimeFormat == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; return; } } } UBool found = setSeparateDateTimePtn(normalizedDateSkeleton, normalizedTimeSkeleton); // for skeletons with seconds, found is false and we enter this block if ( found == false ) { // use fallback // TODO: if user asks "m"(minute), but "d"(day) differ if ( timeSkeleton.length() != 0 ) { if ( dateSkeleton.length() == 0 ) { // prefix with yMd timeSkeleton.insert(0, gDateFormatSkeleton[DateFormat::kShort], -1); UnicodeString pattern = DateFormat::getBestPattern( locale, timeSkeleton, status); if ( U_FAILURE(status) ) { return; } // for fall back interval patterns, // the first part of the pattern is empty, // the second part of the pattern is the full-pattern // should be used in fall-back. setPatternInfo(UCAL_DATE, nullptr, &pattern, fInfo->getDefaultOrder()); setPatternInfo(UCAL_MONTH, nullptr, &pattern, fInfo->getDefaultOrder()); setPatternInfo(UCAL_YEAR, nullptr, &pattern, fInfo->getDefaultOrder()); } else { // TODO: fall back } } else { // TODO: fall back } return; } // end of skeleton not found // interval patterns for skeleton are found in resource if ( timeSkeleton.length() == 0 ) { // done } else if ( dateSkeleton.length() == 0 ) { // prefix with yMd timeSkeleton.insert(0, gDateFormatSkeleton[DateFormat::kShort], -1); UnicodeString pattern = DateFormat::getBestPattern( locale, timeSkeleton, status); if ( U_FAILURE(status) ) { return; } // for fall back interval patterns, // the first part of the pattern is empty, // the second part of the pattern is the full-pattern // should be used in fall-back. setPatternInfo(UCAL_DATE, nullptr, &pattern, fInfo->getDefaultOrder()); setPatternInfo(UCAL_MONTH, nullptr, &pattern, fInfo->getDefaultOrder()); setPatternInfo(UCAL_YEAR, nullptr, &pattern, fInfo->getDefaultOrder()); } else { /* if both present, * 1) when the year, month, or day differs, * concatenate the two original expressions with a separator between, * 2) otherwise, present the date followed by the * range expression for the time. */ /* * 1) when the year, month, or day differs, * concatenate the two original expressions with a separator between, */ // if field exists, use fall back UnicodeString skeleton = fSkeleton; if ( !fieldExistsInSkeleton(UCAL_DATE, dateSkeleton) ) { // prefix skeleton with 'd' skeleton.insert(0, LOW_D); setFallbackPattern(UCAL_DATE, skeleton, status); } if ( !fieldExistsInSkeleton(UCAL_MONTH, dateSkeleton) ) { // then prefix skeleton with 'M' skeleton.insert(0, CAP_M); setFallbackPattern(UCAL_MONTH, skeleton, status); } if ( !fieldExistsInSkeleton(UCAL_YEAR, dateSkeleton) ) { // then prefix skeleton with 'y' skeleton.insert(0, LOW_Y); setFallbackPattern(UCAL_YEAR, skeleton, status); } /* * 2) otherwise, present the date followed by the * range expression for the time. */ if ( fDateTimeFormat == nullptr ) { // earlier failure getting dateTimeFormat return; } UnicodeString datePattern = DateFormat::getBestPattern( locale, dateSkeleton, status); concatSingleDate2TimeInterval(*fDateTimeFormat, datePattern, UCAL_AM_PM, status); concatSingleDate2TimeInterval(*fDateTimeFormat, datePattern, UCAL_HOUR, status); concatSingleDate2TimeInterval(*fDateTimeFormat, datePattern, UCAL_MINUTE, status); } } void U_EXPORT2 DateIntervalFormat::getDateTimeSkeleton(const UnicodeString& skeleton, UnicodeString& dateSkeleton, UnicodeString& normalizedDateSkeleton, UnicodeString& timeSkeleton, UnicodeString& normalizedTimeSkeleton) { // dateSkeleton follows the sequence of y*M*E*d* // timeSkeleton follows the sequence of hm*[v|z]? int32_t ECount = 0; int32_t dCount = 0; int32_t MCount = 0; int32_t yCount = 0; int32_t hCount = 0; int32_t HCount = 0; int32_t mCount = 0; int32_t vCount = 0; int32_t zCount = 0; int32_t i; for (i = 0; i < skeleton.length(); ++i) { UChar ch = skeleton[i]; switch ( ch ) { case CAP_E: dateSkeleton.append(ch); ++ECount; break; case LOW_D: dateSkeleton.append(ch); ++dCount; break; case CAP_M: dateSkeleton.append(ch); ++MCount; break; case LOW_Y: dateSkeleton.append(ch); ++yCount; break; case CAP_G: case CAP_Y: case LOW_U: case CAP_Q: case LOW_Q: case CAP_L: case LOW_L: case CAP_W: case LOW_W: case CAP_D: case CAP_F: case LOW_G: case LOW_E: case LOW_C: case CAP_U: case LOW_R: normalizedDateSkeleton.append(ch); dateSkeleton.append(ch); break; case LOW_A: // 'a' is implicitly handled timeSkeleton.append(ch); break; case LOW_H: timeSkeleton.append(ch); ++hCount; break; case CAP_H: timeSkeleton.append(ch); ++HCount; break; case LOW_M: timeSkeleton.append(ch); ++mCount; break; case LOW_Z: ++zCount; timeSkeleton.append(ch); break; case LOW_V: ++vCount; timeSkeleton.append(ch); break; case CAP_V: case CAP_Z: case LOW_K: case CAP_K: case LOW_J: case LOW_S: case CAP_S: case CAP_A: timeSkeleton.append(ch); normalizedTimeSkeleton.append(ch); break; } } /* generate normalized form for date*/ if ( yCount != 0 ) { for (i = 0; i < yCount; ++i) { normalizedDateSkeleton.append(LOW_Y); } } if ( MCount != 0 ) { if ( MCount < 3 ) { normalizedDateSkeleton.append(CAP_M); } else { for ( int32_t j = 0; j < MCount && j < MAX_M_COUNT; ++j) { normalizedDateSkeleton.append(CAP_M); } } } if ( ECount != 0 ) { if ( ECount <= 3 ) { normalizedDateSkeleton.append(CAP_E); } else { for ( int32_t j = 0; j < ECount && j < MAX_E_COUNT; ++j ) { normalizedDateSkeleton.append(CAP_E); } } } if ( dCount != 0 ) { normalizedDateSkeleton.append(LOW_D); } /* generate normalized form for time */ if ( HCount != 0 ) { normalizedTimeSkeleton.append(CAP_H); } else if ( hCount != 0 ) { normalizedTimeSkeleton.append(LOW_H); } if ( mCount != 0 ) { normalizedTimeSkeleton.append(LOW_M); } if ( zCount != 0 ) { normalizedTimeSkeleton.append(LOW_Z); } if ( vCount != 0 ) { normalizedTimeSkeleton.append(LOW_V); } } /** * Generate date or time interval pattern from resource, * and set them into the interval pattern locale to this formatter. * * It needs to handle the following: * 1. need to adjust field width. * For example, the interval patterns saved in DateIntervalInfo * includes "dMMMy", but not "dMMMMy". * Need to get interval patterns for dMMMMy from dMMMy. * Another example, the interval patterns saved in DateIntervalInfo * includes "hmv", but not "hmz". * Need to get interval patterns for "hmz' from 'hmv' * * 2. there might be no pattern for 'y' differ for skeleton "Md", * in order to get interval patterns for 'y' differ, * need to look for it from skeleton 'yMd' * * @param dateSkeleton normalized date skeleton * @param timeSkeleton normalized time skeleton * @return whether the resource is found for the skeleton. * TRUE if interval pattern found for the skeleton, * FALSE otherwise. * @stable ICU 4.0 */ UBool DateIntervalFormat::setSeparateDateTimePtn( const UnicodeString& dateSkeleton, const UnicodeString& timeSkeleton) { const UnicodeString* skeleton; // if both date and time skeleton present, // the final interval pattern might include time interval patterns // ( when, am_pm, hour, minute differ ), // but not date interval patterns ( when year, month, day differ ). // For year/month/day differ, it falls back to fall-back pattern. if ( timeSkeleton.length() != 0 ) { skeleton = &timeSkeleton; } else { skeleton = &dateSkeleton; } /* interval patterns for skeleton "dMMMy" (but not "dMMMMy") * are defined in resource, * interval patterns for skeleton "dMMMMy" are calculated by * 1. get the best match skeleton for "dMMMMy", which is "dMMMy" * 2. get the interval patterns for "dMMMy", * 3. extend "MMM" to "MMMM" in above interval patterns for "dMMMMy" * getBestSkeleton() is step 1. */ // best skeleton, and the difference information int8_t differenceInfo = 0; const UnicodeString* bestSkeleton = fInfo->getBestSkeleton(*skeleton, differenceInfo); /* best skeleton could be nullptr. For example: in "ca" resource file, interval format is defined as following intervalFormats{ fallback{"{0} - {1}"} } there is no skeletons/interval patterns defined, and the best skeleton match could be nullptr */ if ( bestSkeleton == nullptr ) { return false; } // Set patterns for fallback use, need to do this // before returning if differenceInfo == -1 UErrorCode status; if ( dateSkeleton.length() != 0) { status = U_ZERO_ERROR; fDatePattern = new UnicodeString(DateFormat::getBestPattern( fLocale, dateSkeleton, status)); // no way to report OOM. :( } if ( timeSkeleton.length() != 0) { status = U_ZERO_ERROR; fTimePattern = new UnicodeString(DateFormat::getBestPattern( fLocale, timeSkeleton, status)); // no way to report OOM. :( } // difference: // 0 means the best matched skeleton is the same as input skeleton // 1 means the fields are the same, but field width are different // 2 means the only difference between fields are v/z, // -1 means there are other fields difference // (this will happen, for instance, if the supplied skeleton has seconds, // but no skeletons in the intervalFormats data do) if ( differenceInfo == -1 ) { // skeleton has different fields, not only v/z difference return false; } if ( timeSkeleton.length() == 0 ) { UnicodeString extendedSkeleton; UnicodeString extendedBestSkeleton; // only has date skeleton setIntervalPattern(UCAL_DATE, skeleton, bestSkeleton, differenceInfo, &extendedSkeleton, &extendedBestSkeleton); UBool extended = setIntervalPattern(UCAL_MONTH, skeleton, bestSkeleton, differenceInfo, &extendedSkeleton, &extendedBestSkeleton); if ( extended ) { bestSkeleton = &extendedBestSkeleton; skeleton = &extendedSkeleton; } setIntervalPattern(UCAL_YEAR, skeleton, bestSkeleton, differenceInfo, &extendedSkeleton, &extendedBestSkeleton); setIntervalPattern(UCAL_ERA, skeleton, bestSkeleton, differenceInfo, &extendedSkeleton, &extendedBestSkeleton); } else { setIntervalPattern(UCAL_MINUTE, skeleton, bestSkeleton, differenceInfo); setIntervalPattern(UCAL_HOUR, skeleton, bestSkeleton, differenceInfo); setIntervalPattern(UCAL_AM_PM, skeleton, bestSkeleton, differenceInfo); } return true; } void DateIntervalFormat::setFallbackPattern(UCalendarDateFields field, const UnicodeString& skeleton, UErrorCode& status) { if ( U_FAILURE(status) ) { return; } UnicodeString pattern = DateFormat::getBestPattern( fLocale, skeleton, status); if ( U_FAILURE(status) ) { return; } setPatternInfo(field, nullptr, &pattern, fInfo->getDefaultOrder()); } void DateIntervalFormat::setPatternInfo(UCalendarDateFields field, const UnicodeString* firstPart, const UnicodeString* secondPart, UBool laterDateFirst) { // for fall back interval patterns, // the first part of the pattern is empty, // the second part of the pattern is the full-pattern // should be used in fall-back. UErrorCode status = U_ZERO_ERROR; // following should not set any wrong status. int32_t itvPtnIndex = DateIntervalInfo::calendarFieldToIntervalIndex(field, status); if ( U_FAILURE(status) ) { return; } PatternInfo& ptn = fIntervalPatterns[itvPtnIndex]; if ( firstPart ) { ptn.firstPart = *firstPart; } if ( secondPart ) { ptn.secondPart = *secondPart; } ptn.laterDateFirst = laterDateFirst; } void DateIntervalFormat::setIntervalPattern(UCalendarDateFields field, const UnicodeString& intervalPattern) { UBool order = fInfo->getDefaultOrder(); setIntervalPattern(field, intervalPattern, order); } void DateIntervalFormat::setIntervalPattern(UCalendarDateFields field, const UnicodeString& intervalPattern, UBool laterDateFirst) { const UnicodeString* pattern = &intervalPattern; UBool order = laterDateFirst; // check for "latestFirst:" or "earliestFirst:" prefix int8_t prefixLength = UPRV_LENGTHOF(gLaterFirstPrefix); int8_t earliestFirstLength = UPRV_LENGTHOF(gEarlierFirstPrefix); UnicodeString realPattern; if ( intervalPattern.startsWith(gLaterFirstPrefix, prefixLength) ) { order = true; intervalPattern.extract(prefixLength, intervalPattern.length() - prefixLength, realPattern); pattern = &realPattern; } else if ( intervalPattern.startsWith(gEarlierFirstPrefix, earliestFirstLength) ) { order = false; intervalPattern.extract(earliestFirstLength, intervalPattern.length() - earliestFirstLength, realPattern); pattern = &realPattern; } int32_t splitPoint = splitPatternInto2Part(*pattern); UnicodeString firstPart; UnicodeString secondPart; pattern->extract(0, splitPoint, firstPart); if ( splitPoint < pattern->length() ) { pattern->extract(splitPoint, pattern->length()-splitPoint, secondPart); } setPatternInfo(field, &firstPart, &secondPart, order); } /** * Generate interval pattern from existing resource * * It not only save the interval patterns, * but also return the extended skeleton and its best match skeleton. * * @param field largest different calendar field * @param skeleton skeleton * @param bestSkeleton the best match skeleton which has interval pattern * defined in resource * @param differenceInfo the difference between skeleton and best skeleton * 0 means the best matched skeleton is the same as input skeleton * 1 means the fields are the same, but field width are different * 2 means the only difference between fields are v/z, * -1 means there are other fields difference * * @param extendedSkeleton extended skeleton * @param extendedBestSkeleton extended best match skeleton * @return whether the interval pattern is found * through extending skeleton or not. * TRUE if interval pattern is found by * extending skeleton, FALSE otherwise. * @stable ICU 4.0 */ UBool DateIntervalFormat::setIntervalPattern(UCalendarDateFields field, const UnicodeString* skeleton, const UnicodeString* bestSkeleton, int8_t differenceInfo, UnicodeString* extendedSkeleton, UnicodeString* extendedBestSkeleton) { UErrorCode status = U_ZERO_ERROR; // following getIntervalPattern() should not generate error status UnicodeString pattern; fInfo->getIntervalPattern(*bestSkeleton, field, pattern, status); if ( pattern.isEmpty() ) { // single date if ( SimpleDateFormat::isFieldUnitIgnored(*bestSkeleton, field) ) { // do nothing, format will handle it return false; } // for 24 hour system, interval patterns in resource file // might not include pattern when am_pm differ, // which should be the same as hour differ. // add it here for simplicity if ( field == UCAL_AM_PM ) { fInfo->getIntervalPattern(*bestSkeleton, UCAL_HOUR, pattern,status); if ( !pattern.isEmpty() ) { setIntervalPattern(field, pattern); } return false; } // else, looking for pattern when 'y' differ for 'dMMMM' skeleton, // first, get best match pattern "MMMd", // since there is no pattern for 'y' differs for skeleton 'MMMd', // need to look for it from skeleton 'yMMMd', // if found, adjust field width in interval pattern from // "MMM" to "MMMM". UChar fieldLetter = fgCalendarFieldToPatternLetter[field]; if ( extendedSkeleton ) { *extendedSkeleton = *skeleton; *extendedBestSkeleton = *bestSkeleton; extendedSkeleton->insert(0, fieldLetter); extendedBestSkeleton->insert(0, fieldLetter); // for example, looking for patterns when 'y' differ for // skeleton "MMMM". fInfo->getIntervalPattern(*extendedBestSkeleton,field,pattern,status); if ( pattern.isEmpty() && differenceInfo == 0 ) { // if there is no skeleton "yMMMM" defined, // look for the best match skeleton, for example: "yMMM" const UnicodeString* tmpBest = fInfo->getBestSkeleton( *extendedBestSkeleton, differenceInfo); if ( tmpBest != 0 && differenceInfo != -1 ) { fInfo->getIntervalPattern(*tmpBest, field, pattern, status); bestSkeleton = tmpBest; } } } } if ( !pattern.isEmpty() ) { if ( differenceInfo != 0 ) { UnicodeString adjustIntervalPattern; adjustFieldWidth(*skeleton, *bestSkeleton, pattern, differenceInfo, adjustIntervalPattern); setIntervalPattern(field, adjustIntervalPattern); } else { setIntervalPattern(field, pattern); } if ( extendedSkeleton && !extendedSkeleton->isEmpty() ) { return TRUE; } } return FALSE; } int32_t U_EXPORT2 DateIntervalFormat::splitPatternInto2Part(const UnicodeString& intervalPattern) { UBool inQuote = false; UChar prevCh = 0; int32_t count = 0; /* repeatedPattern used to record whether a pattern has already seen. It is a pattern applies to first calendar if it is first time seen, otherwise, it is a pattern applies to the second calendar */ UBool patternRepeated[] = { // A B C D E F G H I J K L M N O 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // P Q R S T U V W X Y Z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // a b c d e f g h i j k l m n o 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // p q r s t u v w x y z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; int8_t PATTERN_CHAR_BASE = 0x41; /* loop through the pattern string character by character looking for * the first repeated pattern letter, which breaks the interval pattern * into 2 parts. */ int32_t i; UBool foundRepetition = false; for (i = 0; i < intervalPattern.length(); ++i) { UChar ch = intervalPattern.charAt(i); if (ch != prevCh && count > 0) { // check the repeativeness of pattern letter UBool repeated = patternRepeated[(int)(prevCh - PATTERN_CHAR_BASE)]; if ( repeated == FALSE ) { patternRepeated[prevCh - PATTERN_CHAR_BASE] = TRUE; } else { foundRepetition = true; break; } count = 0; } if (ch == 0x0027 /*'*/) { // Consecutive single quotes are a single quote literal, // either outside of quotes or between quotes if ((i+1) < intervalPattern.length() && intervalPattern.charAt(i+1) == 0x0027 /*'*/) { ++i; } else { inQuote = ! inQuote; } } else if (!inQuote && ((ch >= 0x0061 /*'a'*/ && ch <= 0x007A /*'z'*/) || (ch >= 0x0041 /*'A'*/ && ch <= 0x005A /*'Z'*/))) { // ch is a date-time pattern character prevCh = ch; ++count; } } // check last pattern char, distinguish // "dd MM" ( no repetition ), // "d-d"(last char repeated ), and // "d-d MM" ( repetition found ) if ( count > 0 && foundRepetition == FALSE ) { if ( patternRepeated[(int)(prevCh - PATTERN_CHAR_BASE)] == FALSE ) { count = 0; } } return (i - count); } void DateIntervalFormat::fallbackFormatRange( Calendar& fromCalendar, Calendar& toCalendar, UnicodeString& appendTo, int8_t& firstIndex, FieldPositionHandler& fphandler, UErrorCode& status) const { UnicodeString fallbackPattern; fInfo->getFallbackIntervalPattern(fallbackPattern); SimpleFormatter sf(fallbackPattern, 2, 2, status); if (U_FAILURE(status)) { return; } int32_t offsets[2]; UnicodeString patternBody = sf.getTextWithNoArguments(offsets, 2); // TODO(ICU-20406): Use SimpleFormatter Iterator interface when available. if (offsets[0] < offsets[1]) { firstIndex = 0; appendTo.append(patternBody.tempSubStringBetween(0, offsets[0])); fDateFormat->_format(fromCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[0], offsets[1])); fDateFormat->_format(toCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[1])); } else { firstIndex = 1; appendTo.append(patternBody.tempSubStringBetween(0, offsets[1])); fDateFormat->_format(toCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[1], offsets[0])); fDateFormat->_format(fromCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[0])); } } UnicodeString& DateIntervalFormat::fallbackFormat(Calendar& fromCalendar, Calendar& toCalendar, UBool fromToOnSameDay, // new UnicodeString& appendTo, int8_t& firstIndex, FieldPositionHandler& fphandler, UErrorCode& status) const { if ( U_FAILURE(status) ) { return appendTo; } UBool formatDatePlusTimeRange = (fromToOnSameDay && fDatePattern && fTimePattern); if (formatDatePlusTimeRange) { SimpleFormatter sf(*fDateTimeFormat, 2, 2, status); if (U_FAILURE(status)) { return appendTo; } int32_t offsets[2]; UnicodeString patternBody = sf.getTextWithNoArguments(offsets, 2); UnicodeString fullPattern; // for saving the pattern in fDateFormat fDateFormat->toPattern(fullPattern); // save current pattern, restore later // {0} is time range // {1} is single date portion // TODO(ICU-20406): Use SimpleFormatter Iterator interface when available. if (offsets[0] < offsets[1]) { appendTo.append(patternBody.tempSubStringBetween(0, offsets[0])); fDateFormat->applyPattern(*fTimePattern); fallbackFormatRange(fromCalendar, toCalendar, appendTo, firstIndex, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[0], offsets[1])); fDateFormat->applyPattern(*fDatePattern); fDateFormat->_format(fromCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[1])); } else { appendTo.append(patternBody.tempSubStringBetween(0, offsets[1])); fDateFormat->applyPattern(*fDatePattern); fDateFormat->_format(fromCalendar, appendTo, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[1], offsets[0])); fDateFormat->applyPattern(*fTimePattern); fallbackFormatRange(fromCalendar, toCalendar, appendTo, firstIndex, fphandler, status); appendTo.append(patternBody.tempSubStringBetween(offsets[0])); } // restore full pattern fDateFormat->applyPattern(fullPattern); } else { fallbackFormatRange(fromCalendar, toCalendar, appendTo, firstIndex, fphandler, status); } return appendTo; } UBool U_EXPORT2 DateIntervalFormat::fieldExistsInSkeleton(UCalendarDateFields field, const UnicodeString& skeleton) { const UChar fieldChar = fgCalendarFieldToPatternLetter[field]; return ( (skeleton.indexOf(fieldChar) == -1)?FALSE:TRUE ) ; } void U_EXPORT2 DateIntervalFormat::adjustFieldWidth(const UnicodeString& inputSkeleton, const UnicodeString& bestMatchSkeleton, const UnicodeString& bestIntervalPattern, int8_t differenceInfo, UnicodeString& adjustedPtn) { adjustedPtn = bestIntervalPattern; int32_t inputSkeletonFieldWidth[] = { // A B C D E F G H I J K L M N O 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // P Q R S T U V W X Y Z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // a b c d e f g h i j k l m n o 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // p q r s t u v w x y z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; int32_t bestMatchSkeletonFieldWidth[] = { // A B C D E F G H I J K L M N O 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // P Q R S T U V W X Y Z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // a b c d e f g h i j k l m n o 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // p q r s t u v w x y z 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; DateIntervalInfo::parseSkeleton(inputSkeleton, inputSkeletonFieldWidth); DateIntervalInfo::parseSkeleton(bestMatchSkeleton, bestMatchSkeletonFieldWidth); if ( differenceInfo == 2 ) { adjustedPtn.findAndReplace(UnicodeString((UChar)0x76 /* v */), UnicodeString((UChar)0x7a /* z */)); } UBool inQuote = false; UChar prevCh = 0; int32_t count = 0; const int8_t PATTERN_CHAR_BASE = 0x41; // loop through the pattern string character by character int32_t adjustedPtnLength = adjustedPtn.length(); int32_t i; for (i = 0; i < adjustedPtnLength; ++i) { UChar ch = adjustedPtn.charAt(i); if (ch != prevCh && count > 0) { // check the repeativeness of pattern letter UChar skeletonChar = prevCh; if ( skeletonChar == CAP_L ) { // there is no "L" (always be "M") in skeleton, // but there is "L" in pattern. // for skeleton "M+", the pattern might be "...L..." skeletonChar = CAP_M; } int32_t fieldCount = bestMatchSkeletonFieldWidth[(int)(skeletonChar - PATTERN_CHAR_BASE)]; int32_t inputFieldCount = inputSkeletonFieldWidth[(int)(skeletonChar - PATTERN_CHAR_BASE)]; if ( fieldCount == count && inputFieldCount > fieldCount ) { count = inputFieldCount - fieldCount; int32_t j; for ( j = 0; j < count; ++j ) { adjustedPtn.insert(i, prevCh); } i += count; adjustedPtnLength += count; } count = 0; } if (ch == 0x0027 /*'*/) { // Consecutive single quotes are a single quote literal, // either outside of quotes or between quotes if ((i+1) < adjustedPtn.length() && adjustedPtn.charAt(i+1) == 0x0027 /* ' */) { ++i; } else { inQuote = ! inQuote; } } else if ( ! inQuote && ((ch >= 0x0061 /*'a'*/ && ch <= 0x007A /*'z'*/) || (ch >= 0x0041 /*'A'*/ && ch <= 0x005A /*'Z'*/))) { // ch is a date-time pattern character prevCh = ch; ++count; } } if ( count > 0 ) { // last item // check the repeativeness of pattern letter UChar skeletonChar = prevCh; if ( skeletonChar == CAP_L ) { // there is no "L" (always be "M") in skeleton, // but there is "L" in pattern. // for skeleton "M+", the pattern might be "...L..." skeletonChar = CAP_M; } int32_t fieldCount = bestMatchSkeletonFieldWidth[(int)(skeletonChar - PATTERN_CHAR_BASE)]; int32_t inputFieldCount = inputSkeletonFieldWidth[(int)(skeletonChar - PATTERN_CHAR_BASE)]; if ( fieldCount == count && inputFieldCount > fieldCount ) { count = inputFieldCount - fieldCount; int32_t j; for ( j = 0; j < count; ++j ) { adjustedPtn.append(prevCh); } } } } void DateIntervalFormat::concatSingleDate2TimeInterval(UnicodeString& format, const UnicodeString& datePattern, UCalendarDateFields field, UErrorCode& status) { // following should not set wrong status int32_t itvPtnIndex = DateIntervalInfo::calendarFieldToIntervalIndex(field, status); if ( U_FAILURE(status) ) { return; } PatternInfo& timeItvPtnInfo = fIntervalPatterns[itvPtnIndex]; if ( !timeItvPtnInfo.firstPart.isEmpty() ) { UnicodeString timeIntervalPattern(timeItvPtnInfo.firstPart); timeIntervalPattern.append(timeItvPtnInfo.secondPart); UnicodeString combinedPattern; SimpleFormatter(format, 2, 2, status). format(timeIntervalPattern, datePattern, combinedPattern, status); if ( U_FAILURE(status) ) { return; } setIntervalPattern(field, combinedPattern, timeItvPtnInfo.laterDateFirst); } // else: fall back // it should not happen if the interval format defined is valid } const UChar DateIntervalFormat::fgCalendarFieldToPatternLetter[] = { /*GyM*/ CAP_G, LOW_Y, CAP_M, /*wWd*/ LOW_W, CAP_W, LOW_D, /*DEF*/ CAP_D, CAP_E, CAP_F, /*ahH*/ LOW_A, LOW_H, CAP_H, /*msS*/ LOW_M, LOW_S, CAP_S, // MINUTE, SECOND, MILLISECOND /*z.Y*/ LOW_Z, SPACE, CAP_Y, // ZONE_OFFSET, DST_OFFSET, YEAR_WOY, /*eug*/ LOW_E, LOW_U, LOW_G, // DOW_LOCAL, EXTENDED_YEAR, JULIAN_DAY, /*A..*/ CAP_A, SPACE, SPACE, // MILLISECONDS_IN_DAY, IS_LEAP_MONTH, FIELD_COUNT }; U_NAMESPACE_END #endif