// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /* ****************************************************************************** * Copyright (C) 2014-2016, International Business Machines Corporation and * others. All Rights Reserved. ****************************************************************************** * * File reldatefmt.cpp ****************************************************************************** */ #include "unicode/reldatefmt.h" #if !UCONFIG_NO_FORMATTING && !UCONFIG_NO_BREAK_ITERATION #include #include #include "unicode/dtfmtsym.h" #include "unicode/ucasemap.h" #include "unicode/ureldatefmt.h" #include "unicode/udisplaycontext.h" #include "unicode/unum.h" #include "unicode/localpointer.h" #include "unicode/plurrule.h" #include "unicode/simpleformatter.h" #include "unicode/decimfmt.h" #include "unicode/numfmt.h" #include "unicode/brkiter.h" #include "unicode/simpleformatter.h" #include "uresimp.h" #include "unicode/ures.h" #include "cstring.h" #include "ucln_in.h" #include "mutex.h" #include "charstr.h" #include "uassert.h" #include "quantityformatter.h" #include "resource.h" #include "sharedbreakiterator.h" #include "sharedpluralrules.h" #include "sharednumberformat.h" #include "standardplural.h" #include "unifiedcache.h" #include "util.h" #include "number_stringbuilder.h" #include "number_utypes.h" #include "number_modifiers.h" #include "formattedval_impl.h" #include "number_utils.h" // Copied from uscript_props.cpp U_NAMESPACE_BEGIN // RelativeDateTimeFormatter specific data for a single locale class RelativeDateTimeCacheData: public SharedObject { public: RelativeDateTimeCacheData() : combinedDateAndTime(nullptr) { // Initialize the cache arrays for (int32_t style = 0; style < UDAT_STYLE_COUNT; ++style) { for (int32_t relUnit = 0; relUnit < UDAT_REL_UNIT_COUNT; ++relUnit) { for (int32_t pl = 0; pl < StandardPlural::COUNT; ++pl) { relativeUnitsFormatters[style][relUnit][0][pl] = nullptr; relativeUnitsFormatters[style][relUnit][1][pl] = nullptr; } } } for (int32_t i = 0; i < UDAT_STYLE_COUNT; ++i) { fallBackCache[i] = -1; } } virtual ~RelativeDateTimeCacheData(); // no numbers: e.g Next Tuesday; Yesterday; etc. UnicodeString absoluteUnits[UDAT_STYLE_COUNT][UDAT_ABSOLUTE_UNIT_COUNT][UDAT_DIRECTION_COUNT]; // SimpleFormatter pointers for relative unit format, // e.g., Next Tuesday; Yesterday; etc. For third index, 0 // means past, e.g., 5 days ago; 1 means future, e.g., in 5 days. SimpleFormatter *relativeUnitsFormatters[UDAT_STYLE_COUNT] [UDAT_REL_UNIT_COUNT][2][StandardPlural::COUNT]; const UnicodeString& getAbsoluteUnitString(int32_t fStyle, UDateAbsoluteUnit unit, UDateDirection direction) const; const SimpleFormatter* getRelativeUnitFormatter(int32_t fStyle, UDateRelativeUnit unit, int32_t pastFutureIndex, int32_t pluralUnit) const; const SimpleFormatter* getRelativeDateTimeUnitFormatter(int32_t fStyle, URelativeDateTimeUnit unit, int32_t pastFutureIndex, int32_t pluralUnit) const; const UnicodeString emptyString; // Mappping from source to target styles for alias fallback. int32_t fallBackCache[UDAT_STYLE_COUNT]; void adoptCombinedDateAndTime(SimpleFormatter *fmtToAdopt) { delete combinedDateAndTime; combinedDateAndTime = fmtToAdopt; } const SimpleFormatter *getCombinedDateAndTime() const { return combinedDateAndTime; } private: SimpleFormatter *combinedDateAndTime; RelativeDateTimeCacheData(const RelativeDateTimeCacheData &other); RelativeDateTimeCacheData& operator=( const RelativeDateTimeCacheData &other); }; RelativeDateTimeCacheData::~RelativeDateTimeCacheData() { // clear out the cache arrays for (int32_t style = 0; style < UDAT_STYLE_COUNT; ++style) { for (int32_t relUnit = 0; relUnit < UDAT_REL_UNIT_COUNT; ++relUnit) { for (int32_t pl = 0; pl < StandardPlural::COUNT; ++pl) { delete relativeUnitsFormatters[style][relUnit][0][pl]; delete relativeUnitsFormatters[style][relUnit][1][pl]; } } } delete combinedDateAndTime; } // Use fallback cache for absolute units. const UnicodeString& RelativeDateTimeCacheData::getAbsoluteUnitString( int32_t fStyle, UDateAbsoluteUnit unit, UDateDirection direction) const { int32_t style = fStyle; do { if (!absoluteUnits[style][unit][direction].isEmpty()) { return absoluteUnits[style][unit][direction]; } style = fallBackCache[style]; } while (style != -1); return emptyString; } const SimpleFormatter* RelativeDateTimeCacheData::getRelativeUnitFormatter( int32_t fStyle, UDateRelativeUnit unit, int32_t pastFutureIndex, int32_t pluralUnit) const { URelativeDateTimeUnit rdtunit = UDAT_REL_UNIT_COUNT; switch (unit) { case UDAT_RELATIVE_YEARS: rdtunit = UDAT_REL_UNIT_YEAR; break; case UDAT_RELATIVE_MONTHS: rdtunit = UDAT_REL_UNIT_MONTH; break; case UDAT_RELATIVE_WEEKS: rdtunit = UDAT_REL_UNIT_WEEK; break; case UDAT_RELATIVE_DAYS: rdtunit = UDAT_REL_UNIT_DAY; break; case UDAT_RELATIVE_HOURS: rdtunit = UDAT_REL_UNIT_HOUR; break; case UDAT_RELATIVE_MINUTES: rdtunit = UDAT_REL_UNIT_MINUTE; break; case UDAT_RELATIVE_SECONDS: rdtunit = UDAT_REL_UNIT_SECOND; break; default: // a unit that the above method does not handle return nullptr; } return getRelativeDateTimeUnitFormatter(fStyle, rdtunit, pastFutureIndex, pluralUnit); } // Use fallback cache for SimpleFormatter relativeUnits. const SimpleFormatter* RelativeDateTimeCacheData::getRelativeDateTimeUnitFormatter( int32_t fStyle, URelativeDateTimeUnit unit, int32_t pastFutureIndex, int32_t pluralUnit) const { while (true) { int32_t style = fStyle; do { if (relativeUnitsFormatters[style][unit][pastFutureIndex][pluralUnit] != nullptr) { return relativeUnitsFormatters[style][unit][pastFutureIndex][pluralUnit]; } style = fallBackCache[style]; } while (style != -1); if (pluralUnit == StandardPlural::OTHER) { break; } pluralUnit = StandardPlural::OTHER; } return nullptr; // No formatter found. } static UBool getStringWithFallback( const UResourceBundle *resource, const char *key, UnicodeString &result, UErrorCode &status) { int32_t len = 0; const UChar *resStr = ures_getStringByKeyWithFallback( resource, key, &len, &status); if (U_FAILURE(status)) { return FALSE; } result.setTo(TRUE, resStr, len); return TRUE; } static UBool getStringByIndex( const UResourceBundle *resource, int32_t idx, UnicodeString &result, UErrorCode &status) { int32_t len = 0; const UChar *resStr = ures_getStringByIndex( resource, idx, &len, &status); if (U_FAILURE(status)) { return FALSE; } result.setTo(TRUE, resStr, len); return TRUE; } namespace { /** * Sink for enumerating all of the measurement unit display names. * * More specific bundles (en_GB) are enumerated before their parents (en_001, en, root): * Only store a value if it is still missing, that is, it has not been overridden. */ struct RelDateTimeFmtDataSink : public ResourceSink { /** * Sink for patterns for relative dates and times. For example, * fields/relative/... */ // Generic unit enum for storing Unit info. typedef enum RelAbsUnit { INVALID_UNIT = -1, SECOND, MINUTE, HOUR, DAY, WEEK, MONTH, QUARTER, YEAR, SUNDAY, MONDAY, TUESDAY, WEDNESDAY, THURSDAY, FRIDAY, SATURDAY } RelAbsUnit; static int32_t relUnitFromGeneric(RelAbsUnit genUnit) { // Converts the generic units to UDAT_RELATIVE version. switch (genUnit) { case SECOND: return UDAT_REL_UNIT_SECOND; case MINUTE: return UDAT_REL_UNIT_MINUTE; case HOUR: return UDAT_REL_UNIT_HOUR; case DAY: return UDAT_REL_UNIT_DAY; case WEEK: return UDAT_REL_UNIT_WEEK; case MONTH: return UDAT_REL_UNIT_MONTH; case QUARTER: return UDAT_REL_UNIT_QUARTER; case YEAR: return UDAT_REL_UNIT_YEAR; case SUNDAY: return UDAT_REL_UNIT_SUNDAY; case MONDAY: return UDAT_REL_UNIT_MONDAY; case TUESDAY: return UDAT_REL_UNIT_TUESDAY; case WEDNESDAY: return UDAT_REL_UNIT_WEDNESDAY; case THURSDAY: return UDAT_REL_UNIT_THURSDAY; case FRIDAY: return UDAT_REL_UNIT_FRIDAY; case SATURDAY: return UDAT_REL_UNIT_SATURDAY; default: return -1; } } static int32_t absUnitFromGeneric(RelAbsUnit genUnit) { // Converts the generic units to UDAT_RELATIVE version. switch (genUnit) { case DAY: return UDAT_ABSOLUTE_DAY; case WEEK: return UDAT_ABSOLUTE_WEEK; case MONTH: return UDAT_ABSOLUTE_MONTH; case QUARTER: return UDAT_ABSOLUTE_QUARTER; case YEAR: return UDAT_ABSOLUTE_YEAR; case SUNDAY: return UDAT_ABSOLUTE_SUNDAY; case MONDAY: return UDAT_ABSOLUTE_MONDAY; case TUESDAY: return UDAT_ABSOLUTE_TUESDAY; case WEDNESDAY: return UDAT_ABSOLUTE_WEDNESDAY; case THURSDAY: return UDAT_ABSOLUTE_THURSDAY; case FRIDAY: return UDAT_ABSOLUTE_FRIDAY; case SATURDAY: return UDAT_ABSOLUTE_SATURDAY; default: return -1; } } static int32_t keyToDirection(const char* key) { if (uprv_strcmp(key, "-2") == 0) { return UDAT_DIRECTION_LAST_2; } if (uprv_strcmp(key, "-1") == 0) { return UDAT_DIRECTION_LAST; } if (uprv_strcmp(key, "0") == 0) { return UDAT_DIRECTION_THIS; } if (uprv_strcmp(key, "1") == 0) { return UDAT_DIRECTION_NEXT; } if (uprv_strcmp(key, "2") == 0) { return UDAT_DIRECTION_NEXT_2; } return -1; } // Values kept between levels of parsing the CLDR data. int32_t pastFutureIndex; // 0 == past or 1 == future UDateRelativeDateTimeFormatterStyle style; // {LONG, SHORT, NARROW} RelAbsUnit genericUnit; RelativeDateTimeCacheData &outputData; // Constructor RelDateTimeFmtDataSink(RelativeDateTimeCacheData& cacheData) : outputData(cacheData) { // Clear cacheData.fallBackCache cacheData.fallBackCache[UDAT_STYLE_LONG] = -1; cacheData.fallBackCache[UDAT_STYLE_SHORT] = -1; cacheData.fallBackCache[UDAT_STYLE_NARROW] = -1; } ~RelDateTimeFmtDataSink(); // Utility functions static UDateRelativeDateTimeFormatterStyle styleFromString(const char *s) { int32_t len = static_cast(uprv_strlen(s)); if (len >= 7 && uprv_strcmp(s + len - 7, "-narrow") == 0) { return UDAT_STYLE_NARROW; } if (len >= 6 && uprv_strcmp(s + len - 6, "-short") == 0) { return UDAT_STYLE_SHORT; } return UDAT_STYLE_LONG; } static int32_t styleSuffixLength(UDateRelativeDateTimeFormatterStyle style) { switch (style) { case UDAT_STYLE_NARROW: return 7; case UDAT_STYLE_SHORT: return 6; default: return 0; } } // Utility functions static UDateRelativeDateTimeFormatterStyle styleFromAliasUnicodeString(UnicodeString s) { static const UChar narrow[7] = {0x002D, 0x006E, 0x0061, 0x0072, 0x0072, 0x006F, 0x0077}; static const UChar sshort[6] = {0x002D, 0x0073, 0x0068, 0x006F, 0x0072, 0x0074,}; if (s.endsWith(narrow, 7)) { return UDAT_STYLE_NARROW; } if (s.endsWith(sshort, 6)) { return UDAT_STYLE_SHORT; } return UDAT_STYLE_LONG; } static RelAbsUnit unitOrNegativeFromString(const char* keyword, int32_t length) { // Quick check from string to enum. switch (length) { case 3: if (uprv_strncmp(keyword, "day", length) == 0) { return DAY; } else if (uprv_strncmp(keyword, "sun", length) == 0) { return SUNDAY; } else if (uprv_strncmp(keyword, "mon", length) == 0) { return MONDAY; } else if (uprv_strncmp(keyword, "tue", length) == 0) { return TUESDAY; } else if (uprv_strncmp(keyword, "wed", length) == 0) { return WEDNESDAY; } else if (uprv_strncmp(keyword, "thu", length) == 0) { return THURSDAY; } else if (uprv_strncmp(keyword, "fri", length) == 0) { return FRIDAY; } else if (uprv_strncmp(keyword, "sat", length) == 0) { return SATURDAY; } break; case 4: if (uprv_strncmp(keyword, "hour", length) == 0) { return HOUR; } else if (uprv_strncmp(keyword, "week", length) == 0) { return WEEK; } else if (uprv_strncmp(keyword, "year", length) == 0) { return YEAR; } break; case 5: if (uprv_strncmp(keyword, "month", length) == 0) { return MONTH; } break; case 6: if (uprv_strncmp(keyword, "minute", length) == 0) { return MINUTE; } else if (uprv_strncmp(keyword, "second", length) == 0) { return SECOND; } break; case 7: if (uprv_strncmp(keyword, "quarter", length) == 0) { return QUARTER; // TODO: Check @provisional } break; default: break; } return INVALID_UNIT; } void handlePlainDirection(ResourceValue &value, UErrorCode &errorCode) { // Handle Display Name for PLAIN direction for some units. if (U_FAILURE(errorCode)) { return; } int32_t absUnit = absUnitFromGeneric(genericUnit); if (absUnit < 0) { return; // Not interesting. } // Store displayname if not set. if (outputData.absoluteUnits[style] [absUnit][UDAT_DIRECTION_PLAIN].isEmpty()) { outputData.absoluteUnits[style] [absUnit][UDAT_DIRECTION_PLAIN].fastCopyFrom(value.getUnicodeString(errorCode)); return; } } void consumeTableRelative(const char *key, ResourceValue &value, UErrorCode &errorCode) { ResourceTable unitTypesTable = value.getTable(errorCode); if (U_FAILURE(errorCode)) { return; } for (int32_t i = 0; unitTypesTable.getKeyAndValue(i, key, value); ++i) { if (value.getType() == URES_STRING) { int32_t direction = keyToDirection(key); if (direction < 0) { continue; } int32_t relUnitIndex = relUnitFromGeneric(genericUnit); if (relUnitIndex == UDAT_REL_UNIT_SECOND && uprv_strcmp(key, "0") == 0 && outputData.absoluteUnits[style][UDAT_ABSOLUTE_NOW][UDAT_DIRECTION_PLAIN].isEmpty()) { // Handle "NOW" outputData.absoluteUnits[style][UDAT_ABSOLUTE_NOW] [UDAT_DIRECTION_PLAIN].fastCopyFrom(value.getUnicodeString(errorCode)); } int32_t absUnitIndex = absUnitFromGeneric(genericUnit); if (absUnitIndex < 0) { continue; } // Only reset if slot is empty. if (outputData.absoluteUnits[style][absUnitIndex][direction].isEmpty()) { outputData.absoluteUnits[style][absUnitIndex] [direction].fastCopyFrom(value.getUnicodeString(errorCode)); } } } } void consumeTimeDetail(int32_t relUnitIndex, const char *key, ResourceValue &value, UErrorCode &errorCode) { ResourceTable unitTypesTable = value.getTable(errorCode); if (U_FAILURE(errorCode)) { return; } for (int32_t i = 0; unitTypesTable.getKeyAndValue(i, key, value); ++i) { if (value.getType() == URES_STRING) { int32_t pluralIndex = StandardPlural::indexOrNegativeFromString(key); if (pluralIndex >= 0) { SimpleFormatter **patterns = outputData.relativeUnitsFormatters[style][relUnitIndex] [pastFutureIndex]; // Only set if not already established. if (patterns[pluralIndex] == nullptr) { patterns[pluralIndex] = new SimpleFormatter( value.getUnicodeString(errorCode), 0, 1, errorCode); if (patterns[pluralIndex] == nullptr) { errorCode = U_MEMORY_ALLOCATION_ERROR; } } } } } } void consumeTableRelativeTime(const char *key, ResourceValue &value, UErrorCode &errorCode) { ResourceTable relativeTimeTable = value.getTable(errorCode); if (U_FAILURE(errorCode)) { return; } int32_t relUnitIndex = relUnitFromGeneric(genericUnit); if (relUnitIndex < 0) { return; } for (int32_t i = 0; relativeTimeTable.getKeyAndValue(i, key, value); ++i) { if (uprv_strcmp(key, "past") == 0) { pastFutureIndex = 0; } else if (uprv_strcmp(key, "future") == 0) { pastFutureIndex = 1; } else { // Unknown key. continue; } consumeTimeDetail(relUnitIndex, key, value, errorCode); } } void consumeAlias(const char *key, const ResourceValue &value, UErrorCode &errorCode) { UDateRelativeDateTimeFormatterStyle sourceStyle = styleFromString(key); const UnicodeString valueStr = value.getAliasUnicodeString(errorCode); if (U_FAILURE(errorCode)) { return; } UDateRelativeDateTimeFormatterStyle targetStyle = styleFromAliasUnicodeString(valueStr); if (sourceStyle == targetStyle) { errorCode = U_INVALID_FORMAT_ERROR; return; } if (outputData.fallBackCache[sourceStyle] != -1 && outputData.fallBackCache[sourceStyle] != targetStyle) { errorCode = U_INVALID_FORMAT_ERROR; return; } outputData.fallBackCache[sourceStyle] = targetStyle; } void consumeTimeUnit(const char *key, ResourceValue &value, UErrorCode &errorCode) { ResourceTable unitTypesTable = value.getTable(errorCode); if (U_FAILURE(errorCode)) { return; } for (int32_t i = 0; unitTypesTable.getKeyAndValue(i, key, value); ++i) { // Handle display name. if (uprv_strcmp(key, "dn") == 0 && value.getType() == URES_STRING) { handlePlainDirection(value, errorCode); } if (value.getType() == URES_TABLE) { if (uprv_strcmp(key, "relative") == 0) { consumeTableRelative(key, value, errorCode); } else if (uprv_strcmp(key, "relativeTime") == 0) { consumeTableRelativeTime(key, value, errorCode); } } } } virtual void put(const char *key, ResourceValue &value, UBool /*noFallback*/, UErrorCode &errorCode) { // Main entry point to sink ResourceTable table = value.getTable(errorCode); if (U_FAILURE(errorCode)) { return; } for (int32_t i = 0; table.getKeyAndValue(i, key, value); ++i) { if (value.getType() == URES_ALIAS) { consumeAlias(key, value, errorCode); } else { style = styleFromString(key); int32_t unitSize = static_cast(uprv_strlen(key)) - styleSuffixLength(style); genericUnit = unitOrNegativeFromString(key, unitSize); if (style >= 0 && genericUnit != INVALID_UNIT) { consumeTimeUnit(key, value, errorCode); } } } } }; // Virtual destructors must be defined out of line. RelDateTimeFmtDataSink::~RelDateTimeFmtDataSink() {} } // namespace static const DateFormatSymbols::DtWidthType styleToDateFormatSymbolWidth[UDAT_STYLE_COUNT] = { DateFormatSymbols::WIDE, DateFormatSymbols::SHORT, DateFormatSymbols::NARROW }; // Get days of weeks from the DateFormatSymbols class. static void loadWeekdayNames(UnicodeString absoluteUnits[UDAT_STYLE_COUNT] [UDAT_ABSOLUTE_UNIT_COUNT][UDAT_DIRECTION_COUNT], const char* localeId, UErrorCode& status) { if (U_FAILURE(status)) { return; } Locale locale(localeId); DateFormatSymbols dfSym(locale, status); if (U_FAILURE(status)) { return; } for (int32_t style = 0; style < UDAT_STYLE_COUNT; ++style) { DateFormatSymbols::DtWidthType dtfmtWidth = styleToDateFormatSymbolWidth[style]; int32_t count; const UnicodeString* weekdayNames = dfSym.getWeekdays(count, DateFormatSymbols::STANDALONE, dtfmtWidth); for (int32_t dayIndex = UDAT_ABSOLUTE_SUNDAY; dayIndex <= UDAT_ABSOLUTE_SATURDAY; ++ dayIndex) { int32_t dateSymbolIndex = (dayIndex - UDAT_ABSOLUTE_SUNDAY) + UCAL_SUNDAY; absoluteUnits[style][dayIndex][UDAT_DIRECTION_PLAIN].fastCopyFrom( weekdayNames[dateSymbolIndex]); } } } static UBool loadUnitData( const UResourceBundle *resource, RelativeDateTimeCacheData &cacheData, const char* localeId, UErrorCode &status) { RelDateTimeFmtDataSink sink(cacheData); ures_getAllItemsWithFallback(resource, "fields", sink, status); if (U_FAILURE(status)) { return false; } // Get the weekday names from DateFormatSymbols. loadWeekdayNames(cacheData.absoluteUnits, localeId, status); return U_SUCCESS(status); } static UBool getDateTimePattern( const UResourceBundle *resource, UnicodeString &result, UErrorCode &status) { UnicodeString defaultCalendarName; if (!getStringWithFallback( resource, "calendar/default", defaultCalendarName, status)) { return FALSE; } CharString pathBuffer; pathBuffer.append("calendar/", status) .appendInvariantChars(defaultCalendarName, status) .append("/DateTimePatterns", status); LocalUResourceBundlePointer topLevel( ures_getByKeyWithFallback( resource, pathBuffer.data(), nullptr, &status)); if (U_FAILURE(status)) { return FALSE; } int32_t size = ures_getSize(topLevel.getAlias()); if (size <= 8) { // Oops, size is too small to access the index that we want, fallback // to a hard-coded value. result = UNICODE_STRING_SIMPLE("{1} {0}"); return TRUE; } return getStringByIndex(topLevel.getAlias(), 8, result, status); } template<> U_I18N_API const RelativeDateTimeCacheData *LocaleCacheKey::createObject(const void * /*unused*/, UErrorCode &status) const { const char *localeId = fLoc.getName(); LocalUResourceBundlePointer topLevel(ures_open(nullptr, localeId, &status)); if (U_FAILURE(status)) { return nullptr; } LocalPointer result( new RelativeDateTimeCacheData()); if (result.isNull()) { status = U_MEMORY_ALLOCATION_ERROR; return nullptr; } if (!loadUnitData( topLevel.getAlias(), *result, localeId, status)) { return nullptr; } UnicodeString dateTimePattern; if (!getDateTimePattern(topLevel.getAlias(), dateTimePattern, status)) { return nullptr; } result->adoptCombinedDateAndTime( new SimpleFormatter(dateTimePattern, 2, 2, status)); if (U_FAILURE(status)) { return nullptr; } result->addRef(); return result.orphan(); } static constexpr number::impl::Field kRDTNumericField = number::impl::NumFieldUtils::compress(); static constexpr number::impl::Field kRDTLiteralField = number::impl::NumFieldUtils::compress(); class FormattedRelativeDateTimeData : public FormattedValueNumberStringBuilderImpl { public: FormattedRelativeDateTimeData() : FormattedValueNumberStringBuilderImpl(kRDTNumericField) {} virtual ~FormattedRelativeDateTimeData(); }; FormattedRelativeDateTimeData::~FormattedRelativeDateTimeData() = default; UPRV_FORMATTED_VALUE_SUBCLASS_AUTO_IMPL(FormattedRelativeDateTime) RelativeDateTimeFormatter::RelativeDateTimeFormatter(UErrorCode& status) : fCache(nullptr), fNumberFormat(nullptr), fPluralRules(nullptr), fStyle(UDAT_STYLE_LONG), fContext(UDISPCTX_CAPITALIZATION_NONE), fOptBreakIterator(nullptr) { init(nullptr, nullptr, status); } RelativeDateTimeFormatter::RelativeDateTimeFormatter( const Locale& locale, UErrorCode& status) : fCache(nullptr), fNumberFormat(nullptr), fPluralRules(nullptr), fStyle(UDAT_STYLE_LONG), fContext(UDISPCTX_CAPITALIZATION_NONE), fOptBreakIterator(nullptr), fLocale(locale) { init(nullptr, nullptr, status); } RelativeDateTimeFormatter::RelativeDateTimeFormatter( const Locale& locale, NumberFormat *nfToAdopt, UErrorCode& status) : fCache(nullptr), fNumberFormat(nullptr), fPluralRules(nullptr), fStyle(UDAT_STYLE_LONG), fContext(UDISPCTX_CAPITALIZATION_NONE), fOptBreakIterator(nullptr), fLocale(locale) { init(nfToAdopt, nullptr, status); } RelativeDateTimeFormatter::RelativeDateTimeFormatter( const Locale& locale, NumberFormat *nfToAdopt, UDateRelativeDateTimeFormatterStyle styl, UDisplayContext capitalizationContext, UErrorCode& status) : fCache(nullptr), fNumberFormat(nullptr), fPluralRules(nullptr), fStyle(styl), fContext(capitalizationContext), fOptBreakIterator(nullptr), fLocale(locale) { if (U_FAILURE(status)) { return; } if ((capitalizationContext >> 8) != UDISPCTX_TYPE_CAPITALIZATION) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } if (capitalizationContext == UDISPCTX_CAPITALIZATION_FOR_BEGINNING_OF_SENTENCE) { BreakIterator *bi = BreakIterator::createSentenceInstance(locale, status); if (U_FAILURE(status)) { return; } init(nfToAdopt, bi, status); } else { init(nfToAdopt, nullptr, status); } } RelativeDateTimeFormatter::RelativeDateTimeFormatter( const RelativeDateTimeFormatter& other) : UObject(other), fCache(other.fCache), fNumberFormat(other.fNumberFormat), fPluralRules(other.fPluralRules), fStyle(other.fStyle), fContext(other.fContext), fOptBreakIterator(other.fOptBreakIterator), fLocale(other.fLocale) { fCache->addRef(); fNumberFormat->addRef(); fPluralRules->addRef(); if (fOptBreakIterator != nullptr) { fOptBreakIterator->addRef(); } } RelativeDateTimeFormatter& RelativeDateTimeFormatter::operator=( const RelativeDateTimeFormatter& other) { if (this != &other) { SharedObject::copyPtr(other.fCache, fCache); SharedObject::copyPtr(other.fNumberFormat, fNumberFormat); SharedObject::copyPtr(other.fPluralRules, fPluralRules); SharedObject::copyPtr(other.fOptBreakIterator, fOptBreakIterator); fStyle = other.fStyle; fContext = other.fContext; fLocale = other.fLocale; } return *this; } RelativeDateTimeFormatter::~RelativeDateTimeFormatter() { if (fCache != nullptr) { fCache->removeRef(); } if (fNumberFormat != nullptr) { fNumberFormat->removeRef(); } if (fPluralRules != nullptr) { fPluralRules->removeRef(); } if (fOptBreakIterator != nullptr) { fOptBreakIterator->removeRef(); } } const NumberFormat& RelativeDateTimeFormatter::getNumberFormat() const { return **fNumberFormat; } UDisplayContext RelativeDateTimeFormatter::getCapitalizationContext() const { return fContext; } UDateRelativeDateTimeFormatterStyle RelativeDateTimeFormatter::getFormatStyle() const { return fStyle; } // To reduce boilerplate code, we use a helper function that forwards variadic // arguments to the formatImpl function. template UnicodeString& RelativeDateTimeFormatter::doFormat( F callback, UnicodeString& appendTo, UErrorCode& status, Args... args) const { FormattedRelativeDateTimeData output; (this->*callback)(std::forward(args)..., output, status); if (U_FAILURE(status)) { return appendTo; } UnicodeString result = output.getStringRef().toUnicodeString(); return appendTo.append(adjustForContext(result)); } template FormattedRelativeDateTime RelativeDateTimeFormatter::doFormatToValue( F callback, UErrorCode& status, Args... args) const { if (!checkNoAdjustForContext(status)) { return FormattedRelativeDateTime(status); } LocalPointer output( new FormattedRelativeDateTimeData(), status); if (U_FAILURE(status)) { return FormattedRelativeDateTime(status); } (this->*callback)(std::forward(args)..., *output, status); output->getStringRef().writeTerminator(status); return FormattedRelativeDateTime(output.orphan()); } UnicodeString& RelativeDateTimeFormatter::format( double quantity, UDateDirection direction, UDateRelativeUnit unit, UnicodeString& appendTo, UErrorCode& status) const { return doFormat( &RelativeDateTimeFormatter::formatImpl, appendTo, status, quantity, direction, unit); } FormattedRelativeDateTime RelativeDateTimeFormatter::formatToValue( double quantity, UDateDirection direction, UDateRelativeUnit unit, UErrorCode& status) const { return doFormatToValue( &RelativeDateTimeFormatter::formatImpl, status, quantity, direction, unit); } void RelativeDateTimeFormatter::formatImpl( double quantity, UDateDirection direction, UDateRelativeUnit unit, FormattedRelativeDateTimeData& output, UErrorCode& status) const { if (U_FAILURE(status)) { return; } if (direction != UDAT_DIRECTION_LAST && direction != UDAT_DIRECTION_NEXT) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } int32_t bFuture = direction == UDAT_DIRECTION_NEXT ? 1 : 0; StandardPlural::Form pluralForm; QuantityFormatter::formatAndSelect( quantity, **fNumberFormat, **fPluralRules, output.getStringRef(), pluralForm, status); if (U_FAILURE(status)) { return; } const SimpleFormatter* formatter = fCache->getRelativeUnitFormatter(fStyle, unit, bFuture, pluralForm); if (formatter == nullptr) { // TODO: WARN - look at quantity formatter's action with an error. status = U_INVALID_FORMAT_ERROR; return; } number::impl::SimpleModifier modifier(*formatter, kRDTLiteralField, false); modifier.formatAsPrefixSuffix( output.getStringRef(), 0, output.getStringRef().length(), status); } UnicodeString& RelativeDateTimeFormatter::formatNumeric( double offset, URelativeDateTimeUnit unit, UnicodeString& appendTo, UErrorCode& status) const { return doFormat( &RelativeDateTimeFormatter::formatNumericImpl, appendTo, status, offset, unit); } FormattedRelativeDateTime RelativeDateTimeFormatter::formatNumericToValue( double offset, URelativeDateTimeUnit unit, UErrorCode& status) const { return doFormatToValue( &RelativeDateTimeFormatter::formatNumericImpl, status, offset, unit); } void RelativeDateTimeFormatter::formatNumericImpl( double offset, URelativeDateTimeUnit unit, FormattedRelativeDateTimeData& output, UErrorCode& status) const { if (U_FAILURE(status)) { return; } UDateDirection direction = UDAT_DIRECTION_NEXT; if (std::signbit(offset)) { // needed to handle -0.0 direction = UDAT_DIRECTION_LAST; offset = -offset; } if (direction != UDAT_DIRECTION_LAST && direction != UDAT_DIRECTION_NEXT) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } int32_t bFuture = direction == UDAT_DIRECTION_NEXT ? 1 : 0; StandardPlural::Form pluralForm; QuantityFormatter::formatAndSelect( offset, **fNumberFormat, **fPluralRules, output.getStringRef(), pluralForm, status); if (U_FAILURE(status)) { return; } const SimpleFormatter* formatter = fCache->getRelativeDateTimeUnitFormatter(fStyle, unit, bFuture, pluralForm); if (formatter == nullptr) { // TODO: WARN - look at quantity formatter's action with an error. status = U_INVALID_FORMAT_ERROR; return; } number::impl::SimpleModifier modifier(*formatter, kRDTLiteralField, false); modifier.formatAsPrefixSuffix( output.getStringRef(), 0, output.getStringRef().length(), status); } UnicodeString& RelativeDateTimeFormatter::format( UDateDirection direction, UDateAbsoluteUnit unit, UnicodeString& appendTo, UErrorCode& status) const { return doFormat( &RelativeDateTimeFormatter::formatAbsoluteImpl, appendTo, status, direction, unit); } FormattedRelativeDateTime RelativeDateTimeFormatter::formatToValue( UDateDirection direction, UDateAbsoluteUnit unit, UErrorCode& status) const { return doFormatToValue( &RelativeDateTimeFormatter::formatAbsoluteImpl, status, direction, unit); } void RelativeDateTimeFormatter::formatAbsoluteImpl( UDateDirection direction, UDateAbsoluteUnit unit, FormattedRelativeDateTimeData& output, UErrorCode& status) const { if (U_FAILURE(status)) { return; } if (unit == UDAT_ABSOLUTE_NOW && direction != UDAT_DIRECTION_PLAIN) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } // Get string using fallback. output.getStringRef().append( fCache->getAbsoluteUnitString(fStyle, unit, direction), kRDTLiteralField, status); } UnicodeString& RelativeDateTimeFormatter::format( double offset, URelativeDateTimeUnit unit, UnicodeString& appendTo, UErrorCode& status) const { return doFormat( &RelativeDateTimeFormatter::formatRelativeImpl, appendTo, status, offset, unit); } FormattedRelativeDateTime RelativeDateTimeFormatter::formatToValue( double offset, URelativeDateTimeUnit unit, UErrorCode& status) const { return doFormatToValue( &RelativeDateTimeFormatter::formatRelativeImpl, status, offset, unit); } void RelativeDateTimeFormatter::formatRelativeImpl( double offset, URelativeDateTimeUnit unit, FormattedRelativeDateTimeData& output, UErrorCode& status) const { if (U_FAILURE(status)) { return; } // TODO: // The full implementation of this depends on CLDR data that is not yet available, // see: http://unicode.org/cldr/trac/ticket/9165 Add more relative field data. // In the meantime do a quick bring-up by calling the old format method; this // leaves some holes (even for data that is currently available, such as quarter). // When the new CLDR data is available, update the data storage accordingly, // rewrite this to use it directly, and rewrite the old format method to call this // new one; that is covered by http://bugs.icu-project.org/trac/ticket/12171. UDateDirection direction = UDAT_DIRECTION_COUNT; if (offset > -2.1 && offset < 2.1) { // Allow a 1% epsilon, so offsets in -1.01..-0.99 map to LAST double offsetx100 = offset * 100.0; int32_t intoffset = (offsetx100 < 0)? (int32_t)(offsetx100-0.5) : (int32_t)(offsetx100+0.5); switch (intoffset) { case -200/*-2*/: direction = UDAT_DIRECTION_LAST_2; break; case -100/*-1*/: direction = UDAT_DIRECTION_LAST; break; case 0/* 0*/: direction = UDAT_DIRECTION_THIS; break; case 100/* 1*/: direction = UDAT_DIRECTION_NEXT; break; case 200/* 2*/: direction = UDAT_DIRECTION_NEXT_2; break; default: break; } } UDateAbsoluteUnit absunit = UDAT_ABSOLUTE_UNIT_COUNT; switch (unit) { case UDAT_REL_UNIT_YEAR: absunit = UDAT_ABSOLUTE_YEAR; break; case UDAT_REL_UNIT_QUARTER: absunit = UDAT_ABSOLUTE_QUARTER; break; case UDAT_REL_UNIT_MONTH: absunit = UDAT_ABSOLUTE_MONTH; break; case UDAT_REL_UNIT_WEEK: absunit = UDAT_ABSOLUTE_WEEK; break; case UDAT_REL_UNIT_DAY: absunit = UDAT_ABSOLUTE_DAY; break; case UDAT_REL_UNIT_SECOND: if (direction == UDAT_DIRECTION_THIS) { absunit = UDAT_ABSOLUTE_NOW; direction = UDAT_DIRECTION_PLAIN; } break; case UDAT_REL_UNIT_SUNDAY: absunit = UDAT_ABSOLUTE_SUNDAY; break; case UDAT_REL_UNIT_MONDAY: absunit = UDAT_ABSOLUTE_MONDAY; break; case UDAT_REL_UNIT_TUESDAY: absunit = UDAT_ABSOLUTE_TUESDAY; break; case UDAT_REL_UNIT_WEDNESDAY: absunit = UDAT_ABSOLUTE_WEDNESDAY; break; case UDAT_REL_UNIT_THURSDAY: absunit = UDAT_ABSOLUTE_THURSDAY; break; case UDAT_REL_UNIT_FRIDAY: absunit = UDAT_ABSOLUTE_FRIDAY; break; case UDAT_REL_UNIT_SATURDAY: absunit = UDAT_ABSOLUTE_SATURDAY; break; default: break; } if (direction != UDAT_DIRECTION_COUNT && absunit != UDAT_ABSOLUTE_UNIT_COUNT) { formatAbsoluteImpl(direction, absunit, output, status); if (output.getStringRef().length() != 0) { return; } } // otherwise fallback to formatNumeric formatNumericImpl(offset, unit, output, status); } UnicodeString& RelativeDateTimeFormatter::combineDateAndTime( const UnicodeString& relativeDateString, const UnicodeString& timeString, UnicodeString& appendTo, UErrorCode& status) const { return fCache->getCombinedDateAndTime()->format( timeString, relativeDateString, appendTo, status); } UnicodeString& RelativeDateTimeFormatter::adjustForContext(UnicodeString &str) const { if (fOptBreakIterator == nullptr || str.length() == 0 || !u_islower(str.char32At(0))) { return str; } // Must guarantee that one thread at a time accesses the shared break // iterator. static icu::UMutex gBrkIterMutex = U_MUTEX_INITIALIZER; Mutex lock(&gBrkIterMutex); str.toTitle( fOptBreakIterator->get(), fLocale, U_TITLECASE_NO_LOWERCASE | U_TITLECASE_NO_BREAK_ADJUSTMENT); return str; } UBool RelativeDateTimeFormatter::checkNoAdjustForContext(UErrorCode& status) const { // This is unsupported because it's hard to keep fields in sync with title // casing. The code could be written and tested if there is demand. if (fOptBreakIterator != nullptr) { status = U_UNSUPPORTED_ERROR; return FALSE; } return TRUE; } void RelativeDateTimeFormatter::init( NumberFormat *nfToAdopt, BreakIterator *biToAdopt, UErrorCode &status) { LocalPointer nf(nfToAdopt); LocalPointer bi(biToAdopt); UnifiedCache::getByLocale(fLocale, fCache, status); if (U_FAILURE(status)) { return; } const SharedPluralRules *pr = PluralRules::createSharedInstance( fLocale, UPLURAL_TYPE_CARDINAL, status); if (U_FAILURE(status)) { return; } SharedObject::copyPtr(pr, fPluralRules); pr->removeRef(); if (nf.isNull()) { const SharedNumberFormat *shared = NumberFormat::createSharedInstance( fLocale, UNUM_DECIMAL, status); if (U_FAILURE(status)) { return; } SharedObject::copyPtr(shared, fNumberFormat); shared->removeRef(); } else { SharedNumberFormat *shared = new SharedNumberFormat(nf.getAlias()); if (shared == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; return; } nf.orphan(); SharedObject::copyPtr(shared, fNumberFormat); } if (bi.isNull()) { SharedObject::clearPtr(fOptBreakIterator); } else { SharedBreakIterator *shared = new SharedBreakIterator(bi.getAlias()); if (shared == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; return; } bi.orphan(); SharedObject::copyPtr(shared, fOptBreakIterator); } } U_NAMESPACE_END // Plain C API U_NAMESPACE_USE // Magic number: "FRDT" (FormattedRelativeDateTime) in ASCII UPRV_FORMATTED_VALUE_CAPI_AUTO_IMPL( FormattedRelativeDateTime, UFormattedRelativeDateTime, UFormattedRelativeDateTimeImpl, UFormattedRelativeDateTimeApiHelper, ureldatefmt, 0x46524454) U_CAPI URelativeDateTimeFormatter* U_EXPORT2 ureldatefmt_open( const char* locale, UNumberFormat* nfToAdopt, UDateRelativeDateTimeFormatterStyle width, UDisplayContext capitalizationContext, UErrorCode* status ) { if (U_FAILURE(*status)) { return nullptr; } LocalPointer formatter(new RelativeDateTimeFormatter(Locale(locale), (NumberFormat*)nfToAdopt, width, capitalizationContext, *status), *status); if (U_FAILURE(*status)) { return nullptr; } return (URelativeDateTimeFormatter*)formatter.orphan(); } U_CAPI void U_EXPORT2 ureldatefmt_close(URelativeDateTimeFormatter *reldatefmt) { delete (RelativeDateTimeFormatter*)reldatefmt; } U_CAPI int32_t U_EXPORT2 ureldatefmt_formatNumeric( const URelativeDateTimeFormatter* reldatefmt, double offset, URelativeDateTimeUnit unit, UChar* result, int32_t resultCapacity, UErrorCode* status) { if (U_FAILURE(*status)) { return 0; } if (result == nullptr ? resultCapacity != 0 : resultCapacity < 0) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString res; if (result != nullptr) { // nullptr destination for pure preflighting: empty dummy string // otherwise, alias the destination buffer (copied from udat_format) res.setTo(result, 0, resultCapacity); } ((RelativeDateTimeFormatter*)reldatefmt)->formatNumeric(offset, unit, res, *status); if (U_FAILURE(*status)) { return 0; } return res.extract(result, resultCapacity, *status); } U_STABLE void U_EXPORT2 ureldatefmt_formatNumericToResult( const URelativeDateTimeFormatter* reldatefmt, double offset, URelativeDateTimeUnit unit, UFormattedRelativeDateTime* result, UErrorCode* status) { if (U_FAILURE(*status)) { return; } auto* fmt = reinterpret_cast(reldatefmt); auto* resultImpl = UFormattedRelativeDateTimeApiHelper::validate(result, *status); resultImpl->fImpl = fmt->formatNumericToValue(offset, unit, *status); } U_CAPI int32_t U_EXPORT2 ureldatefmt_format( const URelativeDateTimeFormatter* reldatefmt, double offset, URelativeDateTimeUnit unit, UChar* result, int32_t resultCapacity, UErrorCode* status) { if (U_FAILURE(*status)) { return 0; } if (result == nullptr ? resultCapacity != 0 : resultCapacity < 0) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString res; if (result != nullptr) { // nullptr destination for pure preflighting: empty dummy string // otherwise, alias the destination buffer (copied from udat_format) res.setTo(result, 0, resultCapacity); } ((RelativeDateTimeFormatter*)reldatefmt)->format(offset, unit, res, *status); if (U_FAILURE(*status)) { return 0; } return res.extract(result, resultCapacity, *status); } U_DRAFT void U_EXPORT2 ureldatefmt_formatToResult( const URelativeDateTimeFormatter* reldatefmt, double offset, URelativeDateTimeUnit unit, UFormattedRelativeDateTime* result, UErrorCode* status) { if (U_FAILURE(*status)) { return; } auto* fmt = reinterpret_cast(reldatefmt); auto* resultImpl = UFormattedRelativeDateTimeApiHelper::validate(result, *status); resultImpl->fImpl = fmt->formatToValue(offset, unit, *status); } U_CAPI int32_t U_EXPORT2 ureldatefmt_combineDateAndTime( const URelativeDateTimeFormatter* reldatefmt, const UChar * relativeDateString, int32_t relativeDateStringLen, const UChar * timeString, int32_t timeStringLen, UChar* result, int32_t resultCapacity, UErrorCode* status ) { if (U_FAILURE(*status)) { return 0; } if (result == nullptr ? resultCapacity != 0 : resultCapacity < 0 || (relativeDateString == nullptr ? relativeDateStringLen != 0 : relativeDateStringLen < -1) || (timeString == nullptr ? timeStringLen != 0 : timeStringLen < -1)) { *status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } UnicodeString relDateStr((UBool)(relativeDateStringLen == -1), relativeDateString, relativeDateStringLen); UnicodeString timeStr((UBool)(timeStringLen == -1), timeString, timeStringLen); UnicodeString res(result, 0, resultCapacity); ((RelativeDateTimeFormatter*)reldatefmt)->combineDateAndTime(relDateStr, timeStr, res, *status); if (U_FAILURE(*status)) { return 0; } return res.extract(result, resultCapacity, *status); } #endif /* !UCONFIG_NO_FORMATTING */