// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /* ********************************************************************** * Copyright (c) 2003-2013, International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************** * Author: Alan Liu * Created: July 21 2003 * Since: ICU 2.8 ********************************************************************** */ #ifndef OLSONTZ_H #define OLSONTZ_H #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include "unicode/basictz.h" #include "umutex.h" struct UResourceBundle; U_NAMESPACE_BEGIN class SimpleTimeZone; /** * A time zone based on the Olson tz database. Olson time zones change * behavior over time. The raw offset, rules, presence or absence of * daylight savings time, and even the daylight savings amount can all * vary. * * This class uses a resource bundle named "zoneinfo". Zoneinfo is a * table containing different kinds of resources. In several places, * zones are referred to using integers. A zone's integer is a number * from 0..n-1, where n is the number of zones, with the zones sorted * in lexicographic order. * * 1. Zones. These have keys corresponding to the Olson IDs, e.g., * "Asia/Shanghai". Each resource describes the behavior of the given * zone. Zones come in two different formats. * * a. Zone (table). A zone is a table resource contains several * type of resources below: * * - typeOffsets:intvector (Required) * * Sets of UTC raw/dst offset pairs in seconds. Entries at * 2n represents raw offset and 2n+1 represents dst offset * paired with the raw offset at 2n. The very first pair represents * the initial zone offset (before the first transition) always. * * - trans:intvector (Optional) * * List of transition times represented by 32bit seconds from the * epoch (1970-01-01T00:00Z) in ascending order. * * - transPre32/transPost32:intvector (Optional) * * List of transition times before/after 32bit minimum seconds. * Each time is represented by a pair of 32bit integer. * * - typeMap:bin (Optional) * * Array of bytes representing the mapping between each transition * time (transPre32/trans/transPost32) and its corresponding offset * data (typeOffsets). * * - finalRule:string (Optional) * * If a recurrent transition rule is applicable to a zone forever * after the final transition time, finalRule represents the rule * in Rules data. * * - finalRaw:int (Optional) * * When finalRule is available, finalRaw is required and specifies * the raw (base) offset of the rule. * * - finalYear:int (Optional) * * When finalRule is available, finalYear is required and specifies * the start year of the rule. * * - links:intvector (Optional) * * When this zone data is shared with other zones, links specifies * all zones including the zone itself. Each zone is referenced by * integer index. * * b. Link (int, length 1). A link zone is an int resource. The * integer is the zone number of the target zone. The key of this * resource is an alternate name for the target zone. This data * is corresponding to Link data in the tz database. * * * 2. Rules. These have keys corresponding to the Olson rule IDs, * with an underscore prepended, e.g., "_EU". Each resource describes * the behavior of the given rule using an intvector, containing the * onset list, the cessation list, and the DST savings. The onset and * cessation lists consist of the month, dowim, dow, time, and time * mode. The end result is that the 11 integers describing the rule * can be passed directly into the SimpleTimeZone 13-argument * constructor (the other two arguments will be the raw offset, taken * from the complex zone element 5, and the ID string, which is not * used), with the times and the DST savings multiplied by 1000 to * scale from seconds to milliseconds. * * 3. Regions. An array specifies mapping between zones and regions. * Each item is either a 2-letter ISO country code or "001" * (UN M.49 - World). This data is generated from "zone.tab" * in the tz database. */ class U_I18N_API OlsonTimeZone: public BasicTimeZone { public: /** * Construct from a resource bundle. * @param top the top-level zoneinfo resource bundle. This is used * to lookup the rule that `res' may refer to, if there is one. * @param res the resource bundle of the zone to be constructed * @param tzid the time zone ID * @param ec input-output error code */ OlsonTimeZone(const UResourceBundle* top, const UResourceBundle* res, const UnicodeString& tzid, UErrorCode& ec); /** * Copy constructor */ OlsonTimeZone(const OlsonTimeZone& other); /** * Destructor */ virtual ~OlsonTimeZone(); /** * Assignment operator */ OlsonTimeZone& operator=(const OlsonTimeZone& other); /** * Returns true if the two TimeZone objects are equal. */ virtual UBool operator==(const TimeZone& other) const; /** * TimeZone API. */ virtual OlsonTimeZone* clone() const; /** * TimeZone API. */ static UClassID U_EXPORT2 getStaticClassID(); /** * TimeZone API. */ virtual UClassID getDynamicClassID() const; /** * TimeZone API. Do not call this; prefer getOffset(UDate,...). */ virtual int32_t getOffset(uint8_t era, int32_t year, int32_t month, int32_t day, uint8_t dayOfWeek, int32_t millis, UErrorCode& ec) const; /** * TimeZone API. Do not call this; prefer getOffset(UDate,...). */ virtual int32_t getOffset(uint8_t era, int32_t year, int32_t month, int32_t day, uint8_t dayOfWeek, int32_t millis, int32_t monthLength, UErrorCode& ec) const; /** * TimeZone API. */ virtual void getOffset(UDate date, UBool local, int32_t& rawOffset, int32_t& dstOffset, UErrorCode& ec) const; /** * BasicTimeZone API. */ virtual void getOffsetFromLocal(UDate date, int32_t nonExistingTimeOpt, int32_t duplicatedTimeOpt, int32_t& rawoff, int32_t& dstoff, UErrorCode& ec) const; /** * TimeZone API. This method has no effect since objects of this * class are quasi-immutable (the base class allows the ID to be * changed). */ virtual void setRawOffset(int32_t offsetMillis); /** * TimeZone API. For a historical zone, the raw offset can change * over time, so this API is not useful. In order to approximate * expected behavior, this method returns the raw offset for the * current moment in time. */ virtual int32_t getRawOffset() const; /** * TimeZone API. For a historical zone, whether DST is used or * not varies over time. In order to approximate expected * behavior, this method returns TRUE if DST is observed at any * point in the current year. */ virtual UBool useDaylightTime() const; /** * TimeZone API. */ virtual UBool inDaylightTime(UDate date, UErrorCode& ec) const; /** * TimeZone API. */ virtual int32_t getDSTSavings() const; /** * TimeZone API. Also comare historic transitions. */ virtual UBool hasSameRules(const TimeZone& other) const; /** * BasicTimeZone API. * Gets the first time zone transition after the base time. * @param base The base time. * @param inclusive Whether the base time is inclusive or not. * @param result Receives the first transition after the base time. * @return TRUE if the transition is found. */ virtual UBool getNextTransition(UDate base, UBool inclusive, TimeZoneTransition& result) const; /** * BasicTimeZone API. * Gets the most recent time zone transition before the base time. * @param base The base time. * @param inclusive Whether the base time is inclusive or not. * @param result Receives the most recent transition before the base time. * @return TRUE if the transition is found. */ virtual UBool getPreviousTransition(UDate base, UBool inclusive, TimeZoneTransition& result) const; /** * BasicTimeZone API. * Returns the number of TimeZoneRules which represents time transitions, * for this time zone, that is, all TimeZoneRules for this time zone except * InitialTimeZoneRule. The return value range is 0 or any positive value. * @param status Receives error status code. * @return The number of TimeZoneRules representing time transitions. */ virtual int32_t countTransitionRules(UErrorCode& status) const; /** * Gets the InitialTimeZoneRule and the set of TimeZoneRule * which represent time transitions for this time zone. On successful return, * the argument initial points to non-NULL InitialTimeZoneRule and * the array trsrules is filled with 0 or multiple TimeZoneRule * instances up to the size specified by trscount. The results are referencing the * rule instance held by this time zone instance. Therefore, after this time zone * is destructed, they are no longer available. * @param initial Receives the initial timezone rule * @param trsrules Receives the timezone transition rules * @param trscount On input, specify the size of the array 'transitions' receiving * the timezone transition rules. On output, actual number of * rules filled in the array will be set. * @param status Receives error status code. */ virtual void getTimeZoneRules(const InitialTimeZoneRule*& initial, const TimeZoneRule* trsrules[], int32_t& trscount, UErrorCode& status) const; /** * Internal API returning the canonical ID of this zone. * This ID won't be affected by setID(). */ const UChar *getCanonicalID() const; private: /** * Default constructor. Creates a time zone with an empty ID and * a fixed GMT offset of zero. */ OlsonTimeZone(); private: void constructEmpty(); void getHistoricalOffset(UDate date, UBool local, int32_t NonExistingTimeOpt, int32_t DuplicatedTimeOpt, int32_t& rawoff, int32_t& dstoff) const; int16_t transitionCount() const; int64_t transitionTimeInSeconds(int16_t transIdx) const; double transitionTime(int16_t transIdx) const; /* * Following 3 methods return an offset at the given transition time index. * When the index is negative, return the initial offset. */ int32_t zoneOffsetAt(int16_t transIdx) const; int32_t rawOffsetAt(int16_t transIdx) const; int32_t dstOffsetAt(int16_t transIdx) const; /* * Following methods return the initial offset. */ int32_t initialRawOffset() const; int32_t initialDstOffset() const; /** * Number of transitions in each time range */ int16_t transitionCountPre32; int16_t transitionCount32; int16_t transitionCountPost32; /** * Time of each transition in seconds from 1970 epoch before 32bit second range (<= 1900). * Each transition in this range is represented by a pair of int32_t. * Length is transitionCount int32_t's. NULL if no transitions in this range. */ const int32_t *transitionTimesPre32; // alias into res; do not delete /** * Time of each transition in seconds from 1970 epoch in 32bit second range. * Length is transitionCount int32_t's. NULL if no transitions in this range. */ const int32_t *transitionTimes32; // alias into res; do not delete /** * Time of each transition in seconds from 1970 epoch after 32bit second range (>= 2038). * Each transition in this range is represented by a pair of int32_t. * Length is transitionCount int32_t's. NULL if no transitions in this range. */ const int32_t *transitionTimesPost32; // alias into res; do not delete /** * Number of types, 1..255 */ int16_t typeCount; /** * Offset from GMT in seconds for each type. * Length is typeCount int32_t's. At least one type (a pair of int32_t) * is required. */ const int32_t *typeOffsets; // alias into res; do not delete /** * Type description data, consisting of transitionCount uint8_t * type indices (from 0..typeCount-1). * Length is transitionCount int16_t's. NULL if no transitions. */ const uint8_t *typeMapData; // alias into res; do not delete /** * A SimpleTimeZone that governs the behavior for date >= finalMillis. */ SimpleTimeZone *finalZone; // owned, may be NULL /** * For date >= finalMillis, the finalZone will be used. */ double finalStartMillis; /** * For year >= finalYear, the finalZone will be used. */ int32_t finalStartYear; /* * Canonical (CLDR) ID of this zone */ const UChar *canonicalID; /* BasicTimeZone support */ void clearTransitionRules(void); void deleteTransitionRules(void); void checkTransitionRules(UErrorCode& status) const; public: // Internal, for access from plain C code void initTransitionRules(UErrorCode& status); private: InitialTimeZoneRule *initialRule; TimeZoneTransition *firstTZTransition; int16_t firstTZTransitionIdx; TimeZoneTransition *firstFinalTZTransition; TimeArrayTimeZoneRule **historicRules; int16_t historicRuleCount; SimpleTimeZone *finalZoneWithStartYear; // hack UInitOnce transitionRulesInitOnce = U_INITONCE_INITIALIZER; }; inline int16_t OlsonTimeZone::transitionCount() const { return transitionCountPre32 + transitionCount32 + transitionCountPost32; } inline double OlsonTimeZone::transitionTime(int16_t transIdx) const { return (double)transitionTimeInSeconds(transIdx) * U_MILLIS_PER_SECOND; } inline int32_t OlsonTimeZone::zoneOffsetAt(int16_t transIdx) const { int16_t typeIdx = (transIdx >= 0 ? typeMapData[transIdx] : 0) << 1; return typeOffsets[typeIdx] + typeOffsets[typeIdx + 1]; } inline int32_t OlsonTimeZone::rawOffsetAt(int16_t transIdx) const { int16_t typeIdx = (transIdx >= 0 ? typeMapData[transIdx] : 0) << 1; return typeOffsets[typeIdx]; } inline int32_t OlsonTimeZone::dstOffsetAt(int16_t transIdx) const { int16_t typeIdx = (transIdx >= 0 ? typeMapData[transIdx] : 0) << 1; return typeOffsets[typeIdx + 1]; } inline int32_t OlsonTimeZone::initialRawOffset() const { return typeOffsets[0]; } inline int32_t OlsonTimeZone::initialDstOffset() const { return typeOffsets[1]; } inline const UChar* OlsonTimeZone::getCanonicalID() const { return canonicalID; } U_NAMESPACE_END #endif // !UCONFIG_NO_FORMATTING #endif // OLSONTZ_H //eof