source/i18n/olsontz.h - external/github.com/unicode-org/icu - Git at Google

 /*
 **********************************************************************
 * Copyright (c) 2003, 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/timezone.h"

 struct UResourceBundle;

 U_NAMESPACE_BEGIN

 class SimpleTimeZone;

 /**
  * A time zone based on the Olson 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 several formats, which are differentiated
  * based on length.
  *
  *  a. Alias (int, length 1).  An alias 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.  Aliases
  *  represent Olson links and ICU compatibility IDs.
  *
  *  b. Simple zone (array, length 3).  The three subelements are:
  *
  *   i. An intvector of transitions.  These are given in epoch
  *   seconds.  This may be an empty invector (length 0).  If the
  *   transtions list is empty, then the zone's behavior is fixed and
  *   given by the offset list, which will contain exactly one pair.
  *   Otherwise each transtion indicates a time after which (inclusive)
  *   the associated offset pair is in effect.
  *
  *   ii. An intvector of offsets.  These are in pairs of raw offset /
  *   DST offset, in units of seconds.  There will be at least one pair
  *   (length >= 2 && length % 2 == 0).
  *
  *   iii. A binary resource.  This is of the same length as the
  *   transitions vector, so length may be zero.  Each unsigned byte
  *   corresponds to one transition, and has a value of 0..n-1, where n
  *   is the number of pairs in the offset vector.  This forms a map
  *   between transitions and offset pairs.
  *
  *  c. Simple zone with aliases (array, length 4).  This is like a
  *  simple zone, but also contains a fourth element:
  *
  *   iv. An intvector of aliases.  This list includes this zone
  *   itself, and lists all aliases of this zone.
  *
  *  d. Complex zone (array, length 5).  This is like a simple zone,
  *  but contains two more elements:
  *
  *   iv. A string, giving the name of a rule.  This is the "final
  *   rule", which governs the zone's behavior beginning in the "final
  *   year".  The rule ID is given without leading underscore, e.g.,
  *   "EU".
  *
  *   v. An intvector of length 2, containing the raw offset for the
  *   final rule (in seconds), and the final year.  The final rule
  *   takes effect for years >= the final year.
  *
  *  e. Complex zone with aliases (array, length 6).  This is like a
  *  complex zone, but also contains a sixth element:
  *
  *   vi. An intvector of aliases.  This list includes this zone
  *   itself, and lists all aliases of this zone.
  *
  * 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. Countries.  These have keys corresponding to the 2-letter ISO
  * country codes, with a percent sign prepended, e.g., "%US".  Each
  * resource is an intvector listing the zones associated with the
  * given country.  The special entry "%" corresponds to "no country",
  * that is, the category of zones assigned to no country in the Olson
  * DB.
  *
  * 4. Metadata.  Metadata is stored under the key "_".  It is an
  * intvector of length three containing the number of zones resources,
  * rule resources, and country resources.  For the purposes of this
  * count, the metadata entry itself is considered a rule resource,
  * since its key begins with an underscore.
  */
 class U_I18N_API OlsonTimeZone: public TimeZone {
  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 ec input-output error code
      */
     OlsonTimeZone(const UResourceBundle* top,
                   const UResourceBundle* res, 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 TimeZone* clone() const;

     /**
      * TimeZone API.
      */
     static UClassID 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;

     /**
      * 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;

  protected:
     /**
      * Default constructor.  Creates a time zone with an empty ID and
      * a fixed GMT offset of zero.
      */
     OlsonTimeZone();

  private:

     void constructEmpty();

     int16_t findTransition(double time, UBool local) const;

     int32_t zoneOffset(int16_t index) const;
     int32_t rawOffset(int16_t index) const;
     int32_t dstOffset(int16_t index) const;

     /**
      * Number of transitions, 0..~370
      */
     int16_t transitionCount;

     /**
      * Number of types, 1..255
      */
     int16_t typeCount;

     /**
      * Time of each transition in seconds from 1970 epoch.
      * Length is transitionCount int32_t's.
      */
     const int32_t *transitionTimes; // alias into res; do not delete

     /**
      * Offset from GMT in seconds for each type.
      * Length is typeCount int32_t's.
      */
     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 int8_t's.
      */
     const uint8_t *typeData; // alias into res; do not delete

     /**
      * The last year for which the transitions data are to be used
      * rather than the finalZone.  If there is no finalZone, then this
      * is set to INT32_MAX.  NOTE: This corresponds to the year _before_
      * the one indicated by finalMillis.
      */
     int32_t finalYear;

     /**
      * The millis for the start of the first year for which finalZone
      * is to be used, or DBL_MAX if finalZone is 0.  NOTE: This is
      * 0:00 GMT Jan 1, <finalYear + 1> (not <finalMillis>).
      */
     double finalMillis;

     /**
      * A SimpleTimeZone that governs the behavior for years > finalYear.
      * If and only if finalYear == INT32_MAX then finalZone == 0.
      */
     SimpleTimeZone *finalZone; // owned, may be NULL

 };

 inline int32_t
 OlsonTimeZone::zoneOffset(int16_t index) const {
     index <<= 1;
     return typeOffsets[index] + typeOffsets[index+1];
 }

 inline int32_t
 OlsonTimeZone::rawOffset(int16_t index) const {
     return typeOffsets[(uint32_t)(index << 1)];
 }

 inline int32_t
 OlsonTimeZone::dstOffset(int16_t index) const {
     return typeOffsets[(uint32_t)((index << 1) + 1)];
 }

 U_NAMESPACE_END

 #endif // !UCONFIG_NO_FORMATTING
 #endif // OLSONTZ_H

 //eof
	/*
	**********************************************************************
	* Copyright (c) 2003, 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/timezone.h"

	struct UResourceBundle;

	U_NAMESPACE_BEGIN

	class SimpleTimeZone;

	/**
	* A time zone based on the Olson 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 several formats, which are differentiated
	* based on length.
	*
	* a. Alias (int, length 1). An alias 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. Aliases
	* represent Olson links and ICU compatibility IDs.
	*
	* b. Simple zone (array, length 3). The three subelements are:
	*
	* i. An intvector of transitions. These are given in epoch
	* seconds. This may be an empty invector (length 0). If the
	* transtions list is empty, then the zone's behavior is fixed and
	* given by the offset list, which will contain exactly one pair.
	* Otherwise each transtion indicates a time after which (inclusive)
	* the associated offset pair is in effect.
	*
	* ii. An intvector of offsets. These are in pairs of raw offset /
	* DST offset, in units of seconds. There will be at least one pair
	* (length >= 2 && length % 2 == 0).
	*
	* iii. A binary resource. This is of the same length as the
	* transitions vector, so length may be zero. Each unsigned byte
	* corresponds to one transition, and has a value of 0..n-1, where n
	* is the number of pairs in the offset vector. This forms a map
	* between transitions and offset pairs.
	*
	* c. Simple zone with aliases (array, length 4). This is like a
	* simple zone, but also contains a fourth element:
	*
	* iv. An intvector of aliases. This list includes this zone
	* itself, and lists all aliases of this zone.
	*
	* d. Complex zone (array, length 5). This is like a simple zone,
	* but contains two more elements:
	*
	* iv. A string, giving the name of a rule. This is the "final
	* rule", which governs the zone's behavior beginning in the "final
	* year". The rule ID is given without leading underscore, e.g.,
	* "EU".
	*
	* v. An intvector of length 2, containing the raw offset for the
	* final rule (in seconds), and the final year. The final rule
	* takes effect for years >= the final year.
	*
	* e. Complex zone with aliases (array, length 6). This is like a
	* complex zone, but also contains a sixth element:
	*
	* vi. An intvector of aliases. This list includes this zone
	* itself, and lists all aliases of this zone.
	*
	* 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. Countries. These have keys corresponding to the 2-letter ISO
	* country codes, with a percent sign prepended, e.g., "%US". Each
	* resource is an intvector listing the zones associated with the
	* given country. The special entry "%" corresponds to "no country",
	* that is, the category of zones assigned to no country in the Olson
	* DB.
	*
	* 4. Metadata. Metadata is stored under the key "_". It is an
	* intvector of length three containing the number of zones resources,
	* rule resources, and country resources. For the purposes of this
	* count, the metadata entry itself is considered a rule resource,
	* since its key begins with an underscore.
	*/
	class U_I18N_API OlsonTimeZone: public TimeZone {
	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 ec input-output error code
	*/
	OlsonTimeZone(const UResourceBundle* top,
	const UResourceBundle* res, 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 TimeZone* clone() const;

	/**
	* TimeZone API.
	*/
	static UClassID 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;

	/**
	* 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;

	protected:
	/**
	* Default constructor. Creates a time zone with an empty ID and
	* a fixed GMT offset of zero.
	*/
	OlsonTimeZone();

	private:

	void constructEmpty();

	int16_t findTransition(double time, UBool local) const;

	int32_t zoneOffset(int16_t index) const;
	int32_t rawOffset(int16_t index) const;
	int32_t dstOffset(int16_t index) const;

	/**
	* Number of transitions, 0..~370
	*/
	int16_t transitionCount;

	/**
	* Number of types, 1..255
	*/
	int16_t typeCount;

	/**
	* Time of each transition in seconds from 1970 epoch.
	* Length is transitionCount int32_t's.
	*/
	const int32_t *transitionTimes; // alias into res; do not delete

	/**
	* Offset from GMT in seconds for each type.
	* Length is typeCount int32_t's.
	*/
	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 int8_t's.
	*/
	const uint8_t *typeData; // alias into res; do not delete

	/**
	* The last year for which the transitions data are to be used
	* rather than the finalZone. If there is no finalZone, then this
	* is set to INT32_MAX. NOTE: This corresponds to the year _before_
	* the one indicated by finalMillis.
	*/
	int32_t finalYear;

	/**
	* The millis for the start of the first year for which finalZone
	* is to be used, or DBL_MAX if finalZone is 0. NOTE: This is
	* 0:00 GMT Jan 1, <finalYear + 1> (not <finalMillis>).
	*/
	double finalMillis;

	/**
	* A SimpleTimeZone that governs the behavior for years > finalYear.
	* If and only if finalYear == INT32_MAX then finalZone == 0.
	*/
	SimpleTimeZone *finalZone; // owned, may be NULL

	};

	inline int32_t
	OlsonTimeZone::zoneOffset(int16_t index) const {
	index <<= 1;
	return typeOffsets[index] + typeOffsets[index+1];
	}

	inline int32_t
	OlsonTimeZone::rawOffset(int16_t index) const {
	return typeOffsets[(uint32_t)(index << 1)];
	}

	inline int32_t
	OlsonTimeZone::dstOffset(int16_t index) const {
	return typeOffsets[(uint32_t)((index << 1) + 1)];
	}

	U_NAMESPACE_END

	#endif // !UCONFIG_NO_FORMATTING
	#endif // OLSONTZ_H

	//eof