calendar.cpp source code [Skia/third_party/externals/icu/source/i18n/calendar.cpp]

1	// © 2016 and later: Unicode, Inc. and others.
2	// License & terms of use: http://www.unicode.org/copyright.html
3	/*
4	*******************************************************************************
5	* Copyright (C) 1997-2016, International Business Machines Corporation and *
6	* others. All Rights Reserved. *
7	*******************************************************************************
8	*
9	* File CALENDAR.CPP
10	*
11	* Modification History:
12	*
13	* Date Name Description
14	* 02/03/97 clhuang Creation.
15	* 04/22/97 aliu Cleaned up, fixed memory leak, made
16	* setWeekCountData() more robust.
17	* Moved platform code to TPlatformUtilities.
18	* 05/01/97 aliu Made equals(), before(), after() arguments const.
19	* 05/20/97 aliu Changed logic of when to compute fields and time
20	* to fix bugs.
21	* 08/12/97 aliu Added equivalentTo. Misc other fixes.
22	* 07/28/98 stephen Sync up with JDK 1.2
23	* 09/02/98 stephen Sync with JDK 1.2 8/31 build (getActualMin/Max)
24	* 03/17/99 stephen Changed adoptTimeZone() - now fAreFieldsSet is
25	* set to FALSE to force update of time.
26	*******************************************************************************
27	*/
28
29	#include "utypeinfo.h" // for 'typeid' to work
30
31	#include "unicode/utypes.h"
32
33	#if !UCONFIG_NO_FORMATTING
34
35	#include "unicode/gregocal.h"
36	#include "unicode/basictz.h"
37	#include "unicode/simpletz.h"
38	#include "unicode/rbtz.h"
39	#include "unicode/vtzone.h"
40	#include "gregoimp.h"
41	#include "buddhcal.h"
42	#include "taiwncal.h"
43	#include "japancal.h"
44	#include "islamcal.h"
45	#include "hebrwcal.h"
46	#include "persncal.h"
47	#include "indiancal.h"
48	#include "chnsecal.h"
49	#include "coptccal.h"
50	#include "dangical.h"
51	#include "ethpccal.h"
52	#include "unicode/calendar.h"
53	#include "cpputils.h"
54	#include "servloc.h"
55	#include "ucln_in.h"
56	#include "cstring.h"
57	#include "locbased.h"
58	#include "uresimp.h"
59	#include "ustrenum.h"
60	#include "uassert.h"
61	#include "olsontz.h"
62	#include "sharedcalendar.h"
63	#include "unifiedcache.h"
64	#include "ulocimp.h"
65
66	#if !UCONFIG_NO_SERVICE
67	static icu::ICULocaleService* gService = NULL;
68	static icu::UInitOnce gServiceInitOnce = U_INITONCE_INITIALIZER;
69
70	// INTERNAL - for cleanup
71	U_CDECL_BEGIN
72	static UBool calendar_cleanup(void) {
73	#if !UCONFIG_NO_SERVICE
74	if (gService) {
75	delete gService;
76	gService = NULL;
77	}
78	gServiceInitOnce.reset();
79	#endif
80	return TRUE;
81	}
82	U_CDECL_END
83	#endif
84
85	// ------------------------------------------
86	//
87	// Registration
88	//
89	//-------------------------------------------
90	//#define U_DEBUG_CALSVC 1
91	//
92
93	#if defined( U_DEBUG_CALSVC ) \|\| defined (U_DEBUG_CAL)
94
95	/**
96	* fldName was removed as a duplicate implementation.
97	* use udbg_ services instead,
98	* which depend on include files and library from ../tools/toolutil, the following circular link:
99	* CPPFLAGS+=-I$(top_srcdir)/tools/toolutil
100	* LIBS+=$(LIBICUTOOLUTIL)
101	*/
102	#include "udbgutil.h"
103	#include <stdio.h>
104
105	/**
106	* convert a UCalendarDateFields into a string - for debugging
107	* @param f field enum
108	* @return static string to the field name
109	* @internal
110	*/
111
112	const char* fldName(UCalendarDateFields f) {
113	return udbg_enumName(UDBG_UCalendarDateFields, (int32_t)f);
114	}
115
116	#if UCAL_DEBUG_DUMP
117	// from CalendarTest::calToStr - but doesn't modify contents.
118	void ucal_dump(const Calendar &cal) {
119	cal.dump();
120	}
121
122	void Calendar::dump() const {
123	int i;
124	fprintf(stderr, "@calendar=%s, timeset=%c, fieldset=%c, allfields=%c, virtualset=%c, t=%.2f",
125	getType(), fIsTimeSet?`'y'`:`'n'`, fAreFieldsSet?`'y'`:`'n'`, fAreAllFieldsSet?`'y'`:`'n'`,
126	fAreFieldsVirtuallySet?`'y'`:`'n'`,
127	fTime);
128
129	// can add more things here: DST, zone, etc.
130	fprintf(stderr, "\n");
131	for(i = `0`;i<UCAL_FIELD_COUNT;i++) {
132	int n;
133	const char *f = fldName((UCalendarDateFields)i);
134	fprintf(stderr, " %25s: %-11ld", f, fFields[i]);
135	if(fStamp[i] == kUnset) {
136	fprintf(stderr, " (unset) ");
137	} else if(fStamp[i] == kInternallySet) {
138	fprintf(stderr, " (internally set) ");
139	//} else if(fStamp[i] == kInternalDefault) {
140	// fprintf(stderr, " (internal default) ");
141	} else {
142	fprintf(stderr, " %%%d ", fStamp[i]);
143	}
144	fprintf(stderr, "\n");
145
146	}
147	}
148
149	U_CFUNC void ucal_dump(UCalendar* cal) {
150	ucal_dump( ((Calendar)cal) );
151	}
152	#endif
153
154	#endif
155
156	/ Max value for stamp allowable before recalculation /
157	#define STAMP_MAX 10000
158
159	static const char * const gCalTypes[] = {
160	"gregorian",
161	"japanese",
162	"buddhist",
163	"roc",
164	"persian",
165	"islamic-civil",
166	"islamic",
167	"hebrew",
168	"chinese",
169	"indian",
170	"coptic",
171	"ethiopic",
172	"ethiopic-amete-alem",
173	"iso8601",
174	"dangi",
175	"islamic-umalqura",
176	"islamic-tbla",
177	"islamic-rgsa",
178	NULL
179	};
180
181	// Must be in the order of gCalTypes above
182	typedef enum ECalType {
183	CALTYPE_UNKNOWN = -`1`,
184	CALTYPE_GREGORIAN = `0`,
185	CALTYPE_JAPANESE,
186	CALTYPE_BUDDHIST,
187	CALTYPE_ROC,
188	CALTYPE_PERSIAN,
189	CALTYPE_ISLAMIC_CIVIL,
190	CALTYPE_ISLAMIC,
191	CALTYPE_HEBREW,
192	CALTYPE_CHINESE,
193	CALTYPE_INDIAN,
194	CALTYPE_COPTIC,
195	CALTYPE_ETHIOPIC,
196	CALTYPE_ETHIOPIC_AMETE_ALEM,
197	CALTYPE_ISO8601,
198	CALTYPE_DANGI,
199	CALTYPE_ISLAMIC_UMALQURA,
200	CALTYPE_ISLAMIC_TBLA,
201	CALTYPE_ISLAMIC_RGSA
202	} ECalType;
203
204	U_NAMESPACE_BEGIN
205
206	SharedCalendar::~SharedCalendar() {
207	delete ptr;
208	}
209
210	template<> U_I18N_API
211	const SharedCalendar *LocaleCacheKey<SharedCalendar>::createObject(
212	const void * /unusedCreationContext/, UErrorCode &status) const {
213	Calendar *calendar = Calendar::makeInstance(fLoc, status);
214	if (U_FAILURE(status)) {
215	return NULL;
216	}
217	SharedCalendar shared = new* SharedCalendar (calendar);
218	if (shared == NULL) {
219	delete calendar;
220	status = U_MEMORY_ALLOCATION_ERROR;
221	return NULL;
222	}
223	shared->addRef();
224	return shared;
225	}
226
227	static ECalType getCalendarType(const char *s) {
228	for (int i = `0`; gCalTypes[i] != NULL; i++) {
229	if (uprv_stricmp(s, gCalTypes[i]) == `0`) {
230	return (ECalType)i;
231	}
232	}
233	return CALTYPE_UNKNOWN;
234	}
235
236	#if !UCONFIG_NO_SERVICE
237	// Only used with service registration.
238	static UBool isStandardSupportedKeyword(const char *keyword, UErrorCode& status) {
239	if(U_FAILURE(status)) {
240	return FALSE;
241	}
242	ECalType calType = getCalendarType(keyword);
243	return (calType != CALTYPE_UNKNOWN);
244	}
245
246	// only used with service registration.
247	static void getCalendarKeyword(const UnicodeString &id, char *targetBuffer, int32_t targetBufferSize) {
248	UnicodeString calendarKeyword = UNICODE_STRING_SIMPLE("calendar=");
249	int32_t calKeyLen = calendarKeyword.length();
250	int32_t keyLen = `0`;
251
252	int32_t keywordIdx = id.indexOf((UChar)`0x003D`); / '=' /
253	if (id [`0`] == `0x40`/'@'/
254	&& id.compareBetween(`1`, keywordIdx+`1`, calendarKeyword, `0`, calKeyLen) == `0`)
255	{
256	keyLen = id.extract(keywordIdx+`1`, id.length(), targetBuffer, targetBufferSize, US_INV);
257	}
258	targetBuffer[keyLen] = `0`;
259	}
260	#endif
261
262	static ECalType getCalendarTypeForLocale(const char *locid) {
263	UErrorCode status = U_ZERO_ERROR;
264	ECalType calType = CALTYPE_UNKNOWN;
265
266	//TODO: ULOC_FULL_NAME is out of date and too small..
267	char canonicalName[`256`];
268
269	// canonicalize, so grandfathered variant will be transformed to keywords
270	// e.g ja_JP_TRADITIONAL -> ja_JP@calendar=japanese
271	// NOTE: Since ICU-20187, ja_JP_TRADITIONAL no longer canonicalizes, and
272	// the Gregorian calendar is returned instead.
273	int32_t canonicalLen = uloc_canonicalize(locid, canonicalName, sizeof(canonicalName) - `1`, &status);
274	if (U_FAILURE(status)) {
275	return CALTYPE_GREGORIAN;
276	}
277	canonicalName[canonicalLen] = `0`; // terminate
278
279	char calTypeBuf[`32`];
280	int32_t calTypeBufLen;
281
282	calTypeBufLen = uloc_getKeywordValue(canonicalName, "calendar", calTypeBuf, sizeof(calTypeBuf) - `1`, &status);
283	if (U_SUCCESS(status)) {
284	calTypeBuf[calTypeBufLen] = `0`;
285	calType = getCalendarType(calTypeBuf);
286	if (calType != CALTYPE_UNKNOWN) {
287	return calType;
288	}
289	}
290	status = U_ZERO_ERROR;
291
292	// when calendar keyword is not available or not supported, read supplementalData
293	// to get the default calendar type for the locale's region
294	char region[ULOC_COUNTRY_CAPACITY];
295	(void)ulocimp_getRegionForSupplementalData(canonicalName, TRUE, region, sizeof(region), &status);
296	if (U_FAILURE(status)) {
297	return CALTYPE_GREGORIAN;
298	}
299
300	// Read preferred calendar values from supplementalData calendarPreference
301	UResourceBundle *rb = ures_openDirect(NULL, "supplementalData", &status);
302	ures_getByKey(rb, "calendarPreferenceData", rb, &status);
303	UResourceBundle *order = ures_getByKey(rb, region, NULL, &status);
304	if (status == U_MISSING_RESOURCE_ERROR && rb != NULL) {
305	status = U_ZERO_ERROR;
306	order = ures_getByKey(rb, "001", NULL, &status);
307	}
308
309	calTypeBuf[`0`] = `0`;
310	if (U_SUCCESS(status) && order != NULL) {
311	// the first calender type is the default for the region
312	int32_t len = `0`;
313	const UChar *uCalType = ures_getStringByIndex(order, `0`, &len, &status);
314	if (len < (int32_t)sizeof(calTypeBuf)) {
315	u_UCharsToChars(uCalType, calTypeBuf, len);
316	(calTypeBuf + len) = `0`; // terminate;*
317	calType = getCalendarType(calTypeBuf);
318	}
319	}
320
321	ures_close(order);
322	ures_close(rb);
323
324	if (calType == CALTYPE_UNKNOWN) {
325	// final fallback
326	calType = CALTYPE_GREGORIAN;
327	}
328	return calType;
329	}
330
331	static Calendar createStandardCalendar(ECalType calType, const* Locale &loc, UErrorCode& status) {
332	if (U_FAILURE(status)) {
333	return nullptr;
334	}
335	LocalPointer<Calendar> cal;
336
337	switch (calType) {
338	case CALTYPE_GREGORIAN:
339	cal.adoptInsteadAndCheckErrorCode(new GregorianCalendar (loc, status), status);
340	break;
341	case CALTYPE_JAPANESE:
342	cal.adoptInsteadAndCheckErrorCode(new JapaneseCalendar (loc, status), status);
343	break;
344	case CALTYPE_BUDDHIST:
345	cal.adoptInsteadAndCheckErrorCode(new BuddhistCalendar (loc, status), status);
346	break;
347	case CALTYPE_ROC:
348	cal.adoptInsteadAndCheckErrorCode(new TaiwanCalendar (loc, status), status);
349	break;
350	case CALTYPE_PERSIAN:
351	cal.adoptInsteadAndCheckErrorCode(new PersianCalendar (loc, status), status);
352	break;
353	case CALTYPE_ISLAMIC_TBLA:
354	cal.adoptInsteadAndCheckErrorCode(new IslamicCalendar (loc, status, IslamicCalendar::TBLA), status);
355	break;
356	case CALTYPE_ISLAMIC_CIVIL:
357	cal.adoptInsteadAndCheckErrorCode(new IslamicCalendar (loc, status, IslamicCalendar::CIVIL), status);
358	break;
359	case CALTYPE_ISLAMIC_RGSA:
360	// default any region specific not handled individually to islamic
361	case CALTYPE_ISLAMIC:
362	cal.adoptInsteadAndCheckErrorCode(new IslamicCalendar (loc, status, IslamicCalendar::ASTRONOMICAL), status);
363	break;
364	case CALTYPE_ISLAMIC_UMALQURA:
365	cal.adoptInsteadAndCheckErrorCode(new IslamicCalendar (loc, status, IslamicCalendar::UMALQURA), status);
366	break;
367	case CALTYPE_HEBREW:
368	cal.adoptInsteadAndCheckErrorCode(new HebrewCalendar (loc, status), status);
369	break;
370	case CALTYPE_CHINESE:
371	cal.adoptInsteadAndCheckErrorCode(new ChineseCalendar (loc, status), status);
372	break;
373	case CALTYPE_INDIAN:
374	cal.adoptInsteadAndCheckErrorCode(new IndianCalendar (loc, status), status);
375	break;
376	case CALTYPE_COPTIC:
377	cal.adoptInsteadAndCheckErrorCode(new CopticCalendar (loc, status), status);
378	break;
379	case CALTYPE_ETHIOPIC:
380	cal.adoptInsteadAndCheckErrorCode(new EthiopicCalendar (loc, status, EthiopicCalendar::AMETE_MIHRET_ERA), status);
381	break;
382	case CALTYPE_ETHIOPIC_AMETE_ALEM:
383	cal.adoptInsteadAndCheckErrorCode(new EthiopicCalendar (loc, status, EthiopicCalendar::AMETE_ALEM_ERA), status);
384	break;
385	case CALTYPE_ISO8601:
386	cal.adoptInsteadAndCheckErrorCode(new GregorianCalendar (loc, status), status);
387	if (cal.isValid()) {
388	cal ->setFirstDayOfWeek(UCAL_MONDAY);
389	cal ->setMinimalDaysInFirstWeek(`4`);
390	}
391	break;
392	case CALTYPE_DANGI:
393	cal.adoptInsteadAndCheckErrorCode(new DangiCalendar (loc, status), status);
394	break;
395	default:
396	status = U_UNSUPPORTED_ERROR;
397	}
398	return cal.orphan();
399	}
400
401
402	#if !UCONFIG_NO_SERVICE
403
404	// -------------------------------------
405
406	/**
407	* a Calendar Factory which creates the "basic" calendar types, that is, those
408	* shipped with ICU.
409	*/
410	class BasicCalendarFactory : public LocaleKeyFactory {
411	public:
412	/**
413	* @param calendarType static const string (caller owns storage - will be aliased) to calendar type
414	*/
415	BasicCalendarFactory()
416	: LocaleKeyFactory (LocaleKeyFactory::INVISIBLE) { }
417
418	virtual ~BasicCalendarFactory();
419
420	protected:
421	//virtual UBool isSupportedID( const UnicodeString& id, UErrorCode& status) const {
422	// if(U_FAILURE(status)) {
423	// return FALSE;
424	// }
425	// char keyword[ULOC_FULLNAME_CAPACITY];
426	// getCalendarKeyword(id, keyword, (int32_t)sizeof(keyword));
427	// return isStandardSupportedKeyword(keyword, status);
428	//}
429
430	virtual void updateVisibleIDs(Hashtable& result, UErrorCode& status) const
431	{
432	if (U_SUCCESS(status)) {
433	for(int32_t i=`0`;gCalTypes[i] != NULL;i++) {
434	UnicodeString id((UChar)`0x40`); / '@' a variant character /
435	id.append(UNICODE_STRING_SIMPLE("calendar="));
436	id.append(UnicodeString (gCalTypes[i], -`1`, US_INV));
437	result.put(id, (void)this*, status);
438	}
439	}
440	}
441
442	virtual UObject* create(const ICUServiceKey& key, const ICUService* /service/, UErrorCode& status) const {
443	#ifdef U_DEBUG_CALSVC
444	if(dynamic_cast<const LocaleKey*>(&key) == NULL) {
445	fprintf(stderr, "::create - not a LocaleKey!\n");
446	}
447	#endif
448	const LocaleKey& lkey = (LocaleKey&)key;
449	Locale curLoc; // current locale
450	Locale canLoc; // Canonical locale
451
452	lkey.currentLocale(curLoc);
453	lkey.canonicalLocale(canLoc);
454
455	char keyword[ULOC_FULLNAME_CAPACITY];
456	UnicodeString str;
457
458	key.currentID(str);
459	getCalendarKeyword(str, keyword, (int32_t) sizeof(keyword));
460
461	#ifdef U_DEBUG_CALSVC
462	fprintf(stderr, "BasicCalendarFactory::create() - cur %s, can %s\n", (const char)curLoc.getName(), (const* char*)canLoc.getName());
463	#endif
464
465	if(!isStandardSupportedKeyword(keyword,status)) { // Do we handle this type?
466	#ifdef U_DEBUG_CALSVC
467
468	fprintf(stderr, "BasicCalendarFactory - not handling %s.[%s]\n", (const char*) curLoc.getName(), tmp );
469	#endif
470	return NULL;
471	}
472
473	return createStandardCalendar(getCalendarType(keyword), canLoc, status);
474	}
475	};
476
477	BasicCalendarFactory::~BasicCalendarFactory() {}
478
479	/**
480	* A factory which looks up the DefaultCalendar resource to determine which class of calendar to use
481	*/
482
483	class DefaultCalendarFactory : public ICUResourceBundleFactory {
484	public:
485	DefaultCalendarFactory() : ICUResourceBundleFactory () { }
486	virtual ~DefaultCalendarFactory();
487	protected:
488	virtual UObject* create(const ICUServiceKey& key, const ICUService* /service/, UErrorCode& status) const {
489
490	LocaleKey &lkey = (LocaleKey&)key;
491	Locale loc;
492	lkey.currentLocale(loc);
493
494	UnicodeString ret = new* UnicodeString ();
495	if (ret == NULL) {
496	status = U_MEMORY_ALLOCATION_ERROR;
497	} else {
498	ret->append((UChar)`0x40`); // '@' is a variant character
499	ret->append(UNICODE_STRING("calendar=", `9`));
500	ret->append(UnicodeString (gCalTypes[getCalendarTypeForLocale(loc.getName())], -`1`, US_INV));
501	}
502	return ret;
503	}
504	};
505
506	DefaultCalendarFactory::~DefaultCalendarFactory() {}
507
508	// -------------------------------------
509	class CalendarService : public ICULocaleService {
510	public:
511	CalendarService()
512	: ICULocaleService (UNICODE_STRING_SIMPLE("Calendar"))
513	{
514	UErrorCode status = U_ZERO_ERROR;
515	registerFactory(new DefaultCalendarFactory (), status);
516	}
517
518	virtual ~CalendarService();
519
520	virtual UObject* cloneInstance(UObject* instance) const {
521	UnicodeString s = dynamic_cast<UnicodeString >(instance);
522	if(s != NULL) {
523	return s->clone();
524	} else {
525	#ifdef U_DEBUG_CALSVC_F
526	UErrorCode status2 = U_ZERO_ERROR;
527	fprintf(stderr, "Cloning a %s calendar with tz=%ld\n", ((Calendar)instance)->getType(), ((Calendar)instance)->get(UCAL_ZONE_OFFSET, status2));
528	#endif
529	return ((Calendar*)instance)->clone();
530	}
531	}
532
533	virtual UObject* handleDefault(const ICUServiceKey& key, UnicodeString* /actualID/, UErrorCode& status) const {
534	LocaleKey& lkey = (LocaleKey&)key;
535	//int32_t kind = lkey.kind();
536
537	Locale loc;
538	lkey.canonicalLocale(loc);
539
540	#ifdef U_DEBUG_CALSVC
541	Locale loc2;
542	lkey.currentLocale(loc2);
543	fprintf(stderr, "CalSvc:handleDefault for currentLoc %s, canloc %s\n", (const char)loc.getName(), (const* char*)loc2.getName());
544	#endif
545	Calendar nc = new* GregorianCalendar (loc, status);
546	if (nc == nullptr) {
547	status = U_MEMORY_ALLOCATION_ERROR;
548	return nc;
549	}
550
551	#ifdef U_DEBUG_CALSVC
552	UErrorCode status2 = U_ZERO_ERROR;
553	fprintf(stderr, "New default calendar has tz=%d\n", ((Calendar*)nc)->get(UCAL_ZONE_OFFSET, status2));
554	#endif
555	return nc;
556	}
557
558	virtual UBool isDefault() const {
559	return countFactories() == `1`;
560	}
561	};
562
563	CalendarService::~CalendarService() {}
564
565	// -------------------------------------
566
567	static inline UBool
568	isCalendarServiceUsed() {
569	return !gServiceInitOnce.isReset();
570	}
571
572	// -------------------------------------
573
574	static void U_CALLCONV
575	initCalendarService(UErrorCode &status)
576	{
577	#ifdef U_DEBUG_CALSVC
578	fprintf(stderr, "Spinning up Calendar Service\n");
579	#endif
580	ucln_i18n_registerCleanup(UCLN_I18N_CALENDAR, calendar_cleanup);
581	gService = new CalendarService ();
582	if (gService == NULL) {
583	status = U_MEMORY_ALLOCATION_ERROR;
584	return;
585	}
586	#ifdef U_DEBUG_CALSVC
587	fprintf(stderr, "Registering classes..\n");
588	#endif
589
590	// Register all basic instances.
591	gService->registerFactory(new BasicCalendarFactory (),status);
592
593	#ifdef U_DEBUG_CALSVC
594	fprintf(stderr, "Done..\n");
595	#endif
596
597	if(U_FAILURE(status)) {
598	#ifdef U_DEBUG_CALSVC
599	fprintf(stderr, "err (%s) registering classes, deleting service.....\n", u_errorName(status));
600	#endif
601	delete gService;
602	gService = NULL;
603	}
604	}
605
606	static ICULocaleService*
607	getCalendarService(UErrorCode &status)
608	{
609	umtx_initOnce(gServiceInitOnce, &initCalendarService, status);
610	return gService;
611	}
612
613	URegistryKey Calendar::registerFactory(ICUServiceFactory* toAdopt, UErrorCode& status)
614	{
615	return getCalendarService(status)->registerFactory(toAdopt, status);
616	}
617
618	UBool Calendar::unregister(URegistryKey key, UErrorCode& status) {
619	return getCalendarService(status)->unregister(key, status);
620	}
621	#endif /* UCONFIG_NO_SERVICE */
622
623	// -------------------------------------
624
625	static const int32_t kCalendarLimits[UCAL_FIELD_COUNT][`4`] = {
626	// Minimum Greatest min Least max Greatest max
627	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // ERA
628	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // YEAR
629	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // MONTH
630	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // WEEK_OF_YEAR
631	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // WEEK_OF_MONTH
632	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // DAY_OF_MONTH
633	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // DAY_OF_YEAR
634	{ `1`, `1`, `7`, `7` }, // DAY_OF_WEEK
635	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // DAY_OF_WEEK_IN_MONTH
636	{ `0`, `0`, `1`, `1` }, // AM_PM
637	{ `0`, `0`, `11`, `11` }, // HOUR
638	{ `0`, `0`, `23`, `23` }, // HOUR_OF_DAY
639	{ `0`, `0`, `59`, `59` }, // MINUTE
640	{ `0`, `0`, `59`, `59` }, // SECOND
641	{ `0`, `0`, `999`, `999` }, // MILLISECOND
642	{-`12`kOneHour, -`12`kOneHour, `12`kOneHour, `15`kOneHour }, // ZONE_OFFSET
643	{ `0`, `0`, `1`kOneHour, `1`kOneHour }, // DST_OFFSET
644	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // YEAR_WOY
645	{ `1`, `1`, `7`, `7` }, // DOW_LOCAL
646	{/N/A/-`1`, /N/A/-`1`, /N/A/-`1`, /N/A/-`1`}, // EXTENDED_YEAR
647	{ -`0x7F000000`, -`0x7F000000`, `0x7F000000`, `0x7F000000` }, // JULIAN_DAY
648	{ `0`, `0`, `24`kOneHour-`1`, `24`kOneHour-`1` }, // MILLISECONDS_IN_DAY
649	{ `0`, `0`, `1`, `1` }, // IS_LEAP_MONTH
650	};
651
652	// Resource bundle tags read by this class
653	static const char gCalendar[] = "calendar";
654	static const char gMonthNames[] = "monthNames";
655	static const char gGregorian[] = "gregorian";
656
657	// Data flow in Calendar
658	// ---------------------
659
660	// The current time is represented in two ways by Calendar: as UTC
661	// milliseconds from the epoch start (1 January 1970 0:00 UTC), and as local
662	// fields such as MONTH, HOUR, AM_PM, etc. It is possible to compute the
663	// millis from the fields, and vice versa. The data needed to do this
664	// conversion is encapsulated by a TimeZone object owned by the Calendar.
665	// The data provided by the TimeZone object may also be overridden if the
666	// user sets the ZONE_OFFSET and/or DST_OFFSET fields directly. The class
667	// keeps track of what information was most recently set by the caller, and
668	// uses that to compute any other information as needed.
669
670	// If the user sets the fields using set(), the data flow is as follows.
671	// This is implemented by the Calendar subclass's computeTime() method.
672	// During this process, certain fields may be ignored. The disambiguation
673	// algorithm for resolving which fields to pay attention to is described
674	// above.
675
676	// local fields (YEAR, MONTH, DATE, HOUR, MINUTE, etc.)
677	// \|
678	// \| Using Calendar-specific algorithm
679	// V
680	// local standard millis
681	// \|
682	// \| Using TimeZone or user-set ZONE_OFFSET / DST_OFFSET
683	// V
684	// UTC millis (in time data member)
685
686	// If the user sets the UTC millis using setTime(), the data flow is as
687	// follows. This is implemented by the Calendar subclass's computeFields()
688	// method.
689
690	// UTC millis (in time data member)
691	// \|
692	// \| Using TimeZone getOffset()
693	// V
694	// local standard millis
695	// \|
696	// \| Using Calendar-specific algorithm
697	// V
698	// local fields (YEAR, MONTH, DATE, HOUR, MINUTE, etc.)
699
700	// In general, a round trip from fields, through local and UTC millis, and
701	// back out to fields is made when necessary. This is implemented by the
702	// complete() method. Resolving a partial set of fields into a UTC millis
703	// value allows all remaining fields to be generated from that value. If
704	// the Calendar is lenient, the fields are also renormalized to standard
705	// ranges when they are regenerated.
706
707	// -------------------------------------
708
709	Calendar::Calendar(UErrorCode& success)
710	: UObject (),
711	fIsTimeSet(FALSE),
712	fAreFieldsSet(FALSE),
713	fAreAllFieldsSet(FALSE),
714	fAreFieldsVirtuallySet(FALSE),
715	fNextStamp((int32_t)kMinimumUserStamp),
716	fTime(`0`),
717	fLenient(TRUE),
718	fZone(NULL),
719	fRepeatedWallTime(UCAL_WALLTIME_LAST),
720	fSkippedWallTime(UCAL_WALLTIME_LAST)
721	{
722	validLocale[`0`] = `0`;
723	actualLocale[`0`] = `0`;
724	clear();
725	if (U_FAILURE(success)) {
726	return;
727	}
728	fZone = TimeZone::createDefault();
729	if (fZone == NULL) {
730	success = U_MEMORY_ALLOCATION_ERROR;
731	}
732	setWeekData(Locale::getDefault(), NULL, success);
733	}
734
735	// -------------------------------------
736
737	Calendar::Calendar(TimeZone* zone, const Locale& aLocale, UErrorCode& success)
738	: UObject (),
739	fIsTimeSet(FALSE),
740	fAreFieldsSet(FALSE),
741	fAreAllFieldsSet(FALSE),
742	fAreFieldsVirtuallySet(FALSE),
743	fNextStamp((int32_t)kMinimumUserStamp),
744	fTime(`0`),
745	fLenient(TRUE),
746	fZone(NULL),
747	fRepeatedWallTime(UCAL_WALLTIME_LAST),
748	fSkippedWallTime(UCAL_WALLTIME_LAST)
749	{
750	validLocale[`0`] = `0`;
751	actualLocale[`0`] = `0`;
752	if (U_FAILURE(success)) {
753	delete zone;
754	return;
755	}
756	if(zone == `0`) {
757	#if defined (U_DEBUG_CAL)
758	fprintf(stderr, "%s:%d: ILLEGAL ARG because timezone cannot be 0\n",
759	__FILE__, __LINE__);
760	#endif
761	success = U_ILLEGAL_ARGUMENT_ERROR;
762	return;
763	}
764
765	clear();
766	fZone = zone;
767	setWeekData(aLocale, NULL, success);
768	}
769
770	// -------------------------------------
771
772	Calendar::Calendar(const TimeZone& zone, const Locale& aLocale, UErrorCode& success)
773	: UObject (),
774	fIsTimeSet(FALSE),
775	fAreFieldsSet(FALSE),
776	fAreAllFieldsSet(FALSE),
777	fAreFieldsVirtuallySet(FALSE),
778	fNextStamp((int32_t)kMinimumUserStamp),
779	fTime(`0`),
780	fLenient(TRUE),
781	fZone(NULL),
782	fRepeatedWallTime(UCAL_WALLTIME_LAST),
783	fSkippedWallTime(UCAL_WALLTIME_LAST)
784	{
785	validLocale[`0`] = `0`;
786	actualLocale[`0`] = `0`;
787	if (U_FAILURE(success)) {
788	return;
789	}
790	clear();
791	fZone = zone.clone();
792	if (fZone == NULL) {
793	success = U_MEMORY_ALLOCATION_ERROR;
794	}
795	setWeekData(aLocale, NULL, success);
796	}
797
798	// -------------------------------------
799
800	Calendar::~Calendar()
801	{
802	delete fZone;
803	}
804
805	// -------------------------------------
806
807	Calendar::Calendar(const Calendar &source)
808	: UObject (source)
809	{
810	fZone = NULL;
811	*this = source;
812	}
813
814	// -------------------------------------
815
816	Calendar &
817	Calendar::operator=(const Calendar &right)
818	{
819	if (this != &right) {
820	uprv_arrayCopy(right.fFields, fFields, UCAL_FIELD_COUNT);
821	uprv_arrayCopy(right.fIsSet, fIsSet, UCAL_FIELD_COUNT);
822	uprv_arrayCopy(right.fStamp, fStamp, UCAL_FIELD_COUNT);
823	fTime = right.fTime;
824	fIsTimeSet = right.fIsTimeSet;
825	fAreAllFieldsSet = right.fAreAllFieldsSet;
826	fAreFieldsSet = right.fAreFieldsSet;
827	fAreFieldsVirtuallySet = right.fAreFieldsVirtuallySet;
828	fLenient = right.fLenient;
829	fRepeatedWallTime = right.fRepeatedWallTime;
830	fSkippedWallTime = right.fSkippedWallTime;
831	delete fZone;
832	fZone = NULL;
833	if (right.fZone != NULL) {
834	fZone = right.fZone->clone();
835	}
836	fFirstDayOfWeek = right.fFirstDayOfWeek;
837	fMinimalDaysInFirstWeek = right.fMinimalDaysInFirstWeek;
838	fWeekendOnset = right.fWeekendOnset;
839	fWeekendOnsetMillis = right.fWeekendOnsetMillis;
840	fWeekendCease = right.fWeekendCease;
841	fWeekendCeaseMillis = right.fWeekendCeaseMillis;
842	fNextStamp = right.fNextStamp;
843	uprv_strncpy(validLocale, right.validLocale, sizeof(validLocale));
844	uprv_strncpy(actualLocale, right.actualLocale, sizeof(actualLocale));
845	validLocale[sizeof(validLocale)-`1`] = `0`;
846	actualLocale[sizeof(validLocale)-`1`] = `0`;
847	}
848
849	return *this;
850	}
851
852	// -------------------------------------
853
854	Calendar* U_EXPORT2
855	Calendar::createInstance(UErrorCode& success)
856	{
857	return createInstance(TimeZone::createDefault(), Locale::getDefault(), success);
858	}
859
860	// -------------------------------------
861
862	Calendar* U_EXPORT2
863	Calendar::createInstance(const TimeZone& zone, UErrorCode& success)
864	{
865	return createInstance(zone, Locale::getDefault(), success);
866	}
867
868	// -------------------------------------
869
870	Calendar* U_EXPORT2
871	Calendar::createInstance(const Locale& aLocale, UErrorCode& success)
872	{
873	return createInstance(TimeZone::createDefault(), aLocale, success);
874	}
875
876	// ------------------------------------- Adopting
877
878	// Note: this is the bottleneck that actually calls the service routines.
879
880	Calendar * U_EXPORT2
881	Calendar::makeInstance(const Locale& aLocale, UErrorCode& success) {
882	if (U_FAILURE(success)) {
883	return NULL;
884	}
885
886	Locale actualLoc;
887	UObject* u = NULL;
888
889	#if !UCONFIG_NO_SERVICE
890	if (isCalendarServiceUsed()) {
891	u = getCalendarService(success)->get(aLocale, LocaleKey::KIND_ANY, &actualLoc, success);
892	}
893	else
894	#endif
895	{
896	u = createStandardCalendar(getCalendarTypeForLocale(aLocale.getName()), aLocale, success);
897	}
898	Calendar* c = NULL;
899
900	if(U_FAILURE(success) \|\| !u) {
901	if(U_SUCCESS(success)) { // Propagate some kind of err
902	success = U_INTERNAL_PROGRAM_ERROR;
903	}
904	return NULL;
905	}
906
907	#if !UCONFIG_NO_SERVICE
908	const UnicodeString* str = dynamic_cast<const UnicodeString*>(u);
909	if(str != NULL) {
910	// It's a unicode string telling us what type of calendar to load ("gregorian", etc)
911	// Create a Locale over this string
912	Locale l("");
913	LocaleUtility::initLocaleFromName(*str, l);
914
915	#ifdef U_DEBUG_CALSVC
916	fprintf(stderr, "Calendar::createInstance(%s), looking up [%s]\n", aLocale.getName(), l.getName());
917	#endif
918
919	Locale actualLoc2;
920	delete u;
921	u = NULL;
922
923	// Don't overwrite actualLoc, since the actual loc from this call
924	// may be something like "@calendar=gregorian" -- TODO investigate
925	// further...
926	c = (Calendar*)getCalendarService(success)->get(l, LocaleKey::KIND_ANY, &actualLoc2, success);
927
928	if(U_FAILURE(success) \|\| !c) {
929	if(U_SUCCESS(success)) {
930	success = U_INTERNAL_PROGRAM_ERROR; // Propagate some err
931	}
932	return NULL;
933	}
934
935	str = dynamic_cast<const UnicodeString*>(c);
936	if(str != NULL) {
937	// recursed! Second lookup returned a UnicodeString.
938	// Perhaps DefaultCalendar{} was set to another locale.
939	#ifdef U_DEBUG_CALSVC
940	char tmp[`200`];
941	// Extract a char out of it..*
942	int32_t len = str->length();
943	int32_t actLen = sizeof(tmp)-`1`;
944	if(len > actLen) {
945	len = actLen;
946	}
947	str->extract(`0`,len,tmp);
948	tmp[len]=`0`;
949
950	fprintf(stderr, "err - recursed, 2nd lookup was unistring %s\n", tmp);
951	#endif
952	success = U_MISSING_RESOURCE_ERROR; // requested a calendar type which could NOT be found.
953	delete c;
954	return NULL;
955	}
956	#ifdef U_DEBUG_CALSVC
957	fprintf(stderr, "%p: setting week count data to locale %s, actual locale %s\n", c, (const char)aLocale.getName(), (const* char *)actualLoc.getName());
958	#endif
959	c->setWeekData(aLocale, c->getType(), success); // set the correct locale (this was an indirected calendar)
960
961	char keyword[ULOC_FULLNAME_CAPACITY];
962	UErrorCode tmpStatus = U_ZERO_ERROR;
963	l.getKeywordValue("calendar", keyword, ULOC_FULLNAME_CAPACITY, tmpStatus);
964	if (U_SUCCESS(tmpStatus) && uprv_strcmp(keyword, "iso8601") == `0`) {
965	c->setFirstDayOfWeek(UCAL_MONDAY);
966	c->setMinimalDaysInFirstWeek(`4`);
967	}
968	}
969	else
970	#endif /* UCONFIG_NO_SERVICE */
971	{
972	// a calendar was returned - we assume the factory did the right thing.
973	c = (Calendar*)u;
974	}
975
976	return c;
977	}
978
979	Calendar* U_EXPORT2
980	Calendar::createInstance(TimeZone* zone, const Locale& aLocale, UErrorCode& success)
981	{
982	LocalPointer<TimeZone> zonePtr(zone);
983	const SharedCalendar *shared = NULL;
984	UnifiedCache::getByLocale(aLocale, shared, success);
985	if (U_FAILURE(success)) {
986	return NULL;
987	}
988	Calendar c = (shared)->clone();
989	shared->removeRef();
990	if (c == NULL) {
991	success = U_MEMORY_ALLOCATION_ERROR;
992	return NULL;
993	}
994
995	// Now, reset calendar to default state:
996	c->adoptTimeZone(zonePtr.orphan()); // Set the correct time zone
997	c->setTimeInMillis(getNow(), success); // let the new calendar have the current time.
998
999	return c;
1000	}
1001
1002	// -------------------------------------
1003
1004	Calendar* U_EXPORT2
1005	Calendar::createInstance(const TimeZone& zone, const Locale& aLocale, UErrorCode& success)
1006	{
1007	Calendar* c = createInstance(aLocale, success);
1008	if(U_SUCCESS(success) && c) {
1009	c->setTimeZone(zone);
1010	}
1011	return c;
1012	}
1013
1014	// -------------------------------------
1015
1016	void U_EXPORT2
1017	Calendar::getCalendarTypeFromLocale(
1018	const Locale &aLocale,
1019	char *typeBuffer,
1020	int32_t typeBufferSize,
1021	UErrorCode &success) {
1022	const SharedCalendar *shared = NULL;
1023	UnifiedCache::getByLocale(aLocale, shared, success);
1024	if (U_FAILURE(success)) {
1025	return;
1026	}
1027	uprv_strncpy(typeBuffer, (*shared)->getType(), typeBufferSize);
1028	shared->removeRef();
1029	if (typeBuffer[typeBufferSize - `1`]) {
1030	success = U_BUFFER_OVERFLOW_ERROR;
1031	}
1032	}
1033
1034	UBool
1035	Calendar::operator==(const Calendar& that) const
1036	{
1037	UErrorCode status = U_ZERO_ERROR;
1038	return isEquivalentTo(that) &&
1039	getTimeInMillis(status) == that.getTimeInMillis(status) &&
1040	U_SUCCESS(status);
1041	}
1042
1043	UBool
1044	Calendar::isEquivalentTo(const Calendar& other) const
1045	{
1046	return typeid(*this) == typeid(other) &&
1047	fLenient == other.fLenient &&
1048	fRepeatedWallTime == other.fRepeatedWallTime &&
1049	fSkippedWallTime == other.fSkippedWallTime &&
1050	fFirstDayOfWeek == other.fFirstDayOfWeek &&
1051	fMinimalDaysInFirstWeek == other.fMinimalDaysInFirstWeek &&
1052	fWeekendOnset == other.fWeekendOnset &&
1053	fWeekendOnsetMillis == other.fWeekendOnsetMillis &&
1054	fWeekendCease == other.fWeekendCease &&
1055	fWeekendCeaseMillis == other.fWeekendCeaseMillis &&
1056	fZone == other.fZone;
1057	}
1058
1059	// -------------------------------------
1060
1061	UBool
1062	Calendar::equals(const Calendar& when, UErrorCode& status) const
1063	{
1064	return (this == &when \|\|
1065	getTime(status) == when.getTime(status));
1066	}
1067
1068	// -------------------------------------
1069
1070	UBool
1071	Calendar::before(const Calendar& when, UErrorCode& status) const
1072	{
1073	return (this != &when &&
1074	getTimeInMillis(status) < when.getTimeInMillis(status));
1075	}
1076
1077	// -------------------------------------
1078
1079	UBool
1080	Calendar::after(const Calendar& when, UErrorCode& status) const
1081	{
1082	return (this != &when &&
1083	getTimeInMillis(status) > when.getTimeInMillis(status));
1084	}
1085
1086	// -------------------------------------
1087
1088
1089	const Locale* U_EXPORT2
1090	Calendar::getAvailableLocales(int32_t& count)
1091	{
1092	return Locale::getAvailableLocales(count);
1093	}
1094
1095	// -------------------------------------
1096
1097	StringEnumeration* U_EXPORT2
1098	Calendar::getKeywordValuesForLocale(const char* key,
1099	const Locale& locale, UBool commonlyUsed, UErrorCode& status)
1100	{
1101	// This is a wrapper over ucal_getKeywordValuesForLocale
1102	UEnumeration *uenum = ucal_getKeywordValuesForLocale(key, locale.getName(),
1103	commonlyUsed, &status);
1104	if (U_FAILURE(status)) {
1105	uenum_close(uenum);
1106	return NULL;
1107	}
1108	UStringEnumeration* ustringenum = new UStringEnumeration (uenum);
1109	if (ustringenum == nullptr) {
1110	status = U_MEMORY_ALLOCATION_ERROR;
1111	}
1112	return ustringenum;
1113	}
1114
1115	// -------------------------------------
1116
1117	UDate U_EXPORT2
1118	Calendar::getNow()
1119	{
1120	return uprv_getUTCtime(); // return as milliseconds
1121	}
1122
1123	// -------------------------------------
1124
1125	/**
1126	* Gets this Calendar's current time as a long.
1127	* @return the current time as UTC milliseconds from the epoch.
1128	*/
1129	double
1130	Calendar::getTimeInMillis(UErrorCode& status) const
1131	{
1132	if(U_FAILURE(status))
1133	return `0.0`;
1134
1135	if ( ! fIsTimeSet)
1136	((Calendar)this*)->updateTime(status);
1137
1138	/ Test for buffer overflows /
1139	if(U_FAILURE(status)) {
1140	return `0.0`;
1141	}
1142	return fTime;
1143	}
1144
1145	// -------------------------------------
1146
1147	/**
1148	* Sets this Calendar's current time from the given long value.
1149	* A status of U_ILLEGAL_ARGUMENT_ERROR is set when millis is
1150	* outside the range permitted by a Calendar object when not in lenient mode.
1151	* when in lenient mode the out of range values are pinned to their respective min/max.
1152	* @param date the new time in UTC milliseconds from the epoch.
1153	*/
1154	void
1155	Calendar::setTimeInMillis( double millis, UErrorCode& status ) {
1156	if(U_FAILURE(status))
1157	return;
1158
1159	if (millis > MAX_MILLIS) {
1160	if(isLenient()) {
1161	millis = MAX_MILLIS;
1162	} else {
1163	status = U_ILLEGAL_ARGUMENT_ERROR;
1164	return;
1165	}
1166	} else if (millis < MIN_MILLIS) {
1167	if(isLenient()) {
1168	millis = MIN_MILLIS;
1169	} else {
1170	status = U_ILLEGAL_ARGUMENT_ERROR;
1171	return;
1172	}
1173	}
1174
1175	fTime = millis;
1176	fAreFieldsSet = fAreAllFieldsSet = FALSE;
1177	fIsTimeSet = fAreFieldsVirtuallySet = TRUE;
1178
1179	for (int32_t i=`0`; i<UCAL_FIELD_COUNT; ++i) {
1180	fFields[i] = `0`;
1181	fStamp[i] = kUnset;
1182	fIsSet[i] = FALSE;
1183	}
1184
1185
1186	}
1187
1188	// -------------------------------------
1189
1190	int32_t
1191	Calendar::get(UCalendarDateFields field, UErrorCode& status) const
1192	{
1193	// field values are only computed when actually requested; for more on when computation
1194	// of various things happens, see the "data flow in Calendar" description at the top
1195	// of this file
1196	if (U_SUCCESS(status)) ((Calendar)this)->complete(status); // Cast away const*
1197	return U_SUCCESS(status) ? fFields[field] : `0`;
1198	}
1199
1200	// -------------------------------------
1201
1202	void
1203	Calendar::set(UCalendarDateFields field, int32_t value)
1204	{
1205	if (fAreFieldsVirtuallySet) {
1206	UErrorCode ec = U_ZERO_ERROR;
1207	computeFields(ec);
1208	}
1209	fFields[field] = value;
1210	/ Ensure that the fNextStamp value doesn't go pass max value for int32_t /
1211	if (fNextStamp == STAMP_MAX) {
1212	recalculateStamp();
1213	}
1214	fStamp[field] = fNextStamp++;
1215	fIsSet[field] = TRUE; // Remove later
1216	fIsTimeSet = fAreFieldsSet = fAreFieldsVirtuallySet = FALSE;
1217	}
1218
1219	// -------------------------------------
1220
1221	void
1222	Calendar::set(int32_t year, int32_t month, int32_t date)
1223	{
1224	set(UCAL_YEAR, year);
1225	set(UCAL_MONTH, month);
1226	set(UCAL_DATE, date);
1227	}
1228
1229	// -------------------------------------
1230
1231	void
1232	Calendar::set(int32_t year, int32_t month, int32_t date, int32_t hour, int32_t minute)
1233	{
1234	set(UCAL_YEAR, year);
1235	set(UCAL_MONTH, month);
1236	set(UCAL_DATE, date);
1237	set(UCAL_HOUR_OF_DAY, hour);
1238	set(UCAL_MINUTE, minute);
1239	}
1240
1241	// -------------------------------------
1242
1243	void
1244	Calendar::set(int32_t year, int32_t month, int32_t date, int32_t hour, int32_t minute, int32_t second)
1245	{
1246	set(UCAL_YEAR, year);
1247	set(UCAL_MONTH, month);
1248	set(UCAL_DATE, date);
1249	set(UCAL_HOUR_OF_DAY, hour);
1250	set(UCAL_MINUTE, minute);
1251	set(UCAL_SECOND, second);
1252	}
1253
1254	// -------------------------------------
1255	// For now the full getRelatedYear implementation is here;
1256	// per #10752 move the non-default implementation to subclasses
1257	// (default implementation will do no year adjustment)
1258
1259	static int32_t gregoYearFromIslamicStart(int32_t year) {
1260	// ad hoc conversion, improve under #10752
1261	// rough est for now, ok for grego 1846-2138,
1262	// otherwise occasionally wrong (for 3% of years)
1263	int cycle, offset, shift = `0`;
1264	if (year >= `1397`) {
1265	cycle = (year - `1397`) / `67`;
1266	offset = (year - `1397`) % `67`;
1267	shift = `2`*cycle + ((offset >= `33`)? `1`: `0`);
1268	} else {
1269	cycle = (year - `1396`) / `67` - `1`;
1270	offset = -(year - `1396`) % `67`;
1271	shift = `2`*cycle + ((offset <= `33`)? `1`: `0`);
1272	}
1273	return year + `579` - shift;
1274	}
1275
1276	int32_t Calendar::getRelatedYear(UErrorCode &status) const
1277	{
1278	if (U_FAILURE(status)) {
1279	return `0`;
1280	}
1281	int32_t year = get(UCAL_EXTENDED_YEAR, status);
1282	if (U_FAILURE(status)) {
1283	return `0`;
1284	}
1285	// modify for calendar type
1286	ECalType type = getCalendarType(getType());
1287	switch (type) {
1288	case CALTYPE_PERSIAN:
1289	year += `622`; break;
1290	case CALTYPE_HEBREW:
1291	year -= `3760`; break;
1292	case CALTYPE_CHINESE:
1293	year -= `2637`; break;
1294	case CALTYPE_INDIAN:
1295	year += `79`; break;
1296	case CALTYPE_COPTIC:
1297	year += `284`; break;
1298	case CALTYPE_ETHIOPIC:
1299	year += `8`; break;
1300	case CALTYPE_ETHIOPIC_AMETE_ALEM:
1301	year -=`5492`; break;
1302	case CALTYPE_DANGI:
1303	year -= `2333`; break;
1304	case CALTYPE_ISLAMIC_CIVIL:
1305	case CALTYPE_ISLAMIC:
1306	case CALTYPE_ISLAMIC_UMALQURA:
1307	case CALTYPE_ISLAMIC_TBLA:
1308	case CALTYPE_ISLAMIC_RGSA:
1309	year = gregoYearFromIslamicStart(year); break;
1310	default:
1311	// CALTYPE_GREGORIAN
1312	// CALTYPE_JAPANESE
1313	// CALTYPE_BUDDHIST
1314	// CALTYPE_ROC
1315	// CALTYPE_ISO8601
1316	// do nothing, EXTENDED_YEAR same as Gregorian
1317	break;
1318	}
1319	return year;
1320	}
1321
1322	// -------------------------------------
1323	// For now the full setRelatedYear implementation is here;
1324	// per #10752 move the non-default implementation to subclasses
1325	// (default implementation will do no year adjustment)
1326
1327	static int32_t firstIslamicStartYearFromGrego(int32_t year) {
1328	// ad hoc conversion, improve under #10752
1329	// rough est for now, ok for grego 1846-2138,
1330	// otherwise occasionally wrong (for 3% of years)
1331	int cycle, offset, shift = `0`;
1332	if (year >= `1977`) {
1333	cycle = (year - `1977`) / `65`;
1334	offset = (year - `1977`) % `65`;
1335	shift = `2`*cycle + ((offset >= `32`)? `1`: `0`);
1336	} else {
1337	cycle = (year - `1976`) / `65` - `1`;
1338	offset = -(year - `1976`) % `65`;
1339	shift = `2`*cycle + ((offset <= `32`)? `1`: `0`);
1340	}
1341	return year - `579` + shift;
1342	}
1343	void Calendar::setRelatedYear(int32_t year)
1344	{
1345	// modify for calendar type
1346	ECalType type = getCalendarType(getType());
1347	switch (type) {
1348	case CALTYPE_PERSIAN:
1349	year -= `622`; break;
1350	case CALTYPE_HEBREW:
1351	year += `3760`; break;
1352	case CALTYPE_CHINESE:
1353	year += `2637`; break;
1354	case CALTYPE_INDIAN:
1355	year -= `79`; break;
1356	case CALTYPE_COPTIC:
1357	year -= `284`; break;
1358	case CALTYPE_ETHIOPIC:
1359	year -= `8`; break;
1360	case CALTYPE_ETHIOPIC_AMETE_ALEM:
1361	year +=`5492`; break;
1362	case CALTYPE_DANGI:
1363	year += `2333`; break;
1364	case CALTYPE_ISLAMIC_CIVIL:
1365	case CALTYPE_ISLAMIC:
1366	case CALTYPE_ISLAMIC_UMALQURA:
1367	case CALTYPE_ISLAMIC_TBLA:
1368	case CALTYPE_ISLAMIC_RGSA:
1369	year = firstIslamicStartYearFromGrego(year); break;
1370	default:
1371	// CALTYPE_GREGORIAN
1372	// CALTYPE_JAPANESE
1373	// CALTYPE_BUDDHIST
1374	// CALTYPE_ROC
1375	// CALTYPE_ISO8601
1376	// do nothing, EXTENDED_YEAR same as Gregorian
1377	break;
1378	}
1379	// set extended year
1380	set(UCAL_EXTENDED_YEAR, year);
1381	}
1382
1383	// -------------------------------------
1384
1385	void
1386	Calendar::clear()
1387	{
1388	for (int32_t i=`0`; i<UCAL_FIELD_COUNT; ++i) {
1389	fFields[i] = `0`; // Must do this; other code depends on it
1390	fStamp[i] = kUnset;
1391	fIsSet[i] = FALSE; // Remove later
1392	}
1393	fIsTimeSet = fAreFieldsSet = fAreAllFieldsSet = fAreFieldsVirtuallySet = FALSE;
1394	// fTime is not 'cleared' - may be used if no fields are set.
1395	}
1396
1397	// -------------------------------------
1398
1399	void
1400	Calendar::clear(UCalendarDateFields field)
1401	{
1402	if (fAreFieldsVirtuallySet) {
1403	UErrorCode ec = U_ZERO_ERROR;
1404	computeFields(ec);
1405	}
1406	fFields[field] = `0`;
1407	fStamp[field] = kUnset;
1408	fIsSet[field] = FALSE; // Remove later
1409	fIsTimeSet = fAreFieldsSet = fAreAllFieldsSet = fAreFieldsVirtuallySet = FALSE;
1410	}
1411
1412	// -------------------------------------
1413
1414	UBool
1415	Calendar::isSet(UCalendarDateFields field) const
1416	{
1417	return fAreFieldsVirtuallySet \|\| (fStamp[field] != kUnset);
1418	}
1419
1420
1421	int32_t Calendar::newestStamp(UCalendarDateFields first, UCalendarDateFields last, int32_t bestStampSoFar) const
1422	{
1423	int32_t bestStamp = bestStampSoFar;
1424	for (int32_t i=(int32_t)first; i<=(int32_t)last; ++i) {
1425	if (fStamp[i] > bestStamp) {
1426	bestStamp = fStamp[i];
1427	}
1428	}
1429	return bestStamp;
1430	}
1431
1432
1433	// -------------------------------------
1434
1435	void
1436	Calendar::complete(UErrorCode& status)
1437	{
1438	if (!fIsTimeSet) {
1439	updateTime(status);
1440	/ Test for buffer overflows /
1441	if(U_FAILURE(status)) {
1442	return;
1443	}
1444	}
1445	if (!fAreFieldsSet) {
1446	computeFields(status); // fills in unset fields
1447	/ Test for buffer overflows /
1448	if(U_FAILURE(status)) {
1449	return;
1450	}
1451	fAreFieldsSet = TRUE;
1452	fAreAllFieldsSet = TRUE;
1453	}
1454	}
1455
1456	//-------------------------------------------------------------------------
1457	// Protected utility methods for use by subclasses. These are very handy
1458	// for implementing add, roll, and computeFields.
1459	//-------------------------------------------------------------------------
1460
1461	/**
1462	* Adjust the specified field so that it is within
1463	* the allowable range for the date to which this calendar is set.
1464	* For example, in a Gregorian calendar pinning the {@link #DAY_OF_MONTH DAY_OF_MONTH}
1465	* field for a calendar set to April 31 would cause it to be set
1466	* to April 30.
1467	* <p>
1468	* <b>Subclassing:</b>
1469	* <br>
1470	* This utility method is intended for use by subclasses that need to implement
1471	* their own overrides of {@link #roll roll} and {@link #add add}.
1472	* <p>
1473	* <b>Note:</b>
1474	* <code>pinField</code> is implemented in terms of
1475	* {@link #getActualMinimum getActualMinimum}
1476	* and {@link #getActualMaximum getActualMaximum}. If either of those methods uses
1477	* a slow, iterative algorithm for a particular field, it would be
1478	* unwise to attempt to call <code>pinField</code> for that field. If you
1479	* really do need to do so, you should override this method to do
1480	* something more efficient for that field.
1481	* <p>
1482	* @param field The calendar field whose value should be pinned.
1483	*
1484	* @see #getActualMinimum
1485	* @see #getActualMaximum
1486	* @stable ICU 2.0
1487	*/
1488	void Calendar::pinField(UCalendarDateFields field, UErrorCode& status) {
1489	int32_t max = getActualMaximum(field, status);
1490	int32_t min = getActualMinimum(field, status);
1491
1492	if (fFields[field] > max) {
1493	set(field, max);
1494	} else if (fFields[field] < min) {
1495	set(field, min);
1496	}
1497	}
1498
1499
1500	void Calendar::computeFields(UErrorCode &ec)
1501	{
1502	if (U_FAILURE(ec)) {
1503	return;
1504	}
1505	// Compute local wall millis
1506	double localMillis = internalGetTime();
1507	int32_t rawOffset, dstOffset;
1508	getTimeZone().getOffset(localMillis, FALSE, rawOffset, dstOffset, ec);
1509	localMillis += (rawOffset + dstOffset);
1510
1511	// Mark fields as set. Do this before calling handleComputeFields().
1512	uint32_t mask = //fInternalSetMask;
1513	(`1` << UCAL_ERA) \|
1514	(`1` << UCAL_YEAR) \|
1515	(`1` << UCAL_MONTH) \|
1516	(`1` << UCAL_DAY_OF_MONTH) \| // = UCAL_DATE
1517	(`1` << UCAL_DAY_OF_YEAR) \|
1518	(`1` << UCAL_EXTENDED_YEAR);
1519
1520	for (int32_t i=`0`; i<UCAL_FIELD_COUNT; ++i) {
1521	if ((mask & `1`) == `0`) {
1522	fStamp[i] = kInternallySet;
1523	fIsSet[i] = TRUE; // Remove later
1524	} else {
1525	fStamp[i] = kUnset;
1526	fIsSet[i] = FALSE; // Remove later
1527	}
1528	mask >>= `1`;
1529	}
1530
1531	// We used to check for and correct extreme millis values (near
1532	// Long.MIN_VALUE or Long.MAX_VALUE) here. Such values would cause
1533	// overflows from positive to negative (or vice versa) and had to
1534	// be manually tweaked. We no longer need to do this because we
1535	// have limited the range of supported dates to those that have a
1536	// Julian day that fits into an int. This allows us to implement a
1537	// JULIAN_DAY field and also removes some inelegant code. - Liu
1538	// 11/6/00
1539
1540	int32_t days = (int32_t)ClockMath::floorDivide(localMillis, (double)kOneDay);
1541
1542	internalSet(UCAL_JULIAN_DAY,days + kEpochStartAsJulianDay);
1543
1544	#if defined (U_DEBUG_CAL)
1545	//fprintf(stderr, "%s:%d- Hmm! Jules @ %d, as per %.0lf millis\n",
1546	//__FILE__, __LINE__, fFields[UCAL_JULIAN_DAY], localMillis);
1547	#endif
1548
1549	computeGregorianAndDOWFields(fFields[UCAL_JULIAN_DAY], ec);
1550
1551	// Call framework method to have subclass compute its fields.
1552	// These must include, at a minimum, MONTH, DAY_OF_MONTH,
1553	// EXTENDED_YEAR, YEAR, DAY_OF_YEAR. This method will call internalSet(),
1554	// which will update stamp[].
1555	handleComputeFields(fFields[UCAL_JULIAN_DAY], ec);
1556
1557	// Compute week-related fields, based on the subclass-computed
1558	// fields computed by handleComputeFields().
1559	computeWeekFields(ec);
1560
1561	// Compute time-related fields. These are indepent of the date and
1562	// of the subclass algorithm. They depend only on the local zone
1563	// wall milliseconds in day.
1564	int32_t millisInDay = (int32_t) (localMillis - (days * kOneDay));
1565	fFields[UCAL_MILLISECONDS_IN_DAY] = millisInDay;
1566	fFields[UCAL_MILLISECOND] = millisInDay % `1000`;
1567	millisInDay /= `1000`;
1568	fFields[UCAL_SECOND] = millisInDay % `60`;
1569	millisInDay /= `60`;
1570	fFields[UCAL_MINUTE] = millisInDay % `60`;
1571	millisInDay /= `60`;
1572	fFields[UCAL_HOUR_OF_DAY] = millisInDay;
1573	fFields[UCAL_AM_PM] = millisInDay / `12`; // Assume AM == 0
1574	fFields[UCAL_HOUR] = millisInDay % `12`;
1575	fFields[UCAL_ZONE_OFFSET] = rawOffset;
1576	fFields[UCAL_DST_OFFSET] = dstOffset;
1577	}
1578
1579	uint8_t Calendar::julianDayToDayOfWeek(double julian)
1580	{
1581	// If julian is negative, then julian%7 will be negative, so we adjust
1582	// accordingly. We add 1 because Julian day 0 is Monday.
1583	int8_t dayOfWeek = (int8_t) uprv_fmod(julian + `1`, `7`);
1584
1585	uint8_t result = (uint8_t)(dayOfWeek + ((dayOfWeek < `0`) ? (`7`+UCAL_SUNDAY ) : UCAL_SUNDAY));
1586	return result;
1587	}
1588
1589	/**
1590	* Compute the Gregorian calendar year, month, and day of month from
1591	* the given Julian day. These values are not stored in fields, but in
1592	* member variables gregorianXxx. Also compute the DAY_OF_WEEK and
1593	* DOW_LOCAL fields.
1594	*/
1595	void Calendar::computeGregorianAndDOWFields(int32_t julianDay, UErrorCode &ec)
1596	{
1597	computeGregorianFields(julianDay, ec);
1598
1599	// Compute day of week: JD 0 = Monday
1600	int32_t dow = julianDayToDayOfWeek(julianDay);
1601	internalSet(UCAL_DAY_OF_WEEK,dow);
1602
1603	// Calculate 1-based localized day of week
1604	int32_t dowLocal = dow - getFirstDayOfWeek() + `1`;
1605	if (dowLocal < `1`) {
1606	dowLocal += `7`;
1607	}
1608	internalSet(UCAL_DOW_LOCAL,dowLocal);
1609	fFields[UCAL_DOW_LOCAL] = dowLocal;
1610	}
1611
1612	/**
1613	* Compute the Gregorian calendar year, month, and day of month from the
1614	* Julian day. These values are not stored in fields, but in member
1615	* variables gregorianXxx. They are used for time zone computations and by
1616	* subclasses that are Gregorian derivatives. Subclasses may call this
1617	* method to perform a Gregorian calendar millis->fields computation.
1618	*/
1619	void Calendar::computeGregorianFields(int32_t julianDay, UErrorCode & / ec /) {
1620	int32_t gregorianDayOfWeekUnused;
1621	Grego::dayToFields(julianDay - kEpochStartAsJulianDay, fGregorianYear, fGregorianMonth, fGregorianDayOfMonth, gregorianDayOfWeekUnused, fGregorianDayOfYear);
1622	}
1623
1624	/**
1625	* Compute the fields WEEK_OF_YEAR, YEAR_WOY, WEEK_OF_MONTH,
1626	* DAY_OF_WEEK_IN_MONTH, and DOW_LOCAL from EXTENDED_YEAR, YEAR,
1627	* DAY_OF_WEEK, and DAY_OF_YEAR. The latter fields are computed by the
1628	* subclass based on the calendar system.
1629	*
1630	* <p>The YEAR_WOY field is computed simplistically. It is equal to YEAR
1631	* most of the time, but at the year boundary it may be adjusted to YEAR-1
1632	* or YEAR+1 to reflect the overlap of a week into an adjacent year. In
1633	* this case, a simple increment or decrement is performed on YEAR, even
1634	* though this may yield an invalid YEAR value. For instance, if the YEAR
1635	* is part of a calendar system with an N-year cycle field CYCLE, then
1636	* incrementing the YEAR may involve incrementing CYCLE and setting YEAR
1637	* back to 0 or 1. This is not handled by this code, and in fact cannot be
1638	* simply handled without having subclasses define an entire parallel set of
1639	* fields for fields larger than or equal to a year. This additional
1640	* complexity is not warranted, since the intention of the YEAR_WOY field is
1641	* to support ISO 8601 notation, so it will typically be used with a
1642	* proleptic Gregorian calendar, which has no field larger than a year.
1643	*/
1644	void Calendar::computeWeekFields(UErrorCode &ec) {
1645	if(U_FAILURE(ec)) {
1646	return;
1647	}
1648	int32_t eyear = fFields[UCAL_EXTENDED_YEAR];
1649	int32_t dayOfWeek = fFields[UCAL_DAY_OF_WEEK];
1650	int32_t dayOfYear = fFields[UCAL_DAY_OF_YEAR];
1651
1652	// WEEK_OF_YEAR start
1653	// Compute the week of the year. For the Gregorian calendar, valid week
1654	// numbers run from 1 to 52 or 53, depending on the year, the first day
1655	// of the week, and the minimal days in the first week. For other
1656	// calendars, the valid range may be different -- it depends on the year
1657	// length. Days at the start of the year may fall into the last week of
1658	// the previous year; days at the end of the year may fall into the
1659	// first week of the next year. ASSUME that the year length is less than
1660	// 7000 days.
1661	int32_t yearOfWeekOfYear = eyear;
1662	int32_t relDow = (dayOfWeek + `7` - getFirstDayOfWeek()) % `7`; // 0..6
1663	int32_t relDowJan1 = (dayOfWeek - dayOfYear + `7001` - getFirstDayOfWeek()) % `7`; // 0..6
1664	int32_t woy = (dayOfYear - `1` + relDowJan1) / `7`; // 0..53
1665	if ((`7` - relDowJan1) >= getMinimalDaysInFirstWeek()) {
1666	++woy;
1667	}
1668
1669	// Adjust for weeks at the year end that overlap into the previous or
1670	// next calendar year.
1671	if (woy == `0`) {
1672	// We are the last week of the previous year.
1673	// Check to see if we are in the last week; if so, we need
1674	// to handle the case in which we are the first week of the
1675	// next year.
1676
1677	int32_t prevDoy = dayOfYear + handleGetYearLength(eyear - `1`);
1678	woy = weekNumber(prevDoy, dayOfWeek);
1679	yearOfWeekOfYear--;
1680	} else {
1681	int32_t lastDoy = handleGetYearLength(eyear);
1682	// Fast check: For it to be week 1 of the next year, the DOY
1683	// must be on or after L-5, where L is yearLength(), then it
1684	// cannot possibly be week 1 of the next year:
1685	// L-5 L
1686	// doy: 359 360 361 362 363 364 365 001
1687	// dow: 1 2 3 4 5 6 7
1688	if (dayOfYear >= (lastDoy - `5`)) {
1689	int32_t lastRelDow = (relDow + lastDoy - dayOfYear) % `7`;
1690	if (lastRelDow < `0`) {
1691	lastRelDow += `7`;
1692	}
1693	if (((`6` - lastRelDow) >= getMinimalDaysInFirstWeek()) &&
1694	((dayOfYear + `7` - relDow) > lastDoy)) {
1695	woy = `1`;
1696	yearOfWeekOfYear++;
1697	}
1698	}
1699	}
1700	fFields[UCAL_WEEK_OF_YEAR] = woy;
1701	fFields[UCAL_YEAR_WOY] = yearOfWeekOfYear;
1702	// WEEK_OF_YEAR end
1703
1704	int32_t dayOfMonth = fFields[UCAL_DAY_OF_MONTH];
1705	fFields[UCAL_WEEK_OF_MONTH] = weekNumber(dayOfMonth, dayOfWeek);
1706	fFields[UCAL_DAY_OF_WEEK_IN_MONTH] = (dayOfMonth-`1`) / `7` + `1`;
1707	#if defined (U_DEBUG_CAL)
1708	if(fFields[UCAL_DAY_OF_WEEK_IN_MONTH]==`0`) fprintf(stderr, "%s:%d: DOWIM %d on %g\n",
1709	__FILE__, __LINE__,fFields[UCAL_DAY_OF_WEEK_IN_MONTH], fTime);
1710	#endif
1711	}
1712
1713
1714	int32_t Calendar::weekNumber(int32_t desiredDay, int32_t dayOfPeriod, int32_t dayOfWeek)
1715	{
1716	// Determine the day of the week of the first day of the period
1717	// in question (either a year or a month). Zero represents the
1718	// first day of the week on this calendar.
1719	int32_t periodStartDayOfWeek = (dayOfWeek - getFirstDayOfWeek() - dayOfPeriod + `1`) % `7`;
1720	if (periodStartDayOfWeek < `0`) periodStartDayOfWeek += `7`;
1721
1722	// Compute the week number. Initially, ignore the first week, which
1723	// may be fractional (or may not be). We add periodStartDayOfWeek in
1724	// order to fill out the first week, if it is fractional.
1725	int32_t weekNo = (desiredDay + periodStartDayOfWeek - `1`)/`7`;
1726
1727	// If the first week is long enough, then count it. If
1728	// the minimal days in the first week is one, or if the period start
1729	// is zero, we always increment weekNo.
1730	if ((`7` - periodStartDayOfWeek) >= getMinimalDaysInFirstWeek()) ++weekNo;
1731
1732	return weekNo;
1733	}
1734
1735	void Calendar::handleComputeFields(int32_t / julianDay /, UErrorCode &/ status /)
1736	{
1737	internalSet(UCAL_MONTH, getGregorianMonth());
1738	internalSet(UCAL_DAY_OF_MONTH, getGregorianDayOfMonth());
1739	internalSet(UCAL_DAY_OF_YEAR, getGregorianDayOfYear());
1740	int32_t eyear = getGregorianYear();
1741	internalSet(UCAL_EXTENDED_YEAR, eyear);
1742	int32_t era = GregorianCalendar::AD;
1743	if (eyear < `1`) {
1744	era = GregorianCalendar::BC;
1745	eyear = `1` - eyear;
1746	}
1747	internalSet(UCAL_ERA, era);
1748	internalSet(UCAL_YEAR, eyear);
1749	}
1750	// -------------------------------------
1751
1752
1753	void Calendar::roll(EDateFields field, int32_t amount, UErrorCode& status)
1754	{
1755	roll((UCalendarDateFields)field, amount, status);
1756	}
1757
1758	void Calendar::roll(UCalendarDateFields field, int32_t amount, UErrorCode& status)
1759	{
1760	if (amount == `0`) {
1761	return; // Nothing to do
1762	}
1763
1764	complete(status);
1765
1766	if(U_FAILURE(status)) {
1767	return;
1768	}
1769	switch (field) {
1770	case UCAL_DAY_OF_MONTH:
1771	case UCAL_AM_PM:
1772	case UCAL_MINUTE:
1773	case UCAL_SECOND:
1774	case UCAL_MILLISECOND:
1775	case UCAL_MILLISECONDS_IN_DAY:
1776	case UCAL_ERA:
1777	// These are the standard roll instructions. These work for all
1778	// simple cases, that is, cases in which the limits are fixed, such
1779	// as the hour, the day of the month, and the era.
1780	{
1781	int32_t min = getActualMinimum(field,status);
1782	int32_t max = getActualMaximum(field,status);
1783	int32_t gap = max - min + `1`;
1784
1785	int32_t value = internalGet(field) + amount;
1786	value = (value - min) % gap;
1787	if (value < `0`) {
1788	value += gap;
1789	}
1790	value += min;
1791
1792	set(field, value);
1793	return;
1794	}
1795
1796	case UCAL_HOUR:
1797	case UCAL_HOUR_OF_DAY:
1798	// Rolling the hour is difficult on the ONSET and CEASE days of
1799	// daylight savings. For example, if the change occurs at
1800	// 2 AM, we have the following progression:
1801	// ONSET: 12 Std -> 1 Std -> 3 Dst -> 4 Dst
1802	// CEASE: 12 Dst -> 1 Dst -> 1 Std -> 2 Std
1803	// To get around this problem we don't use fields; we manipulate
1804	// the time in millis directly.
1805	{
1806	// Assume min == 0 in calculations below
1807	double start = getTimeInMillis(status);
1808	int32_t oldHour = internalGet(field);
1809	int32_t max = getMaximum(field);
1810	int32_t newHour = (oldHour + amount) % (max + `1`);
1811	if (newHour < `0`) {
1812	newHour += max + `1`;
1813	}
1814	setTimeInMillis(start + kOneHour * (newHour - oldHour),status);
1815	return;
1816	}
1817
1818	case UCAL_MONTH:
1819	// Rolling the month involves both pinning the final value
1820	// and adjusting the DAY_OF_MONTH if necessary. We only adjust the
1821	// DAY_OF_MONTH if, after updating the MONTH field, it is illegal.
1822	// E.g., <jan31>.roll(MONTH, 1) -> <feb28> or <feb29>.
1823	{
1824	int32_t max = getActualMaximum(UCAL_MONTH, status);
1825	int32_t mon = (internalGet(UCAL_MONTH) + amount) % (max+`1`);
1826
1827	if (mon < `0`) {
1828	mon += (max + `1`);
1829	}
1830	set(UCAL_MONTH, mon);
1831
1832	// Keep the day of month in range. We don't want to spill over
1833	// into the next month; e.g., we don't want jan31 + 1 mo -> feb31 ->
1834	// mar3.
1835	pinField(UCAL_DAY_OF_MONTH,status);
1836	return;
1837	}
1838
1839	case UCAL_YEAR:
1840	case UCAL_YEAR_WOY:
1841	{
1842	// If era==0 and years go backwards in time, change sign of amount.*
1843	// Until we have new API per #9393, we temporarily hardcode knowledge of*
1844	// which calendars have era 0 years that go backwards.
1845	UBool era0WithYearsThatGoBackwards = FALSE;
1846	int32_t era = get(UCAL_ERA, status);
1847	if (era == `0`) {
1848	const char * calType = getType();
1849	if ( uprv_strcmp(calType,"gregorian")==`0` \|\| uprv_strcmp(calType,"roc")==`0` \|\| uprv_strcmp(calType,"coptic")==`0` ) {
1850	amount = -amount;
1851	era0WithYearsThatGoBackwards = TRUE;
1852	}
1853	}
1854	int32_t newYear = internalGet(field) + amount;
1855	if (era > `0` \|\| newYear >= `1`) {
1856	int32_t maxYear = getActualMaximum(field, status);
1857	if (maxYear < `32768`) {
1858	// this era has real bounds, roll should wrap years
1859	if (newYear < `1`) {
1860	newYear = maxYear - ((-newYear) % maxYear);
1861	} else if (newYear > maxYear) {
1862	newYear = ((newYear - `1`) % maxYear) + `1`;
1863	}
1864	// else era is unbounded, just pin low year instead of wrapping
1865	} else if (newYear < `1`) {
1866	newYear = `1`;
1867	}
1868	// else we are in era 0 with newYear < 1;
1869	// calendars with years that go backwards must pin the year value at 0,
1870	// other calendars can have years < 0 in era 0
1871	} else if (era0WithYearsThatGoBackwards) {
1872	newYear = `1`;
1873	}
1874	set(field, newYear);
1875	pinField(UCAL_MONTH,status);
1876	pinField(UCAL_DAY_OF_MONTH,status);
1877	return;
1878	}
1879
1880	case UCAL_EXTENDED_YEAR:
1881	// Rolling the year can involve pinning the DAY_OF_MONTH.
1882	set(field, internalGet(field) + amount);
1883	pinField(UCAL_MONTH,status);
1884	pinField(UCAL_DAY_OF_MONTH,status);
1885	return;
1886
1887	case UCAL_WEEK_OF_MONTH:
1888	{
1889	// This is tricky, because during the roll we may have to shift
1890	// to a different day of the week. For example:
1891
1892	// s m t w r f s
1893	// 1 2 3 4 5
1894	// 6 7 8 9 10 11 12
1895
1896	// When rolling from the 6th or 7th back one week, we go to the
1897	// 1st (assuming that the first partial week counts). The same
1898	// thing happens at the end of the month.
1899
1900	// The other tricky thing is that we have to figure out whether
1901	// the first partial week actually counts or not, based on the
1902	// minimal first days in the week. And we have to use the
1903	// correct first day of the week to delineate the week
1904	// boundaries.
1905
1906	// Here's our algorithm. First, we find the real boundaries of
1907	// the month. Then we discard the first partial week if it
1908	// doesn't count in this locale. Then we fill in the ends with
1909	// phantom days, so that the first partial week and the last
1910	// partial week are full weeks. We then have a nice square
1911	// block of weeks. We do the usual rolling within this block,
1912	// as is done elsewhere in this method. If we wind up on one of
1913	// the phantom days that we added, we recognize this and pin to
1914	// the first or the last day of the month. Easy, eh?
1915
1916	// Normalize the DAY_OF_WEEK so that 0 is the first day of the week
1917	// in this locale. We have dow in 0..6.
1918	int32_t dow = internalGet(UCAL_DAY_OF_WEEK) - getFirstDayOfWeek();
1919	if (dow < `0`) dow += `7`;
1920
1921	// Find the day of the week (normalized for locale) for the first
1922	// of the month.
1923	int32_t fdm = (dow - internalGet(UCAL_DAY_OF_MONTH) + `1`) % `7`;
1924	if (fdm < `0`) fdm += `7`;
1925
1926	// Get the first day of the first full week of the month,
1927	// including phantom days, if any. Figure out if the first week
1928	// counts or not; if it counts, then fill in phantom days. If
1929	// not, advance to the first real full week (skip the partial week).
1930	int32_t start;
1931	if ((`7` - fdm) < getMinimalDaysInFirstWeek())
1932	start = `8` - fdm; // Skip the first partial week
1933	else
1934	start = `1` - fdm; // This may be zero or negative
1935
1936	// Get the day of the week (normalized for locale) for the last
1937	// day of the month.
1938	int32_t monthLen = getActualMaximum(UCAL_DAY_OF_MONTH, status);
1939	int32_t ldm = (monthLen - internalGet(UCAL_DAY_OF_MONTH) + dow) % `7`;
1940	// We know monthLen >= DAY_OF_MONTH so we skip the += 7 step here.
1941
1942	// Get the limit day for the blocked-off rectangular month; that
1943	// is, the day which is one past the last day of the month,
1944	// after the month has already been filled in with phantom days
1945	// to fill out the last week. This day has a normalized DOW of 0.
1946	int32_t limit = monthLen + `7` - ldm;
1947
1948	// Now roll between start and (limit - 1).
1949	int32_t gap = limit - start;
1950	int32_t day_of_month = (internalGet(UCAL_DAY_OF_MONTH) + amount*`7` -
1951	start) % gap;
1952	if (day_of_month < `0`) day_of_month += gap;
1953	day_of_month += start;
1954
1955	// Finally, pin to the real start and end of the month.
1956	if (day_of_month < `1`) day_of_month = `1`;
1957	if (day_of_month > monthLen) day_of_month = monthLen;
1958
1959	// Set the DAY_OF_MONTH. We rely on the fact that this field
1960	// takes precedence over everything else (since all other fields
1961	// are also set at this point). If this fact changes (if the
1962	// disambiguation algorithm changes) then we will have to unset
1963	// the appropriate fields here so that DAY_OF_MONTH is attended
1964	// to.
1965	set(UCAL_DAY_OF_MONTH, day_of_month);
1966	return;
1967	}
1968	case UCAL_WEEK_OF_YEAR:
1969	{
1970	// This follows the outline of WEEK_OF_MONTH, except it applies
1971	// to the whole year. Please see the comment for WEEK_OF_MONTH
1972	// for general notes.
1973
1974	// Normalize the DAY_OF_WEEK so that 0 is the first day of the week
1975	// in this locale. We have dow in 0..6.
1976	int32_t dow = internalGet(UCAL_DAY_OF_WEEK) - getFirstDayOfWeek();
1977	if (dow < `0`) dow += `7`;
1978
1979	// Find the day of the week (normalized for locale) for the first
1980	// of the year.
1981	int32_t fdy = (dow - internalGet(UCAL_DAY_OF_YEAR) + `1`) % `7`;
1982	if (fdy < `0`) fdy += `7`;
1983
1984	// Get the first day of the first full week of the year,
1985	// including phantom days, if any. Figure out if the first week
1986	// counts or not; if it counts, then fill in phantom days. If
1987	// not, advance to the first real full week (skip the partial week).
1988	int32_t start;
1989	if ((`7` - fdy) < getMinimalDaysInFirstWeek())
1990	start = `8` - fdy; // Skip the first partial week
1991	else
1992	start = `1` - fdy; // This may be zero or negative
1993
1994	// Get the day of the week (normalized for locale) for the last
1995	// day of the year.
1996	int32_t yearLen = getActualMaximum(UCAL_DAY_OF_YEAR,status);
1997	int32_t ldy = (yearLen - internalGet(UCAL_DAY_OF_YEAR) + dow) % `7`;
1998	// We know yearLen >= DAY_OF_YEAR so we skip the += 7 step here.
1999
2000	// Get the limit day for the blocked-off rectangular year; that
2001	// is, the day which is one past the last day of the year,
2002	// after the year has already been filled in with phantom days
2003	// to fill out the last week. This day has a normalized DOW of 0.
2004	int32_t limit = yearLen + `7` - ldy;
2005
2006	// Now roll between start and (limit - 1).
2007	int32_t gap = limit - start;
2008	int32_t day_of_year = (internalGet(UCAL_DAY_OF_YEAR) + amount*`7` -
2009	start) % gap;
2010	if (day_of_year < `0`) day_of_year += gap;
2011	day_of_year += start;
2012
2013	// Finally, pin to the real start and end of the month.
2014	if (day_of_year < `1`) day_of_year = `1`;
2015	if (day_of_year > yearLen) day_of_year = yearLen;
2016
2017	// Make sure that the year and day of year are attended to by
2018	// clearing other fields which would normally take precedence.
2019	// If the disambiguation algorithm is changed, this section will
2020	// have to be updated as well.
2021	set(UCAL_DAY_OF_YEAR, day_of_year);
2022	clear(UCAL_MONTH);
2023	return;
2024	}
2025	case UCAL_DAY_OF_YEAR:
2026	{
2027	// Roll the day of year using millis. Compute the millis for
2028	// the start of the year, and get the length of the year.
2029	double delta = amount * kOneDay; // Scale up from days to millis
2030	double min2 = internalGet(UCAL_DAY_OF_YEAR)-`1`;
2031	min2 *= kOneDay;
2032	min2 = internalGetTime() - min2;
2033
2034	// double min2 = internalGetTime() - (internalGet(UCAL_DAY_OF_YEAR) - 1.0) kOneDay;*
2035	double newtime;
2036
2037	double yearLength = getActualMaximum(UCAL_DAY_OF_YEAR,status);
2038	double oneYear = yearLength;
2039	oneYear *= kOneDay;
2040	newtime = uprv_fmod((internalGetTime() + delta - min2), oneYear);
2041	if (newtime < `0`) newtime += oneYear;
2042	setTimeInMillis(newtime + min2, status);
2043	return;
2044	}
2045	case UCAL_DAY_OF_WEEK:
2046	case UCAL_DOW_LOCAL:
2047	{
2048	// Roll the day of week using millis. Compute the millis for
2049	// the start of the week, using the first day of week setting.
2050	// Restrict the millis to [start, start+7days).
2051	double delta = amount * kOneDay; // Scale up from days to millis
2052	// Compute the number of days before the current day in this
2053	// week. This will be a value 0..6.
2054	int32_t leadDays = internalGet(field);
2055	leadDays -= (field == UCAL_DAY_OF_WEEK) ? getFirstDayOfWeek() : `1`;
2056	if (leadDays < `0`) leadDays += `7`;
2057	double min2 = internalGetTime() - leadDays * kOneDay;
2058	double newtime = uprv_fmod((internalGetTime() + delta - min2), kOneWeek);
2059	if (newtime < `0`) newtime += kOneWeek;
2060	setTimeInMillis(newtime + min2, status);
2061	return;
2062	}
2063	case UCAL_DAY_OF_WEEK_IN_MONTH:
2064	{
2065	// Roll the day of week in the month using millis. Determine
2066	// the first day of the week in the month, and then the last,
2067	// and then roll within that range.
2068	double delta = amount * kOneWeek; // Scale up from weeks to millis
2069	// Find the number of same days of the week before this one
2070	// in this month.
2071	int32_t preWeeks = (internalGet(UCAL_DAY_OF_MONTH) - `1`) / `7`;
2072	// Find the number of same days of the week after this one
2073	// in this month.
2074	int32_t postWeeks = (getActualMaximum(UCAL_DAY_OF_MONTH,status) -
2075	internalGet(UCAL_DAY_OF_MONTH)) / `7`;
2076	// From these compute the min and gap millis for rolling.
2077	double min2 = internalGetTime() - preWeeks * kOneWeek;
2078	double gap2 = kOneWeek * (preWeeks + postWeeks + `1`); // Must add 1!
2079	// Roll within this range
2080	double newtime = uprv_fmod((internalGetTime() + delta - min2), gap2);
2081	if (newtime < `0`) newtime += gap2;
2082	setTimeInMillis(newtime + min2, status);
2083	return;
2084	}
2085	case UCAL_JULIAN_DAY:
2086	set(field, internalGet(field) + amount);
2087	return;
2088	default:
2089	// Other fields cannot be rolled by this method
2090	#if defined (U_DEBUG_CAL)
2091	fprintf(stderr, "%s:%d: ILLEGAL ARG because of roll on non-rollable field %s\n",
2092	__FILE__, __LINE__,fldName(field));
2093	#endif
2094	status = U_ILLEGAL_ARGUMENT_ERROR;
2095	}
2096	}
2097
2098	void Calendar::add(EDateFields field, int32_t amount, UErrorCode& status)
2099	{
2100	Calendar::add((UCalendarDateFields)field, amount, status);
2101	}
2102
2103	// -------------------------------------
2104	void Calendar::add(UCalendarDateFields field, int32_t amount, UErrorCode& status)
2105	{
2106	if (amount == `0`) {
2107	return; // Do nothing!
2108	}
2109
2110	// We handle most fields in the same way. The algorithm is to add
2111	// a computed amount of millis to the current millis. The only
2112	// wrinkle is with DST (and/or a change to the zone's UTC offset, which
2113	// we'll include with DST) -- for some fields, like the DAY_OF_MONTH,
2114	// we don't want the wall time to shift due to changes in DST. If the
2115	// result of the add operation is to move from DST to Standard, or
2116	// vice versa, we need to adjust by an hour forward or back,
2117	// respectively. For such fields we set keepWallTimeInvariant to TRUE.
2118
2119	// We only adjust the DST for fields larger than an hour. For
2120	// fields smaller than an hour, we cannot adjust for DST without
2121	// causing problems. for instance, if you add one hour to April 5,
2122	// 1998, 1:00 AM, in PST, the time becomes "2:00 AM PDT" (an
2123	// illegal value), but then the adjustment sees the change and
2124	// compensates by subtracting an hour. As a result the time
2125	// doesn't advance at all.
2126
2127	// For some fields larger than a day, such as a UCAL_MONTH, we pin the
2128	// UCAL_DAY_OF_MONTH. This allows <March 31>.add(UCAL_MONTH, 1) to be
2129	// <April 30>, rather than <April 31> => <May 1>.
2130
2131	double delta = amount; // delta in ms
2132	UBool keepWallTimeInvariant = TRUE;
2133
2134	switch (field) {
2135	case UCAL_ERA:
2136	set(field, get(field, status) + amount);
2137	pinField(UCAL_ERA, status);
2138	return;
2139
2140	case UCAL_YEAR:
2141	case UCAL_YEAR_WOY:
2142	{
2143	// If era=0 and years go backwards in time, change sign of amount.*
2144	// Until we have new API per #9393, we temporarily hardcode knowledge of*
2145	// which calendars have era 0 years that go backwards.
2146	// Note that for UCAL_YEAR (but not UCAL_YEAR_WOY) we could instead handle*
2147	// this by applying the amount to the UCAL_EXTENDED_YEAR field; but since
2148	// we would still need to handle UCAL_YEAR_WOY as below, might as well
2149	// also handle UCAL_YEAR the same way.
2150	int32_t era = get(UCAL_ERA, status);
2151	if (era == `0`) {
2152	const char * calType = getType();
2153	if ( uprv_strcmp(calType,"gregorian")==`0` \|\| uprv_strcmp(calType,"roc")==`0` \|\| uprv_strcmp(calType,"coptic")==`0` ) {
2154	amount = -amount;
2155	}
2156	}
2157	}
2158	// Fall through into normal handling
2159	U_FALLTHROUGH;
2160	case UCAL_EXTENDED_YEAR:
2161	case UCAL_MONTH:
2162	{
2163	UBool oldLenient = isLenient();
2164	setLenient(TRUE);
2165	set(field, get(field, status) + amount);
2166	pinField(UCAL_DAY_OF_MONTH, status);
2167	if(oldLenient==FALSE) {
2168	complete(status); / force recalculate /
2169	setLenient(oldLenient);
2170	}
2171	}
2172	return;
2173
2174	case UCAL_WEEK_OF_YEAR:
2175	case UCAL_WEEK_OF_MONTH:
2176	case UCAL_DAY_OF_WEEK_IN_MONTH:
2177	delta *= kOneWeek;
2178	break;
2179
2180	case UCAL_AM_PM:
2181	delta = `12` kOneHour;
2182	break;
2183
2184	case UCAL_DAY_OF_MONTH:
2185	case UCAL_DAY_OF_YEAR:
2186	case UCAL_DAY_OF_WEEK:
2187	case UCAL_DOW_LOCAL:
2188	case UCAL_JULIAN_DAY:
2189	delta *= kOneDay;
2190	break;
2191
2192	case UCAL_HOUR_OF_DAY:
2193	case UCAL_HOUR:
2194	delta *= kOneHour;
2195	keepWallTimeInvariant = FALSE;
2196	break;
2197
2198	case UCAL_MINUTE:
2199	delta *= kOneMinute;
2200	keepWallTimeInvariant = FALSE;
2201	break;
2202
2203	case UCAL_SECOND:
2204	delta *= kOneSecond;
2205	keepWallTimeInvariant = FALSE;
2206	break;
2207
2208	case UCAL_MILLISECOND:
2209	case UCAL_MILLISECONDS_IN_DAY:
2210	keepWallTimeInvariant = FALSE;
2211	break;
2212
2213	default:
2214	#if defined (U_DEBUG_CAL)
2215	fprintf(stderr, "%s:%d: ILLEGAL ARG because field %s not addable",
2216	__FILE__, __LINE__, fldName(field));
2217	#endif
2218	status = U_ILLEGAL_ARGUMENT_ERROR;
2219	return;
2220	// throw new IllegalArgumentException("Calendar.add(" + fieldName(field) +
2221	// ") not supported");
2222	}
2223
2224	// In order to keep the wall time invariant (for fields where this is
2225	// appropriate), check the combined DST & ZONE offset before and
2226	// after the add() operation. If it changes, then adjust the millis
2227	// to compensate.
2228	int32_t prevOffset = `0`;
2229	int32_t prevWallTime = `0`;
2230	if (keepWallTimeInvariant) {
2231	prevOffset = get(UCAL_DST_OFFSET, status) + get(UCAL_ZONE_OFFSET, status);
2232	prevWallTime = get(UCAL_MILLISECONDS_IN_DAY, status);
2233	}
2234
2235	setTimeInMillis(getTimeInMillis(status) + delta, status);
2236
2237	if (keepWallTimeInvariant) {
2238	int32_t newWallTime = get(UCAL_MILLISECONDS_IN_DAY, status);
2239	if (newWallTime != prevWallTime) {
2240	// There is at least one zone transition between the base
2241	// time and the result time. As the result, wall time has
2242	// changed.
2243	UDate t = internalGetTime();
2244	int32_t newOffset = get(UCAL_DST_OFFSET, status) + get(UCAL_ZONE_OFFSET, status);
2245	if (newOffset != prevOffset) {
2246	// When the difference of the previous UTC offset and
2247	// the new UTC offset exceeds 1 full day, we do not want
2248	// to roll over/back the date. For now, this only happens
2249	// in Samoa (Pacific/Apia) on Dec 30, 2011. See ticket:9452.
2250	int32_t adjAmount = prevOffset - newOffset;
2251	adjAmount = adjAmount >= `0` ? adjAmount % (int32_t)kOneDay : -(-adjAmount % (int32_t)kOneDay);
2252	if (adjAmount != `0`) {
2253	setTimeInMillis(t + adjAmount, status);
2254	newWallTime = get(UCAL_MILLISECONDS_IN_DAY, status);
2255	}
2256	if (newWallTime != prevWallTime) {
2257	// The result wall time or adjusted wall time was shifted because
2258	// the target wall time does not exist on the result date.
2259	switch (fSkippedWallTime) {
2260	case UCAL_WALLTIME_FIRST:
2261	if (adjAmount > `0`) {
2262	setTimeInMillis(t, status);
2263	}
2264	break;
2265	case UCAL_WALLTIME_LAST:
2266	if (adjAmount < `0`) {
2267	setTimeInMillis(t, status);
2268	}
2269	break;
2270	case UCAL_WALLTIME_NEXT_VALID:
2271	UDate tmpT = adjAmount > `0` ? internalGetTime() : t;
2272	UDate immediatePrevTrans;
2273	UBool hasTransition = getImmediatePreviousZoneTransition(tmpT, &immediatePrevTrans, status);
2274	if (U_SUCCESS(status) && hasTransition) {
2275	setTimeInMillis(immediatePrevTrans, status);
2276	}
2277	break;
2278	}
2279	}
2280	}
2281	}
2282	}
2283	}
2284
2285	// -------------------------------------
2286	int32_t Calendar::fieldDifference(UDate when, EDateFields field, UErrorCode& status) {
2287	return fieldDifference(when, (UCalendarDateFields) field, status);
2288	}
2289
2290	int32_t Calendar::fieldDifference(UDate targetMs, UCalendarDateFields field, UErrorCode& ec) {
2291	if (U_FAILURE(ec)) return `0`;
2292	int32_t min = `0`;
2293	double startMs = getTimeInMillis(ec);
2294	// Always add from the start millis. This accomodates
2295	// operations like adding years from February 29, 2000 up to
2296	// February 29, 2004. If 1, 1, 1, 1 is added to the year
2297	// field, the DOM gets pinned to 28 and stays there, giving an
2298	// incorrect DOM difference of 1. We have to add 1, reset, 2,
2299	// reset, 3, reset, 4.
2300	if (startMs < targetMs) {
2301	int32_t max = `1`;
2302	// Find a value that is too large
2303	while (U_SUCCESS(ec)) {
2304	setTimeInMillis(startMs, ec);
2305	add(field, max, ec);
2306	double ms = getTimeInMillis(ec);
2307	if (ms == targetMs) {
2308	return max;
2309	} else if (ms > targetMs) {
2310	break;
2311	} else if (max < INT32_MAX) {
2312	min = max;
2313	max <<= `1`;
2314	if (max < `0`) {
2315	max = INT32_MAX;
2316	}
2317	} else {
2318	// Field difference too large to fit into int32_t
2319	#if defined (U_DEBUG_CAL)
2320	fprintf(stderr, "%s:%d: ILLEGAL ARG because field %s's max too large for int32_t\n",
2321	__FILE__, __LINE__, fldName(field));
2322	#endif
2323	ec = U_ILLEGAL_ARGUMENT_ERROR;
2324	}
2325	}
2326	// Do a binary search
2327	while ((max - min) > `1` && U_SUCCESS(ec)) {
2328	int32_t t = min + (max - min)/`2`; // make sure intermediate values don't exceed INT32_MAX
2329	setTimeInMillis(startMs, ec);
2330	add(field, t, ec);
2331	double ms = getTimeInMillis(ec);
2332	if (ms == targetMs) {
2333	return t;
2334	} else if (ms > targetMs) {
2335	max = t;
2336	} else {
2337	min = t;
2338	}
2339	}
2340	} else if (startMs > targetMs) {
2341	int32_t max = -`1`;
2342	// Find a value that is too small
2343	while (U_SUCCESS(ec)) {
2344	setTimeInMillis(startMs, ec);
2345	add(field, max, ec);
2346	double ms = getTimeInMillis(ec);
2347	if (ms == targetMs) {
2348	return max;
2349	} else if (ms < targetMs) {
2350	break;
2351	} else {
2352	min = max;
2353	max <<= `1`;
2354	if (max == `0`) {
2355	// Field difference too large to fit into int32_t
2356	#if defined (U_DEBUG_CAL)
2357	fprintf(stderr, "%s:%d: ILLEGAL ARG because field %s's max too large for int32_t\n",
2358	__FILE__, __LINE__, fldName(field));
2359	#endif
2360	ec = U_ILLEGAL_ARGUMENT_ERROR;
2361	}
2362	}
2363	}
2364	// Do a binary search
2365	while ((min - max) > `1` && U_SUCCESS(ec)) {
2366	int32_t t = min + (max - min)/`2`; // make sure intermediate values don't exceed INT32_MAX
2367	setTimeInMillis(startMs, ec);
2368	add(field, t, ec);
2369	double ms = getTimeInMillis(ec);
2370	if (ms == targetMs) {
2371	return t;
2372	} else if (ms < targetMs) {
2373	max = t;
2374	} else {
2375	min = t;
2376	}
2377	}
2378	}
2379	// Set calendar to end point
2380	setTimeInMillis(startMs, ec);
2381	add(field, min, ec);
2382
2383	/ Test for buffer overflows /
2384	if(U_FAILURE(ec)) {
2385	return `0`;
2386	}
2387	return min;
2388	}
2389
2390	// -------------------------------------
2391
2392	void
2393	Calendar::adoptTimeZone(TimeZone* zone)
2394	{
2395	// Do nothing if passed-in zone is NULL
2396	if (zone == NULL) return;
2397
2398	// fZone should always be non-null
2399	delete fZone;
2400	fZone = zone;
2401
2402	// if the zone changes, we need to recompute the time fields
2403	fAreFieldsSet = FALSE;
2404	}
2405
2406	// -------------------------------------
2407	void
2408	Calendar::setTimeZone(const TimeZone& zone)
2409	{
2410	adoptTimeZone(zone.clone());
2411	}
2412
2413	// -------------------------------------
2414
2415	const TimeZone&
2416	Calendar::getTimeZone() const
2417	{
2418	U_ASSERT(fZone != NULL);
2419	return *fZone;
2420	}
2421
2422	// -------------------------------------
2423
2424	TimeZone*
2425	Calendar::orphanTimeZone()
2426	{
2427	// we let go of the time zone; the new time zone is the system default time zone
2428	TimeZone *defaultZone = TimeZone::createDefault();
2429	if (defaultZone == NULL) {
2430	// No error handling available. Must keep fZone non-NULL, there are many unchecked uses.
2431	return NULL;
2432	}
2433	TimeZone *z = fZone;
2434	fZone = defaultZone;
2435	return z;
2436	}
2437
2438	// -------------------------------------
2439
2440	void
2441	Calendar::setLenient(UBool lenient)
2442	{
2443	fLenient = lenient;
2444	}
2445
2446	// -------------------------------------
2447
2448	UBool
2449	Calendar::isLenient() const
2450	{
2451	return fLenient;
2452	}
2453
2454	// -------------------------------------
2455
2456	void
2457	Calendar::setRepeatedWallTimeOption(UCalendarWallTimeOption option)
2458	{
2459	if (option == UCAL_WALLTIME_LAST \|\| option == UCAL_WALLTIME_FIRST) {
2460	fRepeatedWallTime = option;
2461	}
2462	}
2463
2464	// -------------------------------------
2465
2466	UCalendarWallTimeOption
2467	Calendar::getRepeatedWallTimeOption(void) const
2468	{
2469	return fRepeatedWallTime;
2470	}
2471
2472	// -------------------------------------
2473
2474	void
2475	Calendar::setSkippedWallTimeOption(UCalendarWallTimeOption option)
2476	{
2477	fSkippedWallTime = option;
2478	}
2479
2480	// -------------------------------------
2481
2482	UCalendarWallTimeOption
2483	Calendar::getSkippedWallTimeOption(void) const
2484	{
2485	return fSkippedWallTime;
2486	}
2487
2488	// -------------------------------------
2489
2490	void
2491	Calendar::setFirstDayOfWeek(UCalendarDaysOfWeek value)
2492	{
2493	if (fFirstDayOfWeek != value &&
2494	value >= UCAL_SUNDAY && value <= UCAL_SATURDAY) {
2495	fFirstDayOfWeek = value;
2496	fAreFieldsSet = FALSE;
2497	}
2498	}
2499
2500	// -------------------------------------
2501
2502	Calendar::EDaysOfWeek
2503	Calendar::getFirstDayOfWeek() const
2504	{
2505	return (Calendar::EDaysOfWeek)fFirstDayOfWeek;
2506	}
2507
2508	UCalendarDaysOfWeek
2509	Calendar::getFirstDayOfWeek(UErrorCode & /status/) const
2510	{
2511	return fFirstDayOfWeek;
2512	}
2513	// -------------------------------------
2514
2515	void
2516	Calendar::setMinimalDaysInFirstWeek(uint8_t value)
2517	{
2518	// Values less than 1 have the same effect as 1; values greater
2519	// than 7 have the same effect as 7. However, we normalize values
2520	// so operator== and so forth work.
2521	if (value < `1`) {
2522	value = `1`;
2523	} else if (value > `7`) {
2524	value = `7`;
2525	}
2526	if (fMinimalDaysInFirstWeek != value) {
2527	fMinimalDaysInFirstWeek = value;
2528	fAreFieldsSet = FALSE;
2529	}
2530	}
2531
2532	// -------------------------------------
2533
2534	uint8_t
2535	Calendar::getMinimalDaysInFirstWeek() const
2536	{
2537	return fMinimalDaysInFirstWeek;
2538	}
2539
2540	// -------------------------------------
2541	// weekend functions, just dummy implementations for now (for API freeze)
2542
2543	UCalendarWeekdayType
2544	Calendar::getDayOfWeekType(UCalendarDaysOfWeek dayOfWeek, UErrorCode &status) const
2545	{
2546	if (U_FAILURE(status)) {
2547	return UCAL_WEEKDAY;
2548	}
2549	if (dayOfWeek < UCAL_SUNDAY \|\| dayOfWeek > UCAL_SATURDAY) {
2550	status = U_ILLEGAL_ARGUMENT_ERROR;
2551	return UCAL_WEEKDAY;
2552	}
2553	if (fWeekendOnset == fWeekendCease) {
2554	if (dayOfWeek != fWeekendOnset)
2555	return UCAL_WEEKDAY;
2556	return (fWeekendOnsetMillis == `0`) ? UCAL_WEEKEND : UCAL_WEEKEND_ONSET;
2557	}
2558	if (fWeekendOnset < fWeekendCease) {
2559	if (dayOfWeek < fWeekendOnset \|\| dayOfWeek > fWeekendCease) {
2560	return UCAL_WEEKDAY;
2561	}
2562	} else {
2563	if (dayOfWeek > fWeekendCease && dayOfWeek < fWeekendOnset) {
2564	return UCAL_WEEKDAY;
2565	}
2566	}
2567	if (dayOfWeek == fWeekendOnset) {
2568	return (fWeekendOnsetMillis == `0`) ? UCAL_WEEKEND : UCAL_WEEKEND_ONSET;
2569	}
2570	if (dayOfWeek == fWeekendCease) {
2571	return (fWeekendCeaseMillis >= `86400000`) ? UCAL_WEEKEND : UCAL_WEEKEND_CEASE;
2572	}
2573	return UCAL_WEEKEND;
2574	}
2575
2576	int32_t
2577	Calendar::getWeekendTransition(UCalendarDaysOfWeek dayOfWeek, UErrorCode &status) const
2578	{
2579	if (U_FAILURE(status)) {
2580	return `0`;
2581	}
2582	if (dayOfWeek == fWeekendOnset) {
2583	return fWeekendOnsetMillis;
2584	} else if (dayOfWeek == fWeekendCease) {
2585	return fWeekendCeaseMillis;
2586	}
2587	status = U_ILLEGAL_ARGUMENT_ERROR;
2588	return `0`;
2589	}
2590
2591	UBool
2592	Calendar::isWeekend(UDate date, UErrorCode &status) const
2593	{
2594	if (U_FAILURE(status)) {
2595	return FALSE;
2596	}
2597	// clone the calendar so we don't mess with the real one.
2598	Calendar work = this*->clone();
2599	if (work == NULL) {
2600	status = U_MEMORY_ALLOCATION_ERROR;
2601	return FALSE;
2602	}
2603	UBool result = FALSE;
2604	work->setTime(date, status);
2605	if (U_SUCCESS(status)) {
2606	result = work->isWeekend();
2607	}
2608	delete work;
2609	return result;
2610	}
2611
2612	UBool
2613	Calendar::isWeekend(void) const
2614	{
2615	UErrorCode status = U_ZERO_ERROR;
2616	UCalendarDaysOfWeek dayOfWeek = (UCalendarDaysOfWeek)get(UCAL_DAY_OF_WEEK, status);
2617	UCalendarWeekdayType dayType = getDayOfWeekType(dayOfWeek, status);
2618	if (U_SUCCESS(status)) {
2619	switch (dayType) {
2620	case UCAL_WEEKDAY:
2621	return FALSE;
2622	case UCAL_WEEKEND:
2623	return TRUE;
2624	case UCAL_WEEKEND_ONSET:
2625	case UCAL_WEEKEND_CEASE:
2626	// Use internalGet() because the above call to get() populated all fields.
2627	{
2628	int32_t millisInDay = internalGet(UCAL_MILLISECONDS_IN_DAY);
2629	int32_t transitionMillis = getWeekendTransition(dayOfWeek, status);
2630	if (U_SUCCESS(status)) {
2631	return (dayType == UCAL_WEEKEND_ONSET)?
2632	(millisInDay >= transitionMillis):
2633	(millisInDay < transitionMillis);
2634	}
2635	// else fall through, return FALSE
2636	U_FALLTHROUGH;
2637	}
2638	default:
2639	break;
2640	}
2641	}
2642	return FALSE;
2643	}
2644
2645	// ------------------------------------- limits
2646
2647	int32_t
2648	Calendar::getMinimum(EDateFields field) const {
2649	return getLimit((UCalendarDateFields) field,UCAL_LIMIT_MINIMUM);
2650	}
2651
2652	int32_t
2653	Calendar::getMinimum(UCalendarDateFields field) const
2654	{
2655	return getLimit(field,UCAL_LIMIT_MINIMUM);
2656	}
2657
2658	// -------------------------------------
2659	int32_t
2660	Calendar::getMaximum(EDateFields field) const
2661	{
2662	return getLimit((UCalendarDateFields) field,UCAL_LIMIT_MAXIMUM);
2663	}
2664
2665	int32_t
2666	Calendar::getMaximum(UCalendarDateFields field) const
2667	{
2668	return getLimit(field,UCAL_LIMIT_MAXIMUM);
2669	}
2670
2671	// -------------------------------------
2672	int32_t
2673	Calendar::getGreatestMinimum(EDateFields field) const
2674	{
2675	return getLimit((UCalendarDateFields)field,UCAL_LIMIT_GREATEST_MINIMUM);
2676	}
2677
2678	int32_t
2679	Calendar::getGreatestMinimum(UCalendarDateFields field) const
2680	{
2681	return getLimit(field,UCAL_LIMIT_GREATEST_MINIMUM);
2682	}
2683
2684	// -------------------------------------
2685	int32_t
2686	Calendar::getLeastMaximum(EDateFields field) const
2687	{
2688	return getLimit((UCalendarDateFields) field,UCAL_LIMIT_LEAST_MAXIMUM);
2689	}
2690
2691	int32_t
2692	Calendar::getLeastMaximum(UCalendarDateFields field) const
2693	{
2694	return getLimit( field,UCAL_LIMIT_LEAST_MAXIMUM);
2695	}
2696
2697	// -------------------------------------
2698	int32_t
2699	Calendar::getActualMinimum(EDateFields field, UErrorCode& status) const
2700	{
2701	return getActualMinimum((UCalendarDateFields) field, status);
2702	}
2703
2704	int32_t Calendar::getLimit(UCalendarDateFields field, ELimitType limitType) const {
2705	switch (field) {
2706	case UCAL_DAY_OF_WEEK:
2707	case UCAL_AM_PM:
2708	case UCAL_HOUR:
2709	case UCAL_HOUR_OF_DAY:
2710	case UCAL_MINUTE:
2711	case UCAL_SECOND:
2712	case UCAL_MILLISECOND:
2713	case UCAL_ZONE_OFFSET:
2714	case UCAL_DST_OFFSET:
2715	case UCAL_DOW_LOCAL:
2716	case UCAL_JULIAN_DAY:
2717	case UCAL_MILLISECONDS_IN_DAY:
2718	case UCAL_IS_LEAP_MONTH:
2719	return kCalendarLimits[field][limitType];
2720
2721	case UCAL_WEEK_OF_MONTH:
2722	{
2723	int32_t limit;
2724	if (limitType == UCAL_LIMIT_MINIMUM) {
2725	limit = getMinimalDaysInFirstWeek() == `1` ? `1` : `0`;
2726	} else if (limitType == UCAL_LIMIT_GREATEST_MINIMUM) {
2727	limit = `1`;
2728	} else {
2729	int32_t minDaysInFirst = getMinimalDaysInFirstWeek();
2730	int32_t daysInMonth = handleGetLimit(UCAL_DAY_OF_MONTH, limitType);
2731	if (limitType == UCAL_LIMIT_LEAST_MAXIMUM) {
2732	limit = (daysInMonth + (`7` - minDaysInFirst)) / `7`;
2733	} else { // limitType == UCAL_LIMIT_MAXIMUM
2734	limit = (daysInMonth + `6` + (`7` - minDaysInFirst)) / `7`;
2735	}
2736	}
2737	return limit;
2738	}
2739	default:
2740	return handleGetLimit(field, limitType);
2741	}
2742	}
2743
2744
2745	int32_t
2746	Calendar::getActualMinimum(UCalendarDateFields field, UErrorCode& status) const
2747	{
2748	int32_t fieldValue = getGreatestMinimum(field);
2749	int32_t endValue = getMinimum(field);
2750
2751	// if we know that the minimum value is always the same, just return it
2752	if (fieldValue == endValue) {
2753	return fieldValue;
2754	}
2755
2756	// clone the calendar so we don't mess with the real one, and set it to
2757	// accept anything for the field values
2758	Calendar work = this*->clone();
2759	if (work == NULL) {
2760	status = U_MEMORY_ALLOCATION_ERROR;
2761	return `0`;
2762	}
2763	work->setLenient(TRUE);
2764
2765	// now try each value from getLeastMaximum() to getMaximum() one by one until
2766	// we get a value that normalizes to another value. The last value that
2767	// normalizes to itself is the actual minimum for the current date
2768	int32_t result = fieldValue;
2769
2770	do {
2771	work->set(field, fieldValue);
2772	if (work->get(field, status) != fieldValue) {
2773	break;
2774	}
2775	else {
2776	result = fieldValue;
2777	fieldValue--;
2778	}
2779	} while (fieldValue >= endValue);
2780
2781	delete work;
2782
2783	/ Test for buffer overflows /
2784	if(U_FAILURE(status)) {
2785	return `0`;
2786	}
2787	return result;
2788	}
2789
2790	// -------------------------------------
2791
2792
2793
2794	/**
2795	* Ensure that each field is within its valid range by calling {@link
2796	* #validateField(int)} on each field that has been set. This method
2797	* should only be called if this calendar is not lenient.
2798	* @see #isLenient
2799	* @see #validateField(int)
2800	*/
2801	void Calendar::validateFields(UErrorCode &status) {
2802	for (int32_t field = `0`; U_SUCCESS(status) && (field < UCAL_FIELD_COUNT); field++) {
2803	if (fStamp[field] >= kMinimumUserStamp) {
2804	validateField((UCalendarDateFields)field, status);
2805	}
2806	}
2807	}
2808
2809	/**
2810	* Validate a single field of this calendar. Subclasses should
2811	* override this method to validate any calendar-specific fields.
2812	* Generic fields can be handled by
2813	* <code>Calendar.validateField()</code>.
2814	* @see #validateField(int, int, int)
2815	*/
2816	void Calendar::validateField(UCalendarDateFields field, UErrorCode &status) {
2817	int32_t y;
2818	switch (field) {
2819	case UCAL_DAY_OF_MONTH:
2820	y = handleGetExtendedYear();
2821	validateField(field, `1`, handleGetMonthLength(y, internalGet(UCAL_MONTH)), status);
2822	break;
2823	case UCAL_DAY_OF_YEAR:
2824	y = handleGetExtendedYear();
2825	validateField(field, `1`, handleGetYearLength(y), status);
2826	break;
2827	case UCAL_DAY_OF_WEEK_IN_MONTH:
2828	if (internalGet(field) == `0`) {
2829	#if defined (U_DEBUG_CAL)
2830	fprintf(stderr, "%s:%d: ILLEGAL ARG because DOW in month cannot be 0\n",
2831	__FILE__, __LINE__);
2832	#endif
2833	status = U_ILLEGAL_ARGUMENT_ERROR; // "DAY_OF_WEEK_IN_MONTH cannot be zero"
2834	return;
2835	}
2836	validateField(field, getMinimum(field), getMaximum(field), status);
2837	break;
2838	default:
2839	validateField(field, getMinimum(field), getMaximum(field), status);
2840	break;
2841	}
2842	}
2843
2844	/**
2845	* Validate a single field of this calendar given its minimum and
2846	* maximum allowed value. If the field is out of range, throw a
2847	* descriptive <code>IllegalArgumentException</code>. Subclasses may
2848	* use this method in their implementation of {@link
2849	* #validateField(int)}.
2850	*/
2851	void Calendar::validateField(UCalendarDateFields field, int32_t min, int32_t max, UErrorCode& status)
2852	{
2853	int32_t value = fFields[field];
2854	if (value < min \|\| value > max) {
2855	#if defined (U_DEBUG_CAL)
2856	fprintf(stderr, "%s:%d: ILLEGAL ARG because of field %s out of range %d..%d at %d\n",
2857	__FILE__, __LINE__,fldName(field),min,max,value);
2858	#endif
2859	status = U_ILLEGAL_ARGUMENT_ERROR;
2860	return;
2861	}
2862	}
2863
2864	// -------------------------
2865
2866	const UFieldResolutionTable* Calendar::getFieldResolutionTable() const {
2867	return kDatePrecedence;
2868	}
2869
2870
2871	UCalendarDateFields Calendar::newerField(UCalendarDateFields defaultField, UCalendarDateFields alternateField) const
2872	{
2873	if (fStamp[alternateField] > fStamp[defaultField]) {
2874	return alternateField;
2875	}
2876	return defaultField;
2877	}
2878
2879	UCalendarDateFields Calendar::resolveFields(const UFieldResolutionTable* precedenceTable) {
2880	int32_t bestField = UCAL_FIELD_COUNT;
2881	int32_t tempBestField;
2882	for (int32_t g=`0`; precedenceTable[g][`0`][`0`] != -`1` && (bestField == UCAL_FIELD_COUNT); ++g) {
2883	int32_t bestStamp = kUnset;
2884	for (int32_t l=`0`; precedenceTable[g][l][`0`] != -`1`; ++l) {
2885	int32_t lineStamp = kUnset;
2886	// Skip over first entry if it is negative
2887	for (int32_t i=((precedenceTable[g][l][`0`]>=kResolveRemap)?`1`:`0`); precedenceTable[g][l][i]!=-`1`; ++i) {
2888	U_ASSERT(precedenceTable[g][l][i] < UCAL_FIELD_COUNT);
2889	int32_t s = fStamp[precedenceTable[g][l][i]];
2890	// If any field is unset then don't use this line
2891	if (s == kUnset) {
2892	goto linesInGroup;
2893	} else if(s > lineStamp) {
2894	lineStamp = s;
2895	}
2896	}
2897	// Record new maximum stamp & field no.
2898	if (lineStamp > bestStamp) {
2899	tempBestField = precedenceTable[g][l][`0`]; // First field refers to entire line
2900	if (tempBestField >= kResolveRemap) {
2901	tempBestField &= (kResolveRemap-`1`);
2902	// This check is needed to resolve some issues with UCAL_YEAR precedence mapping
2903	if (tempBestField != UCAL_DATE \|\| (fStamp[UCAL_WEEK_OF_MONTH] < fStamp[tempBestField])) {
2904	bestField = tempBestField;
2905	}
2906	} else {
2907	bestField = tempBestField;
2908	}
2909
2910	if (bestField == tempBestField) {
2911	bestStamp = lineStamp;
2912	}
2913	}
2914	linesInGroup:
2915	;
2916	}
2917	}
2918	return (UCalendarDateFields)bestField;
2919	}
2920
2921	const UFieldResolutionTable Calendar::kDatePrecedence[] =
2922	{
2923	{
2924	{ UCAL_DAY_OF_MONTH, kResolveSTOP },
2925	{ UCAL_WEEK_OF_YEAR, UCAL_DAY_OF_WEEK, kResolveSTOP },
2926	{ UCAL_WEEK_OF_MONTH, UCAL_DAY_OF_WEEK, kResolveSTOP },
2927	{ UCAL_DAY_OF_WEEK_IN_MONTH, UCAL_DAY_OF_WEEK, kResolveSTOP },
2928	{ UCAL_WEEK_OF_YEAR, UCAL_DOW_LOCAL, kResolveSTOP },
2929	{ UCAL_WEEK_OF_MONTH, UCAL_DOW_LOCAL, kResolveSTOP },
2930	{ UCAL_DAY_OF_WEEK_IN_MONTH, UCAL_DOW_LOCAL, kResolveSTOP },
2931	{ UCAL_DAY_OF_YEAR, kResolveSTOP },
2932	{ kResolveRemap \| UCAL_DAY_OF_MONTH, UCAL_YEAR, kResolveSTOP }, // if YEAR is set over YEAR_WOY use DAY_OF_MONTH
2933	{ kResolveRemap \| UCAL_WEEK_OF_YEAR, UCAL_YEAR_WOY, kResolveSTOP }, // if YEAR_WOY is set, calc based on WEEK_OF_YEAR
2934	{ kResolveSTOP }
2935	},
2936	{
2937	{ UCAL_WEEK_OF_YEAR, kResolveSTOP },
2938	{ UCAL_WEEK_OF_MONTH, kResolveSTOP },
2939	{ UCAL_DAY_OF_WEEK_IN_MONTH, kResolveSTOP },
2940	{ kResolveRemap \| UCAL_DAY_OF_WEEK_IN_MONTH, UCAL_DAY_OF_WEEK, kResolveSTOP },
2941	{ kResolveRemap \| UCAL_DAY_OF_WEEK_IN_MONTH, UCAL_DOW_LOCAL, kResolveSTOP },
2942	{ kResolveSTOP }
2943	},
2944	{{kResolveSTOP}}
2945	};
2946
2947
2948	const UFieldResolutionTable Calendar::kDOWPrecedence[] =
2949	{
2950	{
2951	{ UCAL_DAY_OF_WEEK,kResolveSTOP, kResolveSTOP },
2952	{ UCAL_DOW_LOCAL,kResolveSTOP, kResolveSTOP },
2953	{kResolveSTOP}
2954	},
2955	{{kResolveSTOP}}
2956	};
2957
2958	// precedence for calculating a year
2959	const UFieldResolutionTable Calendar::kYearPrecedence[] =
2960	{
2961	{
2962	{ UCAL_YEAR, kResolveSTOP },
2963	{ UCAL_EXTENDED_YEAR, kResolveSTOP },
2964	{ UCAL_YEAR_WOY, UCAL_WEEK_OF_YEAR, kResolveSTOP }, // YEAR_WOY is useless without WEEK_OF_YEAR
2965	{ kResolveSTOP }
2966	},
2967	{{kResolveSTOP}}
2968	};
2969
2970
2971	// -------------------------
2972
2973
2974	void Calendar::computeTime(UErrorCode& status) {
2975	if (!isLenient()) {
2976	validateFields(status);
2977	if (U_FAILURE(status)) {
2978	return;
2979	}
2980	}
2981
2982	// Compute the Julian day
2983	int32_t julianDay = computeJulianDay();
2984
2985	double millis = Grego::julianDayToMillis(julianDay);
2986
2987	#if defined (U_DEBUG_CAL)
2988	// int32_t julianInsanityCheck = (int32_t)ClockMath::floorDivide(millis, kOneDay);
2989	// julianInsanityCheck += kEpochStartAsJulianDay;
2990	// if(1 \|\| julianInsanityCheck != julianDay) {
2991	// fprintf(stderr, "%s:%d- D'oh- computed jules %d, to mills (%s)%.lf, recomputed %d\n",
2992	// __FILE__, __LINE__, julianDay, millis<0.0?"NEG":"", millis, julianInsanityCheck);
2993	// }
2994	#endif
2995
2996	double millisInDay;
2997
2998	// We only use MILLISECONDS_IN_DAY if it has been set by the user.
2999	// This makes it possible for the caller to set the calendar to a
3000	// time and call clear(MONTH) to reset the MONTH to January. This
3001	// is legacy behavior. Without this, clear(MONTH) has no effect,
3002	// since the internally set JULIAN_DAY is used.
3003	if (fStamp[UCAL_MILLISECONDS_IN_DAY] >= ((int32_t)kMinimumUserStamp) &&
3004	newestStamp(UCAL_AM_PM, UCAL_MILLISECOND, kUnset) <= fStamp[UCAL_MILLISECONDS_IN_DAY]) {
3005	millisInDay = internalGet(UCAL_MILLISECONDS_IN_DAY);
3006	} else {
3007	millisInDay = computeMillisInDay();
3008	}
3009
3010	UDate t = `0`;
3011	if (fStamp[UCAL_ZONE_OFFSET] >= ((int32_t)kMinimumUserStamp) \|\| fStamp[UCAL_DST_OFFSET] >= ((int32_t)kMinimumUserStamp)) {
3012	t = millis + millisInDay - (internalGet(UCAL_ZONE_OFFSET) + internalGet(UCAL_DST_OFFSET));
3013	} else {
3014	// Compute the time zone offset and DST offset. There are two potential
3015	// ambiguities here. We'll assume a 2:00 am (wall time) switchover time
3016	// for discussion purposes here.
3017	//
3018	// 1. The positive offset change such as transition into DST.
3019	// Here, a designated time of 2:00 am - 2:59 am does not actually exist.
3020	// For this case, skippedWallTime option specifies the behavior.
3021	// For example, 2:30 am is interpreted as;
3022	// - WALLTIME_LAST(default): 3:30 am (DST) (interpreting 2:30 am as 31 minutes after 1:59 am (STD))
3023	// - WALLTIME_FIRST: 1:30 am (STD) (interpreting 2:30 am as 30 minutes before 3:00 am (DST))
3024	// - WALLTIME_NEXT_VALID: 3:00 am (DST) (next valid time after 2:30 am on a wall clock)
3025	// 2. The negative offset change such as transition out of DST.
3026	// Here, a designated time of 1:00 am - 1:59 am can be in standard or DST. Both are valid
3027	// representations (the rep jumps from 1:59:59 DST to 1:00:00 Std).
3028	// For this case, repeatedWallTime option specifies the behavior.
3029	// For example, 1:30 am is interpreted as;
3030	// - WALLTIME_LAST(default): 1:30 am (STD) - latter occurrence
3031	// - WALLTIME_FIRST: 1:30 am (DST) - former occurrence
3032	//
3033	// In addition to above, when calendar is strict (not default), wall time falls into
3034	// the skipped time range will be processed as an error case.
3035	//
3036	// These special cases are mostly handled in #computeZoneOffset(long), except WALLTIME_NEXT_VALID
3037	// at positive offset change. The protected method computeZoneOffset(long) is exposed to Calendar
3038	// subclass implementations and marked as @stable. Strictly speaking, WALLTIME_NEXT_VALID
3039	// should be also handled in the same place, but we cannot change the code flow without deprecating
3040	// the protected method.
3041	//
3042	// We use the TimeZone object, unless the user has explicitly set the ZONE_OFFSET
3043	// or DST_OFFSET fields; then we use those fields.
3044
3045	if (!isLenient() \|\| fSkippedWallTime == UCAL_WALLTIME_NEXT_VALID) {
3046	// When strict, invalidate a wall time falls into a skipped wall time range.
3047	// When lenient and skipped wall time option is WALLTIME_NEXT_VALID,
3048	// the result time will be adjusted to the next valid time (on wall clock).
3049	int32_t zoneOffset = computeZoneOffset(millis, millisInDay, status);
3050	UDate tmpTime = millis + millisInDay - zoneOffset;
3051
3052	int32_t raw, dst;
3053	fZone->getOffset(tmpTime, FALSE, raw, dst, status);
3054
3055	if (U_SUCCESS(status)) {
3056	// zoneOffset != (raw + dst) only when the given wall time fall into
3057	// a skipped wall time range caused by positive zone offset transition.
3058	if (zoneOffset != (raw + dst)) {
3059	if (!isLenient()) {
3060	status = U_ILLEGAL_ARGUMENT_ERROR;
3061	} else {
3062	U_ASSERT(fSkippedWallTime == UCAL_WALLTIME_NEXT_VALID);
3063	// Adjust time to the next valid wall clock time.
3064	// At this point, tmpTime is on or after the zone offset transition causing
3065	// the skipped time range.
3066	UDate immediatePrevTransition;
3067	UBool hasTransition = getImmediatePreviousZoneTransition(tmpTime, &immediatePrevTransition, status);
3068	if (U_SUCCESS(status) && hasTransition) {
3069	t = immediatePrevTransition;
3070	}
3071	}
3072	} else {
3073	t = tmpTime;
3074	}
3075	}
3076	} else {
3077	t = millis + millisInDay - computeZoneOffset(millis, millisInDay, status);
3078	}
3079	}
3080	if (U_SUCCESS(status)) {
3081	internalSetTime(t);
3082	}
3083	}
3084
3085	/**
3086	* Find the previous zone transtion near the given time.
3087	*/
3088	UBool Calendar::getImmediatePreviousZoneTransition(UDate base, UDate transitionTime, UErrorCode& status) const* {
3089	BasicTimeZone *btz = getBasicTimeZone();
3090	if (btz) {
3091	TimeZoneTransition trans;
3092	UBool hasTransition = btz->getPreviousTransition(base, TRUE, trans);
3093	if (hasTransition) {
3094	*transitionTime = trans.getTime();
3095	return TRUE;
3096	} else {
3097	// Could not find any transitions.
3098	// Note: This should never happen.
3099	status = U_INTERNAL_PROGRAM_ERROR;
3100	}
3101	} else {
3102	// If not BasicTimeZone, return unsupported error for now.
3103	// TODO: We may support non-BasicTimeZone in future.
3104	status = U_UNSUPPORTED_ERROR;
3105	}
3106	return FALSE;
3107	}
3108
3109	/**
3110	* Compute the milliseconds in the day from the fields. This is a
3111	* value from 0 to 23:59:59.999 inclusive, unless fields are out of
3112	* range, in which case it can be an arbitrary value. This value
3113	* reflects local zone wall time.
3114	* @stable ICU 2.0
3115	*/
3116	double Calendar::computeMillisInDay() {
3117	// Do the time portion of the conversion.
3118
3119	double millisInDay = `0`;
3120
3121	// Find the best set of fields specifying the time of day. There
3122	// are only two possibilities here; the HOUR_OF_DAY or the
3123	// AM_PM and the HOUR.
3124	int32_t hourOfDayStamp = fStamp[UCAL_HOUR_OF_DAY];
3125	int32_t hourStamp = (fStamp[UCAL_HOUR] > fStamp[UCAL_AM_PM])?fStamp[UCAL_HOUR]:fStamp[UCAL_AM_PM];
3126	int32_t bestStamp = (hourStamp > hourOfDayStamp) ? hourStamp : hourOfDayStamp;
3127
3128	// Hours
3129	if (bestStamp != kUnset) {
3130	if (bestStamp == hourOfDayStamp) {
3131	// Don't normalize here; let overflow bump into the next period.
3132	// This is consistent with how we handle other fields.
3133	millisInDay += internalGet(UCAL_HOUR_OF_DAY);
3134	} else {
3135	// Don't normalize here; let overflow bump into the next period.
3136	// This is consistent with how we handle other fields.
3137	millisInDay += internalGet(UCAL_HOUR);
3138	millisInDay += `12` * internalGet(UCAL_AM_PM); // Default works for unset AM_PM
3139	}
3140	}
3141
3142	// We use the fact that unset == 0; we start with millisInDay
3143	// == HOUR_OF_DAY.
3144	millisInDay *= `60`;
3145	millisInDay += internalGet(UCAL_MINUTE); // now have minutes
3146	millisInDay *= `60`;
3147	millisInDay += internalGet(UCAL_SECOND); // now have seconds
3148	millisInDay *= `1000`;
3149	millisInDay += internalGet(UCAL_MILLISECOND); // now have millis
3150
3151	return millisInDay;
3152	}
3153
3154	/**
3155	* This method can assume EXTENDED_YEAR has been set.
3156	* @param millis milliseconds of the date fields
3157	* @param millisInDay milliseconds of the time fields; may be out
3158	* or range.
3159	* @stable ICU 2.0
3160	*/
3161	int32_t Calendar::computeZoneOffset(double millis, double millisInDay, UErrorCode &ec) {
3162	int32_t rawOffset, dstOffset;
3163	UDate wall = millis + millisInDay;
3164	BasicTimeZone* btz = getBasicTimeZone();
3165	if (btz) {
3166	int duplicatedTimeOpt = (fRepeatedWallTime == UCAL_WALLTIME_FIRST) ? BasicTimeZone::kFormer : BasicTimeZone::kLatter;
3167	int nonExistingTimeOpt = (fSkippedWallTime == UCAL_WALLTIME_FIRST) ? BasicTimeZone::kLatter : BasicTimeZone::kFormer;
3168	btz->getOffsetFromLocal(wall, nonExistingTimeOpt, duplicatedTimeOpt, rawOffset, dstOffset, ec);
3169	} else {
3170	const TimeZone& tz = getTimeZone();
3171	// By default, TimeZone::getOffset behaves UCAL_WALLTIME_LAST for both.
3172	tz.getOffset(wall, TRUE, rawOffset, dstOffset, ec);
3173
3174	UBool sawRecentNegativeShift = FALSE;
3175	if (fRepeatedWallTime == UCAL_WALLTIME_FIRST) {
3176	// Check if the given wall time falls into repeated time range
3177	UDate tgmt = wall - (rawOffset + dstOffset);
3178
3179	// Any negative zone transition within last 6 hours?
3180	// Note: The maximum historic negative zone transition is -3 hours in the tz database.
3181	// 6 hour window would be sufficient for this purpose.
3182	int32_t tmpRaw, tmpDst;
3183	tz.getOffset(tgmt - `6``60``60`*`1000`, FALSE, tmpRaw, tmpDst, ec);
3184	int32_t offsetDelta = (rawOffset + dstOffset) - (tmpRaw + tmpDst);
3185
3186	U_ASSERT(offsetDelta < -`6``60``60`*`1000`);
3187	if (offsetDelta < `0`) {
3188	sawRecentNegativeShift = TRUE;
3189	// Negative shift within last 6 hours. When UCAL_WALLTIME_FIRST is used and the given wall time falls
3190	// into the repeated time range, use offsets before the transition.
3191	// Note: If it does not fall into the repeated time range, offsets remain unchanged below.
3192	tz.getOffset(wall + offsetDelta, TRUE, rawOffset, dstOffset, ec);
3193	}
3194	}
3195	if (!sawRecentNegativeShift && fSkippedWallTime == UCAL_WALLTIME_FIRST) {
3196	// When skipped wall time option is WALLTIME_FIRST,
3197	// recalculate offsets from the resolved time (non-wall).
3198	// When the given wall time falls into skipped wall time,
3199	// the offsets will be based on the zone offsets AFTER
3200	// the transition (which means, earliest possibe interpretation).
3201	UDate tgmt = wall - (rawOffset + dstOffset);
3202	tz.getOffset(tgmt, FALSE, rawOffset, dstOffset, ec);
3203	}
3204	}
3205	return rawOffset + dstOffset;
3206	}
3207
3208	int32_t Calendar::computeJulianDay()
3209	{
3210	// We want to see if any of the date fields is newer than the
3211	// JULIAN_DAY. If not, then we use JULIAN_DAY. If so, then we do
3212	// the normal resolution. We only use JULIAN_DAY if it has been
3213	// set by the user. This makes it possible for the caller to set
3214	// the calendar to a time and call clear(MONTH) to reset the MONTH
3215	// to January. This is legacy behavior. Without this,
3216	// clear(MONTH) has no effect, since the internally set JULIAN_DAY
3217	// is used.
3218	if (fStamp[UCAL_JULIAN_DAY] >= (int32_t)kMinimumUserStamp) {
3219	int32_t bestStamp = newestStamp(UCAL_ERA, UCAL_DAY_OF_WEEK_IN_MONTH, kUnset);
3220	bestStamp = newestStamp(UCAL_YEAR_WOY, UCAL_EXTENDED_YEAR, bestStamp);
3221	if (bestStamp <= fStamp[UCAL_JULIAN_DAY]) {
3222	return internalGet(UCAL_JULIAN_DAY);
3223	}
3224	}
3225
3226	UCalendarDateFields bestField = resolveFields(getFieldResolutionTable());
3227	if (bestField == UCAL_FIELD_COUNT) {
3228	bestField = UCAL_DAY_OF_MONTH;
3229	}
3230
3231	return handleComputeJulianDay(bestField);
3232	}
3233
3234	// -------------------------------------------
3235
3236	int32_t Calendar::handleComputeJulianDay(UCalendarDateFields bestField) {
3237	UBool useMonth = (bestField == UCAL_DAY_OF_MONTH \|\|
3238	bestField == UCAL_WEEK_OF_MONTH \|\|
3239	bestField == UCAL_DAY_OF_WEEK_IN_MONTH);
3240	int32_t year;
3241
3242	if (bestField == UCAL_WEEK_OF_YEAR && newerField(UCAL_YEAR_WOY, UCAL_YEAR) == UCAL_YEAR_WOY) {
3243	year = internalGet(UCAL_YEAR_WOY);
3244	} else {
3245	year = handleGetExtendedYear();
3246	}
3247
3248	internalSet(UCAL_EXTENDED_YEAR, year);
3249
3250	#if defined (U_DEBUG_CAL)
3251	fprintf(stderr, "%s:%d: bestField= %s - y=%d\n", __FILE__, __LINE__, fldName(bestField), year);
3252	#endif
3253
3254	// Get the Julian day of the day BEFORE the start of this year.
3255	// If useMonth is true, get the day before the start of the month.
3256
3257	// give calendar subclass a chance to have a default 'first' month
3258	int32_t month;
3259
3260	if(isSet(UCAL_MONTH)) {
3261	month = internalGet(UCAL_MONTH);
3262	} else {
3263	month = getDefaultMonthInYear(year);
3264	}
3265
3266	int32_t julianDay = handleComputeMonthStart(year, useMonth ? month : `0`, useMonth);
3267
3268	if (bestField == UCAL_DAY_OF_MONTH) {
3269
3270	// give calendar subclass a chance to have a default 'first' dom
3271	int32_t dayOfMonth;
3272	if(isSet(UCAL_DAY_OF_MONTH)) {
3273	dayOfMonth = internalGet(UCAL_DAY_OF_MONTH,`1`);
3274	} else {
3275	dayOfMonth = getDefaultDayInMonth(year, month);
3276	}
3277	return julianDay + dayOfMonth;
3278	}
3279
3280	if (bestField == UCAL_DAY_OF_YEAR) {
3281	return julianDay + internalGet(UCAL_DAY_OF_YEAR);
3282	}
3283
3284	int32_t firstDayOfWeek = getFirstDayOfWeek(); // Localized fdw
3285
3286	// At this point julianDay is the 0-based day BEFORE the first day of
3287	// January 1, year 1 of the given calendar. If julianDay == 0, it
3288	// specifies (Jan. 1, 1) - 1, in whatever calendar we are using (Julian
3289	// or Gregorian). (or it is before the month we are in, if useMonth is True)
3290
3291	// At this point we need to process the WEEK_OF_MONTH or
3292	// WEEK_OF_YEAR, which are similar, or the DAY_OF_WEEK_IN_MONTH.
3293	// First, perform initial shared computations. These locate the
3294	// first week of the period.
3295
3296	// Get the 0-based localized DOW of day one of the month or year.
3297	// Valid range 0..6.
3298	int32_t first = julianDayToDayOfWeek(julianDay + `1`) - firstDayOfWeek;
3299	if (first < `0`) {
3300	first += `7`;
3301	}
3302
3303	int32_t dowLocal = getLocalDOW();
3304
3305	// Find the first target DOW (dowLocal) in the month or year.
3306	// Actually, it may be just before the first of the month or year.
3307	// It will be an integer from -5..7.
3308	int32_t date = `1` - first + dowLocal;
3309
3310	if (bestField == UCAL_DAY_OF_WEEK_IN_MONTH) {
3311	// Adjust the target DOW to be in the month or year.
3312	if (date < `1`) {
3313	date += `7`;
3314	}
3315
3316	// The only trickiness occurs if the day-of-week-in-month is
3317	// negative.
3318	int32_t dim = internalGet(UCAL_DAY_OF_WEEK_IN_MONTH, `1`);
3319	if (dim >= `0`) {
3320	date += `7`*(dim - `1`);
3321
3322	} else {
3323	// Move date to the last of this day-of-week in this month,
3324	// then back up as needed. If dim==-1, we don't back up at
3325	// all. If dim==-2, we back up once, etc. Don't back up
3326	// past the first of the given day-of-week in this month.
3327	// Note that we handle -2, -3, etc. correctly, even though
3328	// values < -1 are technically disallowed.
3329	int32_t m = internalGet(UCAL_MONTH, UCAL_JANUARY);
3330	int32_t monthLength = handleGetMonthLength(year, m);
3331	date += ((monthLength - date) / `7` + dim + `1`) * `7`;
3332	}
3333	} else {
3334	#if defined (U_DEBUG_CAL)
3335	fprintf(stderr, "%s:%d - bf= %s\n", __FILE__, __LINE__, fldName(bestField));
3336	#endif
3337
3338	if(bestField == UCAL_WEEK_OF_YEAR) { // ------------------------------------- WOY -------------
3339	if(!isSet(UCAL_YEAR_WOY) \|\| // YWOY not set at all or
3340	( (resolveFields(kYearPrecedence) != UCAL_YEAR_WOY) // YWOY doesn't have precedence
3341	&& (fStamp[UCAL_YEAR_WOY]!=kInternallySet) ) ) // (excluding where all fields are internally set - then YWOY is used)
3342	{
3343	// need to be sure to stay in 'real' year.
3344	int32_t woy = internalGet(bestField);
3345
3346	int32_t nextJulianDay = handleComputeMonthStart(year+`1`, `0`, FALSE); // jd of day before jan 1
3347	int32_t nextFirst = julianDayToDayOfWeek(nextJulianDay + `1`) - firstDayOfWeek;
3348
3349	if (nextFirst < `0`) { // 0..6 ldow of Jan 1
3350	nextFirst += `7`;
3351	}
3352
3353	if(woy==`1`) { // FIRST WEEK ---------------------------------
3354	#if defined (U_DEBUG_CAL)
3355	fprintf(stderr, "%s:%d - woy=%d, yp=%d, nj(%d)=%d, nf=%d", __FILE__, __LINE__,
3356	internalGet(bestField), resolveFields(kYearPrecedence), year+`1`,
3357	nextJulianDay, nextFirst);
3358
3359	fprintf(stderr, " next: %d DFW, min=%d \n", (`7`-nextFirst), getMinimalDaysInFirstWeek() );
3360	#endif
3361
3362	// nextFirst is now the localized DOW of Jan 1 of y-woy+1
3363	if((nextFirst > `0`) && // Jan 1 starts on FDOW
3364	(`7`-nextFirst) >= getMinimalDaysInFirstWeek()) // or enough days in the week
3365	{
3366	// Jan 1 of (yearWoy+1) is in yearWoy+1 - recalculate JD to next year
3367	#if defined (U_DEBUG_CAL)
3368	fprintf(stderr, "%s:%d - was going to move JD from %d to %d [d%d]\n", __FILE__, __LINE__,
3369	julianDay, nextJulianDay, (nextJulianDay-julianDay));
3370	#endif
3371	julianDay = nextJulianDay;
3372
3373	// recalculate 'first' [0-based local dow of jan 1]
3374	first = julianDayToDayOfWeek(julianDay + `1`) - firstDayOfWeek;
3375	if (first < `0`) {
3376	first += `7`;
3377	}
3378	// recalculate date.
3379	date = `1` - first + dowLocal;
3380	}
3381	} else if(woy>=getLeastMaximum(bestField)) {
3382	// could be in the last week- find out if this JD would overstep
3383	int32_t testDate = date;
3384	if ((`7` - first) < getMinimalDaysInFirstWeek()) {
3385	testDate += `7`;
3386	}
3387
3388	// Now adjust for the week number.
3389	testDate += `7` * (woy - `1`);
3390
3391	#if defined (U_DEBUG_CAL)
3392	fprintf(stderr, "%s:%d - y=%d, y-1=%d doy%d, njd%d (C.F. %d)\n",
3393	__FILE__, __LINE__, year, year-`1`, testDate, julianDay+testDate, nextJulianDay);
3394	#endif
3395	if(julianDay+testDate > nextJulianDay) { // is it past Dec 31? (nextJulianDay is day BEFORE year+1's Jan 1)
3396	// Fire up the calculating engines.. retry YWOY = (year-1)
3397	julianDay = handleComputeMonthStart(year-`1`, `0`, FALSE); // jd before Jan 1 of previous year
3398	first = julianDayToDayOfWeek(julianDay + `1`) - firstDayOfWeek; // 0 based local dow of first week
3399
3400	if(first < `0`) { // 0..6
3401	first += `7`;
3402	}
3403	date = `1` - first + dowLocal;
3404
3405	#if defined (U_DEBUG_CAL)
3406	fprintf(stderr, "%s:%d - date now %d, jd%d, ywoy%d\n",
3407	__FILE__, __LINE__, date, julianDay, year-`1`);
3408	#endif
3409
3410
3411	} / correction needed /
3412	} / leastmaximum /
3413	} / resolvefields(year) != year_woy /
3414	} / bestfield != week_of_year /
3415
3416	// assert(bestField == WEEK_OF_MONTH \|\| bestField == WEEK_OF_YEAR)
3417	// Adjust for minimal days in first week
3418	if ((`7` - first) < getMinimalDaysInFirstWeek()) {
3419	date += `7`;
3420	}
3421
3422	// Now adjust for the week number.
3423	date += `7` * (internalGet(bestField) - `1`);
3424	}
3425
3426	return julianDay + date;
3427	}
3428
3429	int32_t
3430	Calendar::getDefaultMonthInYear(int32_t /eyear/)
3431	{
3432	return `0`;
3433	}
3434
3435	int32_t
3436	Calendar::getDefaultDayInMonth(int32_t /eyear/, int32_t /month/)
3437	{
3438	return `1`;
3439	}
3440
3441
3442	int32_t Calendar::getLocalDOW()
3443	{
3444	// Get zero-based localized DOW, valid range 0..6. This is the DOW
3445	// we are looking for.
3446	int32_t dowLocal = `0`;
3447	switch (resolveFields(kDOWPrecedence)) {
3448	case UCAL_DAY_OF_WEEK:
3449	dowLocal = internalGet(UCAL_DAY_OF_WEEK) - fFirstDayOfWeek;
3450	break;
3451	case UCAL_DOW_LOCAL:
3452	dowLocal = internalGet(UCAL_DOW_LOCAL) - `1`;
3453	break;
3454	default:
3455	break;
3456	}
3457	dowLocal = dowLocal % `7`;
3458	if (dowLocal < `0`) {
3459	dowLocal += `7`;
3460	}
3461	return dowLocal;
3462	}
3463
3464	int32_t Calendar::handleGetExtendedYearFromWeekFields(int32_t yearWoy, int32_t woy)
3465	{
3466	// We have UCAL_YEAR_WOY and UCAL_WEEK_OF_YEAR - from those, determine
3467	// what year we fall in, so that other code can set it properly.
3468	// (code borrowed from computeWeekFields and handleComputeJulianDay)
3469	//return yearWoy;
3470
3471	// First, we need a reliable DOW.
3472	UCalendarDateFields bestField = resolveFields(kDatePrecedence); // !! Note: if subclasses have a different table, they should override handleGetExtendedYearFromWeekFields
3473
3474	// Now, a local DOW
3475	int32_t dowLocal = getLocalDOW(); // 0..6
3476	int32_t firstDayOfWeek = getFirstDayOfWeek(); // Localized fdw
3477	int32_t jan1Start = handleComputeMonthStart(yearWoy, `0`, FALSE);
3478	int32_t nextJan1Start = handleComputeMonthStart(yearWoy+`1`, `0`, FALSE); // next year's Jan1 start
3479
3480	// At this point julianDay is the 0-based day BEFORE the first day of
3481	// January 1, year 1 of the given calendar. If julianDay == 0, it
3482	// specifies (Jan. 1, 1) - 1, in whatever calendar we are using (Julian
3483	// or Gregorian). (or it is before the month we are in, if useMonth is True)
3484
3485	// At this point we need to process the WEEK_OF_MONTH or
3486	// WEEK_OF_YEAR, which are similar, or the DAY_OF_WEEK_IN_MONTH.
3487	// First, perform initial shared computations. These locate the
3488	// first week of the period.
3489
3490	// Get the 0-based localized DOW of day one of the month or year.
3491	// Valid range 0..6.
3492	int32_t first = julianDayToDayOfWeek(jan1Start + `1`) - firstDayOfWeek;
3493	if (first < `0`) {
3494	first += `7`;
3495	}
3496
3497	//// (nextFirst was not used below)
3498	// int32_t nextFirst = julianDayToDayOfWeek(nextJan1Start + 1) - firstDayOfWeek;
3499	// if (nextFirst < 0) {
3500	// nextFirst += 7;
3501	//}
3502
3503	int32_t minDays = getMinimalDaysInFirstWeek();
3504	UBool jan1InPrevYear = FALSE; // January 1st in the year of WOY is the 1st week? (i.e. first week is < minimal )
3505	//UBool nextJan1InPrevYear = FALSE; // January 1st of Year of WOY + 1 is in the first week?
3506
3507	if((`7` - first) < minDays) {
3508	jan1InPrevYear = TRUE;
3509	}
3510
3511	// if((7 - nextFirst) < minDays) {
3512	// nextJan1InPrevYear = TRUE;
3513	// }
3514
3515	switch(bestField) {
3516	case UCAL_WEEK_OF_YEAR:
3517	if(woy == `1`) {
3518	if(jan1InPrevYear == TRUE) {
3519	// the first week of January is in the previous year
3520	// therefore WOY1 is always solidly within yearWoy
3521	return yearWoy;
3522	} else {
3523	// First WOY is split between two years
3524	if( dowLocal < first) { // we are prior to Jan 1
3525	return yearWoy-`1`; // previous year
3526	} else {
3527	return yearWoy; // in this year
3528	}
3529	}
3530	} else if(woy >= getLeastMaximum(bestField)) {
3531	// we _might_ be in the last week..
3532	int32_t jd = // Calculate JD of our target day:
3533	jan1Start + // JD of Jan 1
3534	(`7`-first) + // days in the first week (Jan 1.. )
3535	(woy-`1`)`7` + // add the weeks of the year*
3536	dowLocal; // the local dow (0..6) of last week
3537	if(jan1InPrevYear==FALSE) {
3538	jd -= `7`; // woy already includes Jan 1's week.
3539	}
3540
3541	if( (jd+`1`) >= nextJan1Start ) {
3542	// we are in week 52 or 53 etc. - actual year is yearWoy+1
3543	return yearWoy+`1`;
3544	} else {
3545	// still in yearWoy;
3546	return yearWoy;
3547	}
3548	} else {
3549	// we're not possibly in the last week -must be ywoy
3550	return yearWoy;
3551	}
3552
3553	case UCAL_DATE:
3554	if((internalGet(UCAL_MONTH)==`0`) &&
3555	(woy >= getLeastMaximum(UCAL_WEEK_OF_YEAR))) {
3556	return yearWoy+`1`; // month 0, late woy = in the next year
3557	} else if(woy==`1`) {
3558	//if(nextJan1InPrevYear) {
3559	if(internalGet(UCAL_MONTH)==`0`) {
3560	return yearWoy;
3561	} else {
3562	return yearWoy-`1`;
3563	}
3564	//}
3565	}
3566
3567	//(internalGet(UCAL_DATE) <= (7-first)) / && in minDow / ) {
3568	//within 1st week and in this month..
3569	//return yearWoy+1;
3570	return yearWoy;
3571
3572	default: // assume the year is appropriate
3573	return yearWoy;
3574	}
3575	}
3576
3577	int32_t Calendar::handleGetMonthLength(int32_t extendedYear, int32_t month) const
3578	{
3579	return handleComputeMonthStart(extendedYear, month+`1`, TRUE) -
3580	handleComputeMonthStart(extendedYear, month, TRUE);
3581	}
3582
3583	int32_t Calendar::handleGetYearLength(int32_t eyear) const {
3584	return handleComputeMonthStart(eyear+`1`, `0`, FALSE) -
3585	handleComputeMonthStart(eyear, `0`, FALSE);
3586	}
3587
3588	int32_t
3589	Calendar::getActualMaximum(UCalendarDateFields field, UErrorCode& status) const
3590	{
3591	int32_t result;
3592	switch (field) {
3593	case UCAL_DATE:
3594	{
3595	if(U_FAILURE(status)) return `0`;
3596	Calendar *cal = clone();
3597	if(!cal) { status = U_MEMORY_ALLOCATION_ERROR; return `0`; }
3598	cal->setLenient(TRUE);
3599	cal->prepareGetActual(field,FALSE,status);
3600	result = handleGetMonthLength(cal->get(UCAL_EXTENDED_YEAR, status), cal->get(UCAL_MONTH, status));
3601	delete cal;
3602	}
3603	break;
3604
3605	case UCAL_DAY_OF_YEAR:
3606	{
3607	if(U_FAILURE(status)) return `0`;
3608	Calendar *cal = clone();
3609	if(!cal) { status = U_MEMORY_ALLOCATION_ERROR; return `0`; }
3610	cal->setLenient(TRUE);
3611	cal->prepareGetActual(field,FALSE,status);
3612	result = handleGetYearLength(cal->get(UCAL_EXTENDED_YEAR, status));
3613	delete cal;
3614	}
3615	break;
3616
3617	case UCAL_DAY_OF_WEEK:
3618	case UCAL_AM_PM:
3619	case UCAL_HOUR:
3620	case UCAL_HOUR_OF_DAY:
3621	case UCAL_MINUTE:
3622	case UCAL_SECOND:
3623	case UCAL_MILLISECOND:
3624	case UCAL_ZONE_OFFSET:
3625	case UCAL_DST_OFFSET:
3626	case UCAL_DOW_LOCAL:
3627	case UCAL_JULIAN_DAY:
3628	case UCAL_MILLISECONDS_IN_DAY:
3629	// These fields all have fixed minima/maxima
3630	result = getMaximum(field);
3631	break;
3632
3633	default:
3634	// For all other fields, do it the hard way....
3635	result = getActualHelper(field, getLeastMaximum(field), getMaximum(field),status);
3636	break;
3637	}
3638	return result;
3639	}
3640
3641
3642	/**
3643	* Prepare this calendar for computing the actual minimum or maximum.
3644	* This method modifies this calendar's fields; it is called on a
3645	* temporary calendar.
3646	*
3647	* <p>Rationale: The semantics of getActualXxx() is to return the
3648	* maximum or minimum value that the given field can take, taking into
3649	* account other relevant fields. In general these other fields are
3650	* larger fields. For example, when computing the actual maximum
3651	* DATE, the current value of DATE itself is ignored,
3652	* as is the value of any field smaller.
3653	*
3654	* <p>The time fields all have fixed minima and maxima, so we don't
3655	* need to worry about them. This also lets us set the
3656	* MILLISECONDS_IN_DAY to zero to erase any effects the time fields
3657	* might have when computing date fields.
3658	*
3659	* <p>DAY_OF_WEEK is adjusted specially for the WEEK_OF_MONTH and
3660	* WEEK_OF_YEAR fields to ensure that they are computed correctly.
3661	* @internal
3662	*/
3663	void Calendar::prepareGetActual(UCalendarDateFields field, UBool isMinimum, UErrorCode &status)
3664	{
3665	set(UCAL_MILLISECONDS_IN_DAY, `0`);
3666
3667	switch (field) {
3668	case UCAL_YEAR:
3669	case UCAL_EXTENDED_YEAR:
3670	set(UCAL_DAY_OF_YEAR, getGreatestMinimum(UCAL_DAY_OF_YEAR));
3671	break;
3672
3673	case UCAL_YEAR_WOY:
3674	set(UCAL_WEEK_OF_YEAR, getGreatestMinimum(UCAL_WEEK_OF_YEAR));
3675	U_FALLTHROUGH;
3676	case UCAL_MONTH:
3677	set(UCAL_DATE, getGreatestMinimum(UCAL_DATE));
3678	break;
3679
3680	case UCAL_DAY_OF_WEEK_IN_MONTH:
3681	// For dowim, the maximum occurs for the DOW of the first of the
3682	// month.
3683	set(UCAL_DATE, `1`);
3684	set(UCAL_DAY_OF_WEEK, get(UCAL_DAY_OF_WEEK, status)); // Make this user set
3685	break;
3686
3687	case UCAL_WEEK_OF_MONTH:
3688	case UCAL_WEEK_OF_YEAR:
3689	// If we're counting weeks, set the day of the week to either the
3690	// first or last localized DOW. We know the last week of a month
3691	// or year will contain the first day of the week, and that the
3692	// first week will contain the last DOW.
3693	{
3694	int32_t dow = fFirstDayOfWeek;
3695	if (isMinimum) {
3696	dow = (dow + `6`) % `7`; // set to last DOW
3697	if (dow < UCAL_SUNDAY) {
3698	dow += `7`;
3699	}
3700	}
3701	#if defined (U_DEBUG_CAL)
3702	fprintf(stderr, "prepareGetActualHelper(WOM/WOY) - dow=%d\n", dow);
3703	#endif
3704	set(UCAL_DAY_OF_WEEK, dow);
3705	}
3706	break;
3707	default:
3708	break;
3709	}
3710
3711	// Do this last to give it the newest time stamp
3712	set(field, getGreatestMinimum(field));
3713	}
3714
3715	int32_t Calendar::getActualHelper(UCalendarDateFields field, int32_t startValue, int32_t endValue, UErrorCode &status) const
3716	{
3717	#if defined (U_DEBUG_CAL)
3718	fprintf(stderr, "getActualHelper(%d,%d .. %d, %s)\n", field, startValue, endValue, u_errorName(status));
3719	#endif
3720	if (startValue == endValue) {
3721	// if we know that the maximum value is always the same, just return it
3722	return startValue;
3723	}
3724
3725	int32_t delta = (endValue > startValue) ? `1` : -`1`;
3726
3727	// clone the calendar so we don't mess with the real one, and set it to
3728	// accept anything for the field values
3729	if(U_FAILURE(status)) return startValue;
3730	Calendar *work = clone();
3731	if(!work) { status = U_MEMORY_ALLOCATION_ERROR; return startValue; }
3732
3733	// need to resolve time here, otherwise, fields set for actual limit
3734	// may cause conflict with fields previously set (but not yet resolved).
3735	work->complete(status);
3736
3737	work->setLenient(TRUE);
3738	work->prepareGetActual(field, delta < `0`, status);
3739
3740	// now try each value from the start to the end one by one until
3741	// we get a value that normalizes to another value. The last value that
3742	// normalizes to itself is the actual maximum for the current date
3743	work->set(field, startValue);
3744
3745	// prepareGetActual sets the first day of week in the same week with
3746	// the first day of a month. Unlike WEEK_OF_YEAR, week number for the
3747	// week which contains days from both previous and current month is
3748	// not unique. For example, last several days in the previous month
3749	// is week 5, and the rest of week is week 1.
3750	int32_t result = startValue;
3751	if ((work->get(field, status) != startValue
3752	&& field != UCAL_WEEK_OF_MONTH && delta > `0` ) \|\| U_FAILURE(status)) {
3753	#if defined (U_DEBUG_CAL)
3754	fprintf(stderr, "getActualHelper(fld %d) - got %d (not %d) - %s\n", field, work->get(field,status), startValue, u_errorName(status));
3755	#endif
3756	} else {
3757	do {
3758	startValue += delta;
3759	work->add(field, delta, status);
3760	if (work->get(field, status) != startValue \|\| U_FAILURE(status)) {
3761	#if defined (U_DEBUG_CAL)
3762	fprintf(stderr, "getActualHelper(fld %d) - got %d (not %d), BREAK - %s\n", field, work->get(field,status), startValue, u_errorName(status));
3763	#endif
3764	break;
3765	}
3766	result = startValue;
3767	} while (startValue != endValue);
3768	}
3769	delete work;
3770	#if defined (U_DEBUG_CAL)
3771	fprintf(stderr, "getActualHelper(%d) = %d\n", field, result);
3772	#endif
3773	return result;
3774	}
3775
3776
3777
3778
3779	// -------------------------------------
3780
3781	void
3782	Calendar::setWeekData(const Locale& desiredLocale, const char *type, UErrorCode& status)
3783	{
3784
3785	if (U_FAILURE(status)) return;
3786
3787	fFirstDayOfWeek = UCAL_SUNDAY;
3788	fMinimalDaysInFirstWeek = `1`;
3789	fWeekendOnset = UCAL_SATURDAY;
3790	fWeekendOnsetMillis = `0`;
3791	fWeekendCease = UCAL_SUNDAY;
3792	fWeekendCeaseMillis = `86400000`; // 2460601000*
3793
3794	// Since week and weekend data is territory based instead of language based,
3795	// we may need to tweak the locale that we are using to try to get the appropriate
3796	// values, using the following logic:
3797	// 1). If the locale has a language but no territory, use the territory as defined by
3798	// the likely subtags.
3799	// 2). If the locale has a script designation then we ignore it,
3800	// then remove it ( i.e. "en_Latn_US" becomes "en_US" )
3801
3802	UErrorCode myStatus = U_ZERO_ERROR;
3803
3804	Locale min(desiredLocale);
3805	min.minimizeSubtags(myStatus);
3806	Locale useLocale;
3807	if ( uprv_strlen(desiredLocale.getCountry()) == `0` \|\|
3808	(uprv_strlen(desiredLocale.getScript()) > `0` && uprv_strlen(min.getScript()) == `0`) ) {
3809	myStatus = U_ZERO_ERROR;
3810	Locale max(desiredLocale);
3811	max.addLikelySubtags(myStatus);
3812	useLocale = Locale (max.getLanguage(),max.getCountry());
3813	} else {
3814	useLocale = desiredLocale;
3815	}
3816
3817	/ The code here is somewhat of a hack, since week data and weekend data aren't really tied to*
3818	a specific calendar, they aren't truly locale data. But this is the only place where valid and
3819	actual locale can be set, so we take a shot at it here by loading a representative resource
3820	from the calendar data. The code used to use the dateTimeElements resource to get first day
3821	of week data, but this was moved to supplemental data under ticket 7755. (JCE) /*
3822
3823	// Get the monthNames resource bundle for the calendar 'type'. Fallback to gregorian if the resource is not
3824	// found.
3825	LocalUResourceBundlePointer calData(ures_open(NULL, useLocale.getBaseName(), &status));
3826	ures_getByKey(calData.getAlias(), gCalendar, calData.getAlias(), &status);
3827
3828	LocalUResourceBundlePointer monthNames;
3829	if (type != NULL && *type != `'\0'` && uprv_strcmp(type, gGregorian) != `0`) {
3830	monthNames.adoptInstead(ures_getByKeyWithFallback(calData.getAlias(), type, NULL, &status));
3831	ures_getByKeyWithFallback(monthNames.getAlias(), gMonthNames,
3832	monthNames.getAlias(), &status);
3833	}
3834
3835	if (monthNames.isNull() \|\| status == U_MISSING_RESOURCE_ERROR) {
3836	status = U_ZERO_ERROR;
3837	monthNames.adoptInstead(ures_getByKeyWithFallback(calData.getAlias(), gGregorian,
3838	monthNames.orphan(), &status));
3839	ures_getByKeyWithFallback(monthNames.getAlias(), gMonthNames,
3840	monthNames.getAlias(), &status);
3841	}
3842
3843	if (U_SUCCESS(status)) {
3844	U_LOCALE_BASED(locBased,*this);
3845	locBased.setLocaleIDs(ures_getLocaleByType(monthNames.getAlias(), ULOC_VALID_LOCALE, &status),
3846	ures_getLocaleByType(monthNames.getAlias(), ULOC_ACTUAL_LOCALE, &status));
3847	} else {
3848	status = U_USING_FALLBACK_WARNING;
3849	return;
3850	}
3851
3852	char region[ULOC_COUNTRY_CAPACITY];
3853	(void)ulocimp_getRegionForSupplementalData(desiredLocale.getName(), TRUE, region, sizeof(region), &status);
3854
3855	// Read week data values from supplementalData week data
3856	UResourceBundle *rb = ures_openDirect(NULL, "supplementalData", &status);
3857	ures_getByKey(rb, "weekData", rb, &status);
3858	UResourceBundle *weekData = ures_getByKey(rb, region, NULL, &status);
3859	if (status == U_MISSING_RESOURCE_ERROR && rb != NULL) {
3860	status = U_ZERO_ERROR;
3861	weekData = ures_getByKey(rb, "001", NULL, &status);
3862	}
3863
3864	if (U_FAILURE(status)) {
3865	status = U_USING_FALLBACK_WARNING;
3866	} else {
3867	int32_t arrLen;
3868	const int32_t *weekDataArr = ures_getIntVector(weekData,&arrLen,&status);
3869	if( U_SUCCESS(status) && arrLen == `6`
3870	&& `1` <= weekDataArr[`0`] && weekDataArr[`0`] <= `7`
3871	&& `1` <= weekDataArr[`1`] && weekDataArr[`1`] <= `7`
3872	&& `1` <= weekDataArr[`2`] && weekDataArr[`2`] <= `7`
3873	&& `1` <= weekDataArr[`4`] && weekDataArr[`4`] <= `7`) {
3874	fFirstDayOfWeek = (UCalendarDaysOfWeek)weekDataArr[`0`];
3875	fMinimalDaysInFirstWeek = (uint8_t)weekDataArr[`1`];
3876	fWeekendOnset = (UCalendarDaysOfWeek)weekDataArr[`2`];
3877	fWeekendOnsetMillis = weekDataArr[`3`];
3878	fWeekendCease = (UCalendarDaysOfWeek)weekDataArr[`4`];
3879	fWeekendCeaseMillis = weekDataArr[`5`];
3880	} else {
3881	status = U_INVALID_FORMAT_ERROR;
3882	}
3883	}
3884	ures_close(weekData);
3885	ures_close(rb);
3886	}
3887
3888	/**
3889	* Recompute the time and update the status fields isTimeSet
3890	* and areFieldsSet. Callers should check isTimeSet and only
3891	* call this method if isTimeSet is false.
3892	*/
3893	void
3894	Calendar::updateTime(UErrorCode& status)
3895	{
3896	computeTime(status);
3897	if(U_FAILURE(status))
3898	return;
3899
3900	// If we are lenient, we need to recompute the fields to normalize
3901	// the values. Also, if we haven't set all the fields yet (i.e.,
3902	// in a newly-created object), we need to fill in the fields. [LIU]
3903	if (isLenient() \|\| ! fAreAllFieldsSet)
3904	fAreFieldsSet = FALSE;
3905
3906	fIsTimeSet = TRUE;
3907	fAreFieldsVirtuallySet = FALSE;
3908	}
3909
3910	Locale
3911	Calendar::getLocale(ULocDataLocaleType type, UErrorCode& status) const {
3912	U_LOCALE_BASED(locBased, *this);
3913	return locBased.getLocale(type, status);
3914	}
3915
3916	const char *
3917	Calendar::getLocaleID(ULocDataLocaleType type, UErrorCode& status) const {
3918	U_LOCALE_BASED(locBased, *this);
3919	return locBased.getLocaleID(type, status);
3920	}
3921
3922	void
3923	Calendar::recalculateStamp() {
3924	int32_t index;
3925	int32_t currentValue;
3926	int32_t j, i;
3927
3928	fNextStamp = `1`;
3929
3930	for (j = `0`; j < UCAL_FIELD_COUNT; j++) {
3931	currentValue = STAMP_MAX;
3932	index = -`1`;
3933	for (i = `0`; i < UCAL_FIELD_COUNT; i++) {
3934	if (fStamp[i] > fNextStamp && fStamp[i] < currentValue) {
3935	currentValue = fStamp[i];
3936	index = i;
3937	}
3938	}
3939
3940	if (index >= `0`) {
3941	fStamp[index] = ++fNextStamp;
3942	} else {
3943	break;
3944	}
3945	}
3946	fNextStamp++;
3947	}
3948
3949	// Deprecated function. This doesn't need to be inline.
3950	void
3951	Calendar::internalSet(EDateFields field, int32_t value)
3952	{
3953	internalSet((UCalendarDateFields) field, value);
3954	}
3955
3956	BasicTimeZone*
3957	Calendar::getBasicTimeZone(void) const {
3958	if (dynamic_cast<const OlsonTimeZone *>(fZone) != NULL
3959	\|\| dynamic_cast<const SimpleTimeZone *>(fZone) != NULL
3960	\|\| dynamic_cast<const RuleBasedTimeZone *>(fZone) != NULL
3961	\|\| dynamic_cast<const VTimeZone *>(fZone) != NULL) {
3962	return (BasicTimeZone*)fZone;
3963	}
3964	return NULL;
3965	}
3966
3967	U_NAMESPACE_END
3968
3969	#endif /* #if !UCONFIG_NO_FORMATTING */
3970
3971
3972	//eof
3973

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