tznames_impl.cpp source code [Skia/third_party/externals/icu/source/i18n/tznames_impl.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) 2011-2016, International Business Machines Corporation and
6	* others. All Rights Reserved.
7	*******************************************************************************
8	*
9	* File TZNAMES_IMPL.CPP
10	*
11	*******************************************************************************
12	*/
13
14	#include "unicode/utypes.h"
15
16	#if !UCONFIG_NO_FORMATTING
17
18	#include "unicode/strenum.h"
19	#include "unicode/ustring.h"
20	#include "unicode/timezone.h"
21	#include "unicode/utf16.h"
22
23	#include "tznames_impl.h"
24	#include "bytesinkutil.h"
25	#include "charstr.h"
26	#include "cmemory.h"
27	#include "cstring.h"
28	#include "uassert.h"
29	#include "mutex.h"
30	#include "resource.h"
31	#include "ulocimp.h"
32	#include "uresimp.h"
33	#include "ureslocs.h"
34	#include "zonemeta.h"
35	#include "ucln_in.h"
36	#include "uvector.h"
37	#include "olsontz.h"
38
39	U_NAMESPACE_BEGIN
40
41	#define ZID_KEY_MAX 128
42	#define MZ_PREFIX_LEN 5
43
44	static const char gZoneStrings[] = "zoneStrings";
45	static const char gMZPrefix[] = "meta:";
46
47	static const char EMPTY[] = "<empty>"; // place holder for empty ZNames
48	static const char DUMMY_LOADER[] = "<dummy>"; // place holder for dummy ZNamesLoader
49	static const UChar NO_NAME[] = { `0` }; // for empty no-fallback time zone names
50
51	// stuff for TZDBTimeZoneNames
52	static const char* TZDBNAMES_KEYS[] = {"ss", "sd"};
53	static const int32_t TZDBNAMES_KEYS_SIZE = UPRV_LENGTHOF(TZDBNAMES_KEYS);
54
55	static UMutex gDataMutex;
56
57	static UHashtable* gTZDBNamesMap = NULL;
58	static icu::UInitOnce gTZDBNamesMapInitOnce = U_INITONCE_INITIALIZER;
59
60	static TextTrieMap* gTZDBNamesTrie = NULL;
61	static icu::UInitOnce gTZDBNamesTrieInitOnce = U_INITONCE_INITIALIZER;
62
63	// The order in which strings are stored may be different than the order in the public enum.
64	enum UTimeZoneNameTypeIndex {
65	UTZNM_INDEX_UNKNOWN = -`1`,
66	UTZNM_INDEX_EXEMPLAR_LOCATION,
67	UTZNM_INDEX_LONG_GENERIC,
68	UTZNM_INDEX_LONG_STANDARD,
69	UTZNM_INDEX_LONG_DAYLIGHT,
70	UTZNM_INDEX_SHORT_GENERIC,
71	UTZNM_INDEX_SHORT_STANDARD,
72	UTZNM_INDEX_SHORT_DAYLIGHT,
73	UTZNM_INDEX_COUNT
74	};
75	static const UChar* const EMPTY_NAMES[UTZNM_INDEX_COUNT] = {`0`,`0`,`0`,`0`,`0`,`0`,`0`};
76
77	U_CDECL_BEGIN
78	static UBool U_CALLCONV tzdbTimeZoneNames_cleanup(void) {
79	if (gTZDBNamesMap != NULL) {
80	uhash_close(gTZDBNamesMap);
81	gTZDBNamesMap = NULL;
82	}
83	gTZDBNamesMapInitOnce.reset();
84
85	if (gTZDBNamesTrie != NULL) {
86	delete gTZDBNamesTrie;
87	gTZDBNamesTrie = NULL;
88	}
89	gTZDBNamesTrieInitOnce.reset();
90
91	return TRUE;
92	}
93	U_CDECL_END
94
95	/**
96	* ZNameInfo stores zone name information in the trie
97	*/
98	struct ZNameInfo {
99	UTimeZoneNameType type;
100	const UChar* tzID;
101	const UChar* mzID;
102	};
103
104	/**
105	* ZMatchInfo stores zone name match information used by find method
106	*/
107	struct ZMatchInfo {
108	const ZNameInfo* znameInfo;
109	int32_t matchLength;
110	};
111
112	// Helper functions
113	static void mergeTimeZoneKey(const UnicodeString& mzID, char* result);
114
115	#define DEFAULT_CHARACTERNODE_CAPACITY 1
116
117	// ---------------------------------------------------
118	// CharacterNode class implementation
119	// ---------------------------------------------------
120	void CharacterNode::clear() {
121	uprv_memset(this, `0`, sizeof(*this));
122	}
123
124	void CharacterNode::deleteValues(UObjectDeleter *valueDeleter) {
125	if (fValues == NULL) {
126	// Do nothing.
127	} else if (!fHasValuesVector) {
128	if (valueDeleter) {
129	valueDeleter(fValues);
130	}
131	} else {
132	delete (UVector *)fValues;
133	}
134	}
135
136	void
137	CharacterNode::addValue(void value, UObjectDeleter valueDeleter, UErrorCode &status) {
138	if (U_FAILURE(status)) {
139	if (valueDeleter) {
140	valueDeleter(value);
141	}
142	return;
143	}
144	if (fValues == NULL) {
145	fValues = value;
146	} else {
147	// At least one value already.
148	if (!fHasValuesVector) {
149	// There is only one value so far, and not in a vector yet.
150	// Create a vector and add the old value.
151	UVector values = new* UVector (valueDeleter, NULL, DEFAULT_CHARACTERNODE_CAPACITY, status);
152	if (U_FAILURE(status)) {
153	if (valueDeleter) {
154	valueDeleter(value);
155	}
156	return;
157	}
158	values->addElement(fValues, status);
159	fValues = values;
160	fHasValuesVector = TRUE;
161	}
162	// Add the new value.
163	((UVector *)fValues)->addElement(value, status);
164	}
165	}
166
167	// ---------------------------------------------------
168	// TextTrieMapSearchResultHandler class implementation
169	// ---------------------------------------------------
170	TextTrieMapSearchResultHandler::~TextTrieMapSearchResultHandler(){
171	}
172
173	// ---------------------------------------------------
174	// TextTrieMap class implementation
175	// ---------------------------------------------------
176	TextTrieMap::TextTrieMap(UBool ignoreCase, UObjectDeleter *valueDeleter)
177	: fIgnoreCase(ignoreCase), fNodes(NULL), fNodesCapacity(`0`), fNodesCount(`0`),
178	fLazyContents(NULL), fIsEmpty(TRUE), fValueDeleter(valueDeleter) {
179	}
180
181	TextTrieMap::~TextTrieMap() {
182	int32_t index;
183	for (index = `0`; index < fNodesCount; ++index) {
184	fNodes[index].deleteValues(fValueDeleter);
185	}
186	uprv_free(fNodes);
187	if (fLazyContents != NULL) {
188	for (int32_t i=`0`; i<fLazyContents->size(); i+=`2`) {
189	if (fValueDeleter) {
190	fValueDeleter(fLazyContents->elementAt(i+`1`));
191	}
192	}
193	delete fLazyContents;
194	}
195	}
196
197	int32_t TextTrieMap::isEmpty() const {
198	// Use a separate field for fIsEmpty because it will remain unchanged once the
199	// Trie is built, while fNodes and fLazyContents change with the lazy init
200	// of the nodes structure. Trying to test the changing fields has
201	// thread safety complications.
202	return fIsEmpty;
203	}
204
205
206	// We defer actually building the TextTrieMap node structure until the first time a
207	// search is performed. put() simply saves the parameters in case we do
208	// eventually need to build it.
209	//
210	void
211	TextTrieMap::put(const UnicodeString &key, void *value, ZNStringPool &sp, UErrorCode &status) {
212	const UChar *s = sp.get(key, status);
213	put(s, value, status);
214	}
215
216	// This method is designed for a persistent key, such as string key stored in
217	// resource bundle.
218	void
219	TextTrieMap::put(const UChar key, void* *value, UErrorCode &status) {
220	fIsEmpty = FALSE;
221	if (fLazyContents == NULL) {
222	fLazyContents = new UVector (status);
223	if (fLazyContents == NULL) {
224	status = U_MEMORY_ALLOCATION_ERROR;
225	}
226	}
227	if (U_FAILURE(status)) {
228	if (fValueDeleter) {
229	fValueDeleter((void*) key);
230	}
231	return;
232	}
233	U_ASSERT(fLazyContents != NULL);
234
235	UChar s = const_cast<UChar >(key);
236	fLazyContents->addElement(s, status);
237	if (U_FAILURE(status)) {
238	if (fValueDeleter) {
239	fValueDeleter((void*) key);
240	}
241	return;
242	}
243
244	fLazyContents->addElement(value, status);
245	}
246
247	void
248	TextTrieMap::putImpl(const UnicodeString &key, void *value, UErrorCode &status) {
249	if (fNodes == NULL) {
250	fNodesCapacity = `512`;
251	fNodes = (CharacterNode )uprv_malloc(fNodesCapacity sizeof(CharacterNode));
252	if (fNodes == NULL) {
253	status = U_MEMORY_ALLOCATION_ERROR;
254	return;
255	}
256	fNodes[`0`].clear(); // Init root node.
257	fNodesCount = `1`;
258	}
259
260	UnicodeString foldedKey;
261	const UChar *keyBuffer;
262	int32_t keyLength;
263	if (fIgnoreCase) {
264	// Ok to use fastCopyFrom() because we discard the copy when we return.
265	foldedKey.fastCopyFrom(key).foldCase();
266	keyBuffer = foldedKey.getBuffer();
267	keyLength = foldedKey.length();
268	} else {
269	keyBuffer = key.getBuffer();
270	keyLength = key.length();
271	}
272
273	CharacterNode *node = fNodes;
274	int32_t index;
275	for (index = `0`; index < keyLength; ++index) {
276	node = addChildNode(node, keyBuffer[index], status);
277	}
278	node->addValue(value, fValueDeleter, status);
279	}
280
281	UBool
282	TextTrieMap::growNodes() {
283	if (fNodesCapacity == `0xffff`) {
284	return FALSE; // We use 16-bit node indexes.
285	}
286	int32_t newCapacity = fNodesCapacity + `1000`;
287	if (newCapacity > `0xffff`) {
288	newCapacity = `0xffff`;
289	}
290	CharacterNode newNodes = (CharacterNode )uprv_malloc(newCapacity * sizeof(CharacterNode));
291	if (newNodes == NULL) {
292	return FALSE;
293	}
294	uprv_memcpy(newNodes, fNodes, fNodesCount * sizeof(CharacterNode));
295	uprv_free(fNodes);
296	fNodes = newNodes;
297	fNodesCapacity = newCapacity;
298	return TRUE;
299	}
300
301	CharacterNode*
302	TextTrieMap::addChildNode(CharacterNode *parent, UChar c, UErrorCode &status) {
303	if (U_FAILURE(status)) {
304	return NULL;
305	}
306	// Linear search of the sorted list of children.
307	uint16_t prevIndex = `0`;
308	uint16_t nodeIndex = parent->fFirstChild;
309	while (nodeIndex > `0`) {
310	CharacterNode *current = fNodes + nodeIndex;
311	UChar childCharacter = current->fCharacter;
312	if (childCharacter == c) {
313	return current;
314	} else if (childCharacter > c) {
315	break;
316	}
317	prevIndex = nodeIndex;
318	nodeIndex = current->fNextSibling;
319	}
320
321	// Ensure capacity. Grow fNodes[] if needed.
322	if (fNodesCount == fNodesCapacity) {
323	int32_t parentIndex = (int32_t)(parent - fNodes);
324	if (!growNodes()) {
325	status = U_MEMORY_ALLOCATION_ERROR;
326	return NULL;
327	}
328	parent = fNodes + parentIndex;
329	}
330
331	// Insert a new child node with c in sorted order.
332	CharacterNode *node = fNodes + fNodesCount;
333	node->clear();
334	node->fCharacter = c;
335	node->fNextSibling = nodeIndex;
336	if (prevIndex == `0`) {
337	parent->fFirstChild = (uint16_t)fNodesCount;
338	} else {
339	fNodes[prevIndex].fNextSibling = (uint16_t)fNodesCount;
340	}
341	++fNodesCount;
342	return node;
343	}
344
345	CharacterNode*
346	TextTrieMap::getChildNode(CharacterNode parent, UChar c) const* {
347	// Linear search of the sorted list of children.
348	uint16_t nodeIndex = parent->fFirstChild;
349	while (nodeIndex > `0`) {
350	CharacterNode *current = fNodes + nodeIndex;
351	UChar childCharacter = current->fCharacter;
352	if (childCharacter == c) {
353	return current;
354	} else if (childCharacter > c) {
355	break;
356	}
357	nodeIndex = current->fNextSibling;
358	}
359	return NULL;
360	}
361
362
363	// buildTrie() - The Trie node structure is needed. Create it from the data that was
364	// saved at the time the ZoneStringFormatter was created. The Trie is only
365	// needed for parsing operations, which are less common than formatting,
366	// and the Trie is big, which is why its creation is deferred until first use.
367	void TextTrieMap::buildTrie(UErrorCode &status) {
368	if (fLazyContents != NULL) {
369	for (int32_t i=`0`; i<fLazyContents->size(); i+=`2`) {
370	const UChar key = (UChar )fLazyContents->elementAt(i);
371	void *val = fLazyContents->elementAt(i+`1`);
372	UnicodeString keyString(TRUE, key, -`1`); // Aliasing UnicodeString constructor.
373	putImpl(keyString, val, status);
374	}
375	delete fLazyContents;
376	fLazyContents = NULL;
377	}
378	}
379
380	void
381	TextTrieMap::search(const UnicodeString &text, int32_t start,
382	TextTrieMapSearchResultHandler handler, UErrorCode &status) const* {
383	{
384	// TODO: if locking the mutex for each check proves to be a performance problem,
385	// add a flag of type atomic_int32_t to class TextTrieMap, and use only
386	// the ICU atomic safe functions for assigning and testing.
387	// Don't test the pointer fLazyContents.
388	// Don't do unless it's really required.
389
390	// Mutex for protecting the lazy creation of the Trie node structure on the first call to search().
391	static UMutex TextTrieMutex;
392
393	Mutex lock(&TextTrieMutex);
394	if (fLazyContents != NULL) {
395	TextTrieMap nonConstThis = const_cast<TextTrieMap >(this);
396	nonConstThis->buildTrie(status);
397	}
398	}
399	if (fNodes == NULL) {
400	return;
401	}
402	search(fNodes, text, start, start, handler, status);
403	}
404
405	void
406	TextTrieMap::search(CharacterNode node, const* UnicodeString &text, int32_t start,
407	int32_t index, TextTrieMapSearchResultHandler handler, UErrorCode &status) const* {
408	if (U_FAILURE(status)) {
409	return;
410	}
411	if (node->hasValues()) {
412	if (!handler->handleMatch(index - start, node, status)) {
413	return;
414	}
415	if (U_FAILURE(status)) {
416	return;
417	}
418	}
419	if (fIgnoreCase) {
420	// for folding we need to get a complete code point.
421	// size of character may grow after fold operation;
422	// then we need to get result as UTF16 code units.
423	UChar32 c32 = text.char32At(index);
424	index += U16_LENGTH(c32);
425	UnicodeString tmp(c32);
426	tmp.foldCase();
427	int32_t tmpidx = `0`;
428	while (tmpidx < tmp.length()) {
429	UChar c = tmp.charAt(tmpidx++);
430	node = getChildNode(node, c);
431	if (node == NULL) {
432	break;
433	}
434	}
435	} else {
436	// here we just get the next UTF16 code unit
437	UChar c = text.charAt(index++);
438	node = getChildNode(node, c);
439	}
440	if (node != NULL) {
441	search(node, text, start, index, handler, status);
442	}
443	}
444
445	// ---------------------------------------------------
446	// ZNStringPool class implementation
447	// ---------------------------------------------------
448	static const int32_t POOL_CHUNK_SIZE = `2000`;
449	struct ZNStringPoolChunk: public UMemory {
450	ZNStringPoolChunk fNext; // Ptr to next pool chunk*
451	int32_t fLimit; // Index to start of unused area at end of fStrings
452	UChar fStrings[POOL_CHUNK_SIZE]; // Strings array
453	ZNStringPoolChunk();
454	};
455
456	ZNStringPoolChunk::ZNStringPoolChunk() {
457	fNext = NULL;
458	fLimit = `0`;
459	}
460
461	ZNStringPool::ZNStringPool(UErrorCode &status) {
462	fChunks = NULL;
463	fHash = NULL;
464	if (U_FAILURE(status)) {
465	return;
466	}
467	fChunks = new ZNStringPoolChunk;
468	if (fChunks == NULL) {
469	status = U_MEMORY_ALLOCATION_ERROR;
470	return;
471	}
472
473	fHash = uhash_open(uhash_hashUChars / keyHash /,
474	uhash_compareUChars / keyComp /,
475	uhash_compareUChars / valueComp /,
476	&status);
477	if (U_FAILURE(status)) {
478	return;
479	}
480	}
481
482	ZNStringPool::~ZNStringPool() {
483	if (fHash != NULL) {
484	uhash_close(fHash);
485	fHash = NULL;
486	}
487
488	while (fChunks != NULL) {
489	ZNStringPoolChunk *nextChunk = fChunks->fNext;
490	delete fChunks;
491	fChunks = nextChunk;
492	}
493	}
494
495	static const UChar EmptyString = `0`;
496
497	const UChar ZNStringPool::get(const* UChar *s, UErrorCode &status) {
498	const UChar *pooledString;
499	if (U_FAILURE(status)) {
500	return &EmptyString;
501	}
502
503	pooledString = static_cast<UChar *>(uhash_get(fHash, s));
504	if (pooledString != NULL) {
505	return pooledString;
506	}
507
508	int32_t length = u_strlen(s);
509	int32_t remainingLength = POOL_CHUNK_SIZE - fChunks->fLimit;
510	if (remainingLength <= length) {
511	U_ASSERT(length < POOL_CHUNK_SIZE);
512	if (length >= POOL_CHUNK_SIZE) {
513	status = U_INTERNAL_PROGRAM_ERROR;
514	return &EmptyString;
515	}
516	ZNStringPoolChunk *oldChunk = fChunks;
517	fChunks = new ZNStringPoolChunk;
518	if (fChunks == NULL) {
519	status = U_MEMORY_ALLOCATION_ERROR;
520	return &EmptyString;
521	}
522	fChunks->fNext = oldChunk;
523	}
524
525	UChar *destString = &fChunks->fStrings[fChunks->fLimit];
526	u_strcpy(destString, s);
527	fChunks->fLimit += (length + `1`);
528	uhash_put(fHash, destString, destString, &status);
529	return destString;
530	}
531
532
533	//
534	// ZNStringPool::adopt() Put a string into the hash, but do not copy the string data
535	// into the pool's storage. Used for strings from resource bundles,
536	// which will perisist for the life of the zone string formatter, and
537	// therefore can be used directly without copying.
538	const UChar ZNStringPool::adopt(const* UChar * s, UErrorCode &status) {
539	const UChar *pooledString;
540	if (U_FAILURE(status)) {
541	return &EmptyString;
542	}
543	if (s != NULL) {
544	pooledString = static_cast<UChar *>(uhash_get(fHash, s));
545	if (pooledString == NULL) {
546	UChar ncs = const_cast<UChar >(s);
547	uhash_put(fHash, ncs, ncs, &status);
548	}
549	}
550	return s;
551	}
552
553
554	const UChar ZNStringPool::get(const* UnicodeString &s, UErrorCode &status) {
555	UnicodeString &nonConstStr = const_cast<UnicodeString &>(s);
556	return this->get(nonConstStr.getTerminatedBuffer(), status);
557	}
558
559	/*
560	* freeze(). Close the hash table that maps to the pooled strings.
561	* After freezing, the pool can not be searched or added to,
562	* but all existing references to pooled strings remain valid.
563	*
564	* The main purpose is to recover the storage used for the hash.
565	*/
566	void ZNStringPool::freeze() {
567	uhash_close(fHash);
568	fHash = NULL;
569	}
570
571
572	/**
573	* This class stores name data for a meta zone or time zone.
574	*/
575	class ZNames : public UMemory {
576	private:
577	friend class TimeZoneNamesImpl;
578
579	static UTimeZoneNameTypeIndex getTZNameTypeIndex(UTimeZoneNameType type) {
580	switch(type) {
581	case UTZNM_EXEMPLAR_LOCATION: return UTZNM_INDEX_EXEMPLAR_LOCATION;
582	case UTZNM_LONG_GENERIC: return UTZNM_INDEX_LONG_GENERIC;
583	case UTZNM_LONG_STANDARD: return UTZNM_INDEX_LONG_STANDARD;
584	case UTZNM_LONG_DAYLIGHT: return UTZNM_INDEX_LONG_DAYLIGHT;
585	case UTZNM_SHORT_GENERIC: return UTZNM_INDEX_SHORT_GENERIC;
586	case UTZNM_SHORT_STANDARD: return UTZNM_INDEX_SHORT_STANDARD;
587	case UTZNM_SHORT_DAYLIGHT: return UTZNM_INDEX_SHORT_DAYLIGHT;
588	default: return UTZNM_INDEX_UNKNOWN;
589	}
590	}
591	static UTimeZoneNameType getTZNameType(UTimeZoneNameTypeIndex index) {
592	switch(index) {
593	case UTZNM_INDEX_EXEMPLAR_LOCATION: return UTZNM_EXEMPLAR_LOCATION;
594	case UTZNM_INDEX_LONG_GENERIC: return UTZNM_LONG_GENERIC;
595	case UTZNM_INDEX_LONG_STANDARD: return UTZNM_LONG_STANDARD;
596	case UTZNM_INDEX_LONG_DAYLIGHT: return UTZNM_LONG_DAYLIGHT;
597	case UTZNM_INDEX_SHORT_GENERIC: return UTZNM_SHORT_GENERIC;
598	case UTZNM_INDEX_SHORT_STANDARD: return UTZNM_SHORT_STANDARD;
599	case UTZNM_INDEX_SHORT_DAYLIGHT: return UTZNM_SHORT_DAYLIGHT;
600	default: return UTZNM_UNKNOWN;
601	}
602	}
603
604	const UChar* fNames[UTZNM_INDEX_COUNT];
605	UBool fDidAddIntoTrie;
606
607	// Whether we own the location string, if computed rather than loaded from a bundle.
608	// A meta zone names instance never has an exemplar location string.
609	UBool fOwnsLocationName;
610
611	ZNames(const UChar* names[], const UChar* locationName)
612	: fDidAddIntoTrie(FALSE) {
613	uprv_memcpy(fNames, names, sizeof(fNames));
614	if (locationName != NULL) {
615	fOwnsLocationName = TRUE;
616	fNames[UTZNM_INDEX_EXEMPLAR_LOCATION] = locationName;
617	} else {
618	fOwnsLocationName = FALSE;
619	}
620	}
621
622	public:
623	~ZNames() {
624	if (fOwnsLocationName) {
625	const UChar* locationName = fNames[UTZNM_INDEX_EXEMPLAR_LOCATION];
626	U_ASSERT(locationName != NULL);
627	uprv_free((void*) locationName);
628	}
629	}
630
631	private:
632	static void* createMetaZoneAndPutInCache(UHashtable* cache, const UChar* names[],
633	const UnicodeString& mzID, UErrorCode& status) {
634	if (U_FAILURE(status)) { return NULL; }
635	U_ASSERT(names != NULL);
636
637	// Use the persistent ID as the resource key, so we can
638	// avoid duplications.
639	// TODO: Is there a more efficient way, like intern() in Java?
640	void* key = (void*) ZoneMeta::findMetaZoneID(mzID);
641	void* value;
642	if (uprv_memcmp(names, EMPTY_NAMES, sizeof(EMPTY_NAMES)) == `0`) {
643	value = (void*) EMPTY;
644	} else {
645	value = (void) (new* ZNames (names, NULL));
646	if (value == NULL) {
647	status = U_MEMORY_ALLOCATION_ERROR;
648	return NULL;
649	}
650	}
651	uhash_put(cache, key, value, &status);
652	return value;
653	}
654
655	static void* createTimeZoneAndPutInCache(UHashtable* cache, const UChar* names[],
656	const UnicodeString& tzID, UErrorCode& status) {
657	if (U_FAILURE(status)) { return NULL; }
658	U_ASSERT(names != NULL);
659
660	// If necessary, compute the location name from the time zone name.
661	UChar* locationName = NULL;
662	if (names[UTZNM_INDEX_EXEMPLAR_LOCATION] == NULL) {
663	UnicodeString locationNameUniStr;
664	TimeZoneNamesImpl::getDefaultExemplarLocationName(tzID, locationNameUniStr);
665
666	// Copy the computed location name to the heap
667	if (locationNameUniStr.length() > `0`) {
668	const UChar* buff = locationNameUniStr.getTerminatedBuffer();
669	int32_t len = sizeof(UChar) * (locationNameUniStr.length() + `1`);
670	locationName = (UChar*) uprv_malloc(len);
671	if (locationName == NULL) {
672	status = U_MEMORY_ALLOCATION_ERROR;
673	return NULL;
674	}
675	uprv_memcpy(locationName, buff, len);
676	}
677	}
678
679	// Use the persistent ID as the resource key, so we can
680	// avoid duplications.
681	// TODO: Is there a more efficient way, like intern() in Java?
682	void* key = (void*) ZoneMeta::findTimeZoneID(tzID);
683	void* value = (void) (new* ZNames (names, locationName));
684	if (value == NULL) {
685	status = U_MEMORY_ALLOCATION_ERROR;
686	return NULL;
687	}
688	uhash_put(cache, key, value, &status);
689	return value;
690	}
691
692	const UChar* getName(UTimeZoneNameType type) const {
693	UTimeZoneNameTypeIndex index = getTZNameTypeIndex(type);
694	return index >= `0` ? fNames[index] : NULL;
695	}
696
697	void addAsMetaZoneIntoTrie(const UChar* mzID, TextTrieMap& trie, UErrorCode& status) {
698	addNamesIntoTrie(mzID, NULL, trie, status);
699	}
700	void addAsTimeZoneIntoTrie(const UChar* tzID, TextTrieMap& trie, UErrorCode& status) {
701	addNamesIntoTrie(NULL, tzID, trie, status);
702	}
703
704	void addNamesIntoTrie(const UChar* mzID, const UChar* tzID, TextTrieMap& trie,
705	UErrorCode& status) {
706	if (U_FAILURE(status)) { return; }
707	if (fDidAddIntoTrie) { return; }
708	fDidAddIntoTrie = TRUE;
709
710	for (int32_t i = `0`; i < UTZNM_INDEX_COUNT; i++) {
711	const UChar* name = fNames[i];
712	if (name != NULL) {
713	ZNameInfo nameinfo = (ZNameInfo )uprv_malloc(sizeof(ZNameInfo));
714	if (nameinfo == NULL) {
715	status = U_MEMORY_ALLOCATION_ERROR;
716	return;
717	}
718	nameinfo->mzID = mzID;
719	nameinfo->tzID = tzID;
720	nameinfo->type = getTZNameType((UTimeZoneNameTypeIndex)i);
721	trie.put(name, nameinfo, status); // trie.put() takes ownership of the key
722	if (U_FAILURE(status)) {
723	return;
724	}
725	}
726	}
727	}
728
729	public:
730	struct ZNamesLoader;
731	};
732
733	struct ZNames::ZNamesLoader : public ResourceSink {
734	const UChar *names[UTZNM_INDEX_COUNT];
735
736	ZNamesLoader() {
737	clear();
738	}
739	virtual ~ZNamesLoader();
740
741	/* Reset for loading another set of names. /
742	void clear() {
743	uprv_memcpy(names, EMPTY_NAMES, sizeof(names));
744	}
745
746	void loadMetaZone(const UResourceBundle* zoneStrings, const UnicodeString& mzID, UErrorCode& errorCode) {
747	if (U_FAILURE(errorCode)) { return; }
748
749	char key[ZID_KEY_MAX + `1`];
750	mergeTimeZoneKey(mzID, key);
751
752	loadNames(zoneStrings, key, errorCode);
753	}
754
755	void loadTimeZone(const UResourceBundle* zoneStrings, const UnicodeString& tzID, UErrorCode& errorCode) {
756	// Replace "/" with ":".
757	UnicodeString uKey(tzID);
758	for (int32_t i = `0`; i < uKey.length(); i++) {
759	if (uKey.charAt(i) == (UChar)`0x2F`) {
760	uKey.setCharAt(i, (UChar)`0x3A`);
761	}
762	}
763
764	char key[ZID_KEY_MAX + `1`];
765	uKey.extract(`0`, uKey.length(), key, sizeof(key), US_INV);
766
767	loadNames(zoneStrings, key, errorCode);
768	}
769
770	void loadNames(const UResourceBundle* zoneStrings, const char* key, UErrorCode& errorCode) {
771	U_ASSERT(zoneStrings != NULL);
772	U_ASSERT(key != NULL);
773	U_ASSERT(key[`0`] != `'\0'`);
774
775	UErrorCode localStatus = U_ZERO_ERROR;
776	clear();
777	ures_getAllItemsWithFallback(zoneStrings, key, *this, localStatus);
778
779	// Ignore errors, but propogate possible warnings.
780	if (U_SUCCESS(localStatus)) {
781	errorCode = localStatus;
782	}
783	}
784
785	void setNameIfEmpty(const char* key, const ResourceValue* value, UErrorCode& errorCode) {
786	UTimeZoneNameTypeIndex type = nameTypeFromKey(key);
787	if (type == UTZNM_INDEX_UNKNOWN) { return; }
788	if (names[type] == NULL) {
789	int32_t length;
790	// 'NO_NAME' indicates internally that this field should remain empty. It will be
791	// replaced by 'NULL' in getNames()
792	names[type] = (value == NULL) ? NO_NAME : value->getString(length, errorCode);
793	}
794	}
795
796	virtual void put(const char* key, ResourceValue& value, UBool /noFallback/,
797	UErrorCode &errorCode) {
798	ResourceTable namesTable = value.getTable(errorCode);
799	if (U_FAILURE(errorCode)) { return; }
800	for (int32_t i = `0`; namesTable.getKeyAndValue(i, key, value); ++i) {
801	if (value.isNoInheritanceMarker()) {
802	setNameIfEmpty(key, NULL, errorCode);
803	} else {
804	setNameIfEmpty(key, &value, errorCode);
805	}
806	}
807	}
808
809	static UTimeZoneNameTypeIndex nameTypeFromKey(const char *key) {
810	char c0, c1;
811	if ((c0 = key[`0`]) == `0` \|\| (c1 = key[`1`]) == `0` \|\| key[`2`] != `0`) {
812	return UTZNM_INDEX_UNKNOWN;
813	}
814	if (c0 == `'l'`) {
815	return c1 == `'g'` ? UTZNM_INDEX_LONG_GENERIC :
816	c1 == `'s'` ? UTZNM_INDEX_LONG_STANDARD :
817	c1 == `'d'` ? UTZNM_INDEX_LONG_DAYLIGHT : UTZNM_INDEX_UNKNOWN;
818	} else if (c0 == `'s'`) {
819	return c1 == `'g'` ? UTZNM_INDEX_SHORT_GENERIC :
820	c1 == `'s'` ? UTZNM_INDEX_SHORT_STANDARD :
821	c1 == `'d'` ? UTZNM_INDEX_SHORT_DAYLIGHT : UTZNM_INDEX_UNKNOWN;
822	} else if (c0 == `'e'` && c1 == `'c'`) {
823	return UTZNM_INDEX_EXEMPLAR_LOCATION;
824	}
825	return UTZNM_INDEX_UNKNOWN;
826	}
827
828	/**
829	* Returns an array of names. It is the caller's responsibility to copy the data into a
830	* permanent location, as the returned array is owned by the loader instance and may be
831	* cleared or leave scope.
832	*
833	* This is different than Java, where the array will no longer be modified and null
834	* may be returned.
835	*/
836	const UChar** getNames() {
837	// Remove 'NO_NAME' references in the array and replace with 'NULL'
838	for (int32_t i = `0`; i < UTZNM_INDEX_COUNT; ++i) {
839	if (names[i] == NO_NAME) {
840	names[i] = NULL;
841	}
842	}
843	return names;
844	}
845	};
846
847	ZNames::ZNamesLoader::~ZNamesLoader() {}
848
849
850	// ---------------------------------------------------
851	// The meta zone ID enumeration class
852	// ---------------------------------------------------
853	class MetaZoneIDsEnumeration : public StringEnumeration {
854	public:
855	MetaZoneIDsEnumeration();
856	MetaZoneIDsEnumeration(const UVector& mzIDs);
857	MetaZoneIDsEnumeration(UVector* mzIDs);
858	virtual ~MetaZoneIDsEnumeration();
859	static UClassID U_EXPORT2 getStaticClassID(void);
860	virtual UClassID getDynamicClassID(void) const;
861	virtual const UnicodeString* snext(UErrorCode& status);
862	virtual void reset(UErrorCode& status);
863	virtual int32_t count(UErrorCode& status) const;
864	private:
865	int32_t fLen;
866	int32_t fPos;
867	const UVector* fMetaZoneIDs;
868	UVector *fLocalVector;
869	};
870
871	UOBJECT_DEFINE_RTTI_IMPLEMENTATION(MetaZoneIDsEnumeration)
872
873	MetaZoneIDsEnumeration::MetaZoneIDsEnumeration()
874	: fLen(`0`), fPos(`0`), fMetaZoneIDs(NULL), fLocalVector(NULL) {
875	}
876
877	MetaZoneIDsEnumeration::MetaZoneIDsEnumeration(const UVector& mzIDs)
878	: fPos(`0`), fMetaZoneIDs(&mzIDs), fLocalVector(NULL) {
879	fLen = fMetaZoneIDs->size();
880	}
881
882	MetaZoneIDsEnumeration::MetaZoneIDsEnumeration(UVector *mzIDs)
883	: fLen(`0`), fPos(`0`), fMetaZoneIDs(mzIDs), fLocalVector(mzIDs) {
884	if (fMetaZoneIDs) {
885	fLen = fMetaZoneIDs->size();
886	}
887	}
888
889	const UnicodeString*
890	MetaZoneIDsEnumeration::snext(UErrorCode& status) {
891	if (U_SUCCESS(status) && fMetaZoneIDs != NULL && fPos < fLen) {
892	unistr.setTo((const UChar*)fMetaZoneIDs->elementAt(fPos++), -`1`);
893	return &unistr;
894	}
895	return NULL;
896	}
897
898	void
899	MetaZoneIDsEnumeration::reset(UErrorCode& /status/) {
900	fPos = `0`;
901	}
902
903	int32_t
904	MetaZoneIDsEnumeration::count(UErrorCode& /status/) const {
905	return fLen;
906	}
907
908	MetaZoneIDsEnumeration::~MetaZoneIDsEnumeration() {
909	if (fLocalVector) {
910	delete fLocalVector;
911	}
912	}
913
914
915	// ---------------------------------------------------
916	// ZNameSearchHandler
917	// ---------------------------------------------------
918	class ZNameSearchHandler : public TextTrieMapSearchResultHandler {
919	public:
920	ZNameSearchHandler(uint32_t types);
921	virtual ~ZNameSearchHandler();
922
923	UBool handleMatch(int32_t matchLength, const CharacterNode *node, UErrorCode &status);
924	TimeZoneNames::MatchInfoCollection* getMatches(int32_t& maxMatchLen);
925
926	private:
927	uint32_t fTypes;
928	int32_t fMaxMatchLen;
929	TimeZoneNames::MatchInfoCollection* fResults;
930	};
931
932	ZNameSearchHandler::ZNameSearchHandler(uint32_t types)
933	: fTypes(types), fMaxMatchLen(`0`), fResults(NULL) {
934	}
935
936	ZNameSearchHandler::~ZNameSearchHandler() {
937	if (fResults != NULL) {
938	delete fResults;
939	}
940	}
941
942	UBool
943	ZNameSearchHandler::handleMatch(int32_t matchLength, const CharacterNode *node, UErrorCode &status) {
944	if (U_FAILURE(status)) {
945	return FALSE;
946	}
947	if (node->hasValues()) {
948	int32_t valuesCount = node->countValues();
949	for (int32_t i = `0`; i < valuesCount; i++) {
950	ZNameInfo nameinfo = (ZNameInfo )node->getValue(i);
951	if (nameinfo == NULL) {
952	continue;
953	}
954	if ((nameinfo->type & fTypes) != `0`) {
955	// matches a requested type
956	if (fResults == NULL) {
957	fResults = new TimeZoneNames::MatchInfoCollection ();
958	if (fResults == NULL) {
959	status = U_MEMORY_ALLOCATION_ERROR;
960	}
961	}
962	if (U_SUCCESS(status)) {
963	U_ASSERT(fResults != NULL);
964	if (nameinfo->tzID) {
965	fResults->addZone(nameinfo->type, matchLength, UnicodeString (nameinfo->tzID, -`1`), status);
966	} else {
967	U_ASSERT(nameinfo->mzID);
968	fResults->addMetaZone(nameinfo->type, matchLength, UnicodeString (nameinfo->mzID, -`1`), status);
969	}
970	if (U_SUCCESS(status) && matchLength > fMaxMatchLen) {
971	fMaxMatchLen = matchLength;
972	}
973	}
974	}
975	}
976	}
977	return TRUE;
978	}
979
980	TimeZoneNames::MatchInfoCollection*
981	ZNameSearchHandler::getMatches(int32_t& maxMatchLen) {
982	// give the ownership to the caller
983	TimeZoneNames::MatchInfoCollection* results = fResults;
984	maxMatchLen = fMaxMatchLen;
985
986	// reset
987	fResults = NULL;
988	fMaxMatchLen = `0`;
989	return results;
990	}
991
992	// ---------------------------------------------------
993	// TimeZoneNamesImpl
994	//
995	// TimeZoneNames implementation class. This is the main
996	// part of this module.
997	// ---------------------------------------------------
998
999	U_CDECL_BEGIN
1000	/**
1001	* Deleter for ZNames
1002	*/
1003	static void U_CALLCONV
1004	deleteZNames(void *obj) {
1005	if (obj != EMPTY) {
1006	delete (ZNames*) obj;
1007	}
1008	}
1009
1010	/**
1011	* Deleter for ZNameInfo
1012	*/
1013	static void U_CALLCONV
1014	deleteZNameInfo(void *obj) {
1015	uprv_free(obj);
1016	}
1017
1018	U_CDECL_END
1019
1020	TimeZoneNamesImpl::TimeZoneNamesImpl(const Locale& locale, UErrorCode& status)
1021	: fLocale (locale),
1022	fZoneStrings(NULL),
1023	fTZNamesMap(NULL),
1024	fMZNamesMap(NULL),
1025	fNamesTrieFullyLoaded(FALSE),
1026	fNamesFullyLoaded(FALSE),
1027	fNamesTrie (TRUE, deleteZNameInfo) {
1028	initialize(locale, status);
1029	}
1030
1031	void
1032	TimeZoneNamesImpl::initialize(const Locale& locale, UErrorCode& status) {
1033	if (U_FAILURE(status)) {
1034	return;
1035	}
1036
1037	// Load zoneStrings bundle
1038	UErrorCode tmpsts = U_ZERO_ERROR; // OK with fallback warning..
1039	fZoneStrings = ures_open(U_ICUDATA_ZONE, locale.getName(), &tmpsts);
1040	fZoneStrings = ures_getByKeyWithFallback(fZoneStrings, gZoneStrings, fZoneStrings, &tmpsts);
1041	if (U_FAILURE(tmpsts)) {
1042	status = tmpsts;
1043	cleanup();
1044	return;
1045	}
1046
1047	// Initialize hashtables holding time zone/meta zone names
1048	fMZNamesMap = uhash_open(uhash_hashUChars, uhash_compareUChars, NULL, &status);
1049	fTZNamesMap = uhash_open(uhash_hashUChars, uhash_compareUChars, NULL, &status);
1050	if (U_FAILURE(status)) {
1051	cleanup();
1052	return;
1053	}
1054
1055	uhash_setValueDeleter(fMZNamesMap, deleteZNames);
1056	uhash_setValueDeleter(fTZNamesMap, deleteZNames);
1057	// no key deleters for name maps
1058
1059	// preload zone strings for the default zone
1060	TimeZone *tz = TimeZone::createDefault();
1061	const UChar tzID = ZoneMeta::getCanonicalCLDRID(tz);
1062	if (tzID != NULL) {
1063	loadStrings(UnicodeString (tzID), status);
1064	}
1065	delete tz;
1066
1067	return;
1068	}
1069
1070	/*
1071	* This method updates the cache and must be called with a lock,
1072	* except initializer.
1073	*/
1074	void
1075	TimeZoneNamesImpl::loadStrings(const UnicodeString& tzCanonicalID, UErrorCode& status) {
1076	loadTimeZoneNames(tzCanonicalID, status);
1077	LocalPointer<StringEnumeration> mzIDs(getAvailableMetaZoneIDs(tzCanonicalID, status));
1078	if (U_FAILURE(status)) { return; }
1079	U_ASSERT(!mzIDs.isNull());
1080
1081	const UnicodeString *mzID;
1082	while (((mzID = mzIDs ->snext(status)) != NULL) && U_SUCCESS(status)) {
1083	loadMetaZoneNames(*mzID, status);
1084	}
1085	}
1086
1087	TimeZoneNamesImpl::~TimeZoneNamesImpl() {
1088	cleanup();
1089	}
1090
1091	void
1092	TimeZoneNamesImpl::cleanup() {
1093	if (fZoneStrings != NULL) {
1094	ures_close(fZoneStrings);
1095	fZoneStrings = NULL;
1096	}
1097	if (fMZNamesMap != NULL) {
1098	uhash_close(fMZNamesMap);
1099	fMZNamesMap = NULL;
1100	}
1101	if (fTZNamesMap != NULL) {
1102	uhash_close(fTZNamesMap);
1103	fTZNamesMap = NULL;
1104	}
1105	}
1106
1107	UBool
1108	TimeZoneNamesImpl::operator==(const TimeZoneNames& other) const {
1109	if (this == &other) {
1110	return TRUE;
1111	}
1112	// No implementation for now
1113	return FALSE;
1114	}
1115
1116	TimeZoneNamesImpl*
1117	TimeZoneNamesImpl::clone() const {
1118	UErrorCode status = U_ZERO_ERROR;
1119	return new TimeZoneNamesImpl (fLocale, status);
1120	}
1121
1122	StringEnumeration*
1123	TimeZoneNamesImpl::getAvailableMetaZoneIDs(UErrorCode& status) const {
1124	return TimeZoneNamesImpl::_getAvailableMetaZoneIDs(status);
1125	}
1126
1127	// static implementation of getAvailableMetaZoneIDs(UErrorCode&)
1128	StringEnumeration*
1129	TimeZoneNamesImpl::_getAvailableMetaZoneIDs(UErrorCode& status) {
1130	if (U_FAILURE(status)) {
1131	return NULL;
1132	}
1133	const UVector* mzIDs = ZoneMeta::getAvailableMetazoneIDs();
1134	if (mzIDs == NULL) {
1135	return new MetaZoneIDsEnumeration ();
1136	}
1137	return new MetaZoneIDsEnumeration (*mzIDs);
1138	}
1139
1140	StringEnumeration*
1141	TimeZoneNamesImpl::getAvailableMetaZoneIDs(const UnicodeString& tzID, UErrorCode& status) const {
1142	return TimeZoneNamesImpl::_getAvailableMetaZoneIDs(tzID, status);
1143	}
1144
1145	// static implementation of getAvailableMetaZoneIDs(const UnicodeString&, UErrorCode&)
1146	StringEnumeration*
1147	TimeZoneNamesImpl::_getAvailableMetaZoneIDs(const UnicodeString& tzID, UErrorCode& status) {
1148	if (U_FAILURE(status)) {
1149	return NULL;
1150	}
1151	const UVector* mappings = ZoneMeta::getMetazoneMappings(tzID);
1152	if (mappings == NULL) {
1153	return new MetaZoneIDsEnumeration ();
1154	}
1155
1156	MetaZoneIDsEnumeration *senum = NULL;
1157	UVector* mzIDs = new UVector (NULL, uhash_compareUChars, status);
1158	if (mzIDs == NULL) {
1159	status = U_MEMORY_ALLOCATION_ERROR;
1160	}
1161	if (U_SUCCESS(status)) {
1162	U_ASSERT(mzIDs != NULL);
1163	for (int32_t i = `0`; U_SUCCESS(status) && i < mappings->size(); i++) {
1164
1165	OlsonToMetaMappingEntry map = (OlsonToMetaMappingEntry )mappings->elementAt(i);
1166	const UChar *mzID = map->mzid;
1167	if (!mzIDs->contains((void *)mzID)) {
1168	mzIDs->addElement((void *)mzID, status);
1169	}
1170	}
1171	if (U_SUCCESS(status)) {
1172	senum = new MetaZoneIDsEnumeration (mzIDs);
1173	} else {
1174	delete mzIDs;
1175	}
1176	}
1177	return senum;
1178	}
1179
1180	UnicodeString&
1181	TimeZoneNamesImpl::getMetaZoneID(const UnicodeString& tzID, UDate date, UnicodeString& mzID) const {
1182	return TimeZoneNamesImpl::_getMetaZoneID(tzID, date, mzID);
1183	}
1184
1185	// static implementation of getMetaZoneID
1186	UnicodeString&
1187	TimeZoneNamesImpl::_getMetaZoneID(const UnicodeString& tzID, UDate date, UnicodeString& mzID) {
1188	ZoneMeta::getMetazoneID(tzID, date, mzID);
1189	return mzID;
1190	}
1191
1192	UnicodeString&
1193	TimeZoneNamesImpl::getReferenceZoneID(const UnicodeString& mzID, const char* region, UnicodeString& tzID) const {
1194	return TimeZoneNamesImpl::_getReferenceZoneID(mzID, region, tzID);
1195	}
1196
1197	// static implementaion of getReferenceZoneID
1198	UnicodeString&
1199	TimeZoneNamesImpl::_getReferenceZoneID(const UnicodeString& mzID, const char* region, UnicodeString& tzID) {
1200	ZoneMeta::getZoneIdByMetazone(mzID, UnicodeString (region, -`1`, US_INV), tzID);
1201	return tzID;
1202	}
1203
1204	UnicodeString&
1205	TimeZoneNamesImpl::getMetaZoneDisplayName(const UnicodeString& mzID,
1206	UTimeZoneNameType type,
1207	UnicodeString& name) const {
1208	name.setToBogus(); // cleanup result.
1209	if (mzID.isEmpty()) {
1210	return name;
1211	}
1212
1213	ZNames *znames = NULL;
1214	TimeZoneNamesImpl nonConstThis = const_cast<TimeZoneNamesImpl >(this);
1215
1216	{
1217	Mutex lock(&gDataMutex);
1218	UErrorCode status = U_ZERO_ERROR;
1219	znames = nonConstThis->loadMetaZoneNames(mzID, status);
1220	if (U_FAILURE(status)) { return name; }
1221	}
1222
1223	if (znames != NULL) {
1224	const UChar* s = znames->getName(type);
1225	if (s != NULL) {
1226	name.setTo(TRUE, s, -`1`);
1227	}
1228	}
1229	return name;
1230	}
1231
1232	UnicodeString&
1233	TimeZoneNamesImpl::getTimeZoneDisplayName(const UnicodeString& tzID, UTimeZoneNameType type, UnicodeString& name) const {
1234	name.setToBogus(); // cleanup result.
1235	if (tzID.isEmpty()) {
1236	return name;
1237	}
1238
1239	ZNames *tznames = NULL;
1240	TimeZoneNamesImpl nonConstThis = const_cast<TimeZoneNamesImpl >(this);
1241
1242	{
1243	Mutex lock(&gDataMutex);
1244	UErrorCode status = U_ZERO_ERROR;
1245	tznames = nonConstThis->loadTimeZoneNames(tzID, status);
1246	if (U_FAILURE(status)) { return name; }
1247	}
1248
1249	if (tznames != NULL) {
1250	const UChar *s = tznames->getName(type);
1251	if (s != NULL) {
1252	name.setTo(TRUE, s, -`1`);
1253	}
1254	}
1255	return name;
1256	}
1257
1258	UnicodeString&
1259	TimeZoneNamesImpl::getExemplarLocationName(const UnicodeString& tzID, UnicodeString& name) const {
1260	name.setToBogus(); // cleanup result.
1261	const UChar* locName = NULL;
1262	ZNames *tznames = NULL;
1263	TimeZoneNamesImpl nonConstThis = const_cast<TimeZoneNamesImpl >(this);
1264
1265	{
1266	Mutex lock(&gDataMutex);
1267	UErrorCode status = U_ZERO_ERROR;
1268	tznames = nonConstThis->loadTimeZoneNames(tzID, status);
1269	if (U_FAILURE(status)) { return name; }
1270	}
1271
1272	if (tznames != NULL) {
1273	locName = tznames->getName(UTZNM_EXEMPLAR_LOCATION);
1274	}
1275	if (locName != NULL) {
1276	name.setTo(TRUE, locName, -`1`);
1277	}
1278
1279	return name;
1280	}
1281
1282
1283	// Merge the MZ_PREFIX and mzId
1284	static void mergeTimeZoneKey(const UnicodeString& mzID, char* result) {
1285	if (mzID.isEmpty()) {
1286	result[`0`] = `'\0'`;
1287	return;
1288	}
1289
1290	char mzIdChar[ZID_KEY_MAX + `1`];
1291	int32_t keyLen;
1292	int32_t prefixLen = static_cast<int32_t>(uprv_strlen(gMZPrefix));
1293	keyLen = mzID.extract(`0`, mzID.length(), mzIdChar, ZID_KEY_MAX + `1`, US_INV);
1294	uprv_memcpy((void )result, (void* *)gMZPrefix, prefixLen);
1295	uprv_memcpy((void )(result + prefixLen), (void* *)mzIdChar, keyLen);
1296	result[keyLen + prefixLen] = `'\0'`;
1297	}
1298
1299	/*
1300	* This method updates the cache and must be called with a lock
1301	*/
1302	ZNames*
1303	TimeZoneNamesImpl::loadMetaZoneNames(const UnicodeString& mzID, UErrorCode& status) {
1304	if (U_FAILURE(status)) { return NULL; }
1305	U_ASSERT(mzID.length() <= ZID_KEY_MAX - MZ_PREFIX_LEN);
1306
1307	UChar mzIDKey[ZID_KEY_MAX + `1`];
1308	mzID.extract(mzIDKey, ZID_KEY_MAX + `1`, status);
1309	U_ASSERT(U_SUCCESS(status)); // already checked length above
1310	mzIDKey[mzID.length()] = `0`;
1311
1312	void* mznames = uhash_get(fMZNamesMap, mzIDKey);
1313	if (mznames == NULL) {
1314	ZNames::ZNamesLoader loader;
1315	loader.loadMetaZone(fZoneStrings, mzID, status);
1316	mznames = ZNames::createMetaZoneAndPutInCache(fMZNamesMap, loader.getNames(), mzID, status);
1317	if (U_FAILURE(status)) { return NULL; }
1318	}
1319
1320	if (mznames != EMPTY) {
1321	return (ZNames*)mznames;
1322	} else {
1323	return NULL;
1324	}
1325	}
1326
1327	/*
1328	* This method updates the cache and must be called with a lock
1329	*/
1330	ZNames*
1331	TimeZoneNamesImpl::loadTimeZoneNames(const UnicodeString& tzID, UErrorCode& status) {
1332	if (U_FAILURE(status)) { return NULL; }
1333	U_ASSERT(tzID.length() <= ZID_KEY_MAX);
1334
1335	UChar tzIDKey[ZID_KEY_MAX + `1`];
1336	int32_t tzIDKeyLen = tzID.extract(tzIDKey, ZID_KEY_MAX + `1`, status);
1337	U_ASSERT(U_SUCCESS(status)); // already checked length above
1338	tzIDKey[tzIDKeyLen] = `0`;
1339
1340	void *tznames = uhash_get(fTZNamesMap, tzIDKey);
1341	if (tznames == NULL) {
1342	ZNames::ZNamesLoader loader;
1343	loader.loadTimeZone(fZoneStrings, tzID, status);
1344	tznames = ZNames::createTimeZoneAndPutInCache(fTZNamesMap, loader.getNames(), tzID, status);
1345	if (U_FAILURE(status)) { return NULL; }
1346	}
1347
1348	// tznames is never EMPTY
1349	return (ZNames*)tznames;
1350	}
1351
1352	TimeZoneNames::MatchInfoCollection*
1353	TimeZoneNamesImpl::find(const UnicodeString& text, int32_t start, uint32_t types, UErrorCode& status) const {
1354	ZNameSearchHandler handler(types);
1355	TimeZoneNames::MatchInfoCollection* matches;
1356	TimeZoneNamesImpl* nonConstThis = const_cast<TimeZoneNamesImpl>(this*);
1357
1358	// Synchronize so that data is not loaded multiple times.
1359	// TODO: Consider more fine-grained synchronization.
1360	{
1361	Mutex lock(&gDataMutex);
1362
1363	// First try of lookup.
1364	matches = doFind(handler, text, start, status);
1365	if (U_FAILURE(status)) { return NULL; }
1366	if (matches != NULL) {
1367	return matches;
1368	}
1369
1370	// All names are not yet loaded into the trie.
1371	// We may have loaded names for formatting several time zones,
1372	// and might be parsing one of those.
1373	// Populate the parsing trie from all of the already-loaded names.
1374	nonConstThis->addAllNamesIntoTrie(status);
1375
1376	// Second try of lookup.
1377	matches = doFind(handler, text, start, status);
1378	if (U_FAILURE(status)) { return NULL; }
1379	if (matches != NULL) {
1380	return matches;
1381	}
1382
1383	// There are still some names we haven't loaded into the trie yet.
1384	// Load everything now.
1385	nonConstThis->internalLoadAllDisplayNames(status);
1386	nonConstThis->addAllNamesIntoTrie(status);
1387	nonConstThis->fNamesTrieFullyLoaded = TRUE;
1388	if (U_FAILURE(status)) { return NULL; }
1389
1390	// Third try: we must return this one.
1391	return doFind(handler, text, start, status);
1392	}
1393	}
1394
1395	TimeZoneNames::MatchInfoCollection*
1396	TimeZoneNamesImpl::doFind(ZNameSearchHandler& handler,
1397	const UnicodeString& text, int32_t start, UErrorCode& status) const {
1398
1399	fNamesTrie.search(text, start, (TextTrieMapSearchResultHandler *)&handler, status);
1400	if (U_FAILURE(status)) { return NULL; }
1401
1402	int32_t maxLen = `0`;
1403	TimeZoneNames::MatchInfoCollection* matches = handler.getMatches(maxLen);
1404	if (matches != NULL && ((maxLen == (text.length() - start)) \|\| fNamesTrieFullyLoaded)) {
1405	// perfect match, or no more names available
1406	return matches;
1407	}
1408	delete matches;
1409	return NULL;
1410	}
1411
1412	// Caller must synchronize.
1413	void TimeZoneNamesImpl::addAllNamesIntoTrie(UErrorCode& status) {
1414	if (U_FAILURE(status)) return;
1415	int32_t pos;
1416	const UHashElement* element;
1417
1418	pos = UHASH_FIRST;
1419	while ((element = uhash_nextElement(fMZNamesMap, &pos)) != NULL) {
1420	if (element->value.pointer == EMPTY) { continue; }
1421	UChar* mzID = (UChar*) element->key.pointer;
1422	ZNames* znames = (ZNames*) element->value.pointer;
1423	znames->addAsMetaZoneIntoTrie(mzID, fNamesTrie, status);
1424	if (U_FAILURE(status)) { return; }
1425	}
1426
1427	pos = UHASH_FIRST;
1428	while ((element = uhash_nextElement(fTZNamesMap, &pos)) != NULL) {
1429	if (element->value.pointer == EMPTY) { continue; }
1430	UChar* tzID = (UChar*) element->key.pointer;
1431	ZNames* znames = (ZNames*) element->value.pointer;
1432	znames->addAsTimeZoneIntoTrie(tzID, fNamesTrie, status);
1433	if (U_FAILURE(status)) { return; }
1434	}
1435	}
1436
1437	U_CDECL_BEGIN
1438	static void U_CALLCONV
1439	deleteZNamesLoader(void* obj) {
1440	if (obj == DUMMY_LOADER) { return; }
1441	const ZNames::ZNamesLoader* loader = (const ZNames::ZNamesLoader*) obj;
1442	delete loader;
1443	}
1444	U_CDECL_END
1445
1446	struct TimeZoneNamesImpl::ZoneStringsLoader : public ResourceSink {
1447	TimeZoneNamesImpl& tzn;
1448	UHashtable* keyToLoader;
1449
1450	ZoneStringsLoader(TimeZoneNamesImpl& _tzn, UErrorCode& status)
1451	: tzn(_tzn) {
1452	keyToLoader = uhash_open(uhash_hashChars, uhash_compareChars, NULL, &status);
1453	if (U_FAILURE(status)) { return; }
1454	uhash_setKeyDeleter(keyToLoader, uprv_free);
1455	uhash_setValueDeleter(keyToLoader, deleteZNamesLoader);
1456	}
1457	virtual ~ZoneStringsLoader();
1458
1459	void* createKey(const char* key, UErrorCode& status) {
1460	int32_t len = sizeof(char) * (static_cast<int32_t>(uprv_strlen(key)) + `1`);
1461	char* newKey = (char*) uprv_malloc(len);
1462	if (newKey == NULL) {
1463	status = U_MEMORY_ALLOCATION_ERROR;
1464	return NULL;
1465	}
1466	uprv_memcpy(newKey, key, len);
1467	newKey[len-`1`] = `'\0'`;
1468	return (void*) newKey;
1469	}
1470
1471	UBool isMetaZone(const char* key) {
1472	return (uprv_strlen(key) >= MZ_PREFIX_LEN && uprv_memcmp(key, gMZPrefix, MZ_PREFIX_LEN) == `0`);
1473	}
1474
1475	UnicodeString mzIDFromKey(const char* key) {
1476	return UnicodeString (key + MZ_PREFIX_LEN, static_cast<int32_t>(uprv_strlen(key)) - MZ_PREFIX_LEN, US_INV);
1477	}
1478
1479	UnicodeString tzIDFromKey(const char* key) {
1480	UnicodeString tzID(key, -`1`, US_INV);
1481	// Replace all colons ':' with slashes '/'
1482	for (int i=`0`; i<tzID.length(); i++) {
1483	if (tzID.charAt(i) == `0x003A`) {
1484	tzID.setCharAt(i, `0x002F`);
1485	}
1486	}
1487	return tzID;
1488	}
1489
1490	void load(UErrorCode& status) {
1491	ures_getAllItemsWithFallback(tzn.fZoneStrings, "", *this, status);
1492	if (U_FAILURE(status)) { return; }
1493
1494	int32_t pos = UHASH_FIRST;
1495	const UHashElement* element;
1496	while ((element = uhash_nextElement(keyToLoader, &pos)) != NULL) {
1497	if (element->value.pointer == DUMMY_LOADER) { continue; }
1498	ZNames::ZNamesLoader* loader = (ZNames::ZNamesLoader*) element->value.pointer;
1499	char* key = (char*) element->key.pointer;
1500
1501	if (isMetaZone(key)) {
1502	UnicodeString mzID = mzIDFromKey(key);
1503	ZNames::createMetaZoneAndPutInCache(tzn.fMZNamesMap, loader->getNames(), mzID, status);
1504	} else {
1505	UnicodeString tzID = tzIDFromKey(key);
1506	ZNames::createTimeZoneAndPutInCache(tzn.fTZNamesMap, loader->getNames(), tzID, status);
1507	}
1508	if (U_FAILURE(status)) { return; }
1509	}
1510	}
1511
1512	void consumeNamesTable(const char *key, ResourceValue &value, UBool noFallback,
1513	UErrorCode &status) {
1514	if (U_FAILURE(status)) { return; }
1515
1516	void* loader = uhash_get(keyToLoader, key);
1517	if (loader == NULL) {
1518	if (isMetaZone(key)) {
1519	UnicodeString mzID = mzIDFromKey(key);
1520	void* cacheVal = uhash_get(tzn.fMZNamesMap, mzID.getTerminatedBuffer());
1521	if (cacheVal != NULL) {
1522	// We have already loaded the names for this meta zone.
1523	loader = (void*) DUMMY_LOADER;
1524	} else {
1525	loader = (void) new* ZNames::ZNamesLoader ();
1526	if (loader == NULL) {
1527	status = U_MEMORY_ALLOCATION_ERROR;
1528	return;
1529	}
1530	}
1531	} else {
1532	UnicodeString tzID = tzIDFromKey(key);
1533	void* cacheVal = uhash_get(tzn.fTZNamesMap, tzID.getTerminatedBuffer());
1534	if (cacheVal != NULL) {
1535	// We have already loaded the names for this time zone.
1536	loader = (void*) DUMMY_LOADER;
1537	} else {
1538	loader = (void) new* ZNames::ZNamesLoader ();
1539	if (loader == NULL) {
1540	status = U_MEMORY_ALLOCATION_ERROR;
1541	return;
1542	}
1543	}
1544	}
1545
1546	void* newKey = createKey(key, status);
1547	if (U_FAILURE(status)) {
1548	deleteZNamesLoader(loader);
1549	return;
1550	}
1551
1552	uhash_put(keyToLoader, newKey, loader, &status);
1553	if (U_FAILURE(status)) { return; }
1554	}
1555
1556	if (loader != DUMMY_LOADER) {
1557	// Let the ZNamesLoader consume the names table.
1558	((ZNames::ZNamesLoader*)loader)->put(key, value, noFallback, status);
1559	}
1560	}
1561
1562	virtual void put(const char *key, ResourceValue &value, UBool noFallback,
1563	UErrorCode &status) {
1564	ResourceTable timeZonesTable = value.getTable(status);
1565	if (U_FAILURE(status)) { return; }
1566	for (int32_t i = `0`; timeZonesTable.getKeyAndValue(i, key, value); ++i) {
1567	U_ASSERT(!value.isNoInheritanceMarker());
1568	if (value.getType() == URES_TABLE) {
1569	consumeNamesTable(key, value, noFallback, status);
1570	} else {
1571	// Ignore fields that aren't tables (e.g., fallbackFormat and regionFormatStandard).
1572	// All time zone fields are tables.
1573	}
1574	if (U_FAILURE(status)) { return; }
1575	}
1576	}
1577	};
1578
1579	// Virtual destructors must be defined out of line.
1580	TimeZoneNamesImpl::ZoneStringsLoader::~ZoneStringsLoader() {
1581	uhash_close(keyToLoader);
1582	}
1583
1584	void TimeZoneNamesImpl::loadAllDisplayNames(UErrorCode& status) {
1585	if (U_FAILURE(status)) return;
1586
1587	{
1588	Mutex lock(&gDataMutex);
1589	internalLoadAllDisplayNames(status);
1590	}
1591	}
1592
1593	void TimeZoneNamesImpl::getDisplayNames(const UnicodeString& tzID,
1594	const UTimeZoneNameType types[], int32_t numTypes,
1595	UDate date, UnicodeString dest[], UErrorCode& status) const {
1596	if (U_FAILURE(status)) return;
1597
1598	if (tzID.isEmpty()) { return; }
1599	void* tznames = NULL;
1600	void* mznames = NULL;
1601	TimeZoneNamesImpl nonConstThis = const_cast<TimeZoneNamesImpl>(this);
1602
1603	// Load the time zone strings
1604	{
1605	Mutex lock(&gDataMutex);
1606	tznames = (void*) nonConstThis->loadTimeZoneNames(tzID, status);
1607	if (U_FAILURE(status)) { return; }
1608	}
1609	U_ASSERT(tznames != NULL);
1610
1611	// Load the values into the dest array
1612	for (int i = `0`; i < numTypes; i++) {
1613	UTimeZoneNameType type = types[i];
1614	const UChar* name = ((ZNames*)tznames)->getName(type);
1615	if (name == NULL) {
1616	if (mznames == NULL) {
1617	// Load the meta zone name
1618	UnicodeString mzID;
1619	getMetaZoneID(tzID, date, mzID);
1620	if (mzID.isEmpty()) {
1621	mznames = (void*) EMPTY;
1622	} else {
1623	// Load the meta zone strings
1624	// Mutex is scoped to the "else" statement
1625	Mutex lock(&gDataMutex);
1626	mznames = (void*) nonConstThis->loadMetaZoneNames(mzID, status);
1627	if (U_FAILURE(status)) { return; }
1628	// Note: when the metazone doesn't exist, in Java, loadMetaZoneNames returns
1629	// a dummy object instead of NULL.
1630	if (mznames == NULL) {
1631	mznames = (void*) EMPTY;
1632	}
1633	}
1634	}
1635	U_ASSERT(mznames != NULL);
1636	if (mznames != EMPTY) {
1637	name = ((ZNames*)mznames)->getName(type);
1638	}
1639	}
1640	if (name != NULL) {
1641	dest[i].setTo(TRUE, name, -`1`);
1642	} else {
1643	dest[i].setToBogus();
1644	}
1645	}
1646	}
1647
1648	// Caller must synchronize.
1649	void TimeZoneNamesImpl::internalLoadAllDisplayNames(UErrorCode& status) {
1650	if (!fNamesFullyLoaded) {
1651	fNamesFullyLoaded = TRUE;
1652
1653	ZoneStringsLoader loader(*this, status);
1654	loader.load(status);
1655	if (U_FAILURE(status)) { return; }
1656
1657	const UnicodeString *id;
1658
1659	// load strings for all zones
1660	StringEnumeration *tzIDs = TimeZone::createTimeZoneIDEnumeration(
1661	UCAL_ZONE_TYPE_CANONICAL, NULL, NULL, status);
1662	if (U_SUCCESS(status)) {
1663	while ((id = tzIDs->snext(status)) != NULL) {
1664	if (U_FAILURE(status)) {
1665	break;
1666	}
1667	UnicodeString copy(*id);
1668	void* value = uhash_get(fTZNamesMap, copy.getTerminatedBuffer());
1669	if (value == NULL) {
1670	// loadStrings also loads related metazone strings
1671	loadStrings(*id, status);
1672	}
1673	}
1674	}
1675	if (tzIDs != NULL) {
1676	delete tzIDs;
1677	}
1678	}
1679	}
1680
1681
1682
1683	static const UChar gEtcPrefix[] = { `0x45`, `0x74`, `0x63`, `0x2F` }; // "Etc/"
1684	static const int32_t gEtcPrefixLen = `4`;
1685	static const UChar gSystemVPrefix[] = { `0x53`, `0x79`, `0x73`, `0x74`, `0x65`, `0x6D`, `0x56`, `0x2F` }; // "SystemV/
1686	static const int32_t gSystemVPrefixLen = `8`;
1687	static const UChar gRiyadh8[] = { `0x52`, `0x69`, `0x79`, `0x61`, `0x64`, `0x68`, `0x38` }; // "Riyadh8"
1688	static const int32_t gRiyadh8Len = `7`;
1689
1690	UnicodeString& U_EXPORT2
1691	TimeZoneNamesImpl::getDefaultExemplarLocationName(const UnicodeString& tzID, UnicodeString& name) {
1692	if (tzID.isEmpty() \|\| tzID.startsWith(gEtcPrefix, gEtcPrefixLen)
1693	\|\| tzID.startsWith(gSystemVPrefix, gSystemVPrefixLen) \|\| tzID.indexOf(gRiyadh8, gRiyadh8Len, `0`) > `0`) {
1694	name.setToBogus();
1695	return name;
1696	}
1697
1698	int32_t sep = tzID.lastIndexOf((UChar)`0x2F` / '/' /);
1699	if (sep > `0` && sep + `1` < tzID.length()) {
1700	name.setTo(tzID, sep + `1`);
1701	name.findAndReplace(UnicodeString ((UChar)`0x5f` / _ /),
1702	UnicodeString ((UChar)`0x20` / space /));
1703	} else {
1704	name.setToBogus();
1705	}
1706	return name;
1707	}
1708
1709	// ---------------------------------------------------
1710	// TZDBTimeZoneNames and its supporting classes
1711	//
1712	// TZDBTimeZoneNames is an implementation class of
1713	// TimeZoneNames holding the IANA tz database abbreviations.
1714	// ---------------------------------------------------
1715
1716	class TZDBNames : public UMemory {
1717	public:
1718	virtual ~TZDBNames();
1719
1720	static TZDBNames* createInstance(UResourceBundle* rb, const char* key);
1721	const UChar* getName(UTimeZoneNameType type) const;
1722	const char** getParseRegions(int32_t& numRegions) const;
1723
1724	protected:
1725	TZDBNames(const UChar** names, char** regions, int32_t numRegions);
1726
1727	private:
1728	const UChar** fNames;
1729	char** fRegions;
1730	int32_t fNumRegions;
1731	};
1732
1733	TZDBNames::TZDBNames(const UChar** names, char** regions, int32_t numRegions)
1734	: fNames(names),
1735	fRegions(regions),
1736	fNumRegions(numRegions) {
1737	}
1738
1739	TZDBNames::~TZDBNames() {
1740	if (fNames != NULL) {
1741	uprv_free(fNames);
1742	}
1743	if (fRegions != NULL) {
1744	char **p = fRegions;
1745	for (int32_t i = `0`; i < fNumRegions; p++, i++) {
1746	uprv_free(*p);
1747	}
1748	uprv_free(fRegions);
1749	}
1750	}
1751
1752	TZDBNames*
1753	TZDBNames::createInstance(UResourceBundle* rb, const char* key) {
1754	if (rb == NULL \|\| key == NULL \|\| *key == `0`) {
1755	return NULL;
1756	}
1757
1758	UErrorCode status = U_ZERO_ERROR;
1759
1760	const UChar **names = NULL;
1761	char** regions = NULL;
1762	int32_t numRegions = `0`;
1763
1764	int32_t len = `0`;
1765
1766	UResourceBundle* rbTable = NULL;
1767	rbTable = ures_getByKey(rb, key, rbTable, &status);
1768	if (U_FAILURE(status)) {
1769	return NULL;
1770	}
1771
1772	names = (const UChar )uprv_malloc(sizeof*(const* UChar) TZDBNAMES_KEYS_SIZE);
1773	UBool isEmpty = TRUE;
1774	if (names != NULL) {
1775	for (int32_t i = `0`; i < TZDBNAMES_KEYS_SIZE; i++) {
1776	status = U_ZERO_ERROR;
1777	const UChar *value = ures_getStringByKey(rbTable, TZDBNAMES_KEYS[i], &len, &status);
1778	if (U_FAILURE(status) \|\| len == `0`) {
1779	names[i] = NULL;
1780	} else {
1781	names[i] = value;
1782	isEmpty = FALSE;
1783	}
1784	}
1785	}
1786
1787	if (isEmpty) {
1788	if (names != NULL) {
1789	uprv_free(names);
1790	}
1791	return NULL;
1792	}
1793
1794	UResourceBundle *regionsRes = ures_getByKey(rbTable, "parseRegions", NULL, &status);
1795	UBool regionError = FALSE;
1796	if (U_SUCCESS(status)) {
1797	numRegions = ures_getSize(regionsRes);
1798	if (numRegions > `0`) {
1799	regions = (char)uprv_malloc(sizeof*(char*) numRegions);
1800	if (regions != NULL) {
1801	char **pRegion = regions;
1802	for (int32_t i = `0`; i < numRegions; i++, pRegion++) {
1803	*pRegion = NULL;
1804	}
1805	// filling regions
1806	pRegion = regions;
1807	for (int32_t i = `0`; i < numRegions; i++, pRegion++) {
1808	status = U_ZERO_ERROR;
1809	const UChar *uregion = ures_getStringByIndex(regionsRes, i, &len, &status);
1810	if (U_FAILURE(status)) {
1811	regionError = TRUE;
1812	break;
1813	}
1814	pRegion = (char)uprv_malloc(sizeof*(char) (len + `1`));
1815	if (*pRegion == NULL) {
1816	regionError = TRUE;
1817	break;
1818	}
1819	u_UCharsToChars(uregion, *pRegion, len);
1820	(*pRegion)[len] = `0`;
1821	}
1822	}
1823	}
1824	}
1825	ures_close(regionsRes);
1826	ures_close(rbTable);
1827
1828	if (regionError) {
1829	if (names != NULL) {
1830	uprv_free(names);
1831	}
1832	if (regions != NULL) {
1833	char **p = regions;
1834	for (int32_t i = `0`; i < numRegions; p++, i++) {
1835	uprv_free(*p);
1836	}
1837	uprv_free(regions);
1838	}
1839	return NULL;
1840	}
1841
1842	return new TZDBNames (names, regions, numRegions);
1843	}
1844
1845	const UChar*
1846	TZDBNames::getName(UTimeZoneNameType type) const {
1847	if (fNames == NULL) {
1848	return NULL;
1849	}
1850	const UChar *name = NULL;
1851	switch(type) {
1852	case UTZNM_SHORT_STANDARD:
1853	name = fNames[`0`];
1854	break;
1855	case UTZNM_SHORT_DAYLIGHT:
1856	name = fNames[`1`];
1857	break;
1858	default:
1859	name = NULL;
1860	}
1861	return name;
1862	}
1863
1864	const char**
1865	TZDBNames::getParseRegions(int32_t& numRegions) const {
1866	if (fRegions == NULL) {
1867	numRegions = `0`;
1868	} else {
1869	numRegions = fNumRegions;
1870	}
1871	return (const char**)fRegions;
1872	}
1873
1874	U_CDECL_BEGIN
1875	/**
1876	* TZDBNameInfo stores metazone name information for the IANA abbreviations
1877	* in the trie
1878	*/
1879	typedef struct TZDBNameInfo {
1880	const UChar* mzID;
1881	UTimeZoneNameType type;
1882	UBool ambiguousType;
1883	const char** parseRegions;
1884	int32_t nRegions;
1885	} TZDBNameInfo;
1886	U_CDECL_END
1887
1888
1889	class TZDBNameSearchHandler : public TextTrieMapSearchResultHandler {
1890	public:
1891	TZDBNameSearchHandler(uint32_t types, const char* region);
1892	virtual ~TZDBNameSearchHandler();
1893
1894	UBool handleMatch(int32_t matchLength, const CharacterNode *node, UErrorCode &status);
1895	TimeZoneNames::MatchInfoCollection* getMatches(int32_t& maxMatchLen);
1896
1897	private:
1898	uint32_t fTypes;
1899	int32_t fMaxMatchLen;
1900	TimeZoneNames::MatchInfoCollection* fResults;
1901	const char* fRegion;
1902	};
1903
1904	TZDBNameSearchHandler::TZDBNameSearchHandler(uint32_t types, const char* region)
1905	: fTypes(types), fMaxMatchLen(`0`), fResults(NULL), fRegion(region) {
1906	}
1907
1908	TZDBNameSearchHandler::~TZDBNameSearchHandler() {
1909	if (fResults != NULL) {
1910	delete fResults;
1911	}
1912	}
1913
1914	UBool
1915	TZDBNameSearchHandler::handleMatch(int32_t matchLength, const CharacterNode *node, UErrorCode &status) {
1916	if (U_FAILURE(status)) {
1917	return FALSE;
1918	}
1919
1920	TZDBNameInfo *match = NULL;
1921	TZDBNameInfo *defaultRegionMatch = NULL;
1922
1923	if (node->hasValues()) {
1924	int32_t valuesCount = node->countValues();
1925	for (int32_t i = `0`; i < valuesCount; i++) {
1926	TZDBNameInfo ninfo = (TZDBNameInfo )node->getValue(i);
1927	if (ninfo == NULL) {
1928	continue;
1929	}
1930	if ((ninfo->type & fTypes) != `0`) {
1931	// Some tz database abbreviations are ambiguous. For example,
1932	// CST means either Central Standard Time or China Standard Time.
1933	// Unlike CLDR time zone display names, this implementation
1934	// does not use unique names. And TimeZoneFormat does not expect
1935	// multiple results returned for the same time zone type.
1936	// For this reason, this implementation resolve one among same
1937	// zone type with a same name at this level.
1938	if (ninfo->parseRegions == NULL) {
1939	// parseRegions == null means this is the default metazone
1940	// mapping for the abbreviation.
1941	if (defaultRegionMatch == NULL) {
1942	match = defaultRegionMatch = ninfo;
1943	}
1944	} else {
1945	UBool matchRegion = FALSE;
1946	// non-default metazone mapping for an abbreviation
1947	// comes with applicable regions. For example, the default
1948	// metazone mapping for "CST" is America_Central,
1949	// but if region is one of CN/MO/TW, "CST" is parsed
1950	// as metazone China (China Standard Time).
1951	for (int32_t j = `0`; j < ninfo->nRegions; j++) {
1952	const char *region = ninfo->parseRegions[j];
1953	if (uprv_strcmp(fRegion, region) == `0`) {
1954	match = ninfo;
1955	matchRegion = TRUE;
1956	break;
1957	}
1958	}
1959	if (matchRegion) {
1960	break;
1961	}
1962	if (match == NULL) {
1963	match = ninfo;
1964	}
1965	}
1966	}
1967	}
1968
1969	if (match != NULL) {
1970	UTimeZoneNameType ntype = match->type;
1971	// Note: Workaround for duplicated standard/daylight names
1972	// The tz database contains a few zones sharing a
1973	// same name for both standard time and daylight saving
1974	// time. For example, Australia/Sydney observes DST,
1975	// but "EST" is used for both standard and daylight.
1976	// When both SHORT_STANDARD and SHORT_DAYLIGHT are included
1977	// in the find operation, we cannot tell which one was
1978	// actually matched.
1979	// TimeZoneFormat#parse returns a matched name type (standard
1980	// or daylight) and DateFormat implementation uses the info to
1981	// to adjust actual time. To avoid false type information,
1982	// this implementation replaces the name type with SHORT_GENERIC.
1983	if (match->ambiguousType
1984	&& (ntype == UTZNM_SHORT_STANDARD \|\| ntype == UTZNM_SHORT_DAYLIGHT)
1985	&& (fTypes & UTZNM_SHORT_STANDARD) != `0`
1986	&& (fTypes & UTZNM_SHORT_DAYLIGHT) != `0`) {
1987	ntype = UTZNM_SHORT_GENERIC;
1988	}
1989
1990	if (fResults == NULL) {
1991	fResults = new TimeZoneNames::MatchInfoCollection ();
1992	if (fResults == NULL) {
1993	status = U_MEMORY_ALLOCATION_ERROR;
1994	}
1995	}
1996	if (U_SUCCESS(status)) {
1997	U_ASSERT(fResults != NULL);
1998	U_ASSERT(match->mzID != NULL);
1999	fResults->addMetaZone(ntype, matchLength, UnicodeString (match->mzID, -`1`), status);
2000	if (U_SUCCESS(status) && matchLength > fMaxMatchLen) {
2001	fMaxMatchLen = matchLength;
2002	}
2003	}
2004	}
2005	}
2006	return TRUE;
2007	}
2008
2009	TimeZoneNames::MatchInfoCollection*
2010	TZDBNameSearchHandler::getMatches(int32_t& maxMatchLen) {
2011	// give the ownership to the caller
2012	TimeZoneNames::MatchInfoCollection* results = fResults;
2013	maxMatchLen = fMaxMatchLen;
2014
2015	// reset
2016	fResults = NULL;
2017	fMaxMatchLen = `0`;
2018	return results;
2019	}
2020
2021	U_CDECL_BEGIN
2022	/**
2023	* Deleter for TZDBNames
2024	*/
2025	static void U_CALLCONV
2026	deleteTZDBNames(void *obj) {
2027	if (obj != EMPTY) {
2028	delete (TZDBNames *)obj;
2029	}
2030	}
2031
2032	static void U_CALLCONV initTZDBNamesMap(UErrorCode &status) {
2033	gTZDBNamesMap = uhash_open(uhash_hashUChars, uhash_compareUChars, NULL, &status);
2034	if (U_FAILURE(status)) {
2035	gTZDBNamesMap = NULL;
2036	return;
2037	}
2038	// no key deleters for tzdb name maps
2039	uhash_setValueDeleter(gTZDBNamesMap, deleteTZDBNames);
2040	ucln_i18n_registerCleanup(UCLN_I18N_TZDBTIMEZONENAMES, tzdbTimeZoneNames_cleanup);
2041	}
2042
2043	/**
2044	* Deleter for TZDBNameInfo
2045	*/
2046	static void U_CALLCONV
2047	deleteTZDBNameInfo(void *obj) {
2048	if (obj != NULL) {
2049	uprv_free(obj);
2050	}
2051	}
2052
2053	static void U_CALLCONV prepareFind(UErrorCode &status) {
2054	if (U_FAILURE(status)) {
2055	return;
2056	}
2057	gTZDBNamesTrie = new TextTrieMap (TRUE, deleteTZDBNameInfo);
2058	if (gTZDBNamesTrie == NULL) {
2059	status = U_MEMORY_ALLOCATION_ERROR;
2060	return;
2061	}
2062
2063	const UnicodeString *mzID;
2064	StringEnumeration *mzIDs = TimeZoneNamesImpl::_getAvailableMetaZoneIDs(status);
2065	if (U_SUCCESS(status)) {
2066	while ((mzID = mzIDs->snext(status)) != `0` && U_SUCCESS(status)) {
2067	const TZDBNames names = TZDBTimeZoneNames::getMetaZoneNames(mzID, status);
2068	if (U_FAILURE(status)) {
2069	break;
2070	}
2071	if (names == NULL) {
2072	continue;
2073	}
2074	const UChar *std = names->getName(UTZNM_SHORT_STANDARD);
2075	const UChar *dst = names->getName(UTZNM_SHORT_DAYLIGHT);
2076	if (std == NULL && dst == NULL) {
2077	continue;
2078	}
2079	int32_t numRegions = `0`;
2080	const char **parseRegions = names->getParseRegions(numRegions);
2081
2082	// The tz database contains a few zones sharing a
2083	// same name for both standard time and daylight saving
2084	// time. For example, Australia/Sydney observes DST,
2085	// but "EST" is used for both standard and daylight.
2086	// we need to store the information for later processing.
2087	UBool ambiguousType = (std != NULL && dst != NULL && u_strcmp(std, dst) == `0`);
2088
2089	const UChar uMzID = ZoneMeta::findMetaZoneID(mzID);
2090	if (std != NULL) {
2091	TZDBNameInfo stdInf = (TZDBNameInfo )uprv_malloc(sizeof(TZDBNameInfo));
2092	if (stdInf == NULL) {
2093	status = U_MEMORY_ALLOCATION_ERROR;
2094	break;
2095	}
2096	stdInf->mzID = uMzID;
2097	stdInf->type = UTZNM_SHORT_STANDARD;
2098	stdInf->ambiguousType = ambiguousType;
2099	stdInf->parseRegions = parseRegions;
2100	stdInf->nRegions = numRegions;
2101	gTZDBNamesTrie->put(std, stdInf, status);
2102	}
2103	if (U_SUCCESS(status) && dst != NULL) {
2104	TZDBNameInfo dstInf = (TZDBNameInfo )uprv_malloc(sizeof(TZDBNameInfo));
2105	if (dstInf == NULL) {
2106	status = U_MEMORY_ALLOCATION_ERROR;
2107	break;
2108	}
2109	dstInf->mzID = uMzID;
2110	dstInf->type = UTZNM_SHORT_DAYLIGHT;
2111	dstInf->ambiguousType = ambiguousType;
2112	dstInf->parseRegions = parseRegions;
2113	dstInf->nRegions = numRegions;
2114	gTZDBNamesTrie->put(dst, dstInf, status);
2115	}
2116	}
2117	}
2118	delete mzIDs;
2119
2120	if (U_FAILURE(status)) {
2121	delete gTZDBNamesTrie;
2122	gTZDBNamesTrie = NULL;
2123	return;
2124	}
2125
2126	ucln_i18n_registerCleanup(UCLN_I18N_TZDBTIMEZONENAMES, tzdbTimeZoneNames_cleanup);
2127	}
2128
2129	U_CDECL_END
2130
2131	TZDBTimeZoneNames::TZDBTimeZoneNames(const Locale& locale)
2132	: fLocale (locale) {
2133	UBool useWorld = TRUE;
2134	const char* region = fLocale.getCountry();
2135	int32_t regionLen = static_cast<int32_t>(uprv_strlen(region));
2136	if (regionLen == `0`) {
2137	UErrorCode status = U_ZERO_ERROR;
2138	CharString loc;
2139	{
2140	CharStringByteSink sink(&loc);
2141	ulocimp_addLikelySubtags(fLocale.getName(), sink, &status);
2142	}
2143	regionLen = uloc_getCountry(loc.data(), fRegion, sizeof(fRegion), &status);
2144	if (U_SUCCESS(status) && regionLen < (int32_t)sizeof(fRegion)) {
2145	useWorld = FALSE;
2146	}
2147	} else if (regionLen < (int32_t)sizeof(fRegion)) {
2148	uprv_strcpy(fRegion, region);
2149	useWorld = FALSE;
2150	}
2151	if (useWorld) {
2152	uprv_strcpy(fRegion, "001");
2153	}
2154	}
2155
2156	TZDBTimeZoneNames::~TZDBTimeZoneNames() {
2157	}
2158
2159	UBool
2160	TZDBTimeZoneNames::operator==(const TimeZoneNames& other) const {
2161	if (this == &other) {
2162	return TRUE;
2163	}
2164	// No implementation for now
2165	return FALSE;
2166	}
2167
2168	TZDBTimeZoneNames*
2169	TZDBTimeZoneNames::clone() const {
2170	return new TZDBTimeZoneNames (fLocale);
2171	}
2172
2173	StringEnumeration*
2174	TZDBTimeZoneNames::getAvailableMetaZoneIDs(UErrorCode& status) const {
2175	return TimeZoneNamesImpl::_getAvailableMetaZoneIDs(status);
2176	}
2177
2178	StringEnumeration*
2179	TZDBTimeZoneNames::getAvailableMetaZoneIDs(const UnicodeString& tzID, UErrorCode& status) const {
2180	return TimeZoneNamesImpl::_getAvailableMetaZoneIDs(tzID, status);
2181	}
2182
2183	UnicodeString&
2184	TZDBTimeZoneNames::getMetaZoneID(const UnicodeString& tzID, UDate date, UnicodeString& mzID) const {
2185	return TimeZoneNamesImpl::_getMetaZoneID(tzID, date, mzID);
2186	}
2187
2188	UnicodeString&
2189	TZDBTimeZoneNames::getReferenceZoneID(const UnicodeString& mzID, const char* region, UnicodeString& tzID) const {
2190	return TimeZoneNamesImpl::_getReferenceZoneID(mzID, region, tzID);
2191	}
2192
2193	UnicodeString&
2194	TZDBTimeZoneNames::getMetaZoneDisplayName(const UnicodeString& mzID,
2195	UTimeZoneNameType type,
2196	UnicodeString& name) const {
2197	name.setToBogus();
2198	if (mzID.isEmpty()) {
2199	return name;
2200	}
2201
2202	UErrorCode status = U_ZERO_ERROR;
2203	const TZDBNames *tzdbNames = TZDBTimeZoneNames::getMetaZoneNames(mzID, status);
2204	if (U_SUCCESS(status)) {
2205	if (tzdbNames != NULL) {
2206	const UChar *s = tzdbNames->getName(type);
2207	if (s != NULL) {
2208	name.setTo(TRUE, s, -`1`);
2209	}
2210	}
2211	}
2212
2213	return name;
2214	}
2215
2216	UnicodeString&
2217	TZDBTimeZoneNames::getTimeZoneDisplayName(const UnicodeString& / tzID /, UTimeZoneNameType / type /, UnicodeString& name) const {
2218	// No abbreviations associated a zone directly for now.
2219	name.setToBogus();
2220	return name;
2221	}
2222
2223	TZDBTimeZoneNames::MatchInfoCollection*
2224	TZDBTimeZoneNames::find(const UnicodeString& text, int32_t start, uint32_t types, UErrorCode& status) const {
2225	umtx_initOnce(gTZDBNamesTrieInitOnce, &prepareFind, status);
2226	if (U_FAILURE(status)) {
2227	return NULL;
2228	}
2229
2230	TZDBNameSearchHandler handler(types, fRegion);
2231	gTZDBNamesTrie->search(text, start, (TextTrieMapSearchResultHandler *)&handler, status);
2232	if (U_FAILURE(status)) {
2233	return NULL;
2234	}
2235	int32_t maxLen = `0`;
2236	return handler.getMatches(maxLen);
2237	}
2238
2239	const TZDBNames*
2240	TZDBTimeZoneNames::getMetaZoneNames(const UnicodeString& mzID, UErrorCode& status) {
2241	umtx_initOnce(gTZDBNamesMapInitOnce, &initTZDBNamesMap, status);
2242	if (U_FAILURE(status)) {
2243	return NULL;
2244	}
2245
2246	TZDBNames* tzdbNames = NULL;
2247
2248	UChar mzIDKey[ZID_KEY_MAX + `1`];
2249	mzID.extract(mzIDKey, ZID_KEY_MAX + `1`, status);
2250	U_ASSERT(status == U_ZERO_ERROR); // already checked length above
2251	mzIDKey[mzID.length()] = `0`;
2252
2253	static UMutex gTZDBNamesMapLock;
2254	umtx_lock(&gTZDBNamesMapLock);
2255	{
2256	void *cacheVal = uhash_get(gTZDBNamesMap, mzIDKey);
2257	if (cacheVal == NULL) {
2258	UResourceBundle *zoneStringsRes = ures_openDirect(U_ICUDATA_ZONE, "tzdbNames", &status);
2259	zoneStringsRes = ures_getByKey(zoneStringsRes, gZoneStrings, zoneStringsRes, &status);
2260	if (U_SUCCESS(status)) {
2261	char key[ZID_KEY_MAX + `1`];
2262	mergeTimeZoneKey(mzID, key);
2263	tzdbNames = TZDBNames::createInstance(zoneStringsRes, key);
2264
2265	if (tzdbNames == NULL) {
2266	cacheVal = (void *)EMPTY;
2267	} else {
2268	cacheVal = tzdbNames;
2269	}
2270	// Use the persistent ID as the resource key, so we can
2271	// avoid duplications.
2272	// TODO: Is there a more efficient way, like intern() in Java?
2273	void* newKey = (void*) ZoneMeta::findMetaZoneID(mzID);
2274	if (newKey != NULL) {
2275	uhash_put(gTZDBNamesMap, newKey, cacheVal, &status);
2276	if (U_FAILURE(status)) {
2277	if (tzdbNames != NULL) {
2278	delete tzdbNames;
2279	tzdbNames = NULL;
2280	}
2281	}
2282	} else {
2283	// Should never happen with a valid input
2284	if (tzdbNames != NULL) {
2285	// It's not possible that we get a valid tzdbNames with unknown ID.
2286	// But just in case..
2287	delete tzdbNames;
2288	tzdbNames = NULL;
2289	}
2290	}
2291	}
2292	ures_close(zoneStringsRes);
2293	} else if (cacheVal != EMPTY) {
2294	tzdbNames = (TZDBNames *)cacheVal;
2295	}
2296	}
2297	umtx_unlock(&gTZDBNamesMapLock);
2298
2299	return tzdbNames;
2300	}
2301
2302	U_NAMESPACE_END
2303
2304
2305	#endif /* #if !UCONFIG_NO_FORMATTING */
2306
2307	//eof
2308

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