/* ******************************************************************************* * Copyright (C) 2007-2009, International Business Machines Corporation and * * others. All Rights Reserved. * ******************************************************************************* */ #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include "tzfmttst.h" #include "simplethread.h" #include "unicode/timezone.h" #include "unicode/simpletz.h" #include "unicode/calendar.h" #include "unicode/strenum.h" #include "unicode/smpdtfmt.h" #include "unicode/uchar.h" #include "unicode/basictz.h" #include "cstring.h" static const char* PATTERNS[] = {"z", "zzzz", "Z", "ZZZZ", "v", "vvvv", "V", "VVVV"}; static const int NUM_PATTERNS = sizeof(PATTERNS)/sizeof(const char*); void TimeZoneFormatTest::runIndexedTest( int32_t index, UBool exec, const char* &name, char* /*par*/ ) { if (exec) { logln("TestSuite TimeZoneFormatTest"); } switch (index) { TESTCASE(0, TestTimeZoneRoundTrip); TESTCASE(1, TestTimeRoundTrip); default: name = ""; break; } } void TimeZoneFormatTest::TestTimeZoneRoundTrip(void) { UErrorCode status = U_ZERO_ERROR; SimpleTimeZone unknownZone(-31415, (UnicodeString)"Etc/Unknown"); int32_t badDstOffset = -1234; int32_t badZoneOffset = -2345; int32_t testDateData[][3] = { {2007, 1, 15}, {2007, 6, 15}, {1990, 1, 15}, {1990, 6, 15}, {1960, 1, 15}, {1960, 6, 15}, }; Calendar *cal = Calendar::createInstance(TimeZone::createTimeZone((UnicodeString)"UTC"), status); if (U_FAILURE(status)) { errln("Calendar::createInstance failed"); return; } // Set up rule equivalency test range UDate low, high; cal->set(1900, UCAL_JANUARY, 1); low = cal->getTime(status); cal->set(2040, UCAL_JANUARY, 1); high = cal->getTime(status); if (U_FAILURE(status)) { errln("getTime failed"); return; } // Set up test dates UDate DATES[(sizeof(testDateData)/sizeof(int32_t))/3]; const int32_t nDates = (sizeof(testDateData)/sizeof(int32_t))/3; cal->clear(); for (int32_t i = 0; i < nDates; i++) { cal->set(testDateData[i][0], testDateData[i][1], testDateData[i][2]); DATES[i] = cal->getTime(status); if (U_FAILURE(status)) { errln("getTime failed"); return; } } // Set up test locales const Locale testLocales[] = { Locale("en"), Locale("en_CA"), Locale("fr"), Locale("zh_Hant") }; const Locale *LOCALES; int32_t nLocales; if (quick) { LOCALES = testLocales; nLocales = sizeof(testLocales)/sizeof(Locale); } else { LOCALES = Locale::getAvailableLocales(nLocales); } StringEnumeration *tzids = TimeZone::createEnumeration(); if (U_FAILURE(status)) { errln("tzids->count failed"); return; } int32_t inRaw, inDst; int32_t outRaw, outDst; // Run the roundtrip test for (int32_t locidx = 0; locidx < nLocales; locidx++) { for (int32_t patidx = 0; patidx < NUM_PATTERNS; patidx++) { SimpleDateFormat *sdf = new SimpleDateFormat((UnicodeString)PATTERNS[patidx], LOCALES[locidx], status); if (U_FAILURE(status)) { errcheckln(status, (UnicodeString)"new SimpleDateFormat failed for pattern " + PATTERNS[patidx] + " for locale " + LOCALES[locidx].getName() + " - " + u_errorName(status)); status = U_ZERO_ERROR; continue; } tzids->reset(status); const UnicodeString *tzid; while ((tzid = tzids->snext(status))) { TimeZone *tz = TimeZone::createTimeZone(*tzid); for (int32_t datidx = 0; datidx < nDates; datidx++) { UnicodeString tzstr; FieldPosition fpos(0); // Format sdf->setTimeZone(*tz); sdf->format(DATES[datidx], tzstr, fpos); // Before parse, set unknown zone to SimpleDateFormat instance // just for making sure that it does not depends on the time zone // originally set. sdf->setTimeZone(unknownZone); // Parse ParsePosition pos(0); Calendar *outcal = Calendar::createInstance(unknownZone, status); if (U_FAILURE(status)) { errln("Failed to create an instance of calendar for receiving parse result."); status = U_ZERO_ERROR; continue; } outcal->set(UCAL_DST_OFFSET, badDstOffset); outcal->set(UCAL_ZONE_OFFSET, badZoneOffset); sdf->parse(tzstr, *outcal, pos); // Check the result const TimeZone &outtz = outcal->getTimeZone(); UnicodeString outtzid; outtz.getID(outtzid); tz->getOffset(DATES[datidx], false, inRaw, inDst, status); if (U_FAILURE(status)) { errln((UnicodeString)"Failed to get offsets from time zone" + *tzid); status = U_ZERO_ERROR; } outtz.getOffset(DATES[datidx], false, outRaw, outDst, status); if (U_FAILURE(status)) { errln((UnicodeString)"Failed to get offsets from time zone" + outtzid); status = U_ZERO_ERROR; } if (uprv_strcmp(PATTERNS[patidx], "VVVV") == 0) { // Location: time zone rule must be preserved except // zones not actually associated with a specific location. // Time zones in this category do not have "/" in its ID. UnicodeString canonical; TimeZone::getCanonicalID(*tzid, canonical, status); if (U_FAILURE(status)) { // Uknown ID - we should not get here errln((UnicodeString)"Unknown ID " + *tzid); status = U_ZERO_ERROR; } else if (outtzid != canonical) { // Canonical ID did not match - check the rules if (!((BasicTimeZone*)&outtz)->hasEquivalentTransitions((BasicTimeZone&)*tz, low, high, TRUE, status)) { if (canonical.indexOf((UChar)0x27 /*'/'*/) == -1) { // Exceptional cases, such as CET, EET, MET and WET logln("Canonical round trip failed (as expected); tz=" + *tzid + ", locale=" + LOCALES[locidx].getName() + ", pattern=" + PATTERNS[patidx] + ", time=" + DATES[datidx] + ", str=" + tzstr + ", outtz=" + outtzid); } else { errln("Canonical round trip failed; tz=" + *tzid + ", locale=" + LOCALES[locidx].getName() + ", pattern=" + PATTERNS[patidx] + ", time=" + DATES[datidx] + ", str=" + tzstr + ", outtz=" + outtzid); } if (U_FAILURE(status)) { errln("hasEquivalentTransitions failed"); status = U_ZERO_ERROR; } } } } else { // Check if localized GMT format or RFC format is used. int32_t numDigits = 0; for (int n = 0; n < tzstr.length(); n++) { if (u_isdigit(tzstr.charAt(n))) { numDigits++; } } if (numDigits >= 3) { // Localized GMT or RFC: total offset (raw + dst) must be preserved. int32_t inOffset = inRaw + inDst; int32_t outOffset = outRaw + outDst; if (inOffset != outOffset) { errln((UnicodeString)"Offset round trip failed; tz=" + *tzid + ", locale=" + LOCALES[locidx].getName() + ", pattern=" + PATTERNS[patidx] + ", time=" + DATES[datidx] + ", str=" + tzstr + ", inOffset=" + inOffset + ", outOffset=" + outOffset); } } else { // Specific or generic: raw offset must be preserved. if (inRaw != outRaw) { errln((UnicodeString)"Raw offset round trip failed; tz=" + *tzid + ", locale=" + LOCALES[locidx].getName() + ", pattern=" + PATTERNS[patidx] + ", time=" + DATES[datidx] + ", str=" + tzstr + ", inRawOffset=" + inRaw + ", outRawOffset=" + outRaw); } } } delete outcal; } delete tz; } delete sdf; } } delete cal; delete tzids; } struct LocaleData { int32_t index; int32_t testCounts; UDate *times; const Locale* locales; // Static int32_t nLocales; // Static UBool quick; // Static UDate START_TIME; // Static UDate END_TIME; // Static int32_t numDone; }; class TestTimeRoundTripThread: public SimpleThread { public: TestTimeRoundTripThread(IntlTest& tlog, LocaleData &ld, int32_t i) : log(tlog), data(ld), index(i) {} virtual void run() { UErrorCode status = U_ZERO_ERROR; UBool REALLY_VERBOSE = FALSE; // Whether each pattern is ambiguous at DST->STD local time overlap UBool AMBIGUOUS_DST_DECESSION[] = { FALSE, FALSE, FALSE, FALSE, TRUE, TRUE, FALSE, TRUE }; // Whether each pattern is ambiguous at STD->STD/DST->DST local time overlap UBool AMBIGUOUS_NEGATIVE_SHIFT[] = { TRUE, TRUE, FALSE, FALSE, TRUE, TRUE, TRUE, TRUE }; // Workaround for #6338 //UnicodeString BASEPATTERN("yyyy-MM-dd'T'HH:mm:ss.SSS"); UnicodeString BASEPATTERN("yyyy.MM.dd HH:mm:ss.SSS"); // timer for performance analysis UDate timer; UDate testTimes[4]; UBool expectedRoundTrip[4]; int32_t testLen = 0; StringEnumeration *tzids = TimeZone::createEnumeration(); if (U_FAILURE(status)) { log.errln("tzids->count failed"); return; } int32_t locidx = -1; UDate times[NUM_PATTERNS]; for (int32_t i = 0; i < NUM_PATTERNS; i++) { times[i] = 0; } int32_t testCounts = 0; UBool done = false; while (true) { umtx_lock(NULL); // Lock to increment the index for (int32_t i = 0; i < NUM_PATTERNS; i++) { data.times[i] += times[i]; data.testCounts += testCounts; } if (data.index < data.nLocales) { locidx = data.index; data.index++; } else { locidx = -1; } umtx_unlock(NULL); // Unlock for other threads to use if (locidx == -1) { log.logln((UnicodeString) "Thread " + index + " is done."); break; } log.logln((UnicodeString) "\nThread " + index + ": Locale: " + UnicodeString(data.locales[locidx].getName())); for (int32_t patidx = 0; patidx < NUM_PATTERNS; patidx++) { log.logln((UnicodeString) " Pattern: " + PATTERNS[patidx]); times[patidx] = 0; UnicodeString pattern(BASEPATTERN); pattern.append(" ").append(PATTERNS[patidx]); SimpleDateFormat *sdf = new SimpleDateFormat(pattern, data.locales[locidx], status); if (U_FAILURE(status)) { log.errcheckln(status, (UnicodeString) "new SimpleDateFormat failed for pattern " + pattern + " for locale " + data.locales[locidx].getName() + " - " + u_errorName(status)); status = U_ZERO_ERROR; continue; } tzids->reset(status); const UnicodeString *tzid; timer = Calendar::getNow(); while ((tzid = tzids->snext(status))) { UnicodeString canonical; TimeZone::getCanonicalID(*tzid, canonical, status); if (U_FAILURE(status)) { // Unknown ID - we should not get here status = U_ZERO_ERROR; continue; } if (*tzid != canonical) { // Skip aliases continue; } BasicTimeZone *tz = (BasicTimeZone*) TimeZone::createTimeZone(*tzid); sdf->setTimeZone(*tz); UDate t = data.START_TIME; TimeZoneTransition tzt; UBool tztAvail = FALSE; UBool middle = TRUE; while (t < data.END_TIME) { if (!tztAvail) { testTimes[0] = t; expectedRoundTrip[0] = TRUE; testLen = 1; } else { int32_t fromOffset = tzt.getFrom()->getRawOffset() + tzt.getFrom()->getDSTSavings(); int32_t toOffset = tzt.getTo()->getRawOffset() + tzt.getTo()->getDSTSavings(); int32_t delta = toOffset - fromOffset; if (delta < 0) { UBool isDstDecession = tzt.getFrom()->getDSTSavings() > 0 && tzt.getTo()->getDSTSavings() == 0; testTimes[0] = t + delta - 1; expectedRoundTrip[0] = TRUE; testTimes[1] = t + delta; expectedRoundTrip[1] = isDstDecession ? !AMBIGUOUS_DST_DECESSION[patidx] : !AMBIGUOUS_NEGATIVE_SHIFT[patidx]; testTimes[2] = t - 1; expectedRoundTrip[2] = isDstDecession ? !AMBIGUOUS_DST_DECESSION[patidx] : !AMBIGUOUS_NEGATIVE_SHIFT[patidx]; testTimes[3] = t; expectedRoundTrip[3] = TRUE; testLen = 4; } else { testTimes[0] = t - 1; expectedRoundTrip[0] = TRUE; testTimes[1] = t; expectedRoundTrip[1] = TRUE; testLen = 2; } } for (int32_t testidx = 0; testidx < testLen; testidx++) { if (data.quick) { // reduce regular test time if (!expectedRoundTrip[testidx]) { continue; } } testCounts++; UnicodeString text; FieldPosition fpos(0); sdf->format(testTimes[testidx], text, fpos); UDate parsedDate = sdf->parse(text, status); if (U_FAILURE(status)) { log.errln((UnicodeString) "Failed to parse " + text); status = U_ZERO_ERROR; continue; } if (parsedDate != testTimes[testidx]) { UnicodeString msg = (UnicodeString) "Time round trip failed for " + "tzid=" + *tzid + ", locale=" + data.locales[locidx].getName() + ", pattern=" + PATTERNS[patidx] + ", text=" + text + ", time=" + testTimes[testidx] + ", restime=" + parsedDate + ", diff=" + (parsedDate - testTimes[testidx]); if (expectedRoundTrip[testidx]) { log.errln((UnicodeString) "FAIL: " + msg); } else if (REALLY_VERBOSE) { log.logln(msg); } } } tztAvail = tz->getNextTransition(t, FALSE, tzt); if (!tztAvail) { break; } if (middle) { // Test the date in the middle of two transitions. t += (int64_t) ((tzt.getTime() - t) / 2); middle = FALSE; tztAvail = FALSE; } else { t = tzt.getTime(); } } delete tz; } times[patidx] += (Calendar::getNow() - timer); delete sdf; } umtx_lock(NULL); data.numDone++; umtx_unlock(NULL); } delete tzids; } private: IntlTest& log; LocaleData& data; int32_t index; }; void TimeZoneFormatTest::TestTimeRoundTrip(void) { int32_t nThreads = threadCount; const Locale *LOCALES; int32_t nLocales; int32_t testCounts = 0; UErrorCode status = U_ZERO_ERROR; Calendar *cal = Calendar::createInstance(TimeZone::createTimeZone((UnicodeString) "UTC"), status); if (U_FAILURE(status)) { errln("Calendar::createInstance failed"); return; } const char* testAllProp = getProperty("TimeZoneRoundTripAll"); UBool bTestAll = (testAllProp && uprv_strcmp(testAllProp, "true") == 0); UDate START_TIME, END_TIME; if (bTestAll || !quick) { cal->set(1900, UCAL_JANUARY, 1); } else { cal->set(1990, UCAL_JANUARY, 1); } START_TIME = cal->getTime(status); cal->set(2015, UCAL_JANUARY, 1); END_TIME = cal->getTime(status); if (U_FAILURE(status)) { errln("getTime failed"); return; } UDate times[NUM_PATTERNS]; for (int32_t i = 0; i < NUM_PATTERNS; i++) { times[i] = 0; } // Set up test locales const Locale locales1[] = {Locale("en")}; const Locale locales2[] = { Locale("ar_EG"), Locale("bg_BG"), Locale("ca_ES"), Locale("da_DK"), Locale("de"), Locale("de_DE"), Locale("el_GR"), Locale("en"), Locale("en_AU"), Locale("en_CA"), Locale("en_US"), Locale("es"), Locale("es_ES"), Locale("es_MX"), Locale("fi_FI"), Locale("fr"), Locale("fr_CA"), Locale("fr_FR"), Locale("he_IL"), Locale("hu_HU"), Locale("it"), Locale("it_IT"), Locale("ja"), Locale("ja_JP"), Locale("ko"), Locale("ko_KR"), Locale("nb_NO"), Locale("nl_NL"), Locale("nn_NO"), Locale("pl_PL"), Locale("pt"), Locale("pt_BR"), Locale("pt_PT"), Locale("ru_RU"), Locale("sv_SE"), Locale("th_TH"), Locale("tr_TR"), Locale("zh"), Locale("zh_Hans"), Locale("zh_Hans_CN"), Locale("zh_Hant"), Locale("zh_Hant_TW") }; if (bTestAll) { LOCALES = Locale::getAvailableLocales(nLocales); } else if (quick) { LOCALES = locales1; nLocales = sizeof(locales1)/sizeof(Locale); } else { LOCALES = locales2; nLocales = sizeof(locales2)/sizeof(Locale); } LocaleData data; data.index = 0; data.testCounts = testCounts; data.times = times; data.locales = LOCALES; data.nLocales = nLocales; data.quick = quick; data.START_TIME = START_TIME; data.END_TIME = END_TIME; data.numDone = 0; #if (ICU_USE_THREADS==0) TestTimeRoundTripThread fakeThread(*this, data, 0); fakeThread.run(); #else TestTimeRoundTripThread **threads = new TestTimeRoundTripThread*[threadCount]; int32_t i; for (i = 0; i < nThreads; i++) { threads[i] = new TestTimeRoundTripThread(*this, data, i); if (threads[i]->start() != 0) { errln("Error starting thread %d", i); } } UBool done = false; while (true) { umtx_lock(NULL); if (data.numDone == nLocales) { done = true; } umtx_unlock(NULL); if (done) break; SimpleThread::sleep(1000); } #endif UDate total = 0; logln("### Elapsed time by patterns ###"); for (int32_t i = 0; i < NUM_PATTERNS; i++) { logln(UnicodeString("") + data.times[i] + "ms (" + PATTERNS[i] + ")"); total += data.times[i]; } logln((UnicodeString) "Total: " + total + "ms"); logln((UnicodeString) "Iteration: " + data.testCounts); for (i = 0; i < nThreads; i++) { delete threads[i]; } delete [] threads; delete cal; } #endif /* #if !UCONFIG_NO_FORMATTING */