// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /*********************************************************************** * COPYRIGHT: * Copyright (c) 1997-2015, International Business Machines Corporation * and others. All Rights Reserved. ***********************************************************************/ #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include "callimts.h" #include "caltest.h" #include "unicode/calendar.h" #include "unicode/gregocal.h" #include "unicode/datefmt.h" #include "unicode/smpdtfmt.h" #include "cstring.h" #include "mutex.h" #include "putilimp.h" #include "simplethread.h" U_NAMESPACE_USE void CalendarLimitTest::runIndexedTest( int32_t index, UBool exec, const char* &name, char* /*par*/ ) { if (exec) logln("TestSuite TestCalendarLimit"); switch (index) { // Re-enable this later case 0: name = "TestCalendarExtremeLimit"; if (exec) { logln("TestCalendarExtremeLimit---"); logln(""); TestCalendarExtremeLimit(); } break; case 1: name = "TestLimits"; if (exec) { logln("TestLimits---"); logln(""); TestLimits(); } break; default: name = ""; break; } } // ***************************************************************************** // class CalendarLimitTest // ***************************************************************************** // ------------------------------------- void CalendarLimitTest::test(UDate millis, icu::Calendar* cal, icu::DateFormat* fmt) { static const UDate kDrift = 1e-10; UErrorCode exception = U_ZERO_ERROR; UnicodeString theDate; UErrorCode status = U_ZERO_ERROR; cal->setTime(millis, exception); if (U_SUCCESS(exception)) { fmt->format(millis, theDate); UDate dt = fmt->parse(theDate, status); // allow a small amount of error (drift) if(! withinErr(dt, millis, kDrift)) { errln("FAIL:round trip for large milli, got: %.1lf wanted: %.1lf. (delta %.2lf greater than %.2lf)", dt, millis, uprv_fabs(millis-dt), uprv_fabs(dt*kDrift)); logln(UnicodeString(" ") + theDate + " " + CalendarTest::calToStr(*cal)); } else { logln(UnicodeString("OK: got ") + dt + ", wanted " + millis); logln(UnicodeString(" ") + theDate); } } } // ------------------------------------- // bug 986c: deprecate nextDouble/previousDouble //|double //|CalendarLimitTest::nextDouble(double a) //|{ //| return uprv_nextDouble(a, TRUE); //|} //| //|double //|CalendarLimitTest::previousDouble(double a) //|{ //| return uprv_nextDouble(a, FALSE); //|} UBool CalendarLimitTest::withinErr(double a, double b, double err) { return ( uprv_fabs(a - b) < uprv_fabs(a * err) ); } void CalendarLimitTest::TestCalendarExtremeLimit() { UErrorCode status = U_ZERO_ERROR; Calendar *cal = Calendar::createInstance(status); if (failure(status, "Calendar::createInstance", TRUE)) return; cal->adoptTimeZone(TimeZone::createTimeZone("GMT")); DateFormat *fmt = DateFormat::createDateTimeInstance(); if(!fmt || !cal) { dataerrln("can't open cal and/or fmt"); return; } fmt->adoptCalendar(cal); ((SimpleDateFormat*) fmt)->applyPattern("HH:mm:ss.SSS Z, EEEE, MMMM d, yyyy G"); // This test used to test the algorithmic limits of the dates that // GregorianCalendar could handle. However, the algorithm has // been rewritten completely since then and the prior limits no // longer apply. Instead, we now do basic round-trip testing of // some extreme (but still manageable) dates. UDate m; logln("checking 1e16..1e17"); for ( m = 1e16; m < 1e17; m *= 1.1) { test(m, cal, fmt); } logln("checking -1e14..-1e15"); for ( m = -1e14; m > -1e15; m *= 1.1) { test(m, cal, fmt); } // This is 2^52 - 1, the largest allowable mantissa with a 0 // exponent in a 64-bit double UDate VERY_EARLY_MILLIS = - 4503599627370495.0; UDate VERY_LATE_MILLIS = 4503599627370495.0; // I am removing the previousDouble and nextDouble calls below for // two reasons: 1. As part of jitterbug 986, I am deprecating // these methods and removing calls to them. 2. This test is a // non-critical boundary behavior test. test(VERY_EARLY_MILLIS, cal, fmt); //test(previousDouble(VERY_EARLY_MILLIS), cal, fmt); test(VERY_LATE_MILLIS, cal, fmt); //test(nextDouble(VERY_LATE_MILLIS), cal, fmt); delete fmt; } namespace { struct TestCase { const char *type; UBool hasLeapMonth; UDate actualTestStart; int32_t actualTestEnd; }; const UDate DEFAULT_START = 944006400000.0; // 1999-12-01T00:00Z const int32_t DEFAULT_END = -120; // Default for non-quick is run 2 minutes TestCase TestCases[] = { {"gregorian", FALSE, DEFAULT_START, DEFAULT_END}, {"japanese", FALSE, 596937600000.0, DEFAULT_END}, // 1988-12-01T00:00Z, Showa 63 {"buddhist", FALSE, DEFAULT_START, DEFAULT_END}, {"roc", FALSE, DEFAULT_START, DEFAULT_END}, {"persian", FALSE, DEFAULT_START, DEFAULT_END}, {"islamic-civil", FALSE, DEFAULT_START, DEFAULT_END}, {"islamic", FALSE, DEFAULT_START, 800000}, // Approx. 2250 years from now, after which // some rounding errors occur in Islamic calendar {"hebrew", TRUE, DEFAULT_START, DEFAULT_END}, {"chinese", TRUE, DEFAULT_START, DEFAULT_END}, {"dangi", TRUE, DEFAULT_START, DEFAULT_END}, {"indian", FALSE, DEFAULT_START, DEFAULT_END}, {"coptic", FALSE, DEFAULT_START, DEFAULT_END}, {"ethiopic", FALSE, DEFAULT_START, DEFAULT_END}, {"ethiopic-amete-alem", FALSE, DEFAULT_START, DEFAULT_END} }; struct { int32_t fIndex; UBool next (int32_t &rIndex) { Mutex lock; if (fIndex >= UPRV_LENGTHOF(TestCases)) { return FALSE; } rIndex = fIndex++; return TRUE; } void reset() { fIndex = 0; } } gTestCaseIterator; } // anonymous name space void CalendarLimitTest::TestLimits(void) { gTestCaseIterator.reset(); ThreadPool threads(this, threadCount, &CalendarLimitTest::TestLimitsThread); threads.start(); threads.join(); } void CalendarLimitTest::TestLimitsThread(int32_t threadNum) { logln("thread %d starting", threadNum); int32_t testIndex = 0; LocalPointer cal; while (gTestCaseIterator.next(testIndex)) { TestCase &testCase = TestCases[testIndex]; logln("begin test of %s calendar.", testCase.type); UErrorCode status = U_ZERO_ERROR; char buf[64]; uprv_strcpy(buf, "root@calendar="); strcat(buf, testCase.type); cal.adoptInstead(Calendar::createInstance(buf, status)); if (failure(status, "Calendar::createInstance", TRUE)) { continue; } if (uprv_strcmp(cal->getType(), testCase.type) != 0) { errln((UnicodeString)"FAIL: Wrong calendar type: " + cal->getType() + " Requested: " + testCase.type); continue; } doTheoreticalLimitsTest(*(cal.getAlias()), testCase.hasLeapMonth); doLimitsTest(*(cal.getAlias()), testCase.actualTestStart, testCase.actualTestEnd); logln("end test of %s calendar.", testCase.type); } } void CalendarLimitTest::doTheoreticalLimitsTest(Calendar& cal, UBool leapMonth) { const char* calType = cal.getType(); int32_t nDOW = cal.getMaximum(UCAL_DAY_OF_WEEK); int32_t maxDOY = cal.getMaximum(UCAL_DAY_OF_YEAR); int32_t lmaxDOW = cal.getLeastMaximum(UCAL_DAY_OF_YEAR); int32_t maxWOY = cal.getMaximum(UCAL_WEEK_OF_YEAR); int32_t lmaxWOY = cal.getLeastMaximum(UCAL_WEEK_OF_YEAR); int32_t maxM = cal.getMaximum(UCAL_MONTH) + 1; int32_t lmaxM = cal.getLeastMaximum(UCAL_MONTH) + 1; int32_t maxDOM = cal.getMaximum(UCAL_DAY_OF_MONTH); int32_t lmaxDOM = cal.getLeastMaximum(UCAL_DAY_OF_MONTH); int32_t maxDOWIM = cal.getMaximum(UCAL_DAY_OF_WEEK_IN_MONTH); int32_t lmaxDOWIM = cal.getLeastMaximum(UCAL_DAY_OF_WEEK_IN_MONTH); int32_t maxWOM = cal.getMaximum(UCAL_WEEK_OF_MONTH); int32_t lmaxWOM = cal.getLeastMaximum(UCAL_WEEK_OF_MONTH); int32_t minDaysInFirstWeek = cal.getMinimalDaysInFirstWeek(); // Day of year int32_t expected; if (!leapMonth) { expected = maxM*maxDOM; if (maxDOY > expected) { errln((UnicodeString)"FAIL: [" + calType + "] Maximum value of DAY_OF_YEAR is too big: " + maxDOY + "/expected: <=" + expected); } expected = lmaxM*lmaxDOM; if (lmaxDOW < expected) { errln((UnicodeString)"FAIL: [" + calType + "] Least maximum value of DAY_OF_YEAR is too small: " + lmaxDOW + "/expected: >=" + expected); } } // Week of year expected = maxDOY/nDOW + 1; if (maxWOY > expected) { errln((UnicodeString)"FAIL: [" + calType + "] Maximum value of WEEK_OF_YEAR is too big: " + maxWOY + "/expected: <=" + expected); } expected = lmaxDOW/nDOW; if (lmaxWOY < expected) { errln((UnicodeString)"FAIL: [" + calType + "] Least maximum value of WEEK_OF_YEAR is too small: " + lmaxWOY + "/expected >=" + expected); } // Day of week in month expected = (maxDOM + nDOW - 1)/nDOW; if (maxDOWIM != expected) { errln((UnicodeString)"FAIL: [" + calType + "] Maximum value of DAY_OF_WEEK_IN_MONTH is incorrect: " + maxDOWIM + "/expected: " + expected); } expected = (lmaxDOM + nDOW - 1)/nDOW; if (lmaxDOWIM != expected) { errln((UnicodeString)"FAIL: [" + calType + "] Least maximum value of DAY_OF_WEEK_IN_MONTH is incorrect: " + lmaxDOWIM + "/expected: " + expected); } // Week of month expected = (maxDOM + (nDOW - 1) + (nDOW - minDaysInFirstWeek)) / nDOW; if (maxWOM != expected) { errln((UnicodeString)"FAIL: [" + calType + "] Maximum value of WEEK_OF_MONTH is incorrect: " + maxWOM + "/expected: " + expected); } expected = (lmaxDOM + (nDOW - minDaysInFirstWeek)) / nDOW; if (lmaxWOM != expected) { errln((UnicodeString)"FAIL: [" + calType + "] Least maximum value of WEEK_OF_MONTH is incorrect: " + lmaxWOM + "/expected: " + expected); } } void CalendarLimitTest::doLimitsTest(Calendar& cal, UDate startDate, int32_t endTime) { int32_t testTime = quick ? ( endTime / 40 ) : endTime; doLimitsTest(cal, NULL /*default fields*/, startDate, testTime); } void CalendarLimitTest::doLimitsTest(Calendar& cal, const int32_t* fieldsToTest, UDate startDate, int32_t testDuration) { static const int32_t FIELDS[] = { UCAL_ERA, UCAL_YEAR, UCAL_MONTH, UCAL_WEEK_OF_YEAR, UCAL_WEEK_OF_MONTH, UCAL_DAY_OF_MONTH, UCAL_DAY_OF_YEAR, UCAL_DAY_OF_WEEK_IN_MONTH, UCAL_YEAR_WOY, UCAL_EXTENDED_YEAR, -1, }; static const char* FIELD_NAME[] = { "ERA", "YEAR", "MONTH", "WEEK_OF_YEAR", "WEEK_OF_MONTH", "DAY_OF_MONTH", "DAY_OF_YEAR", "DAY_OF_WEEK", "DAY_OF_WEEK_IN_MONTH", "AM_PM", "HOUR", "HOUR_OF_DAY", "MINUTE", "SECOND", "MILLISECOND", "ZONE_OFFSET", "DST_OFFSET", "YEAR_WOY", "DOW_LOCAL", "EXTENDED_YEAR", "JULIAN_DAY", "MILLISECONDS_IN_DAY", "IS_LEAP_MONTH" }; UErrorCode status = U_ZERO_ERROR; int32_t i, j; UnicodeString ymd; GregorianCalendar greg(status); if (failure(status, "new GregorianCalendar")) { return; } greg.setTime(startDate, status); if (failure(status, "GregorianCalendar::setTime")) { return; } logln((UnicodeString)"Start: " + startDate); if (fieldsToTest == NULL) { fieldsToTest = FIELDS; } // Keep a record of minima and maxima that we actually see. // These are kept in an array of arrays of hashes. int32_t limits[UCAL_FIELD_COUNT][4]; for (j = 0; j < UCAL_FIELD_COUNT; j++) { limits[j][0] = INT32_MAX; limits[j][1] = INT32_MIN; limits[j][2] = INT32_MAX; limits[j][3] = INT32_MIN; } // This test can run for a long time; show progress. UDate millis = ucal_getNow(); UDate mark = millis + 5000; // 5 sec millis -= testDuration * 1000; // stop time if testDuration<0 for (i = 0; testDuration > 0 ? i < testDuration : ucal_getNow() < millis; ++i) { if (ucal_getNow() >= mark) { logln((UnicodeString)"(" + i + " days)"); mark += 5000; // 5 sec } UDate testMillis = greg.getTime(status); cal.setTime(testMillis, status); cal.setMinimalDaysInFirstWeek(1); if (failure(status, "Calendar set/getTime")) { return; } for (j = 0; fieldsToTest[j] >= 0; ++j) { UCalendarDateFields f = (UCalendarDateFields)fieldsToTest[j]; int32_t v = cal.get(f, status); int32_t minActual = cal.getActualMinimum(f, status); int32_t maxActual = cal.getActualMaximum(f, status); int32_t minLow = cal.getMinimum(f); int32_t minHigh = cal.getGreatestMinimum(f); int32_t maxLow = cal.getLeastMaximum(f); int32_t maxHigh = cal.getMaximum(f); if (limits[j][0] > minActual) { // the minimum limits[j][0] = minActual; } if (limits[j][1] < minActual) { // the greatest minimum limits[j][1] = minActual; } if (limits[j][2] > maxActual) { // the least maximum limits[j][2] = maxActual; } if (limits[j][3] < maxActual) { // the maximum limits[j][3] = maxActual; } if (minActual < minLow || minActual > minHigh) { errln((UnicodeString)"Fail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " Range for min of " + FIELD_NAME[f] + "(" + f + ")=" + minLow + ".." + minHigh + ", actual_min=" + minActual); } if (maxActual < maxLow || maxActual > maxHigh) { if ( uprv_strcmp(cal.getType(), "chinese") == 0 && testMillis >= 2842992000000.0 && testMillis <= 2906668800000.0 && logKnownIssue("12620", "chinese calendar failures for some actualMax tests")) { logln((UnicodeString)"KnownFail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " Range for max of " + FIELD_NAME[f] + "(" + f + ")=" + maxLow + ".." + maxHigh + ", actual_max=" + maxActual); } else { errln((UnicodeString)"Fail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " Range for max of " + FIELD_NAME[f] + "(" + f + ")=" + maxLow + ".." + maxHigh + ", actual_max=" + maxActual); } } if (v < minActual || v > maxActual) { // timebomb per #9967, fix with #9972 if ( uprv_strcmp(cal.getType(), "dangi") == 0 && testMillis >= 1865635198000.0 && logKnownIssue("9972", "as per #9967")) { // Feb 2029 gregorian, end of dangi 4361 logln((UnicodeString)"KnownFail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " " + FIELD_NAME[f] + "(" + f + ")=" + v + ", actual=" + minActual + ".." + maxActual + ", allowed=(" + minLow + ".." + minHigh + ")..(" + maxLow + ".." + maxHigh + ")"); } else if ( uprv_strcmp(cal.getType(), "chinese") == 0 && testMillis >= 2842992000000.0 && testMillis <= 2906668800000.0 && logKnownIssue("12620", "chinese calendar failures for some actualMax tests")) { logln((UnicodeString)"KnownFail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " " + FIELD_NAME[f] + "(" + f + ")=" + v + ", actual=" + minActual + ".." + maxActual + ", allowed=(" + minLow + ".." + minHigh + ")..(" + maxLow + ".." + maxHigh + ")"); } else { errln((UnicodeString)"Fail: [" + cal.getType() + "] " + ymdToString(cal, ymd) + " " + FIELD_NAME[f] + "(" + f + ")=" + v + ", actual=" + minActual + ".." + maxActual + ", allowed=(" + minLow + ".." + minHigh + ")..(" + maxLow + ".." + maxHigh + ")"); } } } greg.add(UCAL_DAY_OF_YEAR, 1, status); if (failure(status, "Calendar::add")) { return; } } // Check actual maxima and minima seen against ranges returned // by API. UnicodeString buf; for (j = 0; fieldsToTest[j] >= 0; ++j) { int32_t rangeLow, rangeHigh; UBool fullRangeSeen = TRUE; UCalendarDateFields f = (UCalendarDateFields)fieldsToTest[j]; buf.remove(); buf.append((UnicodeString)"[" + cal.getType() + "] " + FIELD_NAME[f]); // Minumum rangeLow = cal.getMinimum(f); rangeHigh = cal.getGreatestMinimum(f); if (limits[j][0] != rangeLow || limits[j][1] != rangeHigh) { fullRangeSeen = FALSE; } buf.append((UnicodeString)" minima range=" + rangeLow + ".." + rangeHigh); buf.append((UnicodeString)" minima actual=" + limits[j][0] + ".." + limits[j][1]); // Maximum rangeLow = cal.getLeastMaximum(f); rangeHigh = cal.getMaximum(f); if (limits[j][2] != rangeLow || limits[j][3] != rangeHigh) { fullRangeSeen = FALSE; } buf.append((UnicodeString)" maxima range=" + rangeLow + ".." + rangeHigh); buf.append((UnicodeString)" maxima actual=" + limits[j][2] + ".." + limits[j][3]); if (fullRangeSeen) { logln((UnicodeString)"OK: " + buf); } else { // This may or may not be an error -- if the range of dates // we scan over doesn't happen to contain a minimum or // maximum, it doesn't mean some other range won't. logln((UnicodeString)"Warning: " + buf); } } logln((UnicodeString)"End: " + greg.getTime(status)); } UnicodeString& CalendarLimitTest::ymdToString(const Calendar& cal, UnicodeString& str) { UErrorCode status = U_ZERO_ERROR; str.remove(); str.append((UnicodeString)"" + cal.get(UCAL_EXTENDED_YEAR, status) + "/" + (cal.get(UCAL_MONTH, status) + 1) + (cal.get(UCAL_IS_LEAP_MONTH, status) == 1 ? "(leap)" : "") + "/" + cal.get(UCAL_DATE, status) + " " + cal.get(UCAL_HOUR_OF_DAY, status) + ":" + cal.get(UCAL_MINUTE, status) + " zone(hrs) " + cal.get(UCAL_ZONE_OFFSET, status)/(60.0*60.0*1000.0) + " dst(hrs) " + cal.get(UCAL_DST_OFFSET, status)/(60.0*60.0*1000.0) + ", time(millis)=" + cal.getTime(status)); return str; } #endif /* #if !UCONFIG_NO_FORMATTING */ // eof