src/third_party/icu/source/test/intltest/dtfmtrtts.cpp - cobalt - Git at Google

 /***********************************************************************
  * COPYRIGHT:
  * Copyright (c) 1997-2015, International Business Machines Corporation
  * and others. All Rights Reserved.
  ***********************************************************************/

 #include "unicode/utypes.h"

 #if !UCONFIG_NO_FORMATTING

 #include "unicode/datefmt.h"
 #include "unicode/smpdtfmt.h"
 #include "unicode/gregocal.h"
 #include "dtfmtrtts.h"
 #include "caltest.h"
 #include "cstring.h"

 #include <stdio.h>
 #include <string.h>

 // *****************************************************************************
 // class DateFormatRoundTripTest
 // *****************************************************************************

 // Useful for turning up subtle bugs: Change the following to TRUE, recompile,
 // and run while at lunch.
 // Warning -- makes test run infinite loop!!!
 #ifndef INFINITE
 #define INFINITE 0
 #endif

 // Define this to test just a single locale
 //#define TEST_ONE_LOC  "cs_CZ"

 // If SPARSENESS is > 0, we don't run each exhaustive possibility.
 // There are 24 total possible tests per each locale.  A SPARSENESS
 // of 12 means we run half of them.  A SPARSENESS of 23 means we run
 // 1 of them.  SPARSENESS _must_ be in the range 0..23.
 int32_t DateFormatRoundTripTest::SPARSENESS = 0;
 int32_t DateFormatRoundTripTest::TRIALS = 4;
 int32_t DateFormatRoundTripTest::DEPTH = 5;

 DateFormatRoundTripTest::DateFormatRoundTripTest() : dateFormat(0) {
 }

 DateFormatRoundTripTest::~DateFormatRoundTripTest() {
     delete dateFormat;
 }

 #define CASE(id,test) case id: name = #test; if (exec) { logln(#test "---"); logln((UnicodeString)""); test(); } break;

 void
 DateFormatRoundTripTest::runIndexedTest( int32_t index, UBool exec, const char* &name, char* par )
 {
     optionv = (par && *par=='v');
     switch (index) {
         CASE(0,TestDateFormatRoundTrip)
         CASE(1, TestCentury)
         default: name = ""; break;
     }
 }

 UBool
 DateFormatRoundTripTest::failure(UErrorCode status, const char* msg)
 {
     if(U_FAILURE(status)) {
         errln(UnicodeString("FAIL: ") + msg + " failed, error " + u_errorName(status));
         return TRUE;
     }

     return FALSE;
 }

 UBool
 DateFormatRoundTripTest::failure(UErrorCode status, const char* msg, const UnicodeString& str)
 {
     if(U_FAILURE(status)) {
         UnicodeString escaped;
         escape(str,escaped);
         errln(UnicodeString("FAIL: ") + msg + " failed, error " + u_errorName(status) + ", str=" + escaped);
         return TRUE;
     }

     return FALSE;
 }

 void DateFormatRoundTripTest::TestCentury()
 {
     UErrorCode status = U_ZERO_ERROR;
     Locale locale("es_PA");
     UnicodeString pattern = "MM/dd/yy hh:mm:ss a z";
     SimpleDateFormat fmt(pattern, locale, status);
     if (U_FAILURE(status)) {
         dataerrln("Fail: construct SimpleDateFormat: %s", u_errorName(status));
         return;
     }
     UDate date[] = {-55018555891590.05, 0, 0};
     UnicodeString result[2];

     fmt.format(date[0], result[0]);
     date[1] = fmt.parse(result[0], status);
     fmt.format(date[1], result[1]);
     date[2] = fmt.parse(result[1], status);

     /* This test case worked OK by accident before.  date[1] != date[0],
      * because we use -80/+20 year window for 2-digit year parsing.
      * (date[0] is in year 1926, date[1] is in year 2026.)  result[1] set
      * by the first format call returns "07/13/26 07:48:28 p.m. PST",
      * which is correct, because DST was not used in year 1926 in zone
      * America/Los_Angeles.  When this is parsed, date[1] becomes a time
      * in 2026, which is "07/13/26 08:48:28 p.m. PDT".  There was a zone
      * offset calculation bug that observed DST in 1926, which was resolved.
      * Before the bug was resolved, result[0] == result[1] was true,
      * but after the bug fix, the expected result is actually
      * result[0] != result[1]. -Yoshito
      */
     /* TODO: We need to review this code and clarify what we really
      * want to test here.
      */
     //if (date[1] != date[2] || result[0] != result[1]) {
     if (date[1] != date[2]) {
         errln("Round trip failure: \"%S\" (%f), \"%S\" (%f)", result[0].getBuffer(), date[1], result[1].getBuffer(), date[2]);
     }
 }

 // ==

 void DateFormatRoundTripTest::TestDateFormatRoundTrip()
 {
     UErrorCode status = U_ZERO_ERROR;

     getFieldCal = Calendar::createInstance(status);
     if (U_FAILURE(status)) {
         dataerrln("Fail: Calendar::createInstance: %s", u_errorName(status));
         return;
     }


     int32_t locCount = 0;
     const Locale *avail = DateFormat::getAvailableLocales(locCount);
     logln("DateFormat available locales: %d", locCount);
     if(quick) {
         SPARSENESS = 18;
         logln("Quick mode: only testing SPARSENESS = 18");
     }
     TimeZone *tz = TimeZone::createDefault();
     UnicodeString temp;
     logln("Default TimeZone:             " + tz->getID(temp));
     delete tz;

 #ifdef TEST_ONE_LOC // define this to just test ONE locale.
     Locale loc(TEST_ONE_LOC);
     test(loc);
 #if INFINITE
     for(;;) {
       test(loc);
     }
 #endif

 #else
 # if INFINITE
     // Special infinite loop test mode for finding hard to reproduce errors
     Locale loc = Locale::getDefault();
     logln("ENTERING INFINITE TEST LOOP FOR Locale: " + loc.getDisplayName(temp));
     for(;;)
         test(loc);
 # else
     test(Locale::getDefault());

 #if 1
     // installed locales
     for (int i=0; i < locCount; ++i) {
         test(avail[i]);
     }
 #endif

 #if 1
     // special locales
     int32_t jCount = CalendarTest::testLocaleCount();
     for (int32_t j=0; j < jCount; ++j) {
         test(Locale(CalendarTest::testLocaleID(j)));
     }
 #endif

 # endif
 #endif

     delete getFieldCal;
 }

 static const char *styleName(DateFormat::EStyle s)
 {
     switch(s)
     {
     case DateFormat::SHORT: return "SHORT";
     case DateFormat::MEDIUM: return "MEDIUM";
     case DateFormat::LONG: return "LONG";
     case DateFormat::FULL: return "FULL";
 //  case DateFormat::DEFAULT: return "DEFAULT";
     case DateFormat::DATE_OFFSET: return "DATE_OFFSET";
     case DateFormat::NONE: return "NONE";
     case DateFormat::DATE_TIME: return "DATE_TIME";
     default: return "Unknown";
     }
 }

 void DateFormatRoundTripTest::test(const Locale& loc)
 {
     UnicodeString temp;
 #if !INFINITE
     logln("Locale: " + loc.getDisplayName(temp));
 #endif

     // Total possibilities = 24
     //  4 date
     //  4 time
     //  16 date-time
     UBool TEST_TABLE [24];//= new boolean[24];
     int32_t i = 0;
     for(i = 0; i < 24; ++i)
         TEST_TABLE[i] = TRUE;

     // If we have some sparseness, implement it here.  Sparseness decreases
     // test time by eliminating some tests, up to 23.
     for(i = 0; i < SPARSENESS; ) {
         int random = (int)(randFraction() * 24);
         if (random >= 0 && random < 24 && TEST_TABLE[i]) {
             TEST_TABLE[i] = FALSE;
             ++i;
         }
     }

     int32_t itable = 0;
     int32_t style = 0;
     for(style = DateFormat::FULL; style <= DateFormat::SHORT; ++style) {
         if(TEST_TABLE[itable++]) {
             logln("Testing style " + UnicodeString(styleName((DateFormat::EStyle)style)));
             DateFormat *df = DateFormat::createDateInstance((DateFormat::EStyle)style, loc);
             if(df == NULL) {
               errln(UnicodeString("Could not DF::createDateInstance ") + UnicodeString(styleName((DateFormat::EStyle)style)) +      " Locale: " + loc.getDisplayName(temp));
             } else {
               test(df, loc);
               delete df;
             }
         }
     }

     for(style = DateFormat::FULL; style <= DateFormat::SHORT; ++style) {
         if (TEST_TABLE[itable++]) {
           logln("Testing style " + UnicodeString(styleName((DateFormat::EStyle)style)));
             DateFormat *df = DateFormat::createTimeInstance((DateFormat::EStyle)style, loc);
             if(df == NULL) {
               errln(UnicodeString("Could not DF::createTimeInstance ") + UnicodeString(styleName((DateFormat::EStyle)style)) + " Locale: " + loc.getDisplayName(temp));
             } else {
               test(df, loc, TRUE);
               delete df;
             }
         }
     }

     for(int32_t dstyle = DateFormat::FULL; dstyle <= DateFormat::SHORT; ++dstyle) {
         for(int32_t tstyle = DateFormat::FULL; tstyle <= DateFormat::SHORT; ++tstyle) {
             if(TEST_TABLE[itable++]) {
                 logln("Testing dstyle" + UnicodeString(styleName((DateFormat::EStyle)dstyle)) + ", tstyle" + UnicodeString(styleName((DateFormat::EStyle)tstyle)) );
                 DateFormat *df = DateFormat::createDateTimeInstance((DateFormat::EStyle)dstyle, (DateFormat::EStyle)tstyle, loc);
                 if(df == NULL) {
                     dataerrln(UnicodeString("Could not DF::createDateTimeInstance ") + UnicodeString(styleName((DateFormat::EStyle)dstyle)) + ", tstyle" + UnicodeString(styleName((DateFormat::EStyle)tstyle))    + "Locale: " + loc.getDisplayName(temp));
                 } else {
                     test(df, loc);
                     delete df;
                 }
             }
         }
     }
 }

 void DateFormatRoundTripTest::test(DateFormat *fmt, const Locale &origLocale, UBool timeOnly)
 {
     UnicodeString pat;
     if(fmt->getDynamicClassID() != SimpleDateFormat::getStaticClassID()) {
         errln("DateFormat wasn't a SimpleDateFormat");
         return;
     }

     UBool isGregorian = FALSE;
     UErrorCode minStatus = U_ZERO_ERROR;
     if(fmt->getCalendar() == NULL) {
       errln((UnicodeString)"DateFormatRoundTripTest::test, DateFormat getCalendar() returns null for " + origLocale.getName());
       return;
     }
     UDate minDate = CalendarTest::minDateOfCalendar(*fmt->getCalendar(), isGregorian, minStatus);
     if(U_FAILURE(minStatus)) {
       errln((UnicodeString)"Failure getting min date for " + origLocale.getName());
       return;
     }
     //logln(UnicodeString("Min date is ") + fullFormat(minDate)  + " for " + origLocale.getName());

     pat = ((SimpleDateFormat*)fmt)->toPattern(pat);

     // NOTE TO MAINTAINER
     // This indexOf check into the pattern needs to be refined to ignore
     // quoted characters.  Currently, this isn't a problem with the locale
     // patterns we have, but it may be a problem later.

     UBool hasEra = (pat.indexOf(UnicodeString("G")) != -1);
     UBool hasZoneDisplayName = (pat.indexOf(UnicodeString("z")) != -1) || (pat.indexOf(UnicodeString("v")) != -1)
         || (pat.indexOf(UnicodeString("V")) != -1);

     // Because patterns contain incomplete data representing the Date,
     // we must be careful of how we do the roundtrip.  We start with
     // a randomly generated Date because they're easier to generate.
     // From this we get a string.  The string is our real starting point,
     // because this string should parse the same way all the time.  Note
     // that it will not necessarily parse back to the original date because
     // of incompleteness in patterns.  For example, a time-only pattern won't
     // parse back to the same date.

     //try {
         for(int i = 0; i < TRIALS; ++i) {
             UDate *d                = new UDate    [DEPTH];
             UnicodeString *s    = new UnicodeString[DEPTH];

             if(isGregorian == TRUE) {
               d[0] = generateDate();
             } else {
               d[0] = generateDate(minDate);
             }

             UErrorCode status = U_ZERO_ERROR;

             // We go through this loop until we achieve a match or until
             // the maximum loop count is reached.  We record the points at
             // which the date and the string starts to match.  Once matching
             // starts, it should continue.
             int loop;
             int dmatch = 0; // d[dmatch].getTime() == d[dmatch-1].getTime()
             int smatch = 0; // s[smatch].equals(s[smatch-1])
             for(loop = 0; loop < DEPTH; ++loop) {
                 if (loop > 0)  {
                     d[loop] = fmt->parse(s[loop-1], status);
                     failure(status, "fmt->parse", s[loop-1]+" in locale: " + origLocale.getName() + " with pattern: " + pat);
                     status = U_ZERO_ERROR; /* any error would have been reported */
                 }

                 s[loop] = fmt->format(d[loop], s[loop]);

                 // For displaying which date is being tested
                 //logln(s[loop] + " = " + fullFormat(d[loop]));

                 if(s[loop].length() == 0) {
                   errln("FAIL: fmt->format gave 0-length string in " + pat + " with number " + d[loop] + " in locale " + origLocale.getName());
                 }

                 if(loop > 0) {
                     if(smatch == 0) {
                         UBool match = s[loop] == s[loop-1];
                         if(smatch == 0) {
                             if(match)
                                 smatch = loop;
                         }
                         else if( ! match)
                             errln("FAIL: String mismatch after match");
                     }

                     if(dmatch == 0) {
                         // {sfb} watch out here, this might not work
                         UBool match = d[loop]/*.getTime()*/ == d[loop-1]/*.getTime()*/;
                         if(dmatch == 0) {
                             if(match)
                                 dmatch = loop;
                         }
                         else if( ! match)
                             errln("FAIL: Date mismatch after match");
                     }

                     if(smatch != 0 && dmatch != 0)
                         break;
                 }
             }
             // At this point loop == DEPTH if we've failed, otherwise loop is the
             // max(smatch, dmatch), that is, the index at which we have string and
             // date matching.

             // Date usually matches in 2.  Exceptions handled below.
             int maxDmatch = 2;
             int maxSmatch = 1;
             if (dmatch > maxDmatch) {
                 // Time-only pattern with zone information and a starting date in PST.
                 if(timeOnly && hasZoneDisplayName) {
                     int32_t startRaw, startDst;
                     fmt->getTimeZone().getOffset(d[0], FALSE, startRaw, startDst, status);
                     failure(status, "TimeZone::getOffset");
                     // if the start offset is greater than the offset on Jan 1, 1970
                     // in PST, then need one more round trip.  There are two cases
                     // fall into this category.  The start date is 1) DST or
                     // 2) LMT (GMT-07:52:58).
                     if (startRaw + startDst > -28800000) {
                         maxDmatch = 3;
                         maxSmatch = 2;
                     }
                 }
             }

             // String usually matches in 1.  Exceptions are checked for here.
             if(smatch > maxSmatch) { // Don't compute unless necessary
                 UBool in0;
                 // Starts in BC, with no era in pattern
                 if( ! hasEra && getField(d[0], UCAL_ERA) == GregorianCalendar::BC)
                     maxSmatch = 2;
                 // Starts in DST, no year in pattern
                 else if((in0=fmt->getTimeZone().inDaylightTime(d[0], status)) && ! failure(status, "gettingDaylightTime") &&
                          pat.indexOf(UnicodeString("yyyy")) == -1)
                     maxSmatch = 2;
                 // If we start not in DST, but transition into DST
                 else if (!in0 &&
                          fmt->getTimeZone().inDaylightTime(d[1], status) && !failure(status, "gettingDaylightTime"))
                     maxSmatch = 2;
                 // Two digit year with no time zone change,
                 // unless timezone isn't used or we aren't close to the DST changover
                 else if (pat.indexOf(UnicodeString("y")) != -1
                         && pat.indexOf(UnicodeString("yyyy")) == -1
                         && getField(d[0], UCAL_YEAR)
                             != getField(d[dmatch], UCAL_YEAR)
                         && !failure(status, "error status [smatch>maxSmatch]")
                         && ((hasZoneDisplayName
                          && (fmt->getTimeZone().inDaylightTime(d[0], status)
                                 == fmt->getTimeZone().inDaylightTime(d[dmatch], status)
                             || getField(d[0], UCAL_MONTH) == UCAL_APRIL
                             || getField(d[0], UCAL_MONTH) == UCAL_OCTOBER))
                          || !hasZoneDisplayName)
                          )
                 {
                     maxSmatch = 2;
                 }
                 // If zone display name is used, fallback format might be used before 1970
                 else if (hasZoneDisplayName && d[0] < 0) {
                     maxSmatch = 2;
                 }
                 else if (timeOnly && !isGregorian && hasZoneDisplayName && maxSmatch == 1) {
                     int32_t startRaw, startDst;
                     fmt->getTimeZone().getOffset(d[1], FALSE, startRaw, startDst, status);
                     failure(status, "TimeZone::getOffset");
                     // If the calendar type is not Gregorian and the pattern is time only,
                     // the calendar implementation may use a date before 1970 as day 0.
                     // In this case, time zone offset of the default year might be
                     // different from the one at 1970-01-01 in PST and string match requires
                     // one more iteration.
                     if (startRaw + startDst != -28800000) {
                         maxSmatch = 2;
                     }
                 }
             }

             /*
              * Special case for Japanese and Buddhist (could have large negative years)
              * Also, Hebrew calendar need help handling leap month.
              */
             if(dmatch > maxDmatch || smatch > maxSmatch) {
               const char *type = fmt->getCalendar()->getType();
               if(!strcmp(type,"japanese") || (!strcmp(type,"buddhist"))) {
                 maxSmatch = 4;
                 maxDmatch = 4;
               } else if(!strcmp(type,"hebrew")) {
                   maxSmatch = 3;
                   maxDmatch = 3;
                 }
             }

             // Use @v to see verbose results on successful cases
             UBool fail = (dmatch > maxDmatch || smatch > maxSmatch);
             if (optionv || fail) {
                 if (fail) {
                     errln(UnicodeString("\nFAIL: Pattern: ") + pat +
                           " in Locale: " + origLocale.getName());
                 } else {
                     errln(UnicodeString("\nOk: Pattern: ") + pat +
                           " in Locale: " + origLocale.getName());
                 }

                 logln("Date iters until match=%d (max allowed=%d), string iters until match=%d (max allowed=%d)",
                       dmatch,maxDmatch, smatch, maxSmatch);

                 for(int j = 0; j <= loop && j < DEPTH; ++j) {
                     UnicodeString temp;
                     FieldPosition pos(FieldPosition::DONT_CARE);
                     errln((j>0?" P> ":"    ") + fullFormat(d[j]) + " F> " +
                           escape(s[j], temp) + UnicodeString(" d=") + d[j] +
                           (j > 0 && d[j]/*.getTime()*/==d[j-1]/*.getTime()*/?" d==":"") +
                           (j > 0 && s[j] == s[j-1]?" s==":""));
                 }
             }
             delete[] d;
             delete[] s;
         }
     /*}
     catch (ParseException e) {
         errln("Exception: " + e.getMessage());
         logln(e.toString());
     }*/
 }

 const UnicodeString& DateFormatRoundTripTest::fullFormat(UDate d) {
     UErrorCode ec = U_ZERO_ERROR;
     if (dateFormat == 0) {
         dateFormat = new SimpleDateFormat((UnicodeString)"EEE MMM dd HH:mm:ss.SSS zzz yyyy G", ec);
         if (U_FAILURE(ec) || dateFormat == 0) {
             fgStr = "[FAIL: SimpleDateFormat constructor]";
             delete dateFormat;
             dateFormat = 0;
             return fgStr;
         }
     }
     fgStr.truncate(0);
     dateFormat->format(d, fgStr);
     return fgStr;
 }

 /**
  * Return a field of the given date
  */
 int32_t DateFormatRoundTripTest::getField(UDate d, int32_t f) {
     // Should be synchronized, but we're single threaded so it's ok
     UErrorCode status = U_ZERO_ERROR;
     getFieldCal->setTime(d, status);
     failure(status, "getfieldCal->setTime");
     int32_t ret = getFieldCal->get((UCalendarDateFields)f, status);
     failure(status, "getfieldCal->get");
     return ret;
 }

 UnicodeString& DateFormatRoundTripTest::escape(const UnicodeString& src, UnicodeString& dst )
 {
     dst.remove();
     for (int32_t i = 0; i < src.length(); ++i) {
         UChar c = src[i];
         if(c < 0x0080)
             dst += c;
         else {
             dst += UnicodeString("[");
             char buf [8];
             sprintf(buf, "%#x", c);
             dst += UnicodeString(buf);
             dst += UnicodeString("]");
         }
     }

     return dst;
 }

 #define U_MILLIS_PER_YEAR (365.25 * 24 * 60 * 60 * 1000)

 UDate DateFormatRoundTripTest::generateDate(UDate minDate)
 {
   // Bring range in conformance to generateDate() below.
   if(minDate < (U_MILLIS_PER_YEAR * -(4000-1970))) {
     minDate = (U_MILLIS_PER_YEAR * -(4000-1970));
   }
   for(int i=0;i<8;i++) {
     double a = randFraction();

     // Range from (min) to  (8000-1970) AD
     double dateRange = (0.0 - minDate) + (U_MILLIS_PER_YEAR + (8000-1970));

     a *= dateRange;

     // Now offset from minDate
     a += minDate;

     // Last sanity check
     if(a>=minDate) {
       return a;
     }
   }
   return minDate;
 }

 UDate DateFormatRoundTripTest::generateDate()
 {
     double a = randFraction();

     // Now 'a' ranges from 0..1; scale it to range from 0 to 8000 years
     a *= 8000;

     // Range from (4000-1970) BC to (8000-1970) AD
     a -= 4000;

     // Now scale up to ms
     a *= 365.25 * 24 * 60 * 60 * 1000;

     //return new Date((long)a);
     return a;
 }

 #endif /* #if !UCONFIG_NO_FORMATTING */

 //eof
	/***********************************************************************
	* COPYRIGHT:
	* Copyright (c) 1997-2015, International Business Machines Corporation
	* and others. All Rights Reserved.
	***********************************************************************/

	#include "unicode/utypes.h"

	#if !UCONFIG_NO_FORMATTING

	#include "unicode/datefmt.h"
	#include "unicode/smpdtfmt.h"
	#include "unicode/gregocal.h"
	#include "dtfmtrtts.h"
	#include "caltest.h"
	#include "cstring.h"

	#include <stdio.h>
	#include <string.h>

	// *****************************************************************************
	// class DateFormatRoundTripTest
	// *****************************************************************************

	// Useful for turning up subtle bugs: Change the following to TRUE, recompile,
	// and run while at lunch.
	// Warning -- makes test run infinite loop!!!
	#ifndef INFINITE
	#define INFINITE 0
	#endif

	// Define this to test just a single locale
	//#define TEST_ONE_LOC "cs_CZ"

	// If SPARSENESS is > 0, we don't run each exhaustive possibility.
	// There are 24 total possible tests per each locale. A SPARSENESS
	// of 12 means we run half of them. A SPARSENESS of 23 means we run
	// 1 of them. SPARSENESS _must_ be in the range 0..23.
	int32_t DateFormatRoundTripTest::SPARSENESS = 0;
	int32_t DateFormatRoundTripTest::TRIALS = 4;
	int32_t DateFormatRoundTripTest::DEPTH = 5;

	DateFormatRoundTripTest::DateFormatRoundTripTest() : dateFormat(0) {
	}

	DateFormatRoundTripTest::~DateFormatRoundTripTest() {
	delete dateFormat;
	}

	#define CASE(id,test) case id: name = #test; if (exec) { logln(#test "---"); logln((UnicodeString)""); test(); } break;

	void
	DateFormatRoundTripTest::runIndexedTest( int32_t index, UBool exec, const char* &name, char* par )
	{
	optionv = (par && *par=='v');
	switch (index) {
	CASE(0,TestDateFormatRoundTrip)
	CASE(1, TestCentury)
	default: name = ""; break;
	}
	}

	UBool
	DateFormatRoundTripTest::failure(UErrorCode status, const char* msg)
	{
	if(U_FAILURE(status)) {
	errln(UnicodeString("FAIL: ") + msg + " failed, error " + u_errorName(status));
	return TRUE;
	}

	return FALSE;
	}

	UBool
	DateFormatRoundTripTest::failure(UErrorCode status, const char* msg, const UnicodeString& str)
	{
	if(U_FAILURE(status)) {
	UnicodeString escaped;
	escape(str,escaped);
	errln(UnicodeString("FAIL: ") + msg + " failed, error " + u_errorName(status) + ", str=" + escaped);
	return TRUE;
	}

	return FALSE;
	}

	void DateFormatRoundTripTest::TestCentury()
	{
	UErrorCode status = U_ZERO_ERROR;
	Locale locale("es_PA");
	UnicodeString pattern = "MM/dd/yy hh:mm:ss a z";
	SimpleDateFormat fmt(pattern, locale, status);
	if (U_FAILURE(status)) {
	dataerrln("Fail: construct SimpleDateFormat: %s", u_errorName(status));
	return;
	}
	UDate date[] = {-55018555891590.05, 0, 0};
	UnicodeString result[2];

	fmt.format(date[0], result[0]);
	date[1] = fmt.parse(result[0], status);
	fmt.format(date[1], result[1]);
	date[2] = fmt.parse(result[1], status);

	/* This test case worked OK by accident before. date[1] != date[0],
	* because we use -80/+20 year window for 2-digit year parsing.
	* (date[0] is in year 1926, date[1] is in year 2026.) result[1] set
	* by the first format call returns "07/13/26 07:48:28 p.m. PST",
	* which is correct, because DST was not used in year 1926 in zone
	* America/Los_Angeles. When this is parsed, date[1] becomes a time
	* in 2026, which is "07/13/26 08:48:28 p.m. PDT". There was a zone
	* offset calculation bug that observed DST in 1926, which was resolved.
	* Before the bug was resolved, result[0] == result[1] was true,
	* but after the bug fix, the expected result is actually
	* result[0] != result[1]. -Yoshito
	*/
	/* TODO: We need to review this code and clarify what we really
	* want to test here.
	*/
	//if (date[1] != date[2] \|\| result[0] != result[1]) {
	if (date[1] != date[2]) {
	errln("Round trip failure: \"%S\" (%f), \"%S\" (%f)", result[0].getBuffer(), date[1], result[1].getBuffer(), date[2]);
	}
	}

	// ==

	void DateFormatRoundTripTest::TestDateFormatRoundTrip()
	{
	UErrorCode status = U_ZERO_ERROR;

	getFieldCal = Calendar::createInstance(status);
	if (U_FAILURE(status)) {
	dataerrln("Fail: Calendar::createInstance: %s", u_errorName(status));
	return;
	}


	int32_t locCount = 0;
	const Locale *avail = DateFormat::getAvailableLocales(locCount);
	logln("DateFormat available locales: %d", locCount);
	if(quick) {
	SPARSENESS = 18;
	logln("Quick mode: only testing SPARSENESS = 18");
	}
	TimeZone *tz = TimeZone::createDefault();
	UnicodeString temp;
	logln("Default TimeZone: " + tz->getID(temp));
	delete tz;

	#ifdef TEST_ONE_LOC // define this to just test ONE locale.
	Locale loc(TEST_ONE_LOC);
	test(loc);
	#if INFINITE
	for(;;) {
	test(loc);
	}
	#endif

	#else
	# if INFINITE
	// Special infinite loop test mode for finding hard to reproduce errors
	Locale loc = Locale::getDefault();
	logln("ENTERING INFINITE TEST LOOP FOR Locale: " + loc.getDisplayName(temp));
	for(;;)
	test(loc);
	# else
	test(Locale::getDefault());

	#if 1
	// installed locales
	for (int i=0; i < locCount; ++i) {
	test(avail[i]);
	}
	#endif

	#if 1
	// special locales
	int32_t jCount = CalendarTest::testLocaleCount();
	for (int32_t j=0; j < jCount; ++j) {
	test(Locale(CalendarTest::testLocaleID(j)));
	}
	#endif

	# endif
	#endif

	delete getFieldCal;
	}

	static const char *styleName(DateFormat::EStyle s)
	{
	switch(s)
	{
	case DateFormat::SHORT: return "SHORT";
	case DateFormat::MEDIUM: return "MEDIUM";
	case DateFormat::LONG: return "LONG";
	case DateFormat::FULL: return "FULL";
	// case DateFormat::DEFAULT: return "DEFAULT";
	case DateFormat::DATE_OFFSET: return "DATE_OFFSET";
	case DateFormat::NONE: return "NONE";
	case DateFormat::DATE_TIME: return "DATE_TIME";
	default: return "Unknown";
	}
	}

	void DateFormatRoundTripTest::test(const Locale& loc)
	{
	UnicodeString temp;
	#if !INFINITE
	logln("Locale: " + loc.getDisplayName(temp));
	#endif

	// Total possibilities = 24
	// 4 date
	// 4 time
	// 16 date-time
	UBool TEST_TABLE [24];//= new boolean[24];
	int32_t i = 0;
	for(i = 0; i < 24; ++i)
	TEST_TABLE[i] = TRUE;

	// If we have some sparseness, implement it here. Sparseness decreases
	// test time by eliminating some tests, up to 23.
	for(i = 0; i < SPARSENESS; ) {
	int random = (int)(randFraction() * 24);
	if (random >= 0 && random < 24 && TEST_TABLE[i]) {
	TEST_TABLE[i] = FALSE;
	++i;
	}
	}

	int32_t itable = 0;
	int32_t style = 0;
	for(style = DateFormat::FULL; style <= DateFormat::SHORT; ++style) {
	if(TEST_TABLE[itable++]) {
	logln("Testing style " + UnicodeString(styleName((DateFormat::EStyle)style)));
	DateFormat *df = DateFormat::createDateInstance((DateFormat::EStyle)style, loc);
	if(df == NULL) {
	errln(UnicodeString("Could not DF::createDateInstance ") + UnicodeString(styleName((DateFormat::EStyle)style)) + " Locale: " + loc.getDisplayName(temp));
	} else {
	test(df, loc);
	delete df;
	}
	}
	}

	for(style = DateFormat::FULL; style <= DateFormat::SHORT; ++style) {
	if (TEST_TABLE[itable++]) {
	logln("Testing style " + UnicodeString(styleName((DateFormat::EStyle)style)));
	DateFormat *df = DateFormat::createTimeInstance((DateFormat::EStyle)style, loc);
	if(df == NULL) {
	errln(UnicodeString("Could not DF::createTimeInstance ") + UnicodeString(styleName((DateFormat::EStyle)style)) + " Locale: " + loc.getDisplayName(temp));
	} else {
	test(df, loc, TRUE);
	delete df;
	}
	}
	}

	for(int32_t dstyle = DateFormat::FULL; dstyle <= DateFormat::SHORT; ++dstyle) {
	for(int32_t tstyle = DateFormat::FULL; tstyle <= DateFormat::SHORT; ++tstyle) {
	if(TEST_TABLE[itable++]) {
	logln("Testing dstyle" + UnicodeString(styleName((DateFormat::EStyle)dstyle)) + ", tstyle" + UnicodeString(styleName((DateFormat::EStyle)tstyle)) );
	DateFormat *df = DateFormat::createDateTimeInstance((DateFormat::EStyle)dstyle, (DateFormat::EStyle)tstyle, loc);
	if(df == NULL) {
	dataerrln(UnicodeString("Could not DF::createDateTimeInstance ") + UnicodeString(styleName((DateFormat::EStyle)dstyle)) + ", tstyle" + UnicodeString(styleName((DateFormat::EStyle)tstyle)) + "Locale: " + loc.getDisplayName(temp));
	} else {
	test(df, loc);
	delete df;
	}
	}
	}
	}
	}

	void DateFormatRoundTripTest::test(DateFormat *fmt, const Locale &origLocale, UBool timeOnly)
	{
	UnicodeString pat;
	if(fmt->getDynamicClassID() != SimpleDateFormat::getStaticClassID()) {
	errln("DateFormat wasn't a SimpleDateFormat");
	return;
	}

	UBool isGregorian = FALSE;
	UErrorCode minStatus = U_ZERO_ERROR;
	if(fmt->getCalendar() == NULL) {
	errln((UnicodeString)"DateFormatRoundTripTest::test, DateFormat getCalendar() returns null for " + origLocale.getName());
	return;
	}
	UDate minDate = CalendarTest::minDateOfCalendar(*fmt->getCalendar(), isGregorian, minStatus);
	if(U_FAILURE(minStatus)) {
	errln((UnicodeString)"Failure getting min date for " + origLocale.getName());
	return;
	}
	//logln(UnicodeString("Min date is ") + fullFormat(minDate) + " for " + origLocale.getName());

	pat = ((SimpleDateFormat*)fmt)->toPattern(pat);

	// NOTE TO MAINTAINER
	// This indexOf check into the pattern needs to be refined to ignore
	// quoted characters. Currently, this isn't a problem with the locale
	// patterns we have, but it may be a problem later.

	UBool hasEra = (pat.indexOf(UnicodeString("G")) != -1);
	UBool hasZoneDisplayName = (pat.indexOf(UnicodeString("z")) != -1) \|\| (pat.indexOf(UnicodeString("v")) != -1)
	\|\| (pat.indexOf(UnicodeString("V")) != -1);

	// Because patterns contain incomplete data representing the Date,
	// we must be careful of how we do the roundtrip. We start with
	// a randomly generated Date because they're easier to generate.
	// From this we get a string. The string is our real starting point,
	// because this string should parse the same way all the time. Note
	// that it will not necessarily parse back to the original date because
	// of incompleteness in patterns. For example, a time-only pattern won't
	// parse back to the same date.

	//try {
	for(int i = 0; i < TRIALS; ++i) {
	UDate *d = new UDate [DEPTH];
	UnicodeString *s = new UnicodeString[DEPTH];

	if(isGregorian == TRUE) {
	d[0] = generateDate();
	} else {
	d[0] = generateDate(minDate);
	}

	UErrorCode status = U_ZERO_ERROR;

	// We go through this loop until we achieve a match or until
	// the maximum loop count is reached. We record the points at
	// which the date and the string starts to match. Once matching
	// starts, it should continue.
	int loop;
	int dmatch = 0; // d[dmatch].getTime() == d[dmatch-1].getTime()
	int smatch = 0; // s[smatch].equals(s[smatch-1])
	for(loop = 0; loop < DEPTH; ++loop) {
	if (loop > 0) {
	d[loop] = fmt->parse(s[loop-1], status);
	failure(status, "fmt->parse", s[loop-1]+" in locale: " + origLocale.getName() + " with pattern: " + pat);
	status = U_ZERO_ERROR; /* any error would have been reported */
	}

	s[loop] = fmt->format(d[loop], s[loop]);

	// For displaying which date is being tested
	//logln(s[loop] + " = " + fullFormat(d[loop]));

	if(s[loop].length() == 0) {
	errln("FAIL: fmt->format gave 0-length string in " + pat + " with number " + d[loop] + " in locale " + origLocale.getName());
	}

	if(loop > 0) {
	if(smatch == 0) {
	UBool match = s[loop] == s[loop-1];
	if(smatch == 0) {
	if(match)
	smatch = loop;
	}
	else if( ! match)
	errln("FAIL: String mismatch after match");
	}

	if(dmatch == 0) {
	// {sfb} watch out here, this might not work
	UBool match = d[loop]/.getTime()/ == d[loop-1]/.getTime()/;
	if(dmatch == 0) {
	if(match)
	dmatch = loop;
	}
	else if( ! match)
	errln("FAIL: Date mismatch after match");
	}

	if(smatch != 0 && dmatch != 0)
	break;
	}
	}
	// At this point loop == DEPTH if we've failed, otherwise loop is the
	// max(smatch, dmatch), that is, the index at which we have string and
	// date matching.

	// Date usually matches in 2. Exceptions handled below.
	int maxDmatch = 2;
	int maxSmatch = 1;
	if (dmatch > maxDmatch) {
	// Time-only pattern with zone information and a starting date in PST.
	if(timeOnly && hasZoneDisplayName) {
	int32_t startRaw, startDst;
	fmt->getTimeZone().getOffset(d[0], FALSE, startRaw, startDst, status);
	failure(status, "TimeZone::getOffset");
	// if the start offset is greater than the offset on Jan 1, 1970
	// in PST, then need one more round trip. There are two cases
	// fall into this category. The start date is 1) DST or
	// 2) LMT (GMT-07:52:58).
	if (startRaw + startDst > -28800000) {
	maxDmatch = 3;
	maxSmatch = 2;
	}
	}
	}

	// String usually matches in 1. Exceptions are checked for here.
	if(smatch > maxSmatch) { // Don't compute unless necessary
	UBool in0;
	// Starts in BC, with no era in pattern
	if( ! hasEra && getField(d[0], UCAL_ERA) == GregorianCalendar::BC)
	maxSmatch = 2;
	// Starts in DST, no year in pattern
	else if((in0=fmt->getTimeZone().inDaylightTime(d[0], status)) && ! failure(status, "gettingDaylightTime") &&
	pat.indexOf(UnicodeString("yyyy")) == -1)
	maxSmatch = 2;
	// If we start not in DST, but transition into DST
	else if (!in0 &&
	fmt->getTimeZone().inDaylightTime(d[1], status) && !failure(status, "gettingDaylightTime"))
	maxSmatch = 2;
	// Two digit year with no time zone change,
	// unless timezone isn't used or we aren't close to the DST changover
	else if (pat.indexOf(UnicodeString("y")) != -1
	&& pat.indexOf(UnicodeString("yyyy")) == -1
	&& getField(d[0], UCAL_YEAR)
	!= getField(d[dmatch], UCAL_YEAR)
	&& !failure(status, "error status [smatch>maxSmatch]")
	&& ((hasZoneDisplayName
	&& (fmt->getTimeZone().inDaylightTime(d[0], status)
	== fmt->getTimeZone().inDaylightTime(d[dmatch], status)
	\|\| getField(d[0], UCAL_MONTH) == UCAL_APRIL
	\|\| getField(d[0], UCAL_MONTH) == UCAL_OCTOBER))
	\|\| !hasZoneDisplayName)
	)
	{
	maxSmatch = 2;
	}
	// If zone display name is used, fallback format might be used before 1970
	else if (hasZoneDisplayName && d[0] < 0) {
	maxSmatch = 2;
	}
	else if (timeOnly && !isGregorian && hasZoneDisplayName && maxSmatch == 1) {
	int32_t startRaw, startDst;
	fmt->getTimeZone().getOffset(d[1], FALSE, startRaw, startDst, status);
	failure(status, "TimeZone::getOffset");
	// If the calendar type is not Gregorian and the pattern is time only,
	// the calendar implementation may use a date before 1970 as day 0.
	// In this case, time zone offset of the default year might be
	// different from the one at 1970-01-01 in PST and string match requires
	// one more iteration.
	if (startRaw + startDst != -28800000) {
	maxSmatch = 2;
	}
	}
	}

	/*
	* Special case for Japanese and Buddhist (could have large negative years)
	* Also, Hebrew calendar need help handling leap month.
	*/
	if(dmatch > maxDmatch \|\| smatch > maxSmatch) {
	const char *type = fmt->getCalendar()->getType();
	if(!strcmp(type,"japanese") \|\| (!strcmp(type,"buddhist"))) {
	maxSmatch = 4;
	maxDmatch = 4;
	} else if(!strcmp(type,"hebrew")) {
	maxSmatch = 3;
	maxDmatch = 3;
	}
	}

	// Use @v to see verbose results on successful cases
	UBool fail = (dmatch > maxDmatch \|\| smatch > maxSmatch);
	if (optionv \|\| fail) {
	if (fail) {
	errln(UnicodeString("\nFAIL: Pattern: ") + pat +
	" in Locale: " + origLocale.getName());
	} else {
	errln(UnicodeString("\nOk: Pattern: ") + pat +
	" in Locale: " + origLocale.getName());
	}

	logln("Date iters until match=%d (max allowed=%d), string iters until match=%d (max allowed=%d)",
	dmatch,maxDmatch, smatch, maxSmatch);

	for(int j = 0; j <= loop && j < DEPTH; ++j) {
	UnicodeString temp;
	FieldPosition pos(FieldPosition::DONT_CARE);
	errln((j>0?" P> ":" ") + fullFormat(d[j]) + " F> " +
	escape(s[j], temp) + UnicodeString(" d=") + d[j] +
	(j > 0 && d[j]/.getTime()/==d[j-1]/.getTime()/?" d==":"") +
	(j > 0 && s[j] == s[j-1]?" s==":""));
	}
	}
	delete[] d;
	delete[] s;
	}
	/*}
	catch (ParseException e) {
	errln("Exception: " + e.getMessage());
	logln(e.toString());
	}*/
	}

	const UnicodeString& DateFormatRoundTripTest::fullFormat(UDate d) {
	UErrorCode ec = U_ZERO_ERROR;
	if (dateFormat == 0) {
	dateFormat = new SimpleDateFormat((UnicodeString)"EEE MMM dd HH:mm:ss.SSS zzz yyyy G", ec);
	if (U_FAILURE(ec) \|\| dateFormat == 0) {
	fgStr = "[FAIL: SimpleDateFormat constructor]";
	delete dateFormat;
	dateFormat = 0;
	return fgStr;
	}
	}
	fgStr.truncate(0);
	dateFormat->format(d, fgStr);
	return fgStr;
	}

	/**
	* Return a field of the given date
	*/
	int32_t DateFormatRoundTripTest::getField(UDate d, int32_t f) {
	// Should be synchronized, but we're single threaded so it's ok
	UErrorCode status = U_ZERO_ERROR;
	getFieldCal->setTime(d, status);
	failure(status, "getfieldCal->setTime");
	int32_t ret = getFieldCal->get((UCalendarDateFields)f, status);
	failure(status, "getfieldCal->get");
	return ret;
	}

	UnicodeString& DateFormatRoundTripTest::escape(const UnicodeString& src, UnicodeString& dst )
	{
	dst.remove();
	for (int32_t i = 0; i < src.length(); ++i) {
	UChar c = src[i];
	if(c < 0x0080)
	dst += c;
	else {
	dst += UnicodeString("[");
	char buf [8];
	sprintf(buf, "%#x", c);
	dst += UnicodeString(buf);
	dst += UnicodeString("]");
	}
	}

	return dst;
	}

	#define U_MILLIS_PER_YEAR (365.25 * 24 * 60 * 60 * 1000)

	UDate DateFormatRoundTripTest::generateDate(UDate minDate)
	{
	// Bring range in conformance to generateDate() below.
	if(minDate < (U_MILLIS_PER_YEAR * -(4000-1970))) {
	minDate = (U_MILLIS_PER_YEAR * -(4000-1970));
	}
	for(int i=0;i<8;i++) {
	double a = randFraction();

	// Range from (min) to (8000-1970) AD
	double dateRange = (0.0 - minDate) + (U_MILLIS_PER_YEAR + (8000-1970));

	a *= dateRange;

	// Now offset from minDate
	a += minDate;

	// Last sanity check
	if(a>=minDate) {
	return a;
	}
	}
	return minDate;
	}

	UDate DateFormatRoundTripTest::generateDate()
	{
	double a = randFraction();

	// Now 'a' ranges from 0..1; scale it to range from 0 to 8000 years
	a *= 8000;

	// Range from (4000-1970) BC to (8000-1970) AD
	a -= 4000;

	// Now scale up to ms
	a = 365.25 24 * 60 * 60 * 1000;

	//return new Date((long)a);
	return a;
	}

	#endif /* #if !UCONFIG_NO_FORMATTING */

	//eof