/*********************************************************************** * COPYRIGHT: * Copyright (c) 1997-2004, International Business Machines Corporation * and others. All Rights Reserved. ***********************************************************************/ #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include "unicode/decimfmt.h" #include "tsnmfmt.h" #include "putilimp.h" #include #include IntlTestNumberFormat::~IntlTestNumberFormat() {} static const char * formattableTypeName(Formattable::Type t) { switch(t) { case Formattable::kDate: return "kDate"; case Formattable::kDouble: return "kDouble"; case Formattable::kLong: return "kLong"; case Formattable::kString: return "kString"; case Formattable::kArray: return "kArray"; case Formattable::kInt64: return "kInt64"; default: return "??unknown??"; } } /** * This test does round-trip testing (format -> parse -> format -> parse -> etc.) of * NumberFormat. */ void IntlTestNumberFormat::runIndexedTest( int32_t index, UBool exec, const char* &name, char* /*par*/ ) { if (exec) logln((UnicodeString)"TestSuite NumberFormat"); switch (index) { case 0: name = "createInstance"; if (exec) { logln(name); fStatus = U_ZERO_ERROR; fFormat = NumberFormat::createInstance(fStatus); testFormat(/*par*/); } break; case 1: name = "DefaultLocale"; if (exec) testLocale(/*par, */Locale::getDefault(), name); break; case 2: name = "testAvailableLocales"; if (exec) { logln(name); testAvailableLocales(/*par*/); } break; case 3: name = "monsterTest"; if (exec) { logln(name); monsterTest(/*par*/); } break; default: name = ""; break; } } void IntlTestNumberFormat::testLocale(/* char* par, */const Locale& locale, const UnicodeString& localeName) { const char* name; fLocale = locale; name = "Number test"; logln((UnicodeString)name + " (" + localeName + ")"); fStatus = U_ZERO_ERROR; fFormat = NumberFormat::createInstance(locale, fStatus); testFormat(/* par */); name = "Currency test"; logln((UnicodeString)name + " (" + localeName + ")"); fStatus = U_ZERO_ERROR; fFormat = NumberFormat::createCurrencyInstance(locale, fStatus); testFormat(/* par */); name = "Percent test"; logln((UnicodeString)name + " (" + localeName + ")"); fStatus = U_ZERO_ERROR; fFormat = NumberFormat::createPercentInstance(locale, fStatus); testFormat(/* par */); } double IntlTestNumberFormat::randDouble() { // Assume 8-bit (or larger) rand values. Also assume // that the system rand() function is very poor, which it always is. // Call srand(currentTime) in intltest to make it truly random. double d; uint32_t i; char* poke = (char*)&d; do { for (i=0; i < sizeof(double); ++i) { poke[i] = (char)(rand() & 0xFF); } } while (uprv_isNaN(d) || uprv_isInfinite(d) || !((-DBL_MAX < d && d < DBL_MAX) || (d < -DBL_MIN && DBL_MIN < d))); return d; } /* * Return a random uint32_t **/ uint32_t IntlTestNumberFormat::randLong() { // Assume 8-bit (or larger) rand values. Also assume // that the system rand() function is very poor, which it always is. // Call srand(currentTime) in intltest to make it truly random. uint32_t d; uint32_t i; char* poke = (char*)&d; for (i=0; i < sizeof(uint32_t); ++i) { poke[i] = (char)(rand() & 0xFF); } return d; } /* Make sure that we don't get something too large and multiply into infinity. @param smallerThanMax the requested maximum value smaller than DBL_MAX */ double IntlTestNumberFormat::getSafeDouble(double smallerThanMax) { double it; double high = (DBL_MAX/smallerThanMax)/10.0; double low = -high; do { it = randDouble(); } while (low > it || it > high); return it; } void IntlTestNumberFormat::testFormat(/* char* par */) { if (U_FAILURE(fStatus)) { errln((UnicodeString)"**** FAIL: createXxxInstance failed."); if (fFormat != 0) errln("**** FAIL: Non-null format returned by createXxxInstance upon failure."); delete fFormat; fFormat = 0; return; } if (fFormat == 0) { errln((UnicodeString)"**** FAIL: Null format returned by createXxxInstance."); return; } UnicodeString str; // Assume it's a DecimalFormat and get some info DecimalFormat *s = (DecimalFormat*)fFormat; logln((UnicodeString)" Pattern " + s->toPattern(str)); #if defined(OS390) || defined(OS400) tryIt(-2.02147304840132e-68); tryIt(3.88057859588817e-68); // Test rounding when only some digits are shown because exponent is close to -maxfrac tryIt(-2.64651110485945e+65); // Overflows to +INF when shown as a percent tryIt(9.29526819488338e+64); // Ok -- used to fail? #else tryIt(-2.02147304840132e-100); tryIt(3.88057859588817e-096); // Test rounding when only some digits are shown because exponent is close to -maxfrac tryIt(-2.64651110485945e+306); // Overflows to +INF when shown as a percent tryIt(9.29526819488338e+250); // Ok -- used to fail? #endif // These PASS now, with the sprintf/atof based format-parse. // These fail due to round-off // The least significant digit drops by one during each format-parse cycle. // Both numbers DON'T have a round-off problem when multiplied by 100! (shown as %) #ifdef OS390 tryIt(-9.18228054496402e+64); tryIt(-9.69413034454191e+64); #else tryIt(-9.18228054496402e+255); tryIt(-9.69413034454191e+273); #endif #ifndef OS390 tryIt(1.234e-200); tryIt(-2.3e-168); tryIt(uprv_getNaN()); tryIt(uprv_getInfinity()); tryIt(-uprv_getInfinity()); #endif tryIt((int32_t)251887531); tryIt(5e-20 / 9); tryIt(5e20 / 9); tryIt(1.234e-50); tryIt(9.99999999999996); tryIt(9.999999999999996); tryIt((int32_t)INT32_MIN); tryIt((int32_t)INT32_MAX); tryIt((double)INT32_MIN); tryIt((double)INT32_MAX); tryIt((double)INT32_MIN - 1.0); tryIt((double)INT32_MAX + 1.0); tryIt(5.0 / 9.0 * 1e-20); tryIt(4.0 / 9.0 * 1e-20); tryIt(5.0 / 9.0 * 1e+20); tryIt(4.0 / 9.0 * 1e+20); tryIt(2147483647.); tryIt((int32_t)0); tryIt(0.0); tryIt((int32_t)1); tryIt((int32_t)10); tryIt((int32_t)100); tryIt((int32_t)-1); tryIt((int32_t)-10); tryIt((int32_t)-100); tryIt((int32_t)-1913860352); for (int32_t z=0; z<10; ++z) { double d = randFraction() * 2e10 - 1e10; tryIt(d); } double it = getSafeDouble(100000.0); tryIt(0.0); tryIt(it); tryIt((int32_t)0); tryIt(uprv_floor(it)); tryIt((int32_t)randLong()); // try again it = getSafeDouble(100.0); tryIt(it); tryIt(uprv_floor(it)); tryIt((int32_t)randLong()); // try again with very large numbers it = getSafeDouble(100000000000.0); tryIt(it); // try again with very large numbers // and without going outside of the int32_t range it = randFraction() * INT32_MAX; tryIt(it); tryIt((int32_t)uprv_floor(it)); delete fFormat; } void IntlTestNumberFormat::tryIt(double aNumber) { const int32_t DEPTH = 10; Formattable number[DEPTH]; UnicodeString string[DEPTH]; int32_t numberMatch = 0; int32_t stringMatch = 0; UnicodeString errMsg; int32_t i; for (i=0; iparse(string[i-1], number[i], status); if (U_FAILURE(status)) { number[i].setDouble(1234.5); // "parse failed" value errMsg = "**** FAIL: Parse of " + prettify(string[i-1]) + " failed."; --i; // don't show empty last line: "1234.5 F> (n/a) P>" break; } } // Convert from long to double if (number[i].getType() == Formattable::kLong) number[i].setDouble(number[i].getLong()); else if (number[i].getType() == Formattable::kInt64) number[i].setDouble((double)number[i].getInt64()); else if (number[i].getType() != Formattable::kDouble) { errMsg = ("**** FAIL: Parse of " + prettify(string[i-1]) + " returned non-numeric Formattable, type " + UnicodeString(formattableTypeName(number[i].getType())) + ", Locale=" + UnicodeString(fLocale.getName()) + ", longValue=" + number[i].getLong()); break; } string[i].truncate(0); fFormat->format(number[i].getDouble(), string[i]); if (i > 0) { if (numberMatch == 0 && number[i] == number[i-1]) numberMatch = i; else if (numberMatch > 0 && number[i] != number[i-1]) { errMsg = ("**** FAIL: Numeric mismatch after match."); break; } if (stringMatch == 0 && string[i] == string[i-1]) stringMatch = i; else if (stringMatch > 0 && string[i] != string[i-1]) { errMsg = ("**** FAIL: String mismatch after match."); break; } } if (numberMatch > 0 && stringMatch > 0) break; } if (i == DEPTH) --i; if (stringMatch > 2 || numberMatch > 2) { errMsg = ("**** FAIL: No string and/or number match within 2 iterations."); } if (errMsg.length() != 0) { for (int32_t k=0; k<=i; ++k) { logln((UnicodeString)"" + k + ": " + number[k].getDouble() + " F> " + prettify(string[k]) + " P> "); } errln(errMsg); } } void IntlTestNumberFormat::tryIt(int32_t aNumber) { Formattable number(aNumber); UnicodeString stringNum; UErrorCode status = U_ZERO_ERROR; fFormat->format(number, stringNum, status); if (U_FAILURE(status)) { errln("**** FAIL: Formatting " + aNumber); return; } fFormat->parse(stringNum, number, status); if (U_FAILURE(status)) { errln("**** FAIL: Parse of " + prettify(stringNum) + " failed."); return; } if (number.getType() != Formattable::kLong) { errln("**** FAIL: Parse of " + prettify(stringNum) + " returned non-long Formattable, type " + UnicodeString(formattableTypeName(number.getType())) + ", Locale=" + UnicodeString(fLocale.getName()) + ", doubleValue=" + number.getDouble() + ", longValue=" + number.getLong() + ", origValue=" + aNumber ); } if (number.getLong() != aNumber) { errln("**** FAIL: Parse of " + prettify(stringNum) + " failed. Got:" + number.getLong() + " Expected:" + aNumber); } } void IntlTestNumberFormat::testAvailableLocales(/* char* par */) { int32_t count = 0; const Locale* locales = NumberFormat::getAvailableLocales(count); logln((UnicodeString)"" + count + " available locales"); if (locales && count) { UnicodeString name; UnicodeString all; for (int32_t i=0; i 6) { logln("quick test: testing just 6 locales!"); count = 6; locales = quickLocales; locales[0] = allLocales[0]; locales[1] = allLocales[1]; locales[2] = allLocales[2]; // In a quick test, make sure we test locales that use // currency prefix, currency suffix, and choice currency // logic. Otherwise bugs in these areas can slip through. locales[3] = Locale("ar", "AE", ""); locales[4] = Locale("cs", "CZ", ""); locales[5] = Locale("en", "IN", ""); } for (int32_t i=0; i