/* boost limits_test.cpp test your <limits> file for important * * Copyright Jens Maurer 2000 * Permission to use, copy, modify, sell, and distribute this software * is hereby granted without fee provided that the above copyright notice * appears in all copies and that both that copyright notice and this * permission notice appear in supporting documentation, * * Jens Maurer makes no representations about the suitability of this * software for any purpose. It is provided "as is" without express or * implied warranty. * */ #include <limits> //#include <sstream> #include "cppunit/cppunit_proxy.h" #if !defined (STLPORT) || defined(_STLP_USE_NAMESPACES) using namespace std; #endif // // TestCase class // class LimitTest : public CPPUNIT_NS::TestCase { CPPUNIT_TEST_SUITE(LimitTest); # if defined (__BORLANDC__) /* Ignore FPU exceptions, set FPU precision to 64 bits */ unsigned int _float_control_word = _control87(0, 0); _control87(PC_64|MCW_EM|IC_AFFINE, MCW_PC|MCW_EM|MCW_IC); # endif CPPUNIT_TEST(test); CPPUNIT_TEST(qnan_test); # if defined (__BORLANDC__) /* Reset floating point control word */ _clear87(); _control87(_float_control_word, MCW_PC|MCW_EM|MCW_IC); # endif CPPUNIT_TEST_SUITE_END(); protected: void test(); void qnan_test(); }; CPPUNIT_TEST_SUITE_REGISTRATION(LimitTest); #if defined (STLPORT) && defined (_STLP_STATIC_CONST_INIT_BUG) # define CHECK_COND(X) if (!(X)) { CPPUNIT_MESSAGE(#X); return false; } #else //This version force to have external linkage on static constant which might //reveal that _STLP_NO_STATIC_CONST_DEFINITION should be commented. bool check_cond(const bool& cond) { return cond; } # define CHECK_COND(X) if (!check_cond(X)) { CPPUNIT_MESSAGE(#X); return false; } #endif bool valid_sign_info(bool, bool) { return true; } template <class _Tp> bool valid_sign_info(bool limit_is_signed, const _Tp &) { return (limit_is_signed && _Tp(-1) < 0) || (!limit_is_signed && _Tp(-1) > 0); } template <class _Tp> bool test_integral_limits_base(const _Tp &, bool unknown_sign = true, bool is_signed = true) { typedef numeric_limits<_Tp> lim; CHECK_COND(lim::is_specialized); CHECK_COND(lim::is_exact); CHECK_COND(lim::is_integer); CHECK_COND(!lim::is_iec559); CHECK_COND(lim::min() < lim::max()); CHECK_COND((unknown_sign && ((lim::is_signed && (lim::min() != 0)) || (!lim::is_signed && (lim::min() == 0)))) || (!unknown_sign && ((lim::is_signed && is_signed) || (!lim::is_signed && !is_signed)))); if (unknown_sign) { CHECK_COND(valid_sign_info(lim::is_signed, _Tp())); } return true; } template <class _Tp> bool test_integral_limits(const _Tp &val, bool unknown_sign = true, bool is_signed = true) { if (!test_integral_limits_base(val, unknown_sign, is_signed)) return false; typedef numeric_limits<_Tp> lim; CHECK_COND(lim::is_modulo); if (lim::is_bounded || (!lim::is_bounded && !lim::is_signed)) { _Tp tmp = lim::min(); CHECK_COND( --tmp > lim::min() ); } if (lim::is_bounded) { _Tp tmp = lim::max(); CHECK_COND( ++tmp < lim::max() ); } return true; } template <class _Tp> bool test_signed_integral_limits(const _Tp &__val) { return test_integral_limits(__val, false, true); } template <class _Tp> bool test_unsigned_integral_limits(const _Tp &__val) { return test_integral_limits(__val, false, false); } template <class _Tp> bool test_float_values(_Tp lhs, _Tp rhs) { return lhs == rhs; } template <class _Tp> bool test_float_limits(const _Tp &) { typedef numeric_limits<_Tp> lim; CHECK_COND(lim::is_specialized); CHECK_COND(!lim::is_modulo); CHECK_COND(!lim::is_integer); CHECK_COND(lim::is_signed); CHECK_COND(lim::max() > 1000); CHECK_COND(lim::min() > 0); CHECK_COND(lim::min() < 0.001); CHECK_COND(lim::epsilon() > 0); if (lim::is_iec559) { CHECK_COND(lim::has_infinity); CHECK_COND(lim::has_quiet_NaN); CHECK_COND(lim::has_signaling_NaN); CHECK_COND(lim::has_denorm == denorm_present); } if (lim::has_denorm == denorm_absent) { CHECK_COND(lim::denorm_min() == lim::min()); _Tp tmp = lim::min(); tmp /= 2; if (tmp > 0 && tmp < lim::min()) { // has_denorm could be denorm_present CPPUNIT_MESSAGE("It looks like your compiler/platform supports denormalized floating point representation."); } } else if (lim::has_denorm == denorm_present) { CHECK_COND(lim::denorm_min() > 0); CHECK_COND(lim::denorm_min() < lim::min()); _Tp tmp = lim::min(); while (tmp != 0) { _Tp old_tmp = tmp; tmp /= 2; CHECK_COND(tmp < old_tmp); CHECK_COND(tmp >= lim::denorm_min() || tmp == (_Tp)0); //ostringstream str; //str << "denorm_min = " << lim::denorm_min() << ", tmp = " << tmp; //CPPUNIT_MESSAGE(str.str().c_str()); } } if (lim::has_infinity) { const _Tp infinity = lim::infinity(); /* Make sure those values are not 0 or similar nonsense. * Infinity must compare as if larger than the maximum representable value. */ _Tp val = lim::max(); val *= 2; /* We use test_float_values because without it some compilers (gcc) perform weird * optimization on the test giving unexpected result. */ CHECK_COND(test_float_values(val, infinity)); /* ostringstream str; str << "lim::max() = " << lim::max() << ", val = " << val << ", infinity = " << infinity; CPPUNIT_MESSAGE( str.str().c_str() ); str.str(string()); str << "sizeof(_Tp) = " << sizeof(_Tp); CPPUNIT_MESSAGE( str.str().c_str() ); if (sizeof(_Tp) == 4) { str.str(string()); str << "val in hexa: " << showbase << hex << *((const unsigned int*)&val); str << ", infinity in hexa: " << showbase << hex << *((const unsigned int*)&infinity); } #if defined (_STLP_LONG_LONG) else if (sizeof(_Tp) == sizeof(_STLP_LONG_LONG)) { str.str(string()); str << "val in hexa: " << showbase << hex << *((const unsigned _STLP_LONG_LONG*)&val); str << ", infinity in hexa: " << showbase << hex << *((const unsigned _STLP_LONG_LONG*)&infinity); } #endif else { str.str(string()); str << "val: "; for (int i = 0; i != sizeof(_Tp) / sizeof(unsigned short); ++i) { if (i != 0) str << ' '; str << showbase << hex << setw(4) << setfill('0') << *((const unsigned short*)&val + i); } str << ", infinity: "; for (int i = 0; i != sizeof(_Tp) / sizeof(unsigned short); ++i) { if (i != 0) str << ' '; str << showbase << hex << setw(4) << setfill('0') << *((const unsigned short*)&infinity + i); } } CPPUNIT_MESSAGE( str.str().c_str() ); str.str(string()); str << dec; str << "lim::digits = " << lim::digits << ", lim::digits10 = " << lim::digits10 << endl; str << "lim::min_exponent = " << lim::min_exponent << ", lim::min_exponent10 = " << lim::min_exponent10 << endl; str << "lim::max_exponent = " << lim::max_exponent << ", lim::max_exponent10 = " << lim::max_exponent10 << endl; CPPUNIT_MESSAGE( str.str().c_str() ); */ CHECK_COND(infinity == infinity); CHECK_COND(infinity > lim::max()); CHECK_COND(-infinity < -lim::max()); } return true; } //float generate_nan(float f) { // return 0.0f / f; //} template <class _Tp> bool test_qnan(const _Tp &) { typedef numeric_limits<_Tp> lim; if (lim::has_quiet_NaN) { const _Tp qnan = lim::quiet_NaN(); //if (sizeof(_Tp) == 4) { // ostringstream str; // str << "qnan " << qnan << ", in hexa: " << showbase << hex << *((unsigned int*)&qnan); // CPPUNIT_MESSAGE( str.str().c_str() ); // str.str(""); // float val = generate_nan(0.0f); // str << "val " << val << ", in hexa: " << showbase << hex << *((unsigned int*)&val); // CPPUNIT_MESSAGE( str.str().c_str() ); // str.str(""); // val = -qnan; // str << "-qnan " << val << ", in hexa: " << showbase << hex << *((unsigned int*)&val); // CPPUNIT_MESSAGE( str.str().c_str() ); //} /* NaNs shall always compare "false" when compared for equality * If one of these fail, your compiler may be optimizing incorrectly, * or the STLport is incorrectly configured. */ CHECK_COND(! (qnan == 42)); CHECK_COND(! (qnan == qnan)); CHECK_COND(qnan != 42); CHECK_COND(qnan != qnan); /* The following tests may cause arithmetic traps. * CHECK_COND(! (qnan < 42)); * CHECK_COND(! (qnan > 42)); * CHECK_COND(! (qnan <= 42)); * CHECK_COND(! (qnan >= 42)); */ } return true; } class ArbitraryType {}; void LimitTest::test() { CPPUNIT_CHECK(test_integral_limits_base(bool())); CPPUNIT_CHECK(test_integral_limits(char())); typedef signed char signed_char; CPPUNIT_CHECK(test_signed_integral_limits(signed_char())); typedef unsigned char unsigned_char; CPPUNIT_CHECK(test_unsigned_integral_limits(unsigned_char())); # if defined (_STLP_HAS_WCHAR_T) && !defined (_STLP_WCHAR_T_IS_USHORT) CPPUNIT_CHECK(test_integral_limits(wchar_t())); # endif CPPUNIT_CHECK(test_signed_integral_limits(short())); typedef unsigned short unsigned_short; CPPUNIT_CHECK(test_unsigned_integral_limits(unsigned_short())); CPPUNIT_CHECK(test_signed_integral_limits(int())); typedef unsigned int unsigned_int; CPPUNIT_CHECK(test_unsigned_integral_limits(unsigned_int())); CPPUNIT_CHECK(test_signed_integral_limits(long())); typedef unsigned long unsigned_long; CPPUNIT_CHECK(test_unsigned_integral_limits(unsigned_long())); # if defined (_STLP_LONG_LONG) typedef _STLP_LONG_LONG long_long; CPPUNIT_CHECK(test_signed_integral_limits(long_long())); typedef unsigned _STLP_LONG_LONG unsigned_long_long; CPPUNIT_CHECK(test_unsigned_integral_limits(unsigned_long_long())); #endif CPPUNIT_CHECK(test_float_limits(float())); CPPUNIT_CHECK(test_float_limits(double())); # if !defined ( _STLP_NO_LONG_DOUBLE ) typedef long double long_double; CPPUNIT_CHECK(test_float_limits(long_double())); # endif CPPUNIT_ASSERT( !numeric_limits<ArbitraryType>::is_specialized ); } void LimitTest::qnan_test() { CPPUNIT_CHECK(test_qnan(float())); CPPUNIT_CHECK(test_qnan(double())); # if !defined ( _STLP_NO_LONG_DOUBLE ) typedef long double long_double; CPPUNIT_CHECK(test_qnan(long_double())); # endif }