boost_1_45_0/libs/config/test/limits_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* boost limits_test.cpp   test your <limits> file for important
  *
  * Copyright Jens Maurer 2000
  * Distributed under the Boost Software License, Version 1.0. (See
  * accompanying file LICENSE_1_0.txt or copy at
  * http://www.boost.org/LICENSE_1_0.txt)
  *
  * $Id: limits_test.cpp 30181 2005-07-19 17:14:00Z johnmaddock $
  */

 #include <boost/limits.hpp>
 #define BOOST_INCLUDE_MAIN
 #include <boost/test/test_tools.hpp>
 #include <iostream>

 /*
  * General portability note:
  * MSVC mis-compiles explicit function template instantiations.
  * For example, f<A>() and f<B>() are both compiled to call f<A>().
  * BCC is unable to implicitly convert a "const char *" to a std::string
  * when using explicit function template instantiations.
  *
  * Therefore, avoid explicit function template instantiations.
  */
 #if defined(BOOST_MSVC) && (BOOST_MSVC <= 1300)
 template<typename T> inline T make_char_numeric_for_streaming(T x) { return x; }
 namespace fix{
 inline int make_char_numeric_for_streaming(char c) { return c; }
 inline int make_char_numeric_for_streaming(signed char c) { return c; }
 inline int make_char_numeric_for_streaming(unsigned char c) { return c; }
 }
 using namespace fix;
 #  if defined(_YVALS) && !defined(_CPPLIB_VER) && !defined(__SGI_STL_PORT) && !defined(_STLPORT_VERSION)
 // fix for missing operator<< in original Dinkumware lib:
 std::ostream& operator<<(std::ostream& os, __int64 i )
 {
     char buf[80];
     sprintf(buf,"%I64d", i );
     os << buf;
     return os;
 }
 std::ostream& operator<<(std::ostream& os, unsigned __int64 i )
 {
     char buf[80];
     sprintf(buf,"%I64u", i );
     os << buf;
     return os;
 }
 #  endif
 #else
 template<typename T> inline T make_char_numeric_for_streaming(T x) { return x; }
 inline int make_char_numeric_for_streaming(char c) { return c; }
 inline int make_char_numeric_for_streaming(signed char c) { return c; }
 inline int make_char_numeric_for_streaming(unsigned char c) { return c; }
 #endif

 #if (defined(_GLIBCPP_VERSION) || defined(_GLIBCXX_VERSION)) \
    && defined(BOOST_HAS_LONG_LONG) \
    && !defined(_GLIBCPP_USE_LONG_LONG) \
    && !defined(_GLIBCXX_USE_LONG_LONG)
 //
 // Some libstdc++ versions have numeric_limits<long long> but no
 // iostream support for long long.  TODO, find a better fix!!
 //
 std::ostream& operator<<(std::ostream& os, long long i )
 {
     return os << static_cast<long double>(i);
 }
 std::ostream& operator<<(std::ostream& os, unsigned long long i )
 {
     return os << static_cast<long double>(i);
 }
 #endif

 template<class T>
 void test_integral_limits(const T &, const char * msg)
 {
   typedef std::numeric_limits<T> lim;
   std::cout << "Testing " << msg
             << " (size " << sizeof(T) << ")"
             << " min: " << make_char_numeric_for_streaming((lim::min)())
             << ", max: " << make_char_numeric_for_streaming((lim::max)())
             << std::endl;

   BOOST_CHECK(static_cast<bool>(lim::is_specialized));
   BOOST_CHECK(static_cast<bool>(lim::is_integer));
   // BOOST_CHECK(lim::is_modulo);
   BOOST_CHECK(static_cast<bool>((lim::min)() < (lim::max)()));
 }

 template <class T>
 void print_hex_val(T t, const char* name)
 {
   const unsigned char* p = (const unsigned char*)&t;
   std::cout << "hex value of " << name << " is: ";
   for (unsigned int i = 0; i < sizeof(T); ++i) {
     if(p[i] <= 0xF)
       std::cout << "0";
     std::cout << std::hex << (int)p[i];
   }
   std::cout << std::dec << std::endl;
 }

 template<class T>
 void test_float_limits(const T &, const char * msg)
 {
   std::cout << "\nTesting " << msg << std::endl;
   typedef std::numeric_limits<T> lim;

   BOOST_CHECK(static_cast<bool>(lim::is_specialized));
   BOOST_CHECK(static_cast<bool>(!lim::is_modulo));
   BOOST_CHECK(static_cast<bool>(!lim::is_integer));
   BOOST_CHECK(static_cast<bool>(lim::is_signed));

   const T infinity = lim::infinity();
   const T qnan = lim::quiet_NaN();
   const T snan = lim::signaling_NaN();

   std::cout << "IEEE-compatible: " << lim::is_iec559
        << ", traps: " << lim::traps
        << ", bounded: " << lim::is_bounded
        << ", exact: " << lim::is_exact << '\n'
        << "min: " << (lim::min)() << ", max: " << (lim::max)() << '\n'
        << "infinity: " << infinity << ", QNaN: " << qnan << '\n';
   print_hex_val((lim::max)(), "max");
   print_hex_val(infinity, "infinity");
   print_hex_val(qnan, "qnan");
   print_hex_val(snan, "snan");

   BOOST_CHECK((lim::max)() > 1000);
   BOOST_CHECK((lim::min)() > 0);
   BOOST_CHECK((lim::min)() < 0.001);
   BOOST_CHECK(lim::epsilon() > 0);

   if(lim::is_iec559) {
     BOOST_CHECK(static_cast<bool>(lim::has_infinity));
     BOOST_CHECK(static_cast<bool>(lim::has_quiet_NaN));
     BOOST_CHECK(static_cast<bool>(lim::has_signaling_NaN));
   } else {
     std::cout << "Does not claim IEEE conformance" << std::endl;
   }

   if(lim::has_infinity) {
     // Make sure those values are not 0 or similar nonsense.
     // Infinity must compare as if larger than the maximum representable value.
     BOOST_CHECK(infinity > (lim::max)());
     BOOST_CHECK(-infinity < -(lim::max)());
   } else {
     std::cout << "Does not have infinity" << std::endl;
   }

   if(lim::has_quiet_NaN) {
     // NaNs shall always compare "false" when compared for equality
     // If one of these fail, your compiler may be optimizing incorrectly,
     // or the standard library is incorrectly configured.
     BOOST_CHECK(! (qnan == 42));
     BOOST_CHECK(! (qnan == qnan));
     BOOST_CHECK(qnan != 42);
     BOOST_CHECK(qnan != qnan);

     // The following tests may cause arithmetic traps.
     // BOOST_CHECK(! (qnan < 42));
     // BOOST_CHECK(! (qnan > 42));
     // BOOST_CHECK(! (qnan <= 42));
     // BOOST_CHECK(! (qnan >= 42));
   } else {
     std::cout << "Does not have QNaN" << std::endl;
   }
 }


 int test_main(int, char*[])
 {
   test_integral_limits(bool(), "bool");
   test_integral_limits(char(), "char");
   typedef signed char signed_char;
   test_integral_limits(signed_char(), "signed char");
   typedef unsigned char unsigned_char;
   test_integral_limits(unsigned_char(), "unsigned char");
   test_integral_limits(wchar_t(), "wchar_t");
   test_integral_limits(short(), "short");
   typedef unsigned short unsigned_short;
   test_integral_limits(unsigned_short(), "unsigned short");
   test_integral_limits(int(), "int");
   typedef unsigned int unsigned_int;
   test_integral_limits(unsigned_int(), "unsigned int");
   test_integral_limits(long(), "long");
   typedef unsigned long unsigned_long;
   test_integral_limits(unsigned_long(), "unsigned long");
 #if defined(BOOST_HAS_LONG_LONG)
   test_integral_limits(::boost::long_long_type(), "long long");
   test_integral_limits(::boost::ulong_long_type(), "unsigned long long");
 #endif
 #ifdef BOOST_HAS_MS_INT64
   typedef __int64 long_long2;
   test_integral_limits(long_long2(), "__int64");
   typedef unsigned __int64 unsigned_long_long2;
   test_integral_limits(unsigned_long_long2(), "unsigned __int64");
 #endif

   test_float_limits(float(), "float");
   test_float_limits(double(), "double");
   typedef long double long_double;
   test_float_limits(long_double(), "long double");
   // Some compilers don't pay attention to std:3.6.1/5 and issue a
   // warning here if "return 0;" is omitted.
   return 0;
 }
	/* boost limits_test.cpp test your <limits> file for important
	*
	* Copyright Jens Maurer 2000
	* Distributed under the Boost Software License, Version 1.0. (See
	* accompanying file LICENSE_1_0.txt or copy at
	* http://www.boost.org/LICENSE_1_0.txt)
	*
	* $Id: limits_test.cpp 30181 2005-07-19 17:14:00Z johnmaddock $
	*/

	#include <boost/limits.hpp>
	#define BOOST_INCLUDE_MAIN
	#include <boost/test/test_tools.hpp>
	#include <iostream>

	/*
	* General portability note:
	* MSVC mis-compiles explicit function template instantiations.
	* For example, f<A>() and f<B>() are both compiled to call f<A>().
	* BCC is unable to implicitly convert a "const char *" to a std::string
	* when using explicit function template instantiations.
	*
	* Therefore, avoid explicit function template instantiations.
	*/
	#if defined(BOOST_MSVC) && (BOOST_MSVC <= 1300)
	template<typename T> inline T make_char_numeric_for_streaming(T x) { return x; }
	namespace fix{
	inline int make_char_numeric_for_streaming(char c) { return c; }
	inline int make_char_numeric_for_streaming(signed char c) { return c; }
	inline int make_char_numeric_for_streaming(unsigned char c) { return c; }
	}
	using namespace fix;
	# if defined(_YVALS) && !defined(_CPPLIB_VER) && !defined(__SGI_STL_PORT) && !defined(_STLPORT_VERSION)
	// fix for missing operator<< in original Dinkumware lib:
	std::ostream& operator<<(std::ostream& os, __int64 i )
	{
	char buf[80];
	sprintf(buf,"%I64d", i );
	os << buf;
	return os;
	}
	std::ostream& operator<<(std::ostream& os, unsigned __int64 i )
	{
	char buf[80];
	sprintf(buf,"%I64u", i );
	os << buf;
	return os;
	}
	# endif
	#else
	template<typename T> inline T make_char_numeric_for_streaming(T x) { return x; }
	inline int make_char_numeric_for_streaming(char c) { return c; }
	inline int make_char_numeric_for_streaming(signed char c) { return c; }
	inline int make_char_numeric_for_streaming(unsigned char c) { return c; }
	#endif

	#if (defined(_GLIBCPP_VERSION) \|\| defined(_GLIBCXX_VERSION)) \
	&& defined(BOOST_HAS_LONG_LONG) \
	&& !defined(_GLIBCPP_USE_LONG_LONG) \
	&& !defined(_GLIBCXX_USE_LONG_LONG)
	//
	// Some libstdc++ versions have numeric_limits<long long> but no
	// iostream support for long long. TODO, find a better fix!!
	//
	std::ostream& operator<<(std::ostream& os, long long i )
	{
	return os << static_cast<long double>(i);
	}
	std::ostream& operator<<(std::ostream& os, unsigned long long i )
	{
	return os << static_cast<long double>(i);
	}
	#endif

	template<class T>
	void test_integral_limits(const T &, const char * msg)
	{
	typedef std::numeric_limits<T> lim;
	std::cout << "Testing " << msg
	<< " (size " << sizeof(T) << ")"
	<< " min: " << make_char_numeric_for_streaming((lim::min)())
	<< ", max: " << make_char_numeric_for_streaming((lim::max)())
	<< std::endl;

	BOOST_CHECK(static_cast<bool>(lim::is_specialized));
	BOOST_CHECK(static_cast<bool>(lim::is_integer));
	// BOOST_CHECK(lim::is_modulo);
	BOOST_CHECK(static_cast<bool>((lim::min)() < (lim::max)()));
	}

	template <class T>
	void print_hex_val(T t, const char* name)
	{
	const unsigned char* p = (const unsigned char*)&t;
	std::cout << "hex value of " << name << " is: ";
	for (unsigned int i = 0; i < sizeof(T); ++i) {
	if(p[i] <= 0xF)
	std::cout << "0";
	std::cout << std::hex << (int)p[i];
	}
	std::cout << std::dec << std::endl;
	}

	template<class T>
	void test_float_limits(const T &, const char * msg)
	{
	std::cout << "\nTesting " << msg << std::endl;
	typedef std::numeric_limits<T> lim;

	BOOST_CHECK(static_cast<bool>(lim::is_specialized));
	BOOST_CHECK(static_cast<bool>(!lim::is_modulo));
	BOOST_CHECK(static_cast<bool>(!lim::is_integer));
	BOOST_CHECK(static_cast<bool>(lim::is_signed));

	const T infinity = lim::infinity();
	const T qnan = lim::quiet_NaN();
	const T snan = lim::signaling_NaN();

	std::cout << "IEEE-compatible: " << lim::is_iec559
	<< ", traps: " << lim::traps
	<< ", bounded: " << lim::is_bounded
	<< ", exact: " << lim::is_exact << '\n'
	<< "min: " << (lim::min)() << ", max: " << (lim::max)() << '\n'
	<< "infinity: " << infinity << ", QNaN: " << qnan << '\n';
	print_hex_val((lim::max)(), "max");
	print_hex_val(infinity, "infinity");
	print_hex_val(qnan, "qnan");
	print_hex_val(snan, "snan");

	BOOST_CHECK((lim::max)() > 1000);
	BOOST_CHECK((lim::min)() > 0);
	BOOST_CHECK((lim::min)() < 0.001);
	BOOST_CHECK(lim::epsilon() > 0);

	if(lim::is_iec559) {
	BOOST_CHECK(static_cast<bool>(lim::has_infinity));
	BOOST_CHECK(static_cast<bool>(lim::has_quiet_NaN));
	BOOST_CHECK(static_cast<bool>(lim::has_signaling_NaN));
	} else {
	std::cout << "Does not claim IEEE conformance" << std::endl;
	}

	if(lim::has_infinity) {
	// Make sure those values are not 0 or similar nonsense.
	// Infinity must compare as if larger than the maximum representable value.
	BOOST_CHECK(infinity > (lim::max)());
	BOOST_CHECK(-infinity < -(lim::max)());
	} else {
	std::cout << "Does not have infinity" << std::endl;
	}

	if(lim::has_quiet_NaN) {
	// NaNs shall always compare "false" when compared for equality
	// If one of these fail, your compiler may be optimizing incorrectly,
	// or the standard library is incorrectly configured.
	BOOST_CHECK(! (qnan == 42));
	BOOST_CHECK(! (qnan == qnan));
	BOOST_CHECK(qnan != 42);
	BOOST_CHECK(qnan != qnan);

	// The following tests may cause arithmetic traps.
	// BOOST_CHECK(! (qnan < 42));
	// BOOST_CHECK(! (qnan > 42));
	// BOOST_CHECK(! (qnan <= 42));
	// BOOST_CHECK(! (qnan >= 42));
	} else {
	std::cout << "Does not have QNaN" << std::endl;
	}
	}


	int test_main(int, char*[])
	{
	test_integral_limits(bool(), "bool");
	test_integral_limits(char(), "char");
	typedef signed char signed_char;
	test_integral_limits(signed_char(), "signed char");
	typedef unsigned char unsigned_char;
	test_integral_limits(unsigned_char(), "unsigned char");
	test_integral_limits(wchar_t(), "wchar_t");
	test_integral_limits(short(), "short");
	typedef unsigned short unsigned_short;
	test_integral_limits(unsigned_short(), "unsigned short");
	test_integral_limits(int(), "int");
	typedef unsigned int unsigned_int;
	test_integral_limits(unsigned_int(), "unsigned int");
	test_integral_limits(long(), "long");
	typedef unsigned long unsigned_long;
	test_integral_limits(unsigned_long(), "unsigned long");
	#if defined(BOOST_HAS_LONG_LONG)
	test_integral_limits(::boost::long_long_type(), "long long");
	test_integral_limits(::boost::ulong_long_type(), "unsigned long long");
	#endif
	#ifdef BOOST_HAS_MS_INT64
	typedef __int64 long_long2;
	test_integral_limits(long_long2(), "__int64");
	typedef unsigned __int64 unsigned_long_long2;
	test_integral_limits(unsigned_long_long2(), "unsigned __int64");
	#endif

	test_float_limits(float(), "float");
	test_float_limits(double(), "double");
	typedef long double long_double;
	test_float_limits(long_double(), "long double");
	// Some compilers don't pay attention to std:3.6.1/5 and issue a
	// warning here if "return 0;" is omitted.
	return 0;
	}