boost_1_45_0/libs/spirit/classic/test/numerics_tests.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*=============================================================================
     Copyright (c) 2001-2003 Joel de Guzman
     Copyright (c) 2001-2003 Hartmut Kaiser
     http://spirit.sourceforge.net/

     Use, modification and distribution is subject to 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)
 =============================================================================*/
 #include <boost/spirit/include/classic_core.hpp>
 #include <boost/spirit/include/classic_assign_actor.hpp>
 #include <boost/detail/lightweight_test.hpp>
 #include <iostream>
 #include <climits>

 using namespace std;
 using namespace BOOST_SPIRIT_CLASSIC_NS;

 template <typename T>
 struct ts_real_parser_policies : public ureal_parser_policies<T>
 {
     //  These policies can be used to parse thousand separated
     //  numbers with at most 2 decimal digits after the decimal
     //  point. e.g. 123,456,789.01

     typedef uint_parser<int, 10, 1, 2>  uint2_t;
     typedef uint_parser<T, 10, 1, -1>   uint_parser_t;
     typedef int_parser<int, 10, 1, -1>  int_parser_t;

     //////////////////////////////////  2 decimal places Max
     template <typename ScannerT>
     static typename parser_result<uint2_t, ScannerT>::type
     parse_frac_n(ScannerT& scan)
     { return uint2_t().parse(scan); }

     //////////////////////////////////  No exponent
     template <typename ScannerT>
     static typename parser_result<chlit<>, ScannerT>::type
     parse_exp(ScannerT& scan)
     { return scan.no_match(); }

     //////////////////////////////////  No exponent
     template <typename ScannerT>
     static typename parser_result<int_parser_t, ScannerT>::type
     parse_exp_n(ScannerT& scan)
     { return scan.no_match(); }

     //////////////////////////////////  Thousands separated numbers
     template <typename ScannerT>
     static typename parser_result<uint_parser_t, ScannerT>::type
     parse_n(ScannerT& scan)
     {
         typedef typename parser_result<uint_parser_t, ScannerT>::type RT;
         static uint_parser<unsigned, 10, 1, 3> uint3_p;
         static uint_parser<unsigned, 10, 3, 3> uint3_3_p;

         if (RT hit = uint3_p.parse(scan))
         {
             T n;
             typedef typename ScannerT::iterator_t iterator_t;
             iterator_t save = scan.first;
             while (match<> next = (',' >> uint3_3_p[assign_a(n)]).parse(scan))
             {
                 hit.value((hit.value() * 1000) + n);
                 scan.concat_match(hit, next);
                 save = scan.first;
             }
             scan.first = save;
             return hit;
         }
         return scan.no_match();
     }
 };

 real_parser<double, ts_real_parser_policies<double> > const
     ts_real_p = real_parser<double, ts_real_parser_policies<double> >();

 template <typename T>
 struct no_trailing_dot : public real_parser_policies<T>
 {
     static const bool allow_trailing_dot = false;
 };

 real_parser<double, no_trailing_dot<double> > const
     notrdot_real_p = real_parser<double, no_trailing_dot<double> >();

 template <typename T>
 struct no_leading_dot : public real_parser_policies<T>
 {
     static const bool allow_leading_dot = false;
 };

 real_parser<double, no_leading_dot<double> > const
     nolddot_real_p = real_parser<double, no_leading_dot<double> >();

 ///////////////////////////////////////////////////////////////////////////////
 int
 main()
 {
     cout << "/////////////////////////////////////////////////////////\n\n";
     cout << "\t\tNumeric tests...\n\n";
     cout << "/////////////////////////////////////////////////////////\n\n";

     //  *** The following assumes 32 bit integers. Modify these constant
     //  *** strings when appropriate. BEWARE PLATFORM DEPENDENT!

     char const* max_unsigned = "4294967295";
     char const* unsigned_overflow = "4294967296";
     char const* max_int = "2147483647";
     char const* int_overflow = "2147483648";
     char const* min_int = "-2147483648";
     char const* int_underflow = "-2147483649";
     char const* max_binary = "11111111111111111111111111111111";
     char const* binary_overflow = "100000000000000000000000000000000";
     char const* max_octal = "37777777777";
     char const* octal_overflow = "100000000000";
     char const* max_hex = "FFFFFFFF";
     char const* hex_overflow = "100000000";

 #ifdef BOOST_HAS_LONG_LONG

     char const* max_long_long = "9223372036854775807";
     char const* long_long_overflow = "9223372036854775808";
     char const* min_long_long = "-9223372036854775808";
     char const* long_long_underflow = "-9223372036854775809";

 #endif

 //  BEGIN TESTS...

     unsigned u;

 //  unsigned integer

     parse("123456", uint_p[assign_a(u)]);
     BOOST_TEST(u == 123456);

     parse(max_unsigned, uint_p[assign_a(u)]);
     BOOST_TEST(u == UINT_MAX);

     BOOST_TEST(!parse(unsigned_overflow, uint_p).full);

 //  signed integer

     int i;

     parse("123456", int_p[assign_a(i)]);
     BOOST_TEST(i == 123456);

     parse("-123456", int_p[assign_a(i)]);
     BOOST_TEST(i == -123456);

     parse(max_int, int_p[assign_a(i)]);
     BOOST_TEST(i == INT_MAX);

     parse(min_int, int_p[assign_a(i)]);
     BOOST_TEST(i == INT_MIN);

     BOOST_TEST(!parse(int_overflow, int_p).full);
     BOOST_TEST(!parse(int_underflow, int_p).full);

     BOOST_TEST(!parse("-", int_p).hit);

 //  binary

     parse("11111110", bin_p[assign_a(u)]);
     BOOST_TEST(u == 0xFE);

     parse(max_binary, bin_p[assign_a(u)]);
     BOOST_TEST(u == UINT_MAX);

     BOOST_TEST(!parse(binary_overflow, bin_p).full);

 //  octal

     parse("12545674515", oct_p[assign_a(u)]);
     BOOST_TEST(u == 012545674515);

     parse(max_octal, oct_p[assign_a(u)]);
     BOOST_TEST(u == UINT_MAX);

     BOOST_TEST(!parse(octal_overflow, oct_p).full);

 //  hex

     parse("95BC8DF", hex_p[assign_a(u)]);
     BOOST_TEST(u == 0x95BC8DF);

     parse("abcdef12", hex_p[assign_a(u)]);
     BOOST_TEST(u == 0xabcdef12);

     parse(max_hex, hex_p[assign_a(u)]);
     BOOST_TEST(u == UINT_MAX);

     BOOST_TEST(!parse(hex_overflow, hex_p).full);

 //  limited fieldwidth

     uint_parser<unsigned, 10, 1, 3> uint3_p;
     parse("123456", uint3_p[assign_a(u)]);
     BOOST_TEST(u == 123);

     uint_parser<unsigned, 10, 1, 4> uint4_p;
     parse("123456", uint4_p[assign_a(u)]);
     BOOST_TEST(u == 1234);

     uint_parser<unsigned, 10, 3, 3> uint3_3_p;

 //  thousand separated numbers

 #define r (uint3_p >> *(',' >> uint3_3_p))

     BOOST_TEST(parse("1,234,567,890", r).full);     //  OK
     BOOST_TEST(parse("12,345,678,900", r).full);    //  OK
     BOOST_TEST(parse("123,456,789,000", r).full);   //  OK
     BOOST_TEST(!parse("1000,234,567,890", r).full); //  Bad
     BOOST_TEST(!parse("1,234,56,890", r).full);     //  Bad
     BOOST_TEST(!parse("1,66", r).full);             //  Bad

 //  long long

 #ifdef BOOST_HAS_LONG_LONG

 // Some compilers have long long, but don't define the
 // LONG_LONG_MIN and LONG_LONG_MAX macros in limits.h.  This
 // assumes that long long is 64 bits.
 #if !defined(LONG_LONG_MIN) && !defined(LONG_LONG_MAX) \
             && !defined(ULONG_LONG_MAX)
 #define ULONG_LONG_MAX 0xffffffffffffffffLLU
 #define LONG_LONG_MAX 0x7fffffffffffffffLL
 #define LONG_LONG_MIN (-LONG_LONG_MAX - 1)
 #endif

      ::boost::long_long_type ll;
     int_parser< ::boost::long_long_type> long_long_p;

     parse("1234567890123456789", long_long_p[assign_a(ll)]);
     BOOST_TEST(ll == 1234567890123456789LL);

     parse("-1234567890123456789", long_long_p[assign_a(ll)]);
     BOOST_TEST(ll == -1234567890123456789LL);

     parse(max_long_long, long_long_p[assign_a(ll)]);
     BOOST_TEST(ll == LONG_LONG_MAX);

     parse(min_long_long, long_long_p[assign_a(ll)]);
     BOOST_TEST(ll == LONG_LONG_MIN);

 #if defined(__GNUG__) && (__GNUG__ == 3) && (__GNUC_MINOR__ < 3) \
     && !defined(__EDG__)
     // gcc 3.2.3 crashes on parse(long_long_overflow, long_long_p)
     // wrapping long_long_p into a rule avoids the crash
     rule<> gcc_3_2_3_long_long_r = long_long_p;
     BOOST_TEST(!parse(long_long_overflow, gcc_3_2_3_long_long_r).full);
     BOOST_TEST(!parse(long_long_underflow, gcc_3_2_3_long_long_r).full);
 #else
     BOOST_TEST(!parse(long_long_overflow, long_long_p).full);
     BOOST_TEST(!parse(long_long_underflow, long_long_p).full);
 #endif

 #endif

 //  real numbers

     double  d;

     BOOST_TEST(parse("1234", ureal_p[assign_a(d)]).full && d == 1234);      //  Good.
     BOOST_TEST(parse("1.2e3", ureal_p[assign_a(d)]).full && d == 1.2e3);    //  Good.
     BOOST_TEST(parse("1.2e-3", ureal_p[assign_a(d)]).full && d == 1.2e-3);  //  Good.
     BOOST_TEST(parse("1.e2", ureal_p[assign_a(d)]).full && d == 1.e2);      //  Good.
     BOOST_TEST(parse(".2e3", ureal_p[assign_a(d)]).full && d == .2e3);      //  Good.
     BOOST_TEST(parse("2e3", ureal_p[assign_a(d)]).full && d == 2e3);        //  Good. No fraction
     BOOST_TEST(!parse("e3", ureal_p).full);                                 //  Bad! No number
     BOOST_TEST(!parse("-1.2e3", ureal_p).full);                             //  Bad! Negative number
     BOOST_TEST(!parse("+1.2e3", ureal_p).full);                             //  Bad! Positive sign
     BOOST_TEST(!parse("1.2e", ureal_p).full);                               //  Bad! No exponent
     BOOST_TEST(!parse("-.3", ureal_p).full);                                //  Bad! Negative

     BOOST_TEST(parse("-1234", real_p[assign_a(d)]).full && d == -1234);     //  Good.
     BOOST_TEST(parse("-1.2e3", real_p[assign_a(d)]).full && d == -1.2e3);   //  Good.
     BOOST_TEST(parse("+1.2e3", real_p[assign_a(d)]).full && d == 1.2e3);    //  Good.
     BOOST_TEST(parse("-0.1", real_p[assign_a(d)]).full && d == -0.1);       //  Good.
     BOOST_TEST(parse("-1.2e-3", real_p[assign_a(d)]).full && d == -1.2e-3); //  Good.
     BOOST_TEST(parse("-1.e2", real_p[assign_a(d)]).full && d == -1.e2);     //  Good.
     BOOST_TEST(parse("-.2e3", real_p[assign_a(d)]).full && d == -.2e3);     //  Good.
     BOOST_TEST(parse("-2e3", real_p[assign_a(d)]).full && d == -2e3);       //  Good. No fraction
     BOOST_TEST(!parse("-e3", real_p).full);                                 //  Bad! No number
     BOOST_TEST(!parse("-1.2e", real_p).full);                               //  Bad! No exponent

     BOOST_TEST(!parse("1234", strict_ureal_p[assign_a(d)]).full);           //  Bad. Strict real
     BOOST_TEST(parse("1.2", strict_ureal_p[assign_a(d)]).full && d == 1.2); //  Good.
     BOOST_TEST(!parse("-1234", strict_real_p[assign_a(d)]).full);           //  Bad. Strict real
     BOOST_TEST(parse("123.", strict_real_p[assign_a(d)]).full && d == 123); //  Good.
     BOOST_TEST(parse("3.E6", strict_real_p[assign_a(d)]).full && d == 3e6); //  Good.

     BOOST_TEST(!parse("1234.", notrdot_real_p[assign_a(d)]).full);          //  Bad trailing dot
     BOOST_TEST(!parse(".1234", nolddot_real_p[assign_a(d)]).full);          //  Bad leading dot

 //  Special thousands separated numbers

     BOOST_TEST(parse("123,456,789.01", ts_real_p[assign_a(d)]).full && d == 123456789.01);  //  Good.
     BOOST_TEST(parse("12,345,678.90", ts_real_p[assign_a(d)]).full && d == 12345678.90);    //  Good.
     BOOST_TEST(parse("1,234,567.89", ts_real_p[assign_a(d)]).full && d == 1234567.89);      //  Good.
     BOOST_TEST(!parse("1234,567,890", ts_real_p).full);     //  Bad.
     BOOST_TEST(!parse("1,234,5678,9", ts_real_p).full);     //  Bad.
     BOOST_TEST(!parse("1,234,567.89e6", ts_real_p).full);   //  Bad.
     BOOST_TEST(!parse("1,66", ts_real_p).full);             //  Bad.

 //  END TESTS.

 /////////////////////////////////////////////////////////////////
     return boost::report_errors();
 }
	/*=============================================================================
	Copyright (c) 2001-2003 Joel de Guzman
	Copyright (c) 2001-2003 Hartmut Kaiser
	http://spirit.sourceforge.net/

	Use, modification and distribution is subject to 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)
	=============================================================================*/
	#include <boost/spirit/include/classic_core.hpp>
	#include <boost/spirit/include/classic_assign_actor.hpp>
	#include <boost/detail/lightweight_test.hpp>
	#include <iostream>
	#include <climits>

	using namespace std;
	using namespace BOOST_SPIRIT_CLASSIC_NS;

	template <typename T>
	struct ts_real_parser_policies : public ureal_parser_policies<T>
	{
	// These policies can be used to parse thousand separated
	// numbers with at most 2 decimal digits after the decimal
	// point. e.g. 123,456,789.01

	typedef uint_parser<int, 10, 1, 2> uint2_t;
	typedef uint_parser<T, 10, 1, -1> uint_parser_t;
	typedef int_parser<int, 10, 1, -1> int_parser_t;

	////////////////////////////////// 2 decimal places Max
	template <typename ScannerT>
	static typename parser_result<uint2_t, ScannerT>::type
	parse_frac_n(ScannerT& scan)
	{ return uint2_t().parse(scan); }

	////////////////////////////////// No exponent
	template <typename ScannerT>
	static typename parser_result<chlit<>, ScannerT>::type
	parse_exp(ScannerT& scan)
	{ return scan.no_match(); }

	////////////////////////////////// No exponent
	template <typename ScannerT>
	static typename parser_result<int_parser_t, ScannerT>::type
	parse_exp_n(ScannerT& scan)
	{ return scan.no_match(); }

	////////////////////////////////// Thousands separated numbers
	template <typename ScannerT>
	static typename parser_result<uint_parser_t, ScannerT>::type
	parse_n(ScannerT& scan)
	{
	typedef typename parser_result<uint_parser_t, ScannerT>::type RT;
	static uint_parser<unsigned, 10, 1, 3> uint3_p;
	static uint_parser<unsigned, 10, 3, 3> uint3_3_p;

	if (RT hit = uint3_p.parse(scan))
	{
	T n;
	typedef typename ScannerT::iterator_t iterator_t;
	iterator_t save = scan.first;
	while (match<> next = (',' >> uint3_3_p[assign_a(n)]).parse(scan))
	{
	hit.value((hit.value() * 1000) + n);
	scan.concat_match(hit, next);
	save = scan.first;
	}
	scan.first = save;
	return hit;
	}
	return scan.no_match();
	}
	};

	real_parser<double, ts_real_parser_policies<double> > const
	ts_real_p = real_parser<double, ts_real_parser_policies<double> >();

	template <typename T>
	struct no_trailing_dot : public real_parser_policies<T>
	{
	static const bool allow_trailing_dot = false;
	};

	real_parser<double, no_trailing_dot<double> > const
	notrdot_real_p = real_parser<double, no_trailing_dot<double> >();

	template <typename T>
	struct no_leading_dot : public real_parser_policies<T>
	{
	static const bool allow_leading_dot = false;
	};

	real_parser<double, no_leading_dot<double> > const
	nolddot_real_p = real_parser<double, no_leading_dot<double> >();

	///////////////////////////////////////////////////////////////////////////////
	int
	main()
	{
	cout << "/////////////////////////////////////////////////////////\n\n";
	cout << "\t\tNumeric tests...\n\n";
	cout << "/////////////////////////////////////////////////////////\n\n";

	// *** The following assumes 32 bit integers. Modify these constant
	// *** strings when appropriate. BEWARE PLATFORM DEPENDENT!

	char const* max_unsigned = "4294967295";
	char const* unsigned_overflow = "4294967296";
	char const* max_int = "2147483647";
	char const* int_overflow = "2147483648";
	char const* min_int = "-2147483648";
	char const* int_underflow = "-2147483649";
	char const* max_binary = "11111111111111111111111111111111";
	char const* binary_overflow = "100000000000000000000000000000000";
	char const* max_octal = "37777777777";
	char const* octal_overflow = "100000000000";
	char const* max_hex = "FFFFFFFF";
	char const* hex_overflow = "100000000";

	#ifdef BOOST_HAS_LONG_LONG

	char const* max_long_long = "9223372036854775807";
	char const* long_long_overflow = "9223372036854775808";
	char const* min_long_long = "-9223372036854775808";
	char const* long_long_underflow = "-9223372036854775809";

	#endif

	// BEGIN TESTS...

	unsigned u;

	// unsigned integer

	parse("123456", uint_p[assign_a(u)]);
	BOOST_TEST(u == 123456);

	parse(max_unsigned, uint_p[assign_a(u)]);
	BOOST_TEST(u == UINT_MAX);

	BOOST_TEST(!parse(unsigned_overflow, uint_p).full);

	// signed integer

	int i;

	parse("123456", int_p[assign_a(i)]);
	BOOST_TEST(i == 123456);

	parse("-123456", int_p[assign_a(i)]);
	BOOST_TEST(i == -123456);

	parse(max_int, int_p[assign_a(i)]);
	BOOST_TEST(i == INT_MAX);

	parse(min_int, int_p[assign_a(i)]);
	BOOST_TEST(i == INT_MIN);

	BOOST_TEST(!parse(int_overflow, int_p).full);
	BOOST_TEST(!parse(int_underflow, int_p).full);

	BOOST_TEST(!parse("-", int_p).hit);

	// binary

	parse("11111110", bin_p[assign_a(u)]);
	BOOST_TEST(u == 0xFE);

	parse(max_binary, bin_p[assign_a(u)]);
	BOOST_TEST(u == UINT_MAX);

	BOOST_TEST(!parse(binary_overflow, bin_p).full);

	// octal

	parse("12545674515", oct_p[assign_a(u)]);
	BOOST_TEST(u == 012545674515);

	parse(max_octal, oct_p[assign_a(u)]);
	BOOST_TEST(u == UINT_MAX);

	BOOST_TEST(!parse(octal_overflow, oct_p).full);

	// hex

	parse("95BC8DF", hex_p[assign_a(u)]);
	BOOST_TEST(u == 0x95BC8DF);

	parse("abcdef12", hex_p[assign_a(u)]);
	BOOST_TEST(u == 0xabcdef12);

	parse(max_hex, hex_p[assign_a(u)]);
	BOOST_TEST(u == UINT_MAX);

	BOOST_TEST(!parse(hex_overflow, hex_p).full);

	// limited fieldwidth

	uint_parser<unsigned, 10, 1, 3> uint3_p;
	parse("123456", uint3_p[assign_a(u)]);
	BOOST_TEST(u == 123);

	uint_parser<unsigned, 10, 1, 4> uint4_p;
	parse("123456", uint4_p[assign_a(u)]);
	BOOST_TEST(u == 1234);

	uint_parser<unsigned, 10, 3, 3> uint3_3_p;

	// thousand separated numbers

	#define r (uint3_p >> *(',' >> uint3_3_p))

	BOOST_TEST(parse("1,234,567,890", r).full); // OK
	BOOST_TEST(parse("12,345,678,900", r).full); // OK
	BOOST_TEST(parse("123,456,789,000", r).full); // OK
	BOOST_TEST(!parse("1000,234,567,890", r).full); // Bad
	BOOST_TEST(!parse("1,234,56,890", r).full); // Bad
	BOOST_TEST(!parse("1,66", r).full); // Bad

	// long long

	#ifdef BOOST_HAS_LONG_LONG

	// Some compilers have long long, but don't define the
	// LONG_LONG_MIN and LONG_LONG_MAX macros in limits.h. This
	// assumes that long long is 64 bits.
	#if !defined(LONG_LONG_MIN) && !defined(LONG_LONG_MAX) \
	&& !defined(ULONG_LONG_MAX)
	#define ULONG_LONG_MAX 0xffffffffffffffffLLU
	#define LONG_LONG_MAX 0x7fffffffffffffffLL
	#define LONG_LONG_MIN (-LONG_LONG_MAX - 1)
	#endif

	::boost::long_long_type ll;
	int_parser< ::boost::long_long_type> long_long_p;

	parse("1234567890123456789", long_long_p[assign_a(ll)]);
	BOOST_TEST(ll == 1234567890123456789LL);

	parse("-1234567890123456789", long_long_p[assign_a(ll)]);
	BOOST_TEST(ll == -1234567890123456789LL);

	parse(max_long_long, long_long_p[assign_a(ll)]);
	BOOST_TEST(ll == LONG_LONG_MAX);

	parse(min_long_long, long_long_p[assign_a(ll)]);
	BOOST_TEST(ll == LONG_LONG_MIN);

	#if defined(__GNUG__) && (__GNUG__ == 3) && (__GNUC_MINOR__ < 3) \
	&& !defined(__EDG__)
	// gcc 3.2.3 crashes on parse(long_long_overflow, long_long_p)
	// wrapping long_long_p into a rule avoids the crash
	rule<> gcc_3_2_3_long_long_r = long_long_p;
	BOOST_TEST(!parse(long_long_overflow, gcc_3_2_3_long_long_r).full);
	BOOST_TEST(!parse(long_long_underflow, gcc_3_2_3_long_long_r).full);
	#else
	BOOST_TEST(!parse(long_long_overflow, long_long_p).full);
	BOOST_TEST(!parse(long_long_underflow, long_long_p).full);
	#endif

	#endif

	// real numbers

	double d;

	BOOST_TEST(parse("1234", ureal_p[assign_a(d)]).full && d == 1234); // Good.
	BOOST_TEST(parse("1.2e3", ureal_p[assign_a(d)]).full && d == 1.2e3); // Good.
	BOOST_TEST(parse("1.2e-3", ureal_p[assign_a(d)]).full && d == 1.2e-3); // Good.
	BOOST_TEST(parse("1.e2", ureal_p[assign_a(d)]).full && d == 1.e2); // Good.
	BOOST_TEST(parse(".2e3", ureal_p[assign_a(d)]).full && d == .2e3); // Good.
	BOOST_TEST(parse("2e3", ureal_p[assign_a(d)]).full && d == 2e3); // Good. No fraction
	BOOST_TEST(!parse("e3", ureal_p).full); // Bad! No number
	BOOST_TEST(!parse("-1.2e3", ureal_p).full); // Bad! Negative number
	BOOST_TEST(!parse("+1.2e3", ureal_p).full); // Bad! Positive sign
	BOOST_TEST(!parse("1.2e", ureal_p).full); // Bad! No exponent
	BOOST_TEST(!parse("-.3", ureal_p).full); // Bad! Negative

	BOOST_TEST(parse("-1234", real_p[assign_a(d)]).full && d == -1234); // Good.
	BOOST_TEST(parse("-1.2e3", real_p[assign_a(d)]).full && d == -1.2e3); // Good.
	BOOST_TEST(parse("+1.2e3", real_p[assign_a(d)]).full && d == 1.2e3); // Good.
	BOOST_TEST(parse("-0.1", real_p[assign_a(d)]).full && d == -0.1); // Good.
	BOOST_TEST(parse("-1.2e-3", real_p[assign_a(d)]).full && d == -1.2e-3); // Good.
	BOOST_TEST(parse("-1.e2", real_p[assign_a(d)]).full && d == -1.e2); // Good.
	BOOST_TEST(parse("-.2e3", real_p[assign_a(d)]).full && d == -.2e3); // Good.
	BOOST_TEST(parse("-2e3", real_p[assign_a(d)]).full && d == -2e3); // Good. No fraction
	BOOST_TEST(!parse("-e3", real_p).full); // Bad! No number
	BOOST_TEST(!parse("-1.2e", real_p).full); // Bad! No exponent

	BOOST_TEST(!parse("1234", strict_ureal_p[assign_a(d)]).full); // Bad. Strict real
	BOOST_TEST(parse("1.2", strict_ureal_p[assign_a(d)]).full && d == 1.2); // Good.
	BOOST_TEST(!parse("-1234", strict_real_p[assign_a(d)]).full); // Bad. Strict real
	BOOST_TEST(parse("123.", strict_real_p[assign_a(d)]).full && d == 123); // Good.
	BOOST_TEST(parse("3.E6", strict_real_p[assign_a(d)]).full && d == 3e6); // Good.

	BOOST_TEST(!parse("1234.", notrdot_real_p[assign_a(d)]).full); // Bad trailing dot
	BOOST_TEST(!parse(".1234", nolddot_real_p[assign_a(d)]).full); // Bad leading dot

	// Special thousands separated numbers

	BOOST_TEST(parse("123,456,789.01", ts_real_p[assign_a(d)]).full && d == 123456789.01); // Good.
	BOOST_TEST(parse("12,345,678.90", ts_real_p[assign_a(d)]).full && d == 12345678.90); // Good.
	BOOST_TEST(parse("1,234,567.89", ts_real_p[assign_a(d)]).full && d == 1234567.89); // Good.
	BOOST_TEST(!parse("1234,567,890", ts_real_p).full); // Bad.
	BOOST_TEST(!parse("1,234,5678,9", ts_real_p).full); // Bad.
	BOOST_TEST(!parse("1,234,567.89e6", ts_real_p).full); // Bad.
	BOOST_TEST(!parse("1,66", ts_real_p).full); // Bad.

	// END TESTS.

	/////////////////////////////////////////////////////////////////
	return boost::report_errors();
	}