boost_1_45_0/libs/numeric/conversion/test/udt_example_0.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 2005, Fernando Luis Cacciola Carballal.
 //
 // 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)
 //
 //
 #include "boost/config.hpp"
 #include "boost/utility.hpp"
 #include "boost/limits.hpp"
 #include "boost/utility.hpp"

 #include<iostream>
 #include<iomanip>
 #include<string>
 #include<cmath>


 #include "boost/test/included/test_exec_monitor.hpp"

 #include "boost/numeric/conversion/cast.hpp"

 using namespace std ;
 using namespace boost;
 using namespace numeric;

 //
 // This example illustrates how to add support for user defined types (UDTs)
 // to the Boost Numeric Conversion Library.
 // It is assumed that you are familiar with the following documentation:
 //
 //

 //
 // The minimum requirement is that boost::is_arithmetic<UDT> evaluates to false
 // (Otherwise the converter code will try to examine the UDT as a built-in type)
 //

 //
 // Let's start with the simpliest case of an UDT which supports standard conversions
 //
 struct Double
 {
   Double( double v ) : mV(v) {}

   operator double() const { return mV ; }

   double mV ;
 } ;

 double dv = (numeric_limits<double>::max)() ;
 double fv = (numeric_limits<float >::max)() ;
 Double Dv(dv);
 Double Fv(fv);

 void simplest_case()
 {
   //
   // conversion_traits<>::udt_builtin_mixture works out of the box as long as boost::is_arithmetic<UDT> yields false
   //
   BOOST_CHECK( (conversion_traits<double,Double>::udt_builtin_mixture::value == udt_to_builtin) ) ;
   BOOST_CHECK( (conversion_traits<Double,double>::udt_builtin_mixture::value == builtin_to_udt) ) ;
   BOOST_CHECK( (conversion_traits<Double,Double>::udt_builtin_mixture::value == udt_to_udt    ) ) ;

   // BY DEFINITION, a conversion from UDT to Builtin is subranged. No attempt is made to actually compare ranges.
   BOOST_CHECK( (conversion_traits<double,Double>::subranged::value) == true  ) ;
   BOOST_CHECK( (conversion_traits<Double,double>::subranged::value) == false ) ;


   //
   // Conversions to/from FLOATING types, if already supported by an UDT
   // are also supported out-of-the-box by converter<> in its default configuration.
   //
   BOOST_CHECK( numeric_cast<double>(Dv) == static_cast<double>(Dv) ) ;
   BOOST_CHECK( numeric_cast<Double>(dv) == static_cast<Double>(dv) ) ;

   BOOST_CHECK( numeric_cast<float> (Dv) == static_cast<float> (Dv) ) ;
   BOOST_CHECK( numeric_cast<Double>(fv) == static_cast<Double>(fv) ) ;


   //
   // Range checking is disabled by default if an UDT is either the source or target of the conversion.
   //
   BOOST_CHECK( (converter<float,double>::out_of_range(dv) == cPosOverflow) );
   BOOST_CHECK( (converter<float,Double>::out_of_range(Dv) == cInRange) );

 }

 //
 // The conversion_traits<> class and therefore the converter<> class looks at
 // numeric_limits<UDT>::is_integer/is_signed to generate the proper float_in and sign mixtures.
 // In most implementations, is_integer/is_signed are both false for UDTs if there is no explicit specialization for it.
 // Therefore, the converter<> will see any UDT for which numeric_limits<> is not specialized as Float AND unsigned.
 // Signess is used in the converter<> for range checking, but range checking is disabled by default for UDTs, so,
 // normally, signess is mostly irrelevant as far as the library is concerned, except for the numeric_traits<>::sign_mixture
 // entry.
 // is_integer, however, is relevant in that if the conversion is from a float type to an integer type, the conversion is
 // "rounding" and the rounder policies will participate.
 // ALL implemented rounder policies require proper definitions for floor(udt) and ceil(udt).
 // These names will be searched for using ADL, so, if you need to convert TO integral types from a UDT,
 // you need to supply those functions along with the UDT in right namespace (that is, any namespace that allows
 // ADL to find them)

 // If your UDT doesn't supply floor/ceil, conversions to integer types
 // won't compile unless a custom Float2IntRounder is used.

 Double floor ( Double v ) { return Double(std::floor(v.mV)) ; }
 Double ceil  ( Double v ) { return Double(std::ceil (v.mV)) ; }

 void rounding()
 {
   BOOST_CHECK( numeric_cast<int>(Dv) == static_cast<int>(Dv) ) ;
 }


 //
 // If your UDT can't or won't provide floor/ceil you can set-up and use your own
 // Float2IntRounder policy (though doing this is not always required as shown so far)
 //
 struct DoubleToInt
 {
   static Double nearbyint ( Double const& s ) { return Double(static_cast<int>(s)); }

   typedef mpl::integral_c< std::float_round_style, std::round_toward_zero> round_style ;
 } ;

 void custom_rounding()
 {
   typedef converter<int
                    ,Double
                    ,conversion_traits<int,Double>
                    ,void // By default UDT disable range checking so this won't be used
                    ,DoubleToInt
                    >
                    DoubleToIntConverter ;

    BOOST_CHECK( DoubleToIntConverter::convert(Dv) == static_cast<int>(Dv) ) ;
 }

 //
 // In the next Level of complexity, your UDTs might not support conversion operators
 //
 struct Float
 {
   Float( float v ) : mV(v) {}

   float mV ;
 } ;

 struct Int
 {
   Int( int v ) : mV(v) {}

   int mV ;
 } ;

 typedef conversion_traits<Int,Float> Float2IntTraits ;
 typedef conversion_traits<Float,Int> Int2FloatTraits ;

 namespace boost { namespace numeric
 {
 //
 // Though static_cast<> won't work with them you can still use numeric_cast<> by specializing
 // raw_converter as follows:
 //
 template<> struct raw_converter<Float2IntTraits>
 {
   typedef Float2IntTraits::result_type   result_type   ;
   typedef Float2IntTraits::argument_type argument_type ;

   static result_type low_level_convert ( argument_type s ) { return Int((int)s.mV); }
 } ;
 template<> struct raw_converter<Int2FloatTraits>
 {
   typedef Int2FloatTraits::result_type   result_type   ;
   typedef Int2FloatTraits::argument_type argument_type ;

   static result_type low_level_convert ( argument_type s ) { return Float(s.mV); }
 } ;

 } }

 void custom_raw_converter()
 {
   Float f (12.34);
   Int   i (12);
   Float fi(12);

   BOOST_CHECK(numeric_cast<Int>  (f).mV == i .mV ) ;
   BOOST_CHECK(numeric_cast<Float>(i).mV == fi.mV ) ;
 }

 //
 // Alterntively, the custom raw_converter classes can be defined non-instrusively
 // (not as specializations) and passed along as policies
 //
 struct Float2IntRawConverter
 {
   static Int low_level_convert ( Float const& s ) { return Int((int)s.mV); }
 } ;
 struct Int2FloatRawConverter
 {
   static Float low_level_convert ( Int const& s ) { return Float(s.mV); }
 } ;

 void custom_raw_converter2()
 {
   Float f (12.34);
   Int   i (12);
   Float fi(12);

   typedef converter<Int
                    ,Float
                    ,Float2IntTraits
                    ,void  // By default UDT disable range checking so this won't be used
                    ,void  // Float2Int Rounder won't be used if Int isn't marked as integer via numeric_limits<>
                    ,Float2IntRawConverter
                    >
                    Float2IntConverter ;

   BOOST_CHECK(Float2IntConverter::convert(f).mV == i .mV ) ;
 }

 int test_main( int, char* [] )
 {
   cout << setprecision( numeric_limits<long double>::digits10 ) ;

   simplest_case();
   rounding();
   custom_rounding();
   custom_raw_converter();
   custom_raw_converter2();

   return 0;
 }
	// Copyright (C) 2005, Fernando Luis Cacciola Carballal.
	//
	// 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)
	//
	//
	#include "boost/config.hpp"
	#include "boost/utility.hpp"
	#include "boost/limits.hpp"
	#include "boost/utility.hpp"

	#include<iostream>
	#include<iomanip>
	#include<string>
	#include<cmath>


	#include "boost/test/included/test_exec_monitor.hpp"

	#include "boost/numeric/conversion/cast.hpp"

	using namespace std ;
	using namespace boost;
	using namespace numeric;

	//
	// This example illustrates how to add support for user defined types (UDTs)
	// to the Boost Numeric Conversion Library.
	// It is assumed that you are familiar with the following documentation:
	//
	//

	//
	// The minimum requirement is that boost::is_arithmetic<UDT> evaluates to false
	// (Otherwise the converter code will try to examine the UDT as a built-in type)
	//

	//
	// Let's start with the simpliest case of an UDT which supports standard conversions
	//
	struct Double
	{
	Double( double v ) : mV(v) {}

	operator double() const { return mV ; }

	double mV ;
	} ;

	double dv = (numeric_limits<double>::max)() ;
	double fv = (numeric_limits<float >::max)() ;
	Double Dv(dv);
	Double Fv(fv);

	void simplest_case()
	{
	//
	// conversion_traits<>::udt_builtin_mixture works out of the box as long as boost::is_arithmetic<UDT> yields false
	//
	BOOST_CHECK( (conversion_traits<double,Double>::udt_builtin_mixture::value == udt_to_builtin) ) ;
	BOOST_CHECK( (conversion_traits<Double,double>::udt_builtin_mixture::value == builtin_to_udt) ) ;
	BOOST_CHECK( (conversion_traits<Double,Double>::udt_builtin_mixture::value == udt_to_udt ) ) ;

	// BY DEFINITION, a conversion from UDT to Builtin is subranged. No attempt is made to actually compare ranges.
	BOOST_CHECK( (conversion_traits<double,Double>::subranged::value) == true ) ;
	BOOST_CHECK( (conversion_traits<Double,double>::subranged::value) == false ) ;



	//
	// Conversions to/from FLOATING types, if already supported by an UDT
	// are also supported out-of-the-box by converter<> in its default configuration.
	//
	BOOST_CHECK( numeric_cast<double>(Dv) == static_cast<double>(Dv) ) ;
	BOOST_CHECK( numeric_cast<Double>(dv) == static_cast<Double>(dv) ) ;

	BOOST_CHECK( numeric_cast<float> (Dv) == static_cast<float> (Dv) ) ;
	BOOST_CHECK( numeric_cast<Double>(fv) == static_cast<Double>(fv) ) ;


	//
	// Range checking is disabled by default if an UDT is either the source or target of the conversion.
	//
	BOOST_CHECK( (converter<float,double>::out_of_range(dv) == cPosOverflow) );
	BOOST_CHECK( (converter<float,Double>::out_of_range(Dv) == cInRange) );

	}

	//
	// The conversion_traits<> class and therefore the converter<> class looks at
	// numeric_limits<UDT>::is_integer/is_signed to generate the proper float_in and sign mixtures.
	// In most implementations, is_integer/is_signed are both false for UDTs if there is no explicit specialization for it.
	// Therefore, the converter<> will see any UDT for which numeric_limits<> is not specialized as Float AND unsigned.
	// Signess is used in the converter<> for range checking, but range checking is disabled by default for UDTs, so,
	// normally, signess is mostly irrelevant as far as the library is concerned, except for the numeric_traits<>::sign_mixture
	// entry.
	// is_integer, however, is relevant in that if the conversion is from a float type to an integer type, the conversion is
	// "rounding" and the rounder policies will participate.
	// ALL implemented rounder policies require proper definitions for floor(udt) and ceil(udt).
	// These names will be searched for using ADL, so, if you need to convert TO integral types from a UDT,
	// you need to supply those functions along with the UDT in right namespace (that is, any namespace that allows
	// ADL to find them)

	// If your UDT doesn't supply floor/ceil, conversions to integer types
	// won't compile unless a custom Float2IntRounder is used.

	Double floor ( Double v ) { return Double(std::floor(v.mV)) ; }
	Double ceil ( Double v ) { return Double(std::ceil (v.mV)) ; }

	void rounding()
	{
	BOOST_CHECK( numeric_cast<int>(Dv) == static_cast<int>(Dv) ) ;
	}


	//
	// If your UDT can't or won't provide floor/ceil you can set-up and use your own
	// Float2IntRounder policy (though doing this is not always required as shown so far)
	//
	struct DoubleToInt
	{
	static Double nearbyint ( Double const& s ) { return Double(static_cast<int>(s)); }

	typedef mpl::integral_c< std::float_round_style, std::round_toward_zero> round_style ;
	} ;

	void custom_rounding()
	{
	typedef converter<int
	,Double
	,conversion_traits<int,Double>
	,void // By default UDT disable range checking so this won't be used
	,DoubleToInt
	>
	DoubleToIntConverter ;

	BOOST_CHECK( DoubleToIntConverter::convert(Dv) == static_cast<int>(Dv) ) ;
	}

	//
	// In the next Level of complexity, your UDTs might not support conversion operators
	//
	struct Float
	{
	Float( float v ) : mV(v) {}

	float mV ;
	} ;

	struct Int
	{
	Int( int v ) : mV(v) {}

	int mV ;
	} ;

	typedef conversion_traits<Int,Float> Float2IntTraits ;
	typedef conversion_traits<Float,Int> Int2FloatTraits ;

	namespace boost { namespace numeric
	{
	//
	// Though static_cast<> won't work with them you can still use numeric_cast<> by specializing
	// raw_converter as follows:
	//
	template<> struct raw_converter<Float2IntTraits>
	{
	typedef Float2IntTraits::result_type result_type ;
	typedef Float2IntTraits::argument_type argument_type ;

	static result_type low_level_convert ( argument_type s ) { return Int((int)s.mV); }
	} ;
	template<> struct raw_converter<Int2FloatTraits>
	{
	typedef Int2FloatTraits::result_type result_type ;
	typedef Int2FloatTraits::argument_type argument_type ;

	static result_type low_level_convert ( argument_type s ) { return Float(s.mV); }
	} ;

	} }

	void custom_raw_converter()
	{
	Float f (12.34);
	Int i (12);
	Float fi(12);

	BOOST_CHECK(numeric_cast<Int> (f).mV == i .mV ) ;
	BOOST_CHECK(numeric_cast<Float>(i).mV == fi.mV ) ;
	}

	//
	// Alterntively, the custom raw_converter classes can be defined non-instrusively
	// (not as specializations) and passed along as policies
	//
	struct Float2IntRawConverter
	{
	static Int low_level_convert ( Float const& s ) { return Int((int)s.mV); }
	} ;
	struct Int2FloatRawConverter
	{
	static Float low_level_convert ( Int const& s ) { return Float(s.mV); }
	} ;

	void custom_raw_converter2()
	{
	Float f (12.34);
	Int i (12);
	Float fi(12);

	typedef converter<Int
	,Float
	,Float2IntTraits
	,void // By default UDT disable range checking so this won't be used
	,void // Float2Int Rounder won't be used if Int isn't marked as integer via numeric_limits<>
	,Float2IntRawConverter
	>
	Float2IntConverter ;

	BOOST_CHECK(Float2IntConverter::convert(f).mV == i .mV ) ;
	}

	int test_main( int, char* [] )
	{
	cout << setprecision( numeric_limits<long double>::digits10 ) ;

	simplest_case();
	rounding();
	custom_rounding();
	custom_raw_converter();
	custom_raw_converter2();

	return 0;
	}