boost_1_45_0/libs/units/test/test_dimensionless_quantity.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Boost.Units - A C++ library for zero-overhead dimensional analysis and
 // unit/quantity manipulation and conversion
 //
 // Copyright (C) 2003-2008 Matthias Christian Schabel
 // Copyright (C) 2008 Steven Watanabe
 //
 // 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)

 /**
 \file

 \brief test_dimensionless_quantity.cpp

 \details
 Test unit class.

 Output:
 @verbatim
 @endverbatim
 **/

 #include "test_header.hpp"

 #include <boost/units/pow.hpp>

 namespace bu = boost::units;

 static const double E_ = 2.718281828459045235360287471352662497757;

 int test_main(int,char *[])
 {
     // default constructor
     const bu::quantity<bu::dimensionless>           E1;
     BOOST_CHECK(E1.value() == double());

     // value_type constructor
     const bu::quantity<bu::dimensionless>           E2(E_);
     BOOST_CHECK(E2.value() == E_);

     // copy constructor
     const bu::quantity<bu::dimensionless>           E3(E2);
     BOOST_CHECK(E3.value() == E_);

     // operator=
     const bu::quantity<bu::dimensionless>           E4 = E2;
     BOOST_CHECK(E4.value() == E_);

     // implicit copy constructor value_type conversion
     const bu::quantity<bu::dimensionless,float>     E5(E2);
     BOOST_UNITS_CHECK_CLOSE(E5.value(), float(E_));

     const bu::quantity<bu::dimensionless,long>      E6(E2);
     BOOST_CHECK(E6.value() == long(E_));

     // implicit operator= value_type conversion
     // narrowing conversion disallowed
 //    const bu::quantity<bu::dimensionless,float>     E7 = E2;
 //    BOOST_UNITS_CHECK_CLOSE(E7.value(),float(E_));

     // narrowing conversion disallowed
 //    const bu::quantity<bu::dimensionless,long>      E8 = E2;
 //    BOOST_CHECK(E8.value() == long(E_));

     // const construction
     bu::quantity<bu::dimensionless>                 E9(E2);
     BOOST_CHECK(E9.value() == E_);

 //    // value assignment
 //    E9.value() = 1.5*bu::dimensionless();
 //    BOOST_CHECK(E9.value() == 1.5);
 //
 //    // value assignment with implicit conversion
 //    E9.value() = 1.5;
 //    BOOST_CHECK(E9.value() == 1.5);
 //
 //    // value assignment with implicit value_type conversion
 //    E9.value() = 2*bu::dimensionless();
 //    BOOST_CHECK(E9.value() == double(2));
 //
 //    // value assignment with implicit value_type conversion
 //    E9.value() = 2;
 //    BOOST_CHECK(E9.value() == double(2));

     // operator+=(this_type)
     E9 = 2.0;
     E9 += E9;
     BOOST_CHECK(E9.value() == 4.0);

     // operator-=(this_type)
     E9 = 2.0;
     E9 -= E9;
     BOOST_CHECK(E9.value() == 0.0);

     // operator*=(value_type)
     E9 = 2.0;
     E9 *= 2.0;
     BOOST_CHECK(E9.value() == 4.0);

     // operator/=(value_type)
     E9 = 2.0;
     E9 /= 2.0;
     BOOST_CHECK(E9.value() == 1.0);

     // static construct quantity from value_type
     const bu::quantity<bu::dimensionless>           E(bu::quantity<bu::dimensionless>::from_value(2.5));
     BOOST_CHECK(E.value() == 2.5);

     // implicit conversion to value_type
     const double    V1(E9);
     BOOST_CHECK(V1 == E9.value());

     const double    V2 = E9;
     BOOST_CHECK(V2 == E9.value());

     // unit * scalar
     BOOST_CHECK(bu::dimensionless()*2.0 == bu::quantity<bu::dimensionless>::from_value(2.0));

     // unit / scalar
     BOOST_CHECK(bu::dimensionless()/2.0 == bu::quantity<bu::dimensionless>::from_value(0.5));

     // scalar * unit
     BOOST_CHECK(2.0*bu::dimensionless() == bu::quantity<bu::dimensionless>::from_value(2.0));

     // scalar / unit
     BOOST_CHECK(2.0/bu::dimensionless() == bu::quantity<bu::dimensionless>::from_value(2.0));

     //  quantity * scalar
     BOOST_CHECK(E*2.0 == bu::quantity<bu::dimensionless>::from_value(5.0));

     //  quantity / scalar
     BOOST_CHECK(E/2.0 == bu::quantity<bu::dimensionless>::from_value(1.25));

     // scalar * quantity
     BOOST_CHECK(2.0*E == bu::quantity<bu::dimensionless>::from_value(5.0));

     // scalar / quantity
     BOOST_CHECK(2.0/E == bu::quantity<bu::dimensionless>::from_value(0.8));

     const bu::quantity<bu::dimensionless>       D1(1.0),
                                                 D2(2.0);

     // unit * quantity
     BOOST_CHECK(bu::dimensionless()*D1 == D1);

     // unit / quantity
     BOOST_CHECK(bu::dimensionless()/D1 == D1);

     // quantity * unit
     BOOST_CHECK(D1*bu::dimensionless() == D1);

     // quantity / unit
     BOOST_CHECK(D1*bu::dimensionless() == D1);

     // +quantity
     BOOST_CHECK(+D1 == 1.0*bu::dimensionless());

     // -quantity
     BOOST_CHECK(-D1 == -1.0*bu::dimensionless());

     // quantity + quantity
     BOOST_CHECK(D2+D1 == 3.0*bu::dimensionless());

     // quantity - quantity
     BOOST_CHECK(D2-D1 == 1.0*bu::dimensionless());

     // quantity * quantity
     BOOST_CHECK(D1*D2 == 2.0*bu::dimensionless());

     // quantity / quantity
     BOOST_CHECK(D2/D1 == 2.0*bu::dimensionless());

     // integer power of quantity
     BOOST_CHECK(2.0*bu::pow<2>(D2) == 2.0*std::pow(2.0,2.0)*bu::dimensionless());

     // rational power of quantity
     BOOST_CHECK((2.0*bu::pow< bu::static_rational<2,3> >(D2) == 2.0*std::pow(2.0,2.0/3.0)*bu::dimensionless()));

     // integer root of quantity
     BOOST_CHECK(2.0*bu::root<2>(D2) == 2.0*std::pow(2.0,1.0/2.0)*bu::dimensionless());

     // rational root of quantity
     BOOST_CHECK((2.0*bu::root< bu::static_rational<3,2> >(D2) == 2.0*std::pow(2.0,2.0/3.0)*bu::dimensionless()));

     const bu::quantity<bu::dimensionless>   A1(0.0),
                                             A2(0.0),
                                             A3(1.0),
                                             A4(-1.0);

     // operator==
     BOOST_CHECK((A1 == A2) == true);
     BOOST_CHECK((A1 == A3) == false);

     // operator!=
     BOOST_CHECK((A1 != A2) == false);
     BOOST_CHECK((A1 != A3) == true);

     // operator<
     BOOST_CHECK((A1 < A2) == false);
     BOOST_CHECK((A1 < A3) == true);

     // operator<=
     BOOST_CHECK((A1 <= A2) == true);
     BOOST_CHECK((A1 <= A3) == true);

     // operator>
     BOOST_CHECK((A1 > A2) == false);
     BOOST_CHECK((A1 > A4) == true);

     // operator>=
     BOOST_CHECK((A1 >= A2) == true);
     BOOST_CHECK((A1 >= A4) == true);

     return 0;
 }
	// Boost.Units - A C++ library for zero-overhead dimensional analysis and
	// unit/quantity manipulation and conversion
	//
	// Copyright (C) 2003-2008 Matthias Christian Schabel
	// Copyright (C) 2008 Steven Watanabe
	//
	// 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)

	/**
	\file

	\brief test_dimensionless_quantity.cpp

	\details
	Test unit class.

	Output:
	@verbatim
	@endverbatim
	**/

	#include "test_header.hpp"

	#include <boost/units/pow.hpp>

	namespace bu = boost::units;

	static const double E_ = 2.718281828459045235360287471352662497757;

	int test_main(int,char *[])
	{
	// default constructor
	const bu::quantity<bu::dimensionless> E1;
	BOOST_CHECK(E1.value() == double());

	// value_type constructor
	const bu::quantity<bu::dimensionless> E2(E_);
	BOOST_CHECK(E2.value() == E_);

	// copy constructor
	const bu::quantity<bu::dimensionless> E3(E2);
	BOOST_CHECK(E3.value() == E_);

	// operator=
	const bu::quantity<bu::dimensionless> E4 = E2;
	BOOST_CHECK(E4.value() == E_);

	// implicit copy constructor value_type conversion
	const bu::quantity<bu::dimensionless,float> E5(E2);
	BOOST_UNITS_CHECK_CLOSE(E5.value(), float(E_));

	const bu::quantity<bu::dimensionless,long> E6(E2);
	BOOST_CHECK(E6.value() == long(E_));

	// implicit operator= value_type conversion
	// narrowing conversion disallowed
	// const bu::quantity<bu::dimensionless,float> E7 = E2;
	// BOOST_UNITS_CHECK_CLOSE(E7.value(),float(E_));

	// narrowing conversion disallowed
	// const bu::quantity<bu::dimensionless,long> E8 = E2;
	// BOOST_CHECK(E8.value() == long(E_));

	// const construction
	bu::quantity<bu::dimensionless> E9(E2);
	BOOST_CHECK(E9.value() == E_);

	// // value assignment
	// E9.value() = 1.5*bu::dimensionless();
	// BOOST_CHECK(E9.value() == 1.5);
	//
	// // value assignment with implicit conversion
	// E9.value() = 1.5;
	// BOOST_CHECK(E9.value() == 1.5);
	//
	// // value assignment with implicit value_type conversion
	// E9.value() = 2*bu::dimensionless();
	// BOOST_CHECK(E9.value() == double(2));
	//
	// // value assignment with implicit value_type conversion
	// E9.value() = 2;
	// BOOST_CHECK(E9.value() == double(2));

	// operator+=(this_type)
	E9 = 2.0;
	E9 += E9;
	BOOST_CHECK(E9.value() == 4.0);

	// operator-=(this_type)
	E9 = 2.0;
	E9 -= E9;
	BOOST_CHECK(E9.value() == 0.0);

	// operator*=(value_type)
	E9 = 2.0;
	E9 *= 2.0;
	BOOST_CHECK(E9.value() == 4.0);

	// operator/=(value_type)
	E9 = 2.0;
	E9 /= 2.0;
	BOOST_CHECK(E9.value() == 1.0);

	// static construct quantity from value_type
	const bu::quantity<bu::dimensionless> E(bu::quantity<bu::dimensionless>::from_value(2.5));
	BOOST_CHECK(E.value() == 2.5);

	// implicit conversion to value_type
	const double V1(E9);
	BOOST_CHECK(V1 == E9.value());

	const double V2 = E9;
	BOOST_CHECK(V2 == E9.value());

	// unit * scalar
	BOOST_CHECK(bu::dimensionless()*2.0 == bu::quantity<bu::dimensionless>::from_value(2.0));

	// unit / scalar
	BOOST_CHECK(bu::dimensionless()/2.0 == bu::quantity<bu::dimensionless>::from_value(0.5));

	// scalar * unit
	BOOST_CHECK(2.0*bu::dimensionless() == bu::quantity<bu::dimensionless>::from_value(2.0));

	// scalar / unit
	BOOST_CHECK(2.0/bu::dimensionless() == bu::quantity<bu::dimensionless>::from_value(2.0));

	// quantity * scalar
	BOOST_CHECK(E*2.0 == bu::quantity<bu::dimensionless>::from_value(5.0));

	// quantity / scalar
	BOOST_CHECK(E/2.0 == bu::quantity<bu::dimensionless>::from_value(1.25));

	// scalar * quantity
	BOOST_CHECK(2.0*E == bu::quantity<bu::dimensionless>::from_value(5.0));

	// scalar / quantity
	BOOST_CHECK(2.0/E == bu::quantity<bu::dimensionless>::from_value(0.8));

	const bu::quantity<bu::dimensionless> D1(1.0),
	D2(2.0);

	// unit * quantity
	BOOST_CHECK(bu::dimensionless()*D1 == D1);

	// unit / quantity
	BOOST_CHECK(bu::dimensionless()/D1 == D1);

	// quantity * unit
	BOOST_CHECK(D1*bu::dimensionless() == D1);

	// quantity / unit
	BOOST_CHECK(D1*bu::dimensionless() == D1);

	// +quantity
	BOOST_CHECK(+D1 == 1.0*bu::dimensionless());

	// -quantity
	BOOST_CHECK(-D1 == -1.0*bu::dimensionless());

	// quantity + quantity
	BOOST_CHECK(D2+D1 == 3.0*bu::dimensionless());

	// quantity - quantity
	BOOST_CHECK(D2-D1 == 1.0*bu::dimensionless());

	// quantity * quantity
	BOOST_CHECK(D1D2 == 2.0bu::dimensionless());

	// quantity / quantity
	BOOST_CHECK(D2/D1 == 2.0*bu::dimensionless());

	// integer power of quantity
	BOOST_CHECK(2.0bu::pow<2>(D2) == 2.0std::pow(2.0,2.0)*bu::dimensionless());

	// rational power of quantity
	BOOST_CHECK((2.0bu::pow< bu::static_rational<2,3> >(D2) == 2.0std::pow(2.0,2.0/3.0)*bu::dimensionless()));

	// integer root of quantity
	BOOST_CHECK(2.0bu::root<2>(D2) == 2.0std::pow(2.0,1.0/2.0)*bu::dimensionless());

	// rational root of quantity
	BOOST_CHECK((2.0bu::root< bu::static_rational<3,2> >(D2) == 2.0std::pow(2.0,2.0/3.0)*bu::dimensionless()));

	const bu::quantity<bu::dimensionless> A1(0.0),
	A2(0.0),
	A3(1.0),
	A4(-1.0);

	// operator==
	BOOST_CHECK((A1 == A2) == true);
	BOOST_CHECK((A1 == A3) == false);

	// operator!=
	BOOST_CHECK((A1 != A2) == false);
	BOOST_CHECK((A1 != A3) == true);

	// operator<
	BOOST_CHECK((A1 < A2) == false);
	BOOST_CHECK((A1 < A3) == true);

	// operator<=
	BOOST_CHECK((A1 <= A2) == true);
	BOOST_CHECK((A1 <= A3) == true);

	// operator>
	BOOST_CHECK((A1 > A2) == false);
	BOOST_CHECK((A1 > A4) == true);

	// operator>=
	BOOST_CHECK((A1 >= A2) == true);
	BOOST_CHECK((A1 >= A4) == true);

	return 0;
	}