llvm-gcc-4.2/libstdc++-v3/testsuite/tr1/8_c_compatibility/complex/overloads_int.cc - llvm-archive - Git at Google

 // 2006-01-12  Paolo Carlini  <pcarlini@suse.de>
 //
 // Copyright (C) 2006 Free Software Foundation, Inc.
 //
 // This file is part of the GNU ISO C++ Library.  This library is free
 // software; you can redistribute it and/or modify it under the
 // terms of the GNU General Public License as published by the
 // Free Software Foundation; either version 2, or (at your option)
 // any later version.
 //
 // This library is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.
 //
 // You should have received a copy of the GNU General Public License along
 // with this library; see the file COPYING.  If not, write to the Free
 // Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
 // USA.

 // 8.1 Additions to header <complex>

 #include <tr1/complex>
 #include <testsuite_hooks.h>
 #include <testsuite_tr1.h>

 void test01()
 {
   bool test __attribute__((unused)) = true;
   using __gnu_test::check_ret_type;

   typedef std::complex<float>  cmplx_f_type;
   typedef std::complex<double> cmplx_d_type;

   const int       i1 = 1;
   const unsigned  u1 = 1;
   const long      l1 = 1;
   const double    f1 = 1.0f;
   const double    d1 = 1.0;

   check_ret_type<double>(std::tr1::arg(i1));
   VERIFY( std::tr1::arg(i1) == std::tr1::arg(double(i1)) );
   VERIFY( std::tr1::arg(i1) == std::tr1::arg(cmplx_d_type(double(i1))) );

   check_ret_type<cmplx_d_type>(std::tr1::conj(i1));
   VERIFY( std::tr1::conj(i1) == std::tr1::conj(double(i1)) );
   VERIFY( std::tr1::conj(i1) == std::tr1::conj(cmplx_d_type(double(i1))) );

   check_ret_type<double>(std::tr1::imag(i1));
   VERIFY( std::tr1::imag(i1) == std::tr1::imag(double(i1)) );
   VERIFY( std::tr1::imag(i1) == std::tr1::imag(cmplx_d_type(double(i1))) );

   check_ret_type<double>(std::tr1::norm(i1));
   VERIFY( std::tr1::norm(i1) == std::tr1::norm(double(i1)) );
   // std::norm<const complex<>&) is mathematically equivalent to just
   // this for a real, but the general algorithm goes through std::abs
   // and a multiplication.
   VERIFY( std::tr1::norm(i1) == double(i1) * double(i1) );

   // NB: The existing std::polar wins and a cmplx_i_type is returned.
   // check_ret_type<cmplx_d_type>(std::tr1::polar(i1, i1));
   // VERIFY( std::tr1::polar(i1, i1)
   //         == std::tr1::polar(double(i1), double(i1)) );
   typedef std::complex<int> cmplx_i_type;
   check_ret_type<cmplx_i_type>(std::tr1::polar(i1, i1));

   // NB: According to the letter of 8.1.9/3 the return type should be a
   // cmplx_d_type, but the existing std::pow(const complex<>&, int) wins.
   // check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), i1));
   check_ret_type<cmplx_f_type>(std::tr1::pow(cmplx_f_type(f1, f1), i1));

   check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), u1));
   check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), l1));
   check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_d_type(d1, d1), i1));

   // See last comment.
   // VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), i1)
   //         == std::tr1::pow(cmplx_d_type(d1, d1), double(i1)) );
   VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), u1)
 	  == std::tr1::pow(cmplx_d_type(d1, d1), double(u1)) );
   VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), l1)
 	  == std::tr1::pow(cmplx_d_type(d1, d1), double(l1)) );

   check_ret_type<cmplx_d_type>(std::tr1::pow(i1, cmplx_f_type(f1, f1)));
   check_ret_type<cmplx_d_type>(std::tr1::pow(u1, cmplx_f_type(f1, f1)));
   check_ret_type<cmplx_d_type>(std::tr1::pow(l1, cmplx_f_type(f1, f1)));
   check_ret_type<cmplx_d_type>(std::tr1::pow(i1, cmplx_d_type(d1, d1)));
   VERIFY( std::tr1::pow(i1, cmplx_d_type(d1, d1))
 	  == std::tr1::pow(double(i1), cmplx_d_type(d1, d1)) );
   VERIFY( std::tr1::pow(u1, cmplx_d_type(d1, d1))
 	  == std::tr1::pow(double(u1), cmplx_d_type(d1, d1)) );
   VERIFY( std::tr1::pow(l1, cmplx_d_type(d1, d1))
 	  == std::tr1::pow(double(l1), cmplx_d_type(d1, d1)) );

   check_ret_type<double>(std::tr1::real(i1));
   VERIFY( std::tr1::real(i1) == std::tr1::real(double(i1)) );
   VERIFY( std::tr1::real(i1) == std::tr1::real(cmplx_d_type(double(i1))) );
 }

 int main()
 {
   test01();
   return 0;
 }
	// 2006-01-12 Paolo Carlini <pcarlini@suse.de>
	//
	// Copyright (C) 2006 Free Software Foundation, Inc.
	//
	// This file is part of the GNU ISO C++ Library. This library is free
	// software; you can redistribute it and/or modify it under the
	// terms of the GNU General Public License as published by the
	// Free Software Foundation; either version 2, or (at your option)
	// any later version.
	//
	// This library is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.
	//
	// You should have received a copy of the GNU General Public License along
	// with this library; see the file COPYING. If not, write to the Free
	// Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
	// USA.

	// 8.1 Additions to header <complex>

	#include <tr1/complex>
	#include <testsuite_hooks.h>
	#include <testsuite_tr1.h>

	void test01()
	{
	bool test __attribute__((unused)) = true;
	using __gnu_test::check_ret_type;

	typedef std::complex<float> cmplx_f_type;
	typedef std::complex<double> cmplx_d_type;

	const int i1 = 1;
	const unsigned u1 = 1;
	const long l1 = 1;
	const double f1 = 1.0f;
	const double d1 = 1.0;

	check_ret_type<double>(std::tr1::arg(i1));
	VERIFY( std::tr1::arg(i1) == std::tr1::arg(double(i1)) );
	VERIFY( std::tr1::arg(i1) == std::tr1::arg(cmplx_d_type(double(i1))) );

	check_ret_type<cmplx_d_type>(std::tr1::conj(i1));
	VERIFY( std::tr1::conj(i1) == std::tr1::conj(double(i1)) );
	VERIFY( std::tr1::conj(i1) == std::tr1::conj(cmplx_d_type(double(i1))) );

	check_ret_type<double>(std::tr1::imag(i1));
	VERIFY( std::tr1::imag(i1) == std::tr1::imag(double(i1)) );
	VERIFY( std::tr1::imag(i1) == std::tr1::imag(cmplx_d_type(double(i1))) );

	check_ret_type<double>(std::tr1::norm(i1));
	VERIFY( std::tr1::norm(i1) == std::tr1::norm(double(i1)) );
	// std::norm<const complex<>&) is mathematically equivalent to just
	// this for a real, but the general algorithm goes through std::abs
	// and a multiplication.
	VERIFY( std::tr1::norm(i1) == double(i1) * double(i1) );

	// NB: The existing std::polar wins and a cmplx_i_type is returned.
	// check_ret_type<cmplx_d_type>(std::tr1::polar(i1, i1));
	// VERIFY( std::tr1::polar(i1, i1)
	// == std::tr1::polar(double(i1), double(i1)) );
	typedef std::complex<int> cmplx_i_type;
	check_ret_type<cmplx_i_type>(std::tr1::polar(i1, i1));

	// NB: According to the letter of 8.1.9/3 the return type should be a
	// cmplx_d_type, but the existing std::pow(const complex<>&, int) wins.
	// check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), i1));
	check_ret_type<cmplx_f_type>(std::tr1::pow(cmplx_f_type(f1, f1), i1));

	check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), u1));
	check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_f_type(f1, f1), l1));
	check_ret_type<cmplx_d_type>(std::tr1::pow(cmplx_d_type(d1, d1), i1));

	// See last comment.
	// VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), i1)
	// == std::tr1::pow(cmplx_d_type(d1, d1), double(i1)) );
	VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), u1)
	== std::tr1::pow(cmplx_d_type(d1, d1), double(u1)) );
	VERIFY( std::tr1::pow(cmplx_d_type(d1, d1), l1)
	== std::tr1::pow(cmplx_d_type(d1, d1), double(l1)) );

	check_ret_type<cmplx_d_type>(std::tr1::pow(i1, cmplx_f_type(f1, f1)));
	check_ret_type<cmplx_d_type>(std::tr1::pow(u1, cmplx_f_type(f1, f1)));
	check_ret_type<cmplx_d_type>(std::tr1::pow(l1, cmplx_f_type(f1, f1)));
	check_ret_type<cmplx_d_type>(std::tr1::pow(i1, cmplx_d_type(d1, d1)));
	VERIFY( std::tr1::pow(i1, cmplx_d_type(d1, d1))
	== std::tr1::pow(double(i1), cmplx_d_type(d1, d1)) );
	VERIFY( std::tr1::pow(u1, cmplx_d_type(d1, d1))
	== std::tr1::pow(double(u1), cmplx_d_type(d1, d1)) );
	VERIFY( std::tr1::pow(l1, cmplx_d_type(d1, d1))
	== std::tr1::pow(double(l1), cmplx_d_type(d1, d1)) );

	check_ret_type<double>(std::tr1::real(i1));
	VERIFY( std::tr1::real(i1) == std::tr1::real(double(i1)) );
	VERIFY( std::tr1::real(i1) == std::tr1::real(cmplx_d_type(double(i1))) );
	}

	int main()
	{
	test01();
	return 0;
	}