test/fastmath.cpp - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2015 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #include "main.h"

 void check(bool b, bool ref)
 {
   std::cout << b;
   if(b==ref)
     std::cout << " OK  ";
   else
     std::cout << " BAD ";
 }

 #if EIGEN_COMP_MSVC && EIGEN_COMP_MSVC < 1800
 namespace std {
   template<typename T> bool (isfinite)(T x) { return _finite(x); }
   template<typename T> bool (isnan)(T x) { return _isnan(x); }
   template<typename T> bool (isinf)(T x) { return _fpclass(x)==_FPCLASS_NINF || _fpclass(x)==_FPCLASS_PINF; }
 }
 #endif

 template<typename T>
 void check_inf_nan(bool dryrun) {
   Matrix<T,Dynamic,1> m(10);
   m.setRandom();
   m(3) = std::numeric_limits<T>::quiet_NaN();

   if(dryrun)
   {
     std::cout << "std::isfinite(" << m(3) << ") = "; check((std::isfinite)(m(3)),false); std::cout << "  ; numext::isfinite = "; check((numext::isfinite)(m(3)), false); std::cout << "\n";
     std::cout << "std::isinf(" << m(3) << ")    = "; check((std::isinf)(m(3)),false);    std::cout << "  ; numext::isinf    = "; check((numext::isinf)(m(3)), false); std::cout << "\n";
     std::cout << "std::isnan(" << m(3) << ")    = "; check((std::isnan)(m(3)),true);     std::cout << "  ; numext::isnan    = "; check((numext::isnan)(m(3)), true); std::cout << "\n";
     std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
     std::cout << "hasNaN:    "; check(m.hasNaN(), 1);    std::cout << "\n";
     std::cout << "\n";
   }
   else
   {
     if( (std::isfinite)(m(3))) g_test_level=1;  VERIFY( !(numext::isfinite)(m(3)) ); g_test_level=0;
     if( (std::isinf)   (m(3))) g_test_level=1;  VERIFY( !(numext::isinf)(m(3)) );    g_test_level=0;
     if(!(std::isnan)   (m(3))) g_test_level=1;  VERIFY(  (numext::isnan)(m(3)) );    g_test_level=0;
     if( (std::isfinite)(m(3))) g_test_level=1;  VERIFY( !m.allFinite() );            g_test_level=0;
     if(!(std::isnan)   (m(3))) g_test_level=1;  VERIFY(  m.hasNaN() );               g_test_level=0;
   }
   T hidden_zero = (std::numeric_limits<T>::min)()*(std::numeric_limits<T>::min)();
   m(4) /= hidden_zero;
   if(dryrun)
   {
     std::cout << "std::isfinite(" << m(4) << ") = "; check((std::isfinite)(m(4)),false); std::cout << "  ; numext::isfinite = "; check((numext::isfinite)(m(4)), false); std::cout << "\n";
     std::cout << "std::isinf(" << m(4) << ")    = "; check((std::isinf)(m(4)),true);     std::cout << "  ; numext::isinf    = "; check((numext::isinf)(m(4)), true); std::cout << "\n";
     std::cout << "std::isnan(" << m(4) << ")    = "; check((std::isnan)(m(4)),false);    std::cout << "  ; numext::isnan    = "; check((numext::isnan)(m(4)), false); std::cout << "\n";
     std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
     std::cout << "hasNaN:    "; check(m.hasNaN(), 1);    std::cout << "\n";
     std::cout << "\n";
   }
   else
   {
     if( (std::isfinite)(m(3))) g_test_level=1;  VERIFY( !(numext::isfinite)(m(4)) );  g_test_level=0;
     if(!(std::isinf)   (m(3))) g_test_level=1;  VERIFY(  (numext::isinf)(m(4)) );     g_test_level=0;
     if( (std::isnan)   (m(3))) g_test_level=1;  VERIFY( !(numext::isnan)(m(4)) );     g_test_level=0;
     if( (std::isfinite)(m(3))) g_test_level=1;  VERIFY( !m.allFinite() );             g_test_level=0;
     if(!(std::isnan)   (m(3))) g_test_level=1;  VERIFY(  m.hasNaN() );                g_test_level=0;
   }
   m(3) = 0;
   if(dryrun)
   {
     std::cout << "std::isfinite(" << m(3) << ") = "; check((std::isfinite)(m(3)),true); std::cout << "  ; numext::isfinite = "; check((numext::isfinite)(m(3)), true); std::cout << "\n";
     std::cout << "std::isinf(" << m(3) << ")    = "; check((std::isinf)(m(3)),false);   std::cout << "  ; numext::isinf    = "; check((numext::isinf)(m(3)), false); std::cout << "\n";
     std::cout << "std::isnan(" << m(3) << ")    = "; check((std::isnan)(m(3)),false);   std::cout << "  ; numext::isnan    = "; check((numext::isnan)(m(3)), false); std::cout << "\n";
     std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
     std::cout << "hasNaN:    "; check(m.hasNaN(), 0);    std::cout << "\n";
     std::cout << "\n\n";
   }
   else
   {
     if(!(std::isfinite)(m(3))) g_test_level=1;  VERIFY(  (numext::isfinite)(m(3)) );  g_test_level=0;
     if( (std::isinf)   (m(3))) g_test_level=1;  VERIFY( !(numext::isinf)(m(3)) );     g_test_level=0;
     if( (std::isnan)   (m(3))) g_test_level=1;  VERIFY( !(numext::isnan)(m(3)) );     g_test_level=0;
     if( (std::isfinite)(m(3))) g_test_level=1;  VERIFY( !m.allFinite() );             g_test_level=0;
     if( (std::isnan)   (m(3))) g_test_level=1;  VERIFY( !m.hasNaN() );                g_test_level=0;
   }
 }

 EIGEN_DECLARE_TEST(fastmath) {
   std::cout << "*** float *** \n\n"; check_inf_nan<float>(true);
   std::cout << "*** double ***\n\n"; check_inf_nan<double>(true);
   std::cout << "*** long double *** \n\n"; check_inf_nan<long double>(true);

   check_inf_nan<float>(false);
   check_inf_nan<double>(false);
   check_inf_nan<long double>(false);
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2015 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#include "main.h"

	void check(bool b, bool ref)
	{
	std::cout << b;
	if(b==ref)
	std::cout << " OK ";
	else
	std::cout << " BAD ";
	}

	#if EIGEN_COMP_MSVC && EIGEN_COMP_MSVC < 1800
	namespace std {
	template<typename T> bool (isfinite)(T x) { return _finite(x); }
	template<typename T> bool (isnan)(T x) { return _isnan(x); }
	template<typename T> bool (isinf)(T x) { return _fpclass(x)==_FPCLASS_NINF \|\| _fpclass(x)==_FPCLASS_PINF; }
	}
	#endif

	template<typename T>
	void check_inf_nan(bool dryrun) {
	Matrix<T,Dynamic,1> m(10);
	m.setRandom();
	m(3) = std::numeric_limits<T>::quiet_NaN();

	if(dryrun)
	{
	std::cout << "std::isfinite(" << m(3) << ") = "; check((std::isfinite)(m(3)),false); std::cout << " ; numext::isfinite = "; check((numext::isfinite)(m(3)), false); std::cout << "\n";
	std::cout << "std::isinf(" << m(3) << ") = "; check((std::isinf)(m(3)),false); std::cout << " ; numext::isinf = "; check((numext::isinf)(m(3)), false); std::cout << "\n";
	std::cout << "std::isnan(" << m(3) << ") = "; check((std::isnan)(m(3)),true); std::cout << " ; numext::isnan = "; check((numext::isnan)(m(3)), true); std::cout << "\n";
	std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
	std::cout << "hasNaN: "; check(m.hasNaN(), 1); std::cout << "\n";
	std::cout << "\n";
	}
	else
	{
	if( (std::isfinite)(m(3))) g_test_level=1; VERIFY( !(numext::isfinite)(m(3)) ); g_test_level=0;
	if( (std::isinf) (m(3))) g_test_level=1; VERIFY( !(numext::isinf)(m(3)) ); g_test_level=0;
	if(!(std::isnan) (m(3))) g_test_level=1; VERIFY( (numext::isnan)(m(3)) ); g_test_level=0;
	if( (std::isfinite)(m(3))) g_test_level=1; VERIFY( !m.allFinite() ); g_test_level=0;
	if(!(std::isnan) (m(3))) g_test_level=1; VERIFY( m.hasNaN() ); g_test_level=0;
	}
	T hidden_zero = (std::numeric_limits<T>::min)()*(std::numeric_limits<T>::min)();
	m(4) /= hidden_zero;
	if(dryrun)
	{
	std::cout << "std::isfinite(" << m(4) << ") = "; check((std::isfinite)(m(4)),false); std::cout << " ; numext::isfinite = "; check((numext::isfinite)(m(4)), false); std::cout << "\n";
	std::cout << "std::isinf(" << m(4) << ") = "; check((std::isinf)(m(4)),true); std::cout << " ; numext::isinf = "; check((numext::isinf)(m(4)), true); std::cout << "\n";
	std::cout << "std::isnan(" << m(4) << ") = "; check((std::isnan)(m(4)),false); std::cout << " ; numext::isnan = "; check((numext::isnan)(m(4)), false); std::cout << "\n";
	std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
	std::cout << "hasNaN: "; check(m.hasNaN(), 1); std::cout << "\n";
	std::cout << "\n";
	}
	else
	{
	if( (std::isfinite)(m(3))) g_test_level=1; VERIFY( !(numext::isfinite)(m(4)) ); g_test_level=0;
	if(!(std::isinf) (m(3))) g_test_level=1; VERIFY( (numext::isinf)(m(4)) ); g_test_level=0;
	if( (std::isnan) (m(3))) g_test_level=1; VERIFY( !(numext::isnan)(m(4)) ); g_test_level=0;
	if( (std::isfinite)(m(3))) g_test_level=1; VERIFY( !m.allFinite() ); g_test_level=0;
	if(!(std::isnan) (m(3))) g_test_level=1; VERIFY( m.hasNaN() ); g_test_level=0;
	}
	m(3) = 0;
	if(dryrun)
	{
	std::cout << "std::isfinite(" << m(3) << ") = "; check((std::isfinite)(m(3)),true); std::cout << " ; numext::isfinite = "; check((numext::isfinite)(m(3)), true); std::cout << "\n";
	std::cout << "std::isinf(" << m(3) << ") = "; check((std::isinf)(m(3)),false); std::cout << " ; numext::isinf = "; check((numext::isinf)(m(3)), false); std::cout << "\n";
	std::cout << "std::isnan(" << m(3) << ") = "; check((std::isnan)(m(3)),false); std::cout << " ; numext::isnan = "; check((numext::isnan)(m(3)), false); std::cout << "\n";
	std::cout << "allFinite: "; check(m.allFinite(), 0); std::cout << "\n";
	std::cout << "hasNaN: "; check(m.hasNaN(), 0); std::cout << "\n";
	std::cout << "\n\n";
	}
	else
	{
	if(!(std::isfinite)(m(3))) g_test_level=1; VERIFY( (numext::isfinite)(m(3)) ); g_test_level=0;
	if( (std::isinf) (m(3))) g_test_level=1; VERIFY( !(numext::isinf)(m(3)) ); g_test_level=0;
	if( (std::isnan) (m(3))) g_test_level=1; VERIFY( !(numext::isnan)(m(3)) ); g_test_level=0;
	if( (std::isfinite)(m(3))) g_test_level=1; VERIFY( !m.allFinite() ); g_test_level=0;
	if( (std::isnan) (m(3))) g_test_level=1; VERIFY( !m.hasNaN() ); g_test_level=0;
	}
	}

	EIGEN_DECLARE_TEST(fastmath) {
	std::cout << "* float * \n\n"; check_inf_nan<float>(true);
	std::cout << "* double *\n\n"; check_inf_nan<double>(true);
	std::cout << "* long double * \n\n"; check_inf_nan<long double>(true);

	check_inf_nan<float>(false);
	check_inf_nan<double>(false);
	check_inf_nan<long double>(false);
	}