/usr/include/coin/CoinFloatEqual.hpp is in coinor-libcoinutils-dev 2.9.10-1ubuntu2.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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// Copyright (C) 2000, International Business Machines
// Corporation and others. All Rights Reserved.
// This code is licensed under the terms of the Eclipse Public License (EPL).
#ifndef CoinFloatEqual_H
#define CoinFloatEqual_H
#include <algorithm>
#include <cmath>
#include "CoinFinite.hpp"
/*! \file CoinFloatEqual.hpp
\brief Function objects for testing equality of real numbers.
Two objects are provided; one tests for equality to an absolute tolerance,
one to a scaled tolerance. The tests will handle IEEE floating point, but
note that infinity == infinity. Mathematicians are rolling in their graves,
but this matches the behaviour for the common practice of using
<code>DBL_MAX</code> (<code>numeric_limits<double>::max()</code>, or similar
large finite number) as infinity.
<p>
Example usage:
@verbatim
double d1 = 3.14159 ;
double d2 = d1 ;
double d3 = d1+.0001 ;
CoinAbsFltEq eq1 ;
CoinAbsFltEq eq2(.001) ;
assert( eq1(d1,d2) ) ;
assert( !eq1(d1,d3) ) ;
assert( eq2(d1,d3) ) ;
@endverbatim
CoinRelFltEq follows the same pattern. */
/*! \brief Equality to an absolute tolerance
Operands are considered equal if their difference is within an epsilon ;
the test does not consider the relative magnitude of the operands.
*/
class CoinAbsFltEq
{
public:
//! Compare function
inline bool operator() (const double f1, const double f2) const
{ if (CoinIsnan(f1) || CoinIsnan(f2)) return false ;
if (f1 == f2) return true ;
return (fabs(f1-f2) < epsilon_) ; }
/*! \name Constructors and destructors */
//@{
/*! \brief Default constructor
Default tolerance is 1.0e-10.
*/
CoinAbsFltEq () : epsilon_(1.e-10) {}
//! Alternate constructor with epsilon as a parameter
CoinAbsFltEq (const double epsilon) : epsilon_(epsilon) {}
//! Destructor
virtual ~CoinAbsFltEq () {}
//! Copy constructor
CoinAbsFltEq (const CoinAbsFltEq& src) : epsilon_(src.epsilon_) {}
//! Assignment
CoinAbsFltEq& operator= (const CoinAbsFltEq& rhs)
{ if (this != &rhs) epsilon_ = rhs.epsilon_ ;
return (*this) ; }
//@}
private:
/*! \name Private member data */
//@{
//! Equality tolerance.
double epsilon_ ;
//@}
} ;
/*! \brief Equality to a scaled tolerance
Operands are considered equal if their difference is within a scaled
epsilon calculated as epsilon_*(1+CoinMax(|f1|,|f2|)).
*/
class CoinRelFltEq
{
public:
//! Compare function
inline bool operator() (const double f1, const double f2) const
{ if (CoinIsnan(f1) || CoinIsnan(f2)) return false ;
if (f1 == f2) return true ;
if (!CoinFinite(f1) || !CoinFinite(f2)) return false ;
double tol = (fabs(f1)>fabs(f2))?fabs(f1):fabs(f2) ;
return (fabs(f1-f2) <= epsilon_*(1+tol)) ; }
/*! \name Constructors and destructors */
//@{
#ifndef COIN_FLOAT
/*! Default constructor
Default tolerance is 1.0e-10.
*/
CoinRelFltEq () : epsilon_(1.e-10) {}
#else
/*! Default constructor
Default tolerance is 1.0e-6.
*/
CoinRelFltEq () : epsilon_(1.e-6) {} ; // as float
#endif
//! Alternate constructor with epsilon as a parameter
CoinRelFltEq (const double epsilon) : epsilon_(epsilon) {}
//! Destructor
virtual ~CoinRelFltEq () {}
//! Copy constructor
CoinRelFltEq (const CoinRelFltEq & src) : epsilon_(src.epsilon_) {}
//! Assignment
CoinRelFltEq& operator= (const CoinRelFltEq& rhs)
{ if (this != &rhs) epsilon_ = rhs.epsilon_ ;
return (*this) ; }
//@}
private:
/*! \name Private member data */
//@{
//! Base equality tolerance
double epsilon_ ;
//@}
} ;
#endif
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