/usr/include/trilinos/Teuchos_ScalarTraitsDecl.hpp is in libtrilinos-teuchos-dev 12.4.2-2.
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#ifndef _TEUCHOS_SCALARTRAITS_DECL_HPP_
#define _TEUCHOS_SCALARTRAITS_DECL_HPP_
/*! \file Teuchos_ScalarTraitsDecl.hpp
\brief Declaration and default implementation for basic traits for the scalar field type.
*/
#include "Teuchos_ConfigDefs.hpp"
namespace Teuchos {
template <typename T>
struct UndefinedScalarTraits
{
//! This function should not compile if there is an attempt to instantiate!
static inline T notDefined() { return T::this_type_is_missing_a_specialization(); }
};
/* This is the default structure used by ScalarTraits<T> to produce a compile time
error when the specialization does not exist for type <tt>T</tt>.
*/
/*! \brief This structure defines some basic traits for a scalar field type.
*
* Scalar traits are an essential part of templated codes. This structure offers
* the basic traits of the templated scalar type, like defining zero and one,
* and basic functions on the templated scalar type, like performing a square root.
*
* The functions in the templated base unspecialized struct are designed not to
* compile (giving a nice compile-time error message) and therefore specializations
* must be written for Scalar types actually used.
*
* \note <ol>
*
* <li> The default defined specializations are provided for \c int, \c float, and \c double.
*
* <li> If Teuchos is configured with </tt>Teuchos_ENABLE_COMPLEX=ON</tt> then
* ScalarTraits also has a partial specialization for all
* <tt>std::complex</tt> numbers of the form <tt>std::complex<T></tt>.
*
* </ol>
*/
template <typename T>
struct ScalarTraits
{
//! Mandatory typedef for result of magnitude
typedef T magnitudeType;
//! Typedef for half precision
typedef T halfPrecision;
//! Typedef for double precision
typedef T doublePrecision;
//! Determines if scalar type is std::complex
static const bool isComplex = false;
//! Determines if scalar type is an ordinal type
static const bool isOrdinal = false;
//! Determines if scalar type supports relational operators such as <, >, <=, >=.
static const bool isComparable = false;
/** \brief Determines if scalar type have machine-specific parameters
* (i.e. eps(), sfmin(), base(), prec(), t(), rnd(), emin(), rmin(), emax(),
* rmax() are supported).
*/
static const bool hasMachineParameters = false;
//! Returns relative machine precision.
static inline magnitudeType eps() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns safe minimum (sfmin), such that 1/sfmin does not overflow.
static inline magnitudeType sfmin() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the base of the machine.
static inline magnitudeType base() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns \c eps*base.
static inline magnitudeType prec() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the number of (base) digits in the mantissa.
static inline magnitudeType t() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns 1.0 when rounding occurs in addition, 0.0 otherwise
static inline magnitudeType rnd() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the minimum exponent before (gradual) underflow.
static inline magnitudeType emin() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the underflow threshold - \c base^(emin-1)
static inline magnitudeType rmin() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the largest exponent before overflow.
static inline magnitudeType emax() { return UndefinedScalarTraits<T>::notDefined(); }
//! Overflow theshold - \c (base^emax)*(1-eps)
static inline magnitudeType rmax() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the magnitudeType of the scalar type \c a.
static inline magnitudeType magnitude(T a) { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns representation of zero for this scalar type.
static inline T zero() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns representation of one for this scalar type.
static inline T one() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the real part of the scalar type \c a.
static inline magnitudeType real(T a) { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the imaginary part of the scalar type \c a.
static inline magnitudeType imag(T a) { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the conjugate of the scalar type \c a.
static inline T conjugate(T a) { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns a number that represents NaN.
static inline T nan() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns <tt>true</tt> if <tt>x</tt> is NaN or Inf.
static inline bool isnaninf(const T& x) { return UndefinedScalarTraits<T>::notDefined(); }
//! Seed the random number generator returned by <tt>random()</tt>.
static inline void seedrandom(unsigned int s) { int i; T t = &i; }
//! Returns a random number (between -one() and +one()) of this scalar type.
static inline T random() { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the name of this scalar type.
static inline std::string name() { (void)UndefinedScalarTraits<T>::notDefined(); return 0; }
//! Returns a number of magnitudeType that is the square root of this scalar type \c x.
static inline T squareroot(T x) { return UndefinedScalarTraits<T>::notDefined(); }
//! Returns the result of raising one scalar \c x to the power \c y.
static inline T pow(T x, T y) { return UndefinedScalarTraits<T>::notDefined(); }
};
} // Teuchos namespace
#endif // _TEUCHOS_SCALARTRAITS_DECL_HPP_
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