Eigen/src/Core/NumTraits.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2006-2010 Benoit Jacob <jacob.benoit.1@gmail.com>
 //
 // 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/.

 #ifndef EIGEN_NUMTRAITS_H
 #define EIGEN_NUMTRAITS_H

 namespace Eigen {

 namespace internal {

 // default implementation of digits10(), based on numeric_limits if specialized,
 // 0 for integer types, and log10(epsilon()) otherwise.
 template< typename T,
           bool use_numeric_limits = std::numeric_limits<T>::is_specialized,
           bool is_integer = NumTraits<T>::IsInteger>
 struct default_digits10_impl
 {
   EIGEN_DEVICE_FUNC
   static int run() { return std::numeric_limits<T>::digits10; }
 };

 template<typename T>
 struct default_digits10_impl<T,false,false> // Floating point
 {
   EIGEN_DEVICE_FUNC
   static int run() {
     using std::log10;
     using std::ceil;
     typedef typename NumTraits<T>::Real Real;
     return int(ceil(-log10(NumTraits<Real>::epsilon())));
   }
 };

 template<typename T>
 struct default_digits10_impl<T,false,true> // Integer
 {
   EIGEN_DEVICE_FUNC
   static int run() { return 0; }
 };


 // default implementation of digits(), based on numeric_limits if specialized,
 // 0 for integer types, and log2(epsilon()) otherwise.
 template< typename T,
           bool use_numeric_limits = std::numeric_limits<T>::is_specialized,
           bool is_integer = NumTraits<T>::IsInteger>
 struct default_digits_impl
 {
   EIGEN_DEVICE_FUNC
   static int run() { return std::numeric_limits<T>::digits; }
 };

 template<typename T>
 struct default_digits_impl<T,false,false> // Floating point
 {
   EIGEN_DEVICE_FUNC
   static int run() {
     using std::log;
     using std::ceil;
     typedef typename NumTraits<T>::Real Real;
     return int(ceil(-log(NumTraits<Real>::epsilon())/log(static_cast<Real>(2))));
   }
 };

 template<typename T>
 struct default_digits_impl<T,false,true> // Integer
 {
   EIGEN_DEVICE_FUNC
   static int run() { return 0; }
 };

 } // end namespace internal

 /** \class NumTraits
   * \ingroup Core_Module
   *
   * \brief Holds information about the various numeric (i.e. scalar) types allowed by Eigen.
   *
   * \tparam T the numeric type at hand
   *
   * This class stores enums, typedefs and static methods giving information about a numeric type.
   *
   * The provided data consists of:
   * \li A typedef \c Real, giving the "real part" type of \a T. If \a T is already real,
   *     then \c Real is just a typedef to \a T. If \a T is \c std::complex<U> then \c Real
   *     is a typedef to \a U.
   * \li A typedef \c NonInteger, giving the type that should be used for operations producing non-integral values,
   *     such as quotients, square roots, etc. If \a T is a floating-point type, then this typedef just gives
   *     \a T again. Note however that many Eigen functions such as internal::sqrt simply refuse to
   *     take integers. Outside of a few cases, Eigen doesn't do automatic type promotion. Thus, this typedef is
   *     only intended as a helper for code that needs to explicitly promote types.
   * \li A typedef \c Literal giving the type to use for numeric literals such as "2" or "0.5". For instance, for \c std::complex<U>, Literal is defined as \c U.
   *     Of course, this type must be fully compatible with \a T. In doubt, just use \a T here.
   * \li A typedef \a Nested giving the type to use to nest a value inside of the expression tree. If you don't know what
   *     this means, just use \a T here.
   * \li An enum value \a IsComplex. It is equal to 1 if \a T is a \c std::complex
   *     type, and to 0 otherwise.
   * \li An enum value \a IsInteger. It is equal to \c 1 if \a T is an integer type such as \c int,
   *     and to \c 0 otherwise.
   * \li Enum values ReadCost, AddCost and MulCost representing a rough estimate of the number of CPU cycles needed
   *     to by move / add / mul instructions respectively, assuming the data is already stored in CPU registers.
   *     Stay vague here. No need to do architecture-specific stuff. If you don't know what this means, just use \c Eigen::HugeCost.
   * \li An enum value \a IsSigned. It is equal to \c 1 if \a T is a signed type and to 0 if \a T is unsigned.
   * \li An enum value \a RequireInitialization. It is equal to \c 1 if the constructor of the numeric type \a T must
   *     be called, and to 0 if it is safe not to call it. Default is 0 if \a T is an arithmetic type, and 1 otherwise.
   * \li An epsilon() function which, unlike <a href="http://en.cppreference.com/w/cpp/types/numeric_limits/epsilon">std::numeric_limits::epsilon()</a>,
   *     it returns a \a Real instead of a \a T.
   * \li A dummy_precision() function returning a weak epsilon value. It is mainly used as a default
   *     value by the fuzzy comparison operators.
   * \li highest() and lowest() functions returning the highest and lowest possible values respectively.
   * \li digits10() function returning the number of decimal digits that can be represented without change. This is
   *     the analogue of <a href="http://en.cppreference.com/w/cpp/types/numeric_limits/digits10">std::numeric_limits<T>::digits10</a>
   *     which is used as the default implementation if specialized.
   */

 template<typename T> struct GenericNumTraits
 {
   enum {
     IsInteger = std::numeric_limits<T>::is_integer,
     IsSigned = std::numeric_limits<T>::is_signed,
     IsComplex = 0,
     RequireInitialization = internal::is_arithmetic<T>::value ? 0 : 1,
     ReadCost = 1,
     AddCost = 1,
     MulCost = 1
   };

   typedef T Real;
   typedef typename internal::conditional<
                      IsInteger,
                      typename internal::conditional<sizeof(T)<=2, float, double>::type,
                      T
                    >::type NonInteger;
   typedef T Nested;
   typedef T Literal;

   EIGEN_DEVICE_FUNC
   static inline Real epsilon()
   {
     return numext::numeric_limits<T>::epsilon();
   }

   EIGEN_DEVICE_FUNC
   static inline int digits10()
   {
     return internal::default_digits10_impl<T>::run();
   }

   EIGEN_DEVICE_FUNC
   static inline int digits()
   {
     return internal::default_digits_impl<T>::run();
   }

   EIGEN_DEVICE_FUNC
   static inline Real dummy_precision()
   {
     // make sure to override this for floating-point types
     return Real(0);
   }


   EIGEN_DEVICE_FUNC
   static inline T highest() {
     return (numext::numeric_limits<T>::max)();
   }

   EIGEN_DEVICE_FUNC
   static inline T lowest()  {
     return IsInteger ? (numext::numeric_limits<T>::min)()
                      : static_cast<T>(-(numext::numeric_limits<T>::max)());
   }

   EIGEN_DEVICE_FUNC
   static inline T infinity() {
     return numext::numeric_limits<T>::infinity();
   }

   EIGEN_DEVICE_FUNC
   static inline T quiet_NaN() {
     return numext::numeric_limits<T>::quiet_NaN();
   }
 };

 template<typename T> struct NumTraits : GenericNumTraits<T>
 {};

 template<> struct NumTraits<float>
   : GenericNumTraits<float>
 {
   EIGEN_DEVICE_FUNC
   static inline float dummy_precision() { return 1e-5f; }
 };

 template<> struct NumTraits<double> : GenericNumTraits<double>
 {
   EIGEN_DEVICE_FUNC
   static inline double dummy_precision() { return 1e-12; }
 };

 template<> struct NumTraits<long double>
   : GenericNumTraits<long double>
 {
   static inline long double dummy_precision() { return 1e-15l; }
 };

 template<typename _Real> struct NumTraits<std::complex<_Real> >
   : GenericNumTraits<std::complex<_Real> >
 {
   typedef _Real Real;
   typedef typename NumTraits<_Real>::Literal Literal;
   enum {
     IsComplex = 1,
     RequireInitialization = NumTraits<_Real>::RequireInitialization,
     ReadCost = 2 * NumTraits<_Real>::ReadCost,
     AddCost = 2 * NumTraits<Real>::AddCost,
     MulCost = 4 * NumTraits<Real>::MulCost + 2 * NumTraits<Real>::AddCost
   };

   EIGEN_DEVICE_FUNC
   static inline Real epsilon() { return NumTraits<Real>::epsilon(); }
   EIGEN_DEVICE_FUNC
   static inline Real dummy_precision() { return NumTraits<Real>::dummy_precision(); }
   EIGEN_DEVICE_FUNC
   static inline int digits10() { return NumTraits<Real>::digits10(); }
 };

 template<typename Scalar, int Rows, int Cols, int Options, int MaxRows, int MaxCols>
 struct NumTraits<Array<Scalar, Rows, Cols, Options, MaxRows, MaxCols> >
 {
   typedef Array<Scalar, Rows, Cols, Options, MaxRows, MaxCols> ArrayType;
   typedef typename NumTraits<Scalar>::Real RealScalar;
   typedef Array<RealScalar, Rows, Cols, Options, MaxRows, MaxCols> Real;
   typedef typename NumTraits<Scalar>::NonInteger NonIntegerScalar;
   typedef Array<NonIntegerScalar, Rows, Cols, Options, MaxRows, MaxCols> NonInteger;
   typedef ArrayType & Nested;
   typedef typename NumTraits<Scalar>::Literal Literal;

   enum {
     IsComplex = NumTraits<Scalar>::IsComplex,
     IsInteger = NumTraits<Scalar>::IsInteger,
     IsSigned  = NumTraits<Scalar>::IsSigned,
     RequireInitialization = 1,
     ReadCost = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::ReadCost,
     AddCost  = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::AddCost,
     MulCost  = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::MulCost
   };

   EIGEN_DEVICE_FUNC
   static inline RealScalar epsilon() { return NumTraits<RealScalar>::epsilon(); }
   EIGEN_DEVICE_FUNC
   static inline RealScalar dummy_precision() { return NumTraits<RealScalar>::dummy_precision(); }

   static inline int digits10() { return NumTraits<Scalar>::digits10(); }
 };

 template<> struct NumTraits<std::string>
   : GenericNumTraits<std::string>
 {
   enum {
     RequireInitialization = 1,
     ReadCost = HugeCost,
     AddCost  = HugeCost,
     MulCost  = HugeCost
   };

   static inline int digits10() { return 0; }

 private:
   static inline std::string epsilon();
   static inline std::string dummy_precision();
   static inline std::string lowest();
   static inline std::string highest();
   static inline std::string infinity();
   static inline std::string quiet_NaN();
 };

 // Empty specialization for void to allow template specialization based on NumTraits<T>::Real with T==void and SFINAE.
 template<> struct NumTraits<void> {};

 } // end namespace Eigen

 #endif // EIGEN_NUMTRAITS_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2006-2010 Benoit Jacob <jacob.benoit.1@gmail.com>
	//
	// 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/.

	#ifndef EIGEN_NUMTRAITS_H
	#define EIGEN_NUMTRAITS_H

	namespace Eigen {

	namespace internal {

	// default implementation of digits10(), based on numeric_limits if specialized,
	// 0 for integer types, and log10(epsilon()) otherwise.
	template< typename T,
	bool use_numeric_limits = std::numeric_limits<T>::is_specialized,
	bool is_integer = NumTraits<T>::IsInteger>
	struct default_digits10_impl
	{
	EIGEN_DEVICE_FUNC
	static int run() { return std::numeric_limits<T>::digits10; }
	};

	template<typename T>
	struct default_digits10_impl<T,false,false> // Floating point
	{
	EIGEN_DEVICE_FUNC
	static int run() {
	using std::log10;
	using std::ceil;
	typedef typename NumTraits<T>::Real Real;
	return int(ceil(-log10(NumTraits<Real>::epsilon())));
	}
	};

	template<typename T>
	struct default_digits10_impl<T,false,true> // Integer
	{
	EIGEN_DEVICE_FUNC
	static int run() { return 0; }
	};


	// default implementation of digits(), based on numeric_limits if specialized,
	// 0 for integer types, and log2(epsilon()) otherwise.
	template< typename T,
	bool use_numeric_limits = std::numeric_limits<T>::is_specialized,
	bool is_integer = NumTraits<T>::IsInteger>
	struct default_digits_impl
	{
	EIGEN_DEVICE_FUNC
	static int run() { return std::numeric_limits<T>::digits; }
	};

	template<typename T>
	struct default_digits_impl<T,false,false> // Floating point
	{
	EIGEN_DEVICE_FUNC
	static int run() {
	using std::log;
	using std::ceil;
	typedef typename NumTraits<T>::Real Real;
	return int(ceil(-log(NumTraits<Real>::epsilon())/log(static_cast<Real>(2))));
	}
	};

	template<typename T>
	struct default_digits_impl<T,false,true> // Integer
	{
	EIGEN_DEVICE_FUNC
	static int run() { return 0; }
	};

	} // end namespace internal

	/** \class NumTraits
	* \ingroup Core_Module
	*
	* \brief Holds information about the various numeric (i.e. scalar) types allowed by Eigen.
	*
	* \tparam T the numeric type at hand
	*
	* This class stores enums, typedefs and static methods giving information about a numeric type.
	*
	* The provided data consists of:
	* \li A typedef \c Real, giving the "real part" type of \a T. If \a T is already real,
	* then \c Real is just a typedef to \a T. If \a T is \c std::complex<U> then \c Real
	* is a typedef to \a U.
	* \li A typedef \c NonInteger, giving the type that should be used for operations producing non-integral values,
	* such as quotients, square roots, etc. If \a T is a floating-point type, then this typedef just gives
	* \a T again. Note however that many Eigen functions such as internal::sqrt simply refuse to
	* take integers. Outside of a few cases, Eigen doesn't do automatic type promotion. Thus, this typedef is
	* only intended as a helper for code that needs to explicitly promote types.
	* \li A typedef \c Literal giving the type to use for numeric literals such as "2" or "0.5". For instance, for \c std::complex<U>, Literal is defined as \c U.
	* Of course, this type must be fully compatible with \a T. In doubt, just use \a T here.
	* \li A typedef \a Nested giving the type to use to nest a value inside of the expression tree. If you don't know what
	* this means, just use \a T here.
	* \li An enum value \a IsComplex. It is equal to 1 if \a T is a \c std::complex
	* type, and to 0 otherwise.
	* \li An enum value \a IsInteger. It is equal to \c 1 if \a T is an integer type such as \c int,
	* and to \c 0 otherwise.
	* \li Enum values ReadCost, AddCost and MulCost representing a rough estimate of the number of CPU cycles needed
	* to by move / add / mul instructions respectively, assuming the data is already stored in CPU registers.
	* Stay vague here. No need to do architecture-specific stuff. If you don't know what this means, just use \c Eigen::HugeCost.
	* \li An enum value \a IsSigned. It is equal to \c 1 if \a T is a signed type and to 0 if \a T is unsigned.
	* \li An enum value \a RequireInitialization. It is equal to \c 1 if the constructor of the numeric type \a T must
	* be called, and to 0 if it is safe not to call it. Default is 0 if \a T is an arithmetic type, and 1 otherwise.
	* \li An epsilon() function which, unlike <a href="http://en.cppreference.com/w/cpp/types/numeric_limits/epsilon">std::numeric_limits::epsilon()</a>,
	* it returns a \a Real instead of a \a T.
	* \li A dummy_precision() function returning a weak epsilon value. It is mainly used as a default
	* value by the fuzzy comparison operators.
	* \li highest() and lowest() functions returning the highest and lowest possible values respectively.
	* \li digits10() function returning the number of decimal digits that can be represented without change. This is
	* the analogue of <a href="http://en.cppreference.com/w/cpp/types/numeric_limits/digits10">std::numeric_limits<T>::digits10</a>
	* which is used as the default implementation if specialized.
	*/

	template<typename T> struct GenericNumTraits
	{
	enum {
	IsInteger = std::numeric_limits<T>::is_integer,
	IsSigned = std::numeric_limits<T>::is_signed,
	IsComplex = 0,
	RequireInitialization = internal::is_arithmetic<T>::value ? 0 : 1,
	ReadCost = 1,
	AddCost = 1,
	MulCost = 1
	};

	typedef T Real;
	typedef typename internal::conditional<
	IsInteger,
	typename internal::conditional<sizeof(T)<=2, float, double>::type,
	T
	>::type NonInteger;
	typedef T Nested;
	typedef T Literal;

	EIGEN_DEVICE_FUNC
	static inline Real epsilon()
	{
	return numext::numeric_limits<T>::epsilon();
	}

	EIGEN_DEVICE_FUNC
	static inline int digits10()
	{
	return internal::default_digits10_impl<T>::run();
	}

	EIGEN_DEVICE_FUNC
	static inline int digits()
	{
	return internal::default_digits_impl<T>::run();
	}

	EIGEN_DEVICE_FUNC
	static inline Real dummy_precision()
	{
	// make sure to override this for floating-point types
	return Real(0);
	}


	EIGEN_DEVICE_FUNC
	static inline T highest() {
	return (numext::numeric_limits<T>::max)();
	}

	EIGEN_DEVICE_FUNC
	static inline T lowest() {
	return IsInteger ? (numext::numeric_limits<T>::min)()
	: static_cast<T>(-(numext::numeric_limits<T>::max)());
	}

	EIGEN_DEVICE_FUNC
	static inline T infinity() {
	return numext::numeric_limits<T>::infinity();
	}

	EIGEN_DEVICE_FUNC
	static inline T quiet_NaN() {
	return numext::numeric_limits<T>::quiet_NaN();
	}
	};

	template<typename T> struct NumTraits : GenericNumTraits<T>
	{};

	template<> struct NumTraits<float>
	: GenericNumTraits<float>
	{
	EIGEN_DEVICE_FUNC
	static inline float dummy_precision() { return 1e-5f; }
	};

	template<> struct NumTraits<double> : GenericNumTraits<double>
	{
	EIGEN_DEVICE_FUNC
	static inline double dummy_precision() { return 1e-12; }
	};

	template<> struct NumTraits<long double>
	: GenericNumTraits<long double>
	{
	static inline long double dummy_precision() { return 1e-15l; }
	};

	template<typename _Real> struct NumTraits<std::complex<_Real> >
	: GenericNumTraits<std::complex<_Real> >
	{
	typedef _Real Real;
	typedef typename NumTraits<_Real>::Literal Literal;
	enum {
	IsComplex = 1,
	RequireInitialization = NumTraits<_Real>::RequireInitialization,
	ReadCost = 2 * NumTraits<_Real>::ReadCost,
	AddCost = 2 * NumTraits<Real>::AddCost,
	MulCost = 4 * NumTraits<Real>::MulCost + 2 * NumTraits<Real>::AddCost
	};

	EIGEN_DEVICE_FUNC
	static inline Real epsilon() { return NumTraits<Real>::epsilon(); }
	EIGEN_DEVICE_FUNC
	static inline Real dummy_precision() { return NumTraits<Real>::dummy_precision(); }
	EIGEN_DEVICE_FUNC
	static inline int digits10() { return NumTraits<Real>::digits10(); }
	};

	template<typename Scalar, int Rows, int Cols, int Options, int MaxRows, int MaxCols>
	struct NumTraits<Array<Scalar, Rows, Cols, Options, MaxRows, MaxCols> >
	{
	typedef Array<Scalar, Rows, Cols, Options, MaxRows, MaxCols> ArrayType;
	typedef typename NumTraits<Scalar>::Real RealScalar;
	typedef Array<RealScalar, Rows, Cols, Options, MaxRows, MaxCols> Real;
	typedef typename NumTraits<Scalar>::NonInteger NonIntegerScalar;
	typedef Array<NonIntegerScalar, Rows, Cols, Options, MaxRows, MaxCols> NonInteger;
	typedef ArrayType & Nested;
	typedef typename NumTraits<Scalar>::Literal Literal;

	enum {
	IsComplex = NumTraits<Scalar>::IsComplex,
	IsInteger = NumTraits<Scalar>::IsInteger,
	IsSigned = NumTraits<Scalar>::IsSigned,
	RequireInitialization = 1,
	ReadCost = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::ReadCost,
	AddCost = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::AddCost,
	MulCost = ArrayType::SizeAtCompileTime==Dynamic ? HugeCost : ArrayType::SizeAtCompileTime * NumTraits<Scalar>::MulCost
	};

	EIGEN_DEVICE_FUNC
	static inline RealScalar epsilon() { return NumTraits<RealScalar>::epsilon(); }
	EIGEN_DEVICE_FUNC
	static inline RealScalar dummy_precision() { return NumTraits<RealScalar>::dummy_precision(); }

	static inline int digits10() { return NumTraits<Scalar>::digits10(); }
	};

	template<> struct NumTraits<std::string>
	: GenericNumTraits<std::string>
	{
	enum {
	RequireInitialization = 1,
	ReadCost = HugeCost,
	AddCost = HugeCost,
	MulCost = HugeCost
	};

	static inline int digits10() { return 0; }

	private:
	static inline std::string epsilon();
	static inline std::string dummy_precision();
	static inline std::string lowest();
	static inline std::string highest();
	static inline std::string infinity();
	static inline std::string quiet_NaN();
	};

	// Empty specialization for void to allow template specialization based on NumTraits<T>::Real with T==void and SFINAE.
	template<> struct NumTraits<void> {};

	} // end namespace Eigen

	#endif // EIGEN_NUMTRAITS_H