boost/boost/random/lagged_fibonacci.hpp - nest-cam/4320010/boost - Git at Google

 /* boost random/lagged_fibonacci.hpp header file
  *
  * Copyright Jens Maurer 2000-2001
  * Distributed under the Boost Software License, Version 1.0. (See
  * accompanying file LICENSE_1_0.txt or copy at
  * http://www.boost.org/LICENSE_1_0.txt)
  *
  * See http://www.boost.org for most recent version including documentation.
  *
  * $Id$
  *
  * Revision history
  *  2013-10-14  fixed some warnings with Wshadow (mgaunard)
  *  2001-02-18  moved to individual header files
  */

 #ifndef BOOST_RANDOM_LAGGED_FIBONACCI_HPP
 #define BOOST_RANDOM_LAGGED_FIBONACCI_HPP

 #include <istream>
 #include <iosfwd>
 #include <algorithm>     // std::max
 #include <iterator>
 #include <boost/config/no_tr1/cmath.hpp>         // std::pow
 #include <boost/config.hpp>
 #include <boost/limits.hpp>
 #include <boost/cstdint.hpp>
 #include <boost/integer/integer_mask.hpp>
 #include <boost/random/linear_congruential.hpp>
 #include <boost/random/uniform_01.hpp>
 #include <boost/random/detail/config.hpp>
 #include <boost/random/detail/seed.hpp>
 #include <boost/random/detail/operators.hpp>
 #include <boost/random/detail/generator_seed_seq.hpp>

 namespace boost {
 namespace random {

 /**
  * Instantiations of class template \lagged_fibonacci_engine model a
  * \pseudo_random_number_generator. It uses a lagged Fibonacci
  * algorithm with two lags @c p and @c q:
  * x(i) = x(i-p) + x(i-q) (mod 2<sup>w</sup>) with p > q.
  */
 template<class UIntType, int w, unsigned int p, unsigned int q>
 class lagged_fibonacci_engine
 {
 public:
     typedef UIntType result_type;
     BOOST_STATIC_CONSTANT(bool, has_fixed_range = false);
     BOOST_STATIC_CONSTANT(int, word_size = w);
     BOOST_STATIC_CONSTANT(unsigned int, long_lag = p);
     BOOST_STATIC_CONSTANT(unsigned int, short_lag = q);

     BOOST_STATIC_CONSTANT(UIntType, default_seed = 331u);

     /** Returns the smallest value that the generator can produce. */
     static result_type min BOOST_PREVENT_MACRO_SUBSTITUTION () { return 0; }
     /** Returns the largest value that the generator can produce. */
     static result_type max BOOST_PREVENT_MACRO_SUBSTITUTION ()
     { return low_bits_mask_t<w>::sig_bits; }

     /** Creates a new @c lagged_fibonacci_engine and calls @c seed(). */
     lagged_fibonacci_engine() { seed(); }

     /** Creates a new @c lagged_fibonacci_engine and calls @c seed(value). */
     BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_engine,
         UIntType, value)
     { seed(value); }

     /** Creates a new @c lagged_fibonacci_engine and calls @c seed(seq). */
     BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_engine,
         SeedSeq, seq)
     { seed(seq); }

     /**
      * Creates a new @c lagged_fibonacci_engine and calls @c seed(first, last).
      */
     template<class It> lagged_fibonacci_engine(It& first, It last)
     { seed(first, last); }

     // compiler-generated copy ctor and assignment operator are fine

     /** Calls @c seed(default_seed). */
     void seed() { seed(default_seed); }

     /**
      * Sets the state of the generator to values produced by
      * a \minstd_rand0 generator.
      */
     BOOST_RANDOM_DETAIL_ARITHMETIC_SEED(lagged_fibonacci_engine,
         UIntType, value)
     {
         minstd_rand0 intgen(static_cast<boost::uint32_t>(value));
         detail::generator_seed_seq<minstd_rand0> gen(intgen);
         seed(gen);
     }

     /**
      * Sets the state of the generator using values produced by seq.
      */
     BOOST_RANDOM_DETAIL_SEED_SEQ_SEED(lagged_fibonacci_engine, SeedSeq, seq)
     {
         detail::seed_array_int<w>(seq, x);
         i = long_lag;
     }

     /**
      * Sets the state of the generator to values from the iterator
      * range [first, last).  If there are not enough elements in the
      * range [first, last) throws @c std::invalid_argument.
      */
     template<class It>
     void seed(It& first, It last)
     {
         detail::fill_array_int<w>(first, last, x);
         i = long_lag;
     }

     /** Returns the next value of the generator. */
     result_type operator()()
     {
         if(i >= long_lag)
             fill();
         return x[i++];
     }

     /** Fills a range with random values */
     template<class Iter>
     void generate(Iter first, Iter last)
     { detail::generate_from_int(*this, first, last); }

     /** Advances the state of the generator by @c z. */
     void discard(boost::uintmax_t z)
     {
         for(boost::uintmax_t j = 0; j < z; ++j) {
             (*this)();
         }
     }

     /**
      * Writes the textual representation of the generator to a @c std::ostream.
      */
     BOOST_RANDOM_DETAIL_OSTREAM_OPERATOR(os, lagged_fibonacci_engine, f)
     {
         os << f.i;
         for(unsigned int j = 0; j < f.long_lag; ++j)
             os << ' ' << f.x[j];
         return os;
     }

     /**
      * Reads the textual representation of the generator from a @c std::istream.
      */
     BOOST_RANDOM_DETAIL_ISTREAM_OPERATOR(is, lagged_fibonacci_engine, f)
     {
         is >> f.i >> std::ws;
         for(unsigned int j = 0; j < f.long_lag; ++j)
             is >> f.x[j] >> std::ws;
         return is;
     }

     /**
      * Returns true if the two generators will produce identical
      * sequences of outputs.
      */
     BOOST_RANDOM_DETAIL_EQUALITY_OPERATOR(lagged_fibonacci_engine, x_, y_)
     { return x_.i == y_.i && std::equal(x_.x, x_.x+long_lag, y_.x); }

     /**
      * Returns true if the two generators will produce different
      * sequences of outputs.
      */
     BOOST_RANDOM_DETAIL_INEQUALITY_OPERATOR(lagged_fibonacci_engine)

 private:
     /// \cond show_private
     void fill();
     /// \endcond

     unsigned int i;
     UIntType x[long_lag];
 };

 #ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
 //  A definition is required even for integral static constants
 template<class UIntType, int w, unsigned int p, unsigned int q>
 const bool lagged_fibonacci_engine<UIntType, w, p, q>::has_fixed_range;
 template<class UIntType, int w, unsigned int p, unsigned int q>
 const unsigned int lagged_fibonacci_engine<UIntType, w, p, q>::long_lag;
 template<class UIntType, int w, unsigned int p, unsigned int q>
 const unsigned int lagged_fibonacci_engine<UIntType, w, p, q>::short_lag;
 template<class UIntType, int w, unsigned int p, unsigned int q>
 const UIntType lagged_fibonacci_engine<UIntType, w, p, q>::default_seed;
 #endif

 /// \cond show_private

 template<class UIntType, int w, unsigned int p, unsigned int q>
 void lagged_fibonacci_engine<UIntType, w, p, q>::fill()
 {
     // two loops to avoid costly modulo operations
     {  // extra scope for MSVC brokenness w.r.t. for scope
     for(unsigned int j = 0; j < short_lag; ++j)
         x[j] = (x[j] + x[j+(long_lag-short_lag)]) & low_bits_mask_t<w>::sig_bits;
     }
     for(unsigned int j = short_lag; j < long_lag; ++j)
         x[j] = (x[j] + x[j-short_lag]) & low_bits_mask_t<w>::sig_bits;
     i = 0;
 }

 /// \endcond

 /// \cond show_deprecated

 // provided for backwards compatibility
 template<class UIntType, int w, unsigned int p, unsigned int q, UIntType v = 0>
 class lagged_fibonacci : public lagged_fibonacci_engine<UIntType, w, p, q>
 {
     typedef lagged_fibonacci_engine<UIntType, w, p, q> base_type;
 public:
     lagged_fibonacci() {}
     BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci, UIntType, val)
     { this->seed(val); }
     BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci, SeedSeq, seq)
     { this->seed(seq); }
     template<class It>
     lagged_fibonacci(It& first, It last) : base_type(first, last) {}
 };

 /// \endcond

 // lagged Fibonacci generator for the range [0..1)
 // contributed by Matthias Troyer
 // for p=55, q=24 originally by G. J. Mitchell and D. P. Moore 1958

 /**
  * Instantiations of class template @c lagged_fibonacci_01 model a
  * \pseudo_random_number_generator. It uses a lagged Fibonacci
  * algorithm with two lags @c p and @c q, evaluated in floating-point
  * arithmetic: x(i) = x(i-p) + x(i-q) (mod 1) with p > q. See
  *
  *  @blockquote
  *  "Uniform random number generators for supercomputers", Richard Brent,
  *  Proc. of Fifth Australian Supercomputer Conference, Melbourne,
  *  Dec. 1992, pp. 704-706.
  *  @endblockquote
  *
  * @xmlnote
  * The quality of the generator crucially depends on the choice
  * of the parameters. User code should employ one of the sensibly
  * parameterized generators such as \lagged_fibonacci607 instead.
  * @endxmlnote
  *
  * The generator requires considerable amounts of memory for the storage
  * of its state array. For example, \lagged_fibonacci607 requires about
  * 4856 bytes and \lagged_fibonacci44497 requires about 350 KBytes.
  */
 template<class RealType, int w, unsigned int p, unsigned int q>
 class lagged_fibonacci_01_engine
 {
 public:
     typedef RealType result_type;
     BOOST_STATIC_CONSTANT(bool, has_fixed_range = false);
     BOOST_STATIC_CONSTANT(int, word_size = w);
     BOOST_STATIC_CONSTANT(unsigned int, long_lag = p);
     BOOST_STATIC_CONSTANT(unsigned int, short_lag = q);

     BOOST_STATIC_CONSTANT(boost::uint32_t, default_seed = 331u);

     /** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(). */
     lagged_fibonacci_01_engine() { seed(); }
     /** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(value). */
     BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_01_engine, uint32_t, value)
     { seed(value); }
     /** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(gen). */
     BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_01_engine, SeedSeq, seq)
     { seed(seq); }
     template<class It> lagged_fibonacci_01_engine(It& first, It last)
     { seed(first, last); }

     // compiler-generated copy ctor and assignment operator are fine

     /** Calls seed(default_seed). */
     void seed() { seed(default_seed); }

     /**
      * Constructs a \minstd_rand0 generator with the constructor parameter
      * value and calls seed with it. Distinct seeds in the range
      * [1, 2147483647) will produce generators with different states. Other
      * seeds will be equivalent to some seed within this range. See
      * \linear_congruential_engine for details.
      */
     BOOST_RANDOM_DETAIL_ARITHMETIC_SEED(lagged_fibonacci_01_engine, boost::uint32_t, value)
     {
         minstd_rand0 intgen(value);
         detail::generator_seed_seq<minstd_rand0> gen(intgen);
         seed(gen);
     }

     /**
      * Seeds this @c lagged_fibonacci_01_engine using values produced by
      * @c seq.generate.
      */
     BOOST_RANDOM_DETAIL_SEED_SEQ_SEED(lagged_fibonacci_01_engine, SeedSeq, seq)
     {
         detail::seed_array_real<w>(seq, x);
         i = long_lag;
     }

     /**
      * Seeds this @c lagged_fibonacci_01_engine using values from the
      * iterator range [first, last).  If there are not enough elements
      * in the range, throws @c std::invalid_argument.
      */
     template<class It>
     void seed(It& first, It last)
     {
         detail::fill_array_real<w>(first, last, x);
         i = long_lag;
     }

     /** Returns the smallest value that the generator can produce. */
     static result_type min BOOST_PREVENT_MACRO_SUBSTITUTION () { return result_type(0); }
     /** Returns the upper bound of the generators outputs. */
     static result_type max BOOST_PREVENT_MACRO_SUBSTITUTION () { return result_type(1); }

     /** Returns the next value of the generator. */
     result_type operator()()
     {
         if(i >= long_lag)
             fill();
         return x[i++];
     }

     /** Fills a range with random values */
     template<class Iter>
     void generate(Iter first, Iter last)
     { return detail::generate_from_real(*this, first, last); }

     /** Advances the state of the generator by @c z. */
     void discard(boost::uintmax_t z)
     {
         for(boost::uintmax_t j = 0; j < z; ++j) {
             (*this)();
         }
     }

     /**
      * Writes the textual representation of the generator to a @c std::ostream.
      */
     BOOST_RANDOM_DETAIL_OSTREAM_OPERATOR(os, lagged_fibonacci_01_engine, f)
     {
         // allow for Koenig lookup
         using std::pow;
         os << f.i;
         std::ios_base::fmtflags oldflags = os.flags(os.dec | os.fixed | os.left);
         for(unsigned int j = 0; j < f.long_lag; ++j)
             os << ' ' << f.x[j] * f.modulus();
         os.flags(oldflags);
         return os;
     }

     /**
      * Reads the textual representation of the generator from a @c std::istream.
      */
     BOOST_RANDOM_DETAIL_ISTREAM_OPERATOR(is, lagged_fibonacci_01_engine, f)
     {
         is >> f.i;
         for(unsigned int j = 0; j < f.long_lag; ++j) {
             typename lagged_fibonacci_01_engine::result_type value;
             is >> std::ws >> value;
             f.x[j] = value / f.modulus();
         }
         return is;
     }

     /**
      * Returns true if the two generators will produce identical
      * sequences of outputs.
      */
     BOOST_RANDOM_DETAIL_EQUALITY_OPERATOR(lagged_fibonacci_01_engine, x_, y_)
     { return x_.i == y_.i && std::equal(x_.x, x_.x+long_lag, y_.x); }

     /**
      * Returns true if the two generators will produce different
      * sequences of outputs.
      */
     BOOST_RANDOM_DETAIL_INEQUALITY_OPERATOR(lagged_fibonacci_01_engine)

 private:
     /// \cond show_private
     void fill();
     static RealType modulus()
     {
         using std::pow;
         return pow(RealType(2), word_size);
     }
     /// \endcond
     unsigned int i;
     RealType x[long_lag];
 };

 #ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
 //  A definition is required even for integral static constants
 template<class RealType, int w, unsigned int p, unsigned int q>
 const bool lagged_fibonacci_01_engine<RealType, w, p, q>::has_fixed_range;
 template<class RealType, int w, unsigned int p, unsigned int q>
 const unsigned int lagged_fibonacci_01_engine<RealType, w, p, q>::long_lag;
 template<class RealType, int w, unsigned int p, unsigned int q>
 const unsigned int lagged_fibonacci_01_engine<RealType, w, p, q>::short_lag;
 template<class RealType, int w, unsigned int p, unsigned int q>
 const int lagged_fibonacci_01_engine<RealType,w,p,q>::word_size;
 template<class RealType, int w, unsigned int p, unsigned int q>
 const boost::uint32_t lagged_fibonacci_01_engine<RealType,w,p,q>::default_seed;
 #endif

 /// \cond show_private
 template<class RealType, int w, unsigned int p, unsigned int q>
 void lagged_fibonacci_01_engine<RealType, w, p, q>::fill()
 {
     // two loops to avoid costly modulo operations
     {  // extra scope for MSVC brokenness w.r.t. for scope
     for(unsigned int j = 0; j < short_lag; ++j) {
         RealType t = x[j] + x[j+(long_lag-short_lag)];
         if(t >= RealType(1))
             t -= RealType(1);
         x[j] = t;
     }
     }
     for(unsigned int j = short_lag; j < long_lag; ++j) {
         RealType t = x[j] + x[j-short_lag];
         if(t >= RealType(1))
             t -= RealType(1);
         x[j] = t;
     }
     i = 0;
 }
 /// \endcond

 /// \cond show_deprecated

 // provided for backwards compatibility
 template<class RealType, int w, unsigned int p, unsigned int q>
 class lagged_fibonacci_01 : public lagged_fibonacci_01_engine<RealType, w, p, q>
 {
     typedef lagged_fibonacci_01_engine<RealType, w, p, q> base_type;
 public:
     lagged_fibonacci_01() {}
     BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_01, boost::uint32_t, val)
     { this->seed(val); }
     BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_01, SeedSeq, seq)
     { this->seed(seq); }
     template<class It>
     lagged_fibonacci_01(It& first, It last) : base_type(first, last) {}
 };

 /// \endcond

 namespace detail {

 template<class Engine>
 struct generator_bits;

 template<class RealType, int w, unsigned int p, unsigned int q>
 struct generator_bits<lagged_fibonacci_01_engine<RealType, w, p, q> >
 {
     static std::size_t value() { return w; }
 };

 template<class RealType, int w, unsigned int p, unsigned int q>
 struct generator_bits<lagged_fibonacci_01<RealType, w, p, q> >
 {
     static std::size_t value() { return w; }
 };

 }

 #ifdef BOOST_RANDOM_DOXYGEN
 namespace detail {
 /**
  * The specializations lagged_fibonacci607 ... lagged_fibonacci44497
  * use well tested lags.
  *
  * See
  *
  *  @blockquote
  *  "On the Periods of Generalized Fibonacci Recurrences", Richard P. Brent
  *  Computer Sciences Laboratory Australian National University, December 1992
  *  @endblockquote
  *
  * The lags used here can be found in
  *
  *  @blockquote
  *  "Uniform random number generators for supercomputers", Richard Brent,
  *  Proc. of Fifth Australian Supercomputer Conference, Melbourne,
  *  Dec. 1992, pp. 704-706.
  *  @endblockquote
  */
 struct lagged_fibonacci_doc {};
 }
 #endif

 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 607, 273> lagged_fibonacci607;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 1279, 418> lagged_fibonacci1279;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 2281, 1252> lagged_fibonacci2281;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 3217, 576> lagged_fibonacci3217;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 4423, 2098> lagged_fibonacci4423;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 9689, 5502> lagged_fibonacci9689;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 19937, 9842> lagged_fibonacci19937;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 23209, 13470> lagged_fibonacci23209;
 /** @copydoc boost::random::detail::lagged_fibonacci_doc */
 typedef lagged_fibonacci_01_engine<double, 48, 44497, 21034> lagged_fibonacci44497;

 } // namespace random

 using random::lagged_fibonacci607;
 using random::lagged_fibonacci1279;
 using random::lagged_fibonacci2281;
 using random::lagged_fibonacci3217;
 using random::lagged_fibonacci4423;
 using random::lagged_fibonacci9689;
 using random::lagged_fibonacci19937;
 using random::lagged_fibonacci23209;
 using random::lagged_fibonacci44497;

 } // namespace boost

 #endif // BOOST_RANDOM_LAGGED_FIBONACCI_HPP
	/* boost random/lagged_fibonacci.hpp header file
	*
	* Copyright Jens Maurer 2000-2001
	* Distributed under the Boost Software License, Version 1.0. (See
	* accompanying file LICENSE_1_0.txt or copy at
	* http://www.boost.org/LICENSE_1_0.txt)
	*
	* See http://www.boost.org for most recent version including documentation.
	*
	* $Id$
	*
	* Revision history
	* 2013-10-14 fixed some warnings with Wshadow (mgaunard)
	* 2001-02-18 moved to individual header files
	*/

	#ifndef BOOST_RANDOM_LAGGED_FIBONACCI_HPP
	#define BOOST_RANDOM_LAGGED_FIBONACCI_HPP

	#include <istream>
	#include <iosfwd>
	#include <algorithm> // std::max
	#include <iterator>
	#include <boost/config/no_tr1/cmath.hpp> // std::pow
	#include <boost/config.hpp>
	#include <boost/limits.hpp>
	#include <boost/cstdint.hpp>
	#include <boost/integer/integer_mask.hpp>
	#include <boost/random/linear_congruential.hpp>
	#include <boost/random/uniform_01.hpp>
	#include <boost/random/detail/config.hpp>
	#include <boost/random/detail/seed.hpp>
	#include <boost/random/detail/operators.hpp>
	#include <boost/random/detail/generator_seed_seq.hpp>

	namespace boost {
	namespace random {

	/**
	* Instantiations of class template \lagged_fibonacci_engine model a
	* \pseudo_random_number_generator. It uses a lagged Fibonacci
	* algorithm with two lags @c p and @c q:
	* x(i) = x(i-p) + x(i-q) (mod 2<sup>w</sup>) with p > q.
	*/
	template<class UIntType, int w, unsigned int p, unsigned int q>
	class lagged_fibonacci_engine
	{
	public:
	typedef UIntType result_type;
	BOOST_STATIC_CONSTANT(bool, has_fixed_range = false);
	BOOST_STATIC_CONSTANT(int, word_size = w);
	BOOST_STATIC_CONSTANT(unsigned int, long_lag = p);
	BOOST_STATIC_CONSTANT(unsigned int, short_lag = q);

	BOOST_STATIC_CONSTANT(UIntType, default_seed = 331u);

	/** Returns the smallest value that the generator can produce. */
	static result_type min BOOST_PREVENT_MACRO_SUBSTITUTION () { return 0; }
	/** Returns the largest value that the generator can produce. */
	static result_type max BOOST_PREVENT_MACRO_SUBSTITUTION ()
	{ return low_bits_mask_t<w>::sig_bits; }

	/** Creates a new @c lagged_fibonacci_engine and calls @c seed(). */
	lagged_fibonacci_engine() { seed(); }

	/** Creates a new @c lagged_fibonacci_engine and calls @c seed(value). */
	BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_engine,
	UIntType, value)
	{ seed(value); }

	/** Creates a new @c lagged_fibonacci_engine and calls @c seed(seq). */
	BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_engine,
	SeedSeq, seq)
	{ seed(seq); }

	/**
	* Creates a new @c lagged_fibonacci_engine and calls @c seed(first, last).
	*/
	template<class It> lagged_fibonacci_engine(It& first, It last)
	{ seed(first, last); }

	// compiler-generated copy ctor and assignment operator are fine

	/** Calls @c seed(default_seed). */
	void seed() { seed(default_seed); }

	/**
	* Sets the state of the generator to values produced by
	* a \minstd_rand0 generator.
	*/
	BOOST_RANDOM_DETAIL_ARITHMETIC_SEED(lagged_fibonacci_engine,
	UIntType, value)
	{
	minstd_rand0 intgen(static_cast<boost::uint32_t>(value));
	detail::generator_seed_seq<minstd_rand0> gen(intgen);
	seed(gen);
	}

	/**
	* Sets the state of the generator using values produced by seq.
	*/
	BOOST_RANDOM_DETAIL_SEED_SEQ_SEED(lagged_fibonacci_engine, SeedSeq, seq)
	{
	detail::seed_array_int<w>(seq, x);
	i = long_lag;
	}

	/**
	* Sets the state of the generator to values from the iterator
	* range [first, last). If there are not enough elements in the
	* range [first, last) throws @c std::invalid_argument.
	*/
	template<class It>
	void seed(It& first, It last)
	{
	detail::fill_array_int<w>(first, last, x);
	i = long_lag;
	}

	/** Returns the next value of the generator. */
	result_type operator()()
	{
	if(i >= long_lag)
	fill();
	return x[i++];
	}

	/** Fills a range with random values */
	template<class Iter>
	void generate(Iter first, Iter last)
	{ detail::generate_from_int(*this, first, last); }

	/** Advances the state of the generator by @c z. */
	void discard(boost::uintmax_t z)
	{
	for(boost::uintmax_t j = 0; j < z; ++j) {
	(*this)();
	}
	}

	/**
	* Writes the textual representation of the generator to a @c std::ostream.
	*/
	BOOST_RANDOM_DETAIL_OSTREAM_OPERATOR(os, lagged_fibonacci_engine, f)
	{
	os << f.i;
	for(unsigned int j = 0; j < f.long_lag; ++j)
	os << ' ' << f.x[j];
	return os;
	}

	/**
	* Reads the textual representation of the generator from a @c std::istream.
	*/
	BOOST_RANDOM_DETAIL_ISTREAM_OPERATOR(is, lagged_fibonacci_engine, f)
	{
	is >> f.i >> std::ws;
	for(unsigned int j = 0; j < f.long_lag; ++j)
	is >> f.x[j] >> std::ws;
	return is;
	}

	/**
	* Returns true if the two generators will produce identical
	* sequences of outputs.
	*/
	BOOST_RANDOM_DETAIL_EQUALITY_OPERATOR(lagged_fibonacci_engine, x_, y_)
	{ return x_.i == y_.i && std::equal(x_.x, x_.x+long_lag, y_.x); }

	/**
	* Returns true if the two generators will produce different
	* sequences of outputs.
	*/
	BOOST_RANDOM_DETAIL_INEQUALITY_OPERATOR(lagged_fibonacci_engine)

	private:
	/// \cond show_private
	void fill();
	/// \endcond

	unsigned int i;
	UIntType x[long_lag];
	};

	#ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
	// A definition is required even for integral static constants
	template<class UIntType, int w, unsigned int p, unsigned int q>
	const bool lagged_fibonacci_engine<UIntType, w, p, q>::has_fixed_range;
	template<class UIntType, int w, unsigned int p, unsigned int q>
	const unsigned int lagged_fibonacci_engine<UIntType, w, p, q>::long_lag;
	template<class UIntType, int w, unsigned int p, unsigned int q>
	const unsigned int lagged_fibonacci_engine<UIntType, w, p, q>::short_lag;
	template<class UIntType, int w, unsigned int p, unsigned int q>
	const UIntType lagged_fibonacci_engine<UIntType, w, p, q>::default_seed;
	#endif

	/// \cond show_private

	template<class UIntType, int w, unsigned int p, unsigned int q>
	void lagged_fibonacci_engine<UIntType, w, p, q>::fill()
	{
	// two loops to avoid costly modulo operations
	{ // extra scope for MSVC brokenness w.r.t. for scope
	for(unsigned int j = 0; j < short_lag; ++j)
	x[j] = (x[j] + x[j+(long_lag-short_lag)]) & low_bits_mask_t<w>::sig_bits;
	}
	for(unsigned int j = short_lag; j < long_lag; ++j)
	x[j] = (x[j] + x[j-short_lag]) & low_bits_mask_t<w>::sig_bits;
	i = 0;
	}

	/// \endcond

	/// \cond show_deprecated

	// provided for backwards compatibility
	template<class UIntType, int w, unsigned int p, unsigned int q, UIntType v = 0>
	class lagged_fibonacci : public lagged_fibonacci_engine<UIntType, w, p, q>
	{
	typedef lagged_fibonacci_engine<UIntType, w, p, q> base_type;
	public:
	lagged_fibonacci() {}
	BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci, UIntType, val)
	{ this->seed(val); }
	BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci, SeedSeq, seq)
	{ this->seed(seq); }
	template<class It>
	lagged_fibonacci(It& first, It last) : base_type(first, last) {}
	};

	/// \endcond

	// lagged Fibonacci generator for the range [0..1)
	// contributed by Matthias Troyer
	// for p=55, q=24 originally by G. J. Mitchell and D. P. Moore 1958

	/**
	* Instantiations of class template @c lagged_fibonacci_01 model a
	* \pseudo_random_number_generator. It uses a lagged Fibonacci
	* algorithm with two lags @c p and @c q, evaluated in floating-point
	* arithmetic: x(i) = x(i-p) + x(i-q) (mod 1) with p > q. See
	*
	* @blockquote
	* "Uniform random number generators for supercomputers", Richard Brent,
	* Proc. of Fifth Australian Supercomputer Conference, Melbourne,
	* Dec. 1992, pp. 704-706.
	* @endblockquote
	*
	* @xmlnote
	* The quality of the generator crucially depends on the choice
	* of the parameters. User code should employ one of the sensibly
	* parameterized generators such as \lagged_fibonacci607 instead.
	* @endxmlnote
	*
	* The generator requires considerable amounts of memory for the storage
	* of its state array. For example, \lagged_fibonacci607 requires about
	* 4856 bytes and \lagged_fibonacci44497 requires about 350 KBytes.
	*/
	template<class RealType, int w, unsigned int p, unsigned int q>
	class lagged_fibonacci_01_engine
	{
	public:
	typedef RealType result_type;
	BOOST_STATIC_CONSTANT(bool, has_fixed_range = false);
	BOOST_STATIC_CONSTANT(int, word_size = w);
	BOOST_STATIC_CONSTANT(unsigned int, long_lag = p);
	BOOST_STATIC_CONSTANT(unsigned int, short_lag = q);

	BOOST_STATIC_CONSTANT(boost::uint32_t, default_seed = 331u);

	/** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(). */
	lagged_fibonacci_01_engine() { seed(); }
	/** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(value). */
	BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_01_engine, uint32_t, value)
	{ seed(value); }
	/** Constructs a @c lagged_fibonacci_01 generator and calls @c seed(gen). */
	BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_01_engine, SeedSeq, seq)
	{ seed(seq); }
	template<class It> lagged_fibonacci_01_engine(It& first, It last)
	{ seed(first, last); }

	// compiler-generated copy ctor and assignment operator are fine

	/** Calls seed(default_seed). */
	void seed() { seed(default_seed); }

	/**
	* Constructs a \minstd_rand0 generator with the constructor parameter
	* value and calls seed with it. Distinct seeds in the range
	* [1, 2147483647) will produce generators with different states. Other
	* seeds will be equivalent to some seed within this range. See
	* \linear_congruential_engine for details.
	*/
	BOOST_RANDOM_DETAIL_ARITHMETIC_SEED(lagged_fibonacci_01_engine, boost::uint32_t, value)
	{
	minstd_rand0 intgen(value);
	detail::generator_seed_seq<minstd_rand0> gen(intgen);
	seed(gen);
	}

	/**
	* Seeds this @c lagged_fibonacci_01_engine using values produced by
	* @c seq.generate.
	*/
	BOOST_RANDOM_DETAIL_SEED_SEQ_SEED(lagged_fibonacci_01_engine, SeedSeq, seq)
	{
	detail::seed_array_real<w>(seq, x);
	i = long_lag;
	}

	/**
	* Seeds this @c lagged_fibonacci_01_engine using values from the
	* iterator range [first, last). If there are not enough elements
	* in the range, throws @c std::invalid_argument.
	*/
	template<class It>
	void seed(It& first, It last)
	{
	detail::fill_array_real<w>(first, last, x);
	i = long_lag;
	}

	/** Returns the smallest value that the generator can produce. */
	static result_type min BOOST_PREVENT_MACRO_SUBSTITUTION () { return result_type(0); }
	/** Returns the upper bound of the generators outputs. */
	static result_type max BOOST_PREVENT_MACRO_SUBSTITUTION () { return result_type(1); }

	/** Returns the next value of the generator. */
	result_type operator()()
	{
	if(i >= long_lag)
	fill();
	return x[i++];
	}

	/** Fills a range with random values */
	template<class Iter>
	void generate(Iter first, Iter last)
	{ return detail::generate_from_real(*this, first, last); }

	/** Advances the state of the generator by @c z. */
	void discard(boost::uintmax_t z)
	{
	for(boost::uintmax_t j = 0; j < z; ++j) {
	(*this)();
	}
	}

	/**
	* Writes the textual representation of the generator to a @c std::ostream.
	*/
	BOOST_RANDOM_DETAIL_OSTREAM_OPERATOR(os, lagged_fibonacci_01_engine, f)
	{
	// allow for Koenig lookup
	using std::pow;
	os << f.i;
	std::ios_base::fmtflags oldflags = os.flags(os.dec \| os.fixed \| os.left);
	for(unsigned int j = 0; j < f.long_lag; ++j)
	os << ' ' << f.x[j] * f.modulus();
	os.flags(oldflags);
	return os;
	}

	/**
	* Reads the textual representation of the generator from a @c std::istream.
	*/
	BOOST_RANDOM_DETAIL_ISTREAM_OPERATOR(is, lagged_fibonacci_01_engine, f)
	{
	is >> f.i;
	for(unsigned int j = 0; j < f.long_lag; ++j) {
	typename lagged_fibonacci_01_engine::result_type value;
	is >> std::ws >> value;
	f.x[j] = value / f.modulus();
	}
	return is;
	}

	/**
	* Returns true if the two generators will produce identical
	* sequences of outputs.
	*/
	BOOST_RANDOM_DETAIL_EQUALITY_OPERATOR(lagged_fibonacci_01_engine, x_, y_)
	{ return x_.i == y_.i && std::equal(x_.x, x_.x+long_lag, y_.x); }

	/**
	* Returns true if the two generators will produce different
	* sequences of outputs.
	*/
	BOOST_RANDOM_DETAIL_INEQUALITY_OPERATOR(lagged_fibonacci_01_engine)

	private:
	/// \cond show_private
	void fill();
	static RealType modulus()
	{
	using std::pow;
	return pow(RealType(2), word_size);
	}
	/// \endcond
	unsigned int i;
	RealType x[long_lag];
	};

	#ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
	// A definition is required even for integral static constants
	template<class RealType, int w, unsigned int p, unsigned int q>
	const bool lagged_fibonacci_01_engine<RealType, w, p, q>::has_fixed_range;
	template<class RealType, int w, unsigned int p, unsigned int q>
	const unsigned int lagged_fibonacci_01_engine<RealType, w, p, q>::long_lag;
	template<class RealType, int w, unsigned int p, unsigned int q>
	const unsigned int lagged_fibonacci_01_engine<RealType, w, p, q>::short_lag;
	template<class RealType, int w, unsigned int p, unsigned int q>
	const int lagged_fibonacci_01_engine<RealType,w,p,q>::word_size;
	template<class RealType, int w, unsigned int p, unsigned int q>
	const boost::uint32_t lagged_fibonacci_01_engine<RealType,w,p,q>::default_seed;
	#endif

	/// \cond show_private
	template<class RealType, int w, unsigned int p, unsigned int q>
	void lagged_fibonacci_01_engine<RealType, w, p, q>::fill()
	{
	// two loops to avoid costly modulo operations
	{ // extra scope for MSVC brokenness w.r.t. for scope
	for(unsigned int j = 0; j < short_lag; ++j) {
	RealType t = x[j] + x[j+(long_lag-short_lag)];
	if(t >= RealType(1))
	t -= RealType(1);
	x[j] = t;
	}
	}
	for(unsigned int j = short_lag; j < long_lag; ++j) {
	RealType t = x[j] + x[j-short_lag];
	if(t >= RealType(1))
	t -= RealType(1);
	x[j] = t;
	}
	i = 0;
	}
	/// \endcond

	/// \cond show_deprecated

	// provided for backwards compatibility
	template<class RealType, int w, unsigned int p, unsigned int q>
	class lagged_fibonacci_01 : public lagged_fibonacci_01_engine<RealType, w, p, q>
	{
	typedef lagged_fibonacci_01_engine<RealType, w, p, q> base_type;
	public:
	lagged_fibonacci_01() {}
	BOOST_RANDOM_DETAIL_ARITHMETIC_CONSTRUCTOR(lagged_fibonacci_01, boost::uint32_t, val)
	{ this->seed(val); }
	BOOST_RANDOM_DETAIL_SEED_SEQ_CONSTRUCTOR(lagged_fibonacci_01, SeedSeq, seq)
	{ this->seed(seq); }
	template<class It>
	lagged_fibonacci_01(It& first, It last) : base_type(first, last) {}
	};

	/// \endcond

	namespace detail {

	template<class Engine>
	struct generator_bits;

	template<class RealType, int w, unsigned int p, unsigned int q>
	struct generator_bits<lagged_fibonacci_01_engine<RealType, w, p, q> >
	{
	static std::size_t value() { return w; }
	};

	template<class RealType, int w, unsigned int p, unsigned int q>
	struct generator_bits<lagged_fibonacci_01<RealType, w, p, q> >
	{
	static std::size_t value() { return w; }
	};

	}

	#ifdef BOOST_RANDOM_DOXYGEN
	namespace detail {
	/**
	* The specializations lagged_fibonacci607 ... lagged_fibonacci44497
	* use well tested lags.
	*
	* See
	*
	* @blockquote
	* "On the Periods of Generalized Fibonacci Recurrences", Richard P. Brent
	* Computer Sciences Laboratory Australian National University, December 1992
	* @endblockquote
	*
	* The lags used here can be found in
	*
	* @blockquote
	* "Uniform random number generators for supercomputers", Richard Brent,
	* Proc. of Fifth Australian Supercomputer Conference, Melbourne,
	* Dec. 1992, pp. 704-706.
	* @endblockquote
	*/
	struct lagged_fibonacci_doc {};
	}
	#endif

	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 607, 273> lagged_fibonacci607;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 1279, 418> lagged_fibonacci1279;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 2281, 1252> lagged_fibonacci2281;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 3217, 576> lagged_fibonacci3217;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 4423, 2098> lagged_fibonacci4423;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 9689, 5502> lagged_fibonacci9689;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 19937, 9842> lagged_fibonacci19937;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 23209, 13470> lagged_fibonacci23209;
	/** @copydoc boost::random::detail::lagged_fibonacci_doc */
	typedef lagged_fibonacci_01_engine<double, 48, 44497, 21034> lagged_fibonacci44497;

	} // namespace random

	using random::lagged_fibonacci607;
	using random::lagged_fibonacci1279;
	using random::lagged_fibonacci2281;
	using random::lagged_fibonacci3217;
	using random::lagged_fibonacci4423;
	using random::lagged_fibonacci9689;
	using random::lagged_fibonacci19937;
	using random::lagged_fibonacci23209;
	using random::lagged_fibonacci44497;

	} // namespace boost

	#endif // BOOST_RANDOM_LAGGED_FIBONACCI_HPP