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

 /* boost random/detail/const_mod.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
  *  2001-02-18  moved to individual header files
  */

 #ifndef BOOST_RANDOM_CONST_MOD_HPP
 #define BOOST_RANDOM_CONST_MOD_HPP

 #include <boost/assert.hpp>
 #include <boost/static_assert.hpp>
 #include <boost/integer_traits.hpp>
 #include <boost/type_traits/make_unsigned.hpp>
 #include <boost/random/detail/large_arithmetic.hpp>

 #include <boost/random/detail/disable_warnings.hpp>

 namespace boost {
 namespace random {

 template<class IntType, IntType m>
 class const_mod
 {
 public:
   static IntType apply(IntType x)
   {
     if(((unsigned_m() - 1) & unsigned_m()) == 0)
       return (unsigned_type(x)) & (unsigned_m() - 1);
     else {
       IntType suppress_warnings = (m == 0);
       BOOST_ASSERT(suppress_warnings == 0);
       return x % (m + suppress_warnings);
     }
   }

   static IntType add(IntType x, IntType c)
   {
     if(((unsigned_m() - 1) & unsigned_m()) == 0)
       return (unsigned_type(x) + unsigned_type(c)) & (unsigned_m() - 1);
     else if(c == 0)
       return x;
     else if(x < m - c)
       return x + c;
     else
       return x - (m - c);
   }

   static IntType mult(IntType a, IntType x)
   {
     if(((unsigned_m() - 1) & unsigned_m()) == 0)
       return unsigned_type(a) * unsigned_type(x) & (unsigned_m() - 1);
     else if(a == 0)
       return 0;
     else if(a == 1)
       return x;
     else if(m <= traits::const_max/a)      // i.e. a*m <= max
       return mult_small(a, x);
     else if(traits::is_signed && (m%a < m/a))
       return mult_schrage(a, x);
     else
       return mult_general(a, x);
   }

   static IntType mult_add(IntType a, IntType x, IntType c)
   {
     if(((unsigned_m() - 1) & unsigned_m()) == 0)
       return (unsigned_type(a) * unsigned_type(x) + unsigned_type(c)) & (unsigned_m() - 1);
     else if(a == 0)
       return c;
     else if(m <= (traits::const_max-c)/a) {  // i.e. a*m+c <= max
       IntType suppress_warnings = (m == 0);
       BOOST_ASSERT(suppress_warnings == 0);
       return (a*x+c) % (m + suppress_warnings);
     } else
       return add(mult(a, x), c);
   }

   static IntType pow(IntType a, boost::uintmax_t exponent)
   {
       IntType result = 1;
       while(exponent != 0) {
           if(exponent % 2 == 1) {
               result = mult(result, a);
           }
           a = mult(a, a);
           exponent /= 2;
       }
       return result;
   }

   static IntType invert(IntType x)
   { return x == 0 ? 0 : (m == 0? invert_euclidian0(x) : invert_euclidian(x)); }

 private:
   typedef integer_traits<IntType> traits;
   typedef typename make_unsigned<IntType>::type unsigned_type;

   const_mod();      // don't instantiate

   static IntType mult_small(IntType a, IntType x)
   {
     IntType suppress_warnings = (m == 0);
     BOOST_ASSERT(suppress_warnings == 0);
     return a*x % (m + suppress_warnings);
   }

   static IntType mult_schrage(IntType a, IntType value)
   {
     const IntType q = m / a;
     const IntType r = m % a;

     BOOST_ASSERT(r < q);        // check that overflow cannot happen

     return sub(a*(value%q), r*(value/q));
   }

   static IntType mult_general(IntType a, IntType b)
   {
     IntType suppress_warnings = (m == 0);
     BOOST_ASSERT(suppress_warnings == 0);
     IntType modulus = m + suppress_warnings;
     BOOST_ASSERT(modulus == m);
     if(::boost::uintmax_t(modulus) <=
         (::std::numeric_limits< ::boost::uintmax_t>::max)() / modulus)
     {
       return static_cast<IntType>(boost::uintmax_t(a) * b % modulus);
     } else {
       return static_cast<IntType>(detail::mulmod(a, b, modulus));
     }
   }

   static IntType sub(IntType a, IntType b)
   {
     if(a < b)
       return m - (b - a);
     else
       return a - b;
   }

   static unsigned_type unsigned_m()
   {
       if(m == 0) {
           return unsigned_type((std::numeric_limits<IntType>::max)()) + 1;
       } else {
           return unsigned_type(m);
       }
   }

   // invert c in the finite field (mod m) (m must be prime)
   static IntType invert_euclidian(IntType c)
   {
     // we are interested in the gcd factor for c, because this is our inverse
     BOOST_ASSERT(c > 0);
     IntType l1 = 0;
     IntType l2 = 1;
     IntType n = c;
     IntType p = m;
     for(;;) {
       IntType q = p / n;
       l1 += q * l2;
       p -= q * n;
       if(p == 0)
         return l2;
       IntType q2 = n / p;
       l2 += q2 * l1;
       n -= q2 * p;
       if(n == 0)
         return m - l1;
     }
   }

   // invert c in the finite field (mod m) (c must be relatively prime to m)
   static IntType invert_euclidian0(IntType c)
   {
     // we are interested in the gcd factor for c, because this is our inverse
     BOOST_ASSERT(c > 0);
     if(c == 1) return 1;
     IntType l1 = 0;
     IntType l2 = 1;
     IntType n = c;
     IntType p = m;
     IntType max = (std::numeric_limits<IntType>::max)();
     IntType q = max / n;
     BOOST_ASSERT(max % n != n - 1 && "c must be relatively prime to m.");
     l1 += q * l2;
     p = max - q * n + 1;
     for(;;) {
       if(p == 0)
         return l2;
       IntType q2 = n / p;
       l2 += q2 * l1;
       n -= q2 * p;
       if(n == 0)
         return m - l1;
       q = p / n;
       l1 += q * l2;
       p -= q * n;
     }
   }
 };

 } // namespace random
 } // namespace boost

 #include <boost/random/detail/enable_warnings.hpp>

 #endif // BOOST_RANDOM_CONST_MOD_HPP
	/* boost random/detail/const_mod.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
	* 2001-02-18 moved to individual header files
	*/

	#ifndef BOOST_RANDOM_CONST_MOD_HPP
	#define BOOST_RANDOM_CONST_MOD_HPP

	#include <boost/assert.hpp>
	#include <boost/static_assert.hpp>
	#include <boost/integer_traits.hpp>
	#include <boost/type_traits/make_unsigned.hpp>
	#include <boost/random/detail/large_arithmetic.hpp>

	#include <boost/random/detail/disable_warnings.hpp>

	namespace boost {
	namespace random {

	template<class IntType, IntType m>
	class const_mod
	{
	public:
	static IntType apply(IntType x)
	{
	if(((unsigned_m() - 1) & unsigned_m()) == 0)
	return (unsigned_type(x)) & (unsigned_m() - 1);
	else {
	IntType suppress_warnings = (m == 0);
	BOOST_ASSERT(suppress_warnings == 0);
	return x % (m + suppress_warnings);
	}
	}

	static IntType add(IntType x, IntType c)
	{
	if(((unsigned_m() - 1) & unsigned_m()) == 0)
	return (unsigned_type(x) + unsigned_type(c)) & (unsigned_m() - 1);
	else if(c == 0)
	return x;
	else if(x < m - c)
	return x + c;
	else
	return x - (m - c);
	}

	static IntType mult(IntType a, IntType x)
	{
	if(((unsigned_m() - 1) & unsigned_m()) == 0)
	return unsigned_type(a) * unsigned_type(x) & (unsigned_m() - 1);
	else if(a == 0)
	return 0;
	else if(a == 1)
	return x;
	else if(m <= traits::const_max/a) // i.e. a*m <= max
	return mult_small(a, x);
	else if(traits::is_signed && (m%a < m/a))
	return mult_schrage(a, x);
	else
	return mult_general(a, x);
	}

	static IntType mult_add(IntType a, IntType x, IntType c)
	{
	if(((unsigned_m() - 1) & unsigned_m()) == 0)
	return (unsigned_type(a) * unsigned_type(x) + unsigned_type(c)) & (unsigned_m() - 1);
	else if(a == 0)
	return c;
	else if(m <= (traits::const_max-c)/a) { // i.e. a*m+c <= max
	IntType suppress_warnings = (m == 0);
	BOOST_ASSERT(suppress_warnings == 0);
	return (a*x+c) % (m + suppress_warnings);
	} else
	return add(mult(a, x), c);
	}

	static IntType pow(IntType a, boost::uintmax_t exponent)
	{
	IntType result = 1;
	while(exponent != 0) {
	if(exponent % 2 == 1) {
	result = mult(result, a);
	}
	a = mult(a, a);
	exponent /= 2;
	}
	return result;
	}

	static IntType invert(IntType x)
	{ return x == 0 ? 0 : (m == 0? invert_euclidian0(x) : invert_euclidian(x)); }

	private:
	typedef integer_traits<IntType> traits;
	typedef typename make_unsigned<IntType>::type unsigned_type;

	const_mod(); // don't instantiate

	static IntType mult_small(IntType a, IntType x)
	{
	IntType suppress_warnings = (m == 0);
	BOOST_ASSERT(suppress_warnings == 0);
	return a*x % (m + suppress_warnings);
	}

	static IntType mult_schrage(IntType a, IntType value)
	{
	const IntType q = m / a;
	const IntType r = m % a;

	BOOST_ASSERT(r < q); // check that overflow cannot happen

	return sub(a(value%q), r(value/q));
	}

	static IntType mult_general(IntType a, IntType b)
	{
	IntType suppress_warnings = (m == 0);
	BOOST_ASSERT(suppress_warnings == 0);
	IntType modulus = m + suppress_warnings;
	BOOST_ASSERT(modulus == m);
	if(::boost::uintmax_t(modulus) <=
	(::std::numeric_limits< ::boost::uintmax_t>::max)() / modulus)
	{
	return static_cast<IntType>(boost::uintmax_t(a) * b % modulus);
	} else {
	return static_cast<IntType>(detail::mulmod(a, b, modulus));
	}
	}

	static IntType sub(IntType a, IntType b)
	{
	if(a < b)
	return m - (b - a);
	else
	return a - b;
	}

	static unsigned_type unsigned_m()
	{
	if(m == 0) {
	return unsigned_type((std::numeric_limits<IntType>::max)()) + 1;
	} else {
	return unsigned_type(m);
	}
	}

	// invert c in the finite field (mod m) (m must be prime)
	static IntType invert_euclidian(IntType c)
	{
	// we are interested in the gcd factor for c, because this is our inverse
	BOOST_ASSERT(c > 0);
	IntType l1 = 0;
	IntType l2 = 1;
	IntType n = c;
	IntType p = m;
	for(;;) {
	IntType q = p / n;
	l1 += q * l2;
	p -= q * n;
	if(p == 0)
	return l2;
	IntType q2 = n / p;
	l2 += q2 * l1;
	n -= q2 * p;
	if(n == 0)
	return m - l1;
	}
	}

	// invert c in the finite field (mod m) (c must be relatively prime to m)
	static IntType invert_euclidian0(IntType c)
	{
	// we are interested in the gcd factor for c, because this is our inverse
	BOOST_ASSERT(c > 0);
	if(c == 1) return 1;
	IntType l1 = 0;
	IntType l2 = 1;
	IntType n = c;
	IntType p = m;
	IntType max = (std::numeric_limits<IntType>::max)();
	IntType q = max / n;
	BOOST_ASSERT(max % n != n - 1 && "c must be relatively prime to m.");
	l1 += q * l2;
	p = max - q * n + 1;
	for(;;) {
	if(p == 0)
	return l2;
	IntType q2 = n / p;
	l2 += q2 * l1;
	n -= q2 * p;
	if(n == 0)
	return m - l1;
	q = p / n;
	l1 += q * l2;
	p -= q * n;
	}
	}
	};

	} // namespace random
	} // namespace boost

	#include <boost/random/detail/enable_warnings.hpp>

	#endif // BOOST_RANDOM_CONST_MOD_HPP