boost_1_45_0/libs/random/example/random_demo.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* boost random_demo.cpp profane demo
  *
  * Copyright Jens Maurer 2000
  * 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)
  *
  * $Id: random_demo.cpp 60755 2010-03-22 00:45:06Z steven_watanabe $
  *
  * A short demo program how to use the random number library.
  */

 #include <iostream>
 #include <fstream>
 #include <ctime>            // std::time

 #include <boost/random/linear_congruential.hpp>
 #include <boost/random/uniform_int.hpp>
 #include <boost/random/uniform_real.hpp>
 #include <boost/random/variate_generator.hpp>

 // Sun CC doesn't handle boost::iterator_adaptor yet
 #if !defined(__SUNPRO_CC) || (__SUNPRO_CC > 0x530)
 #include <boost/generator_iterator.hpp>
 #endif

 #ifdef BOOST_NO_STDC_NAMESPACE
 namespace std {
   using ::time;
 }
 #endif

 // This is a typedef for a random number generator.
 // Try boost::mt19937 or boost::ecuyer1988 instead of boost::minstd_rand
 typedef boost::minstd_rand base_generator_type;

 // This is a reproducible simulation experiment.  See main().
 void experiment(base_generator_type & generator)
 {
   // Define a uniform random number distribution of integer values between
   // 1 and 6 inclusive.
   typedef boost::uniform_int<> distribution_type;
   typedef boost::variate_generator<base_generator_type&, distribution_type> gen_type;
   gen_type die_gen(generator, distribution_type(1, 6));

 #if !defined(__SUNPRO_CC) || (__SUNPRO_CC > 0x530)
   // If you want to use an STL iterator interface, use iterator_adaptors.hpp.
   // Unfortunately, this doesn't work on SunCC yet.
   boost::generator_iterator<gen_type> die(&die_gen);
   for(int i = 0; i < 10; i++)
     std::cout << *die++ << " ";
   std::cout << '\n';
 #endif
 }

 int main()
 {
   // Define a random number generator and initialize it with a reproducible
   // seed.
   // (The seed is unsigned, otherwise the wrong overload may be selected
   // when using mt19937 as the base_generator_type.)
   base_generator_type generator(42u);

   std::cout << "10 samples of a uniform distribution in [0..1):\n";

   // Define a uniform random number distribution which produces "double"
   // values between 0 and 1 (0 inclusive, 1 exclusive).
   boost::uniform_real<> uni_dist(0,1);
   boost::variate_generator<base_generator_type&, boost::uniform_real<> > uni(generator, uni_dist);

   std::cout.setf(std::ios::fixed);
   // You can now retrieve random numbers from that distribution by means
   // of a STL Generator interface, i.e. calling the generator as a zero-
   // argument function.
   for(int i = 0; i < 10; i++)
     std::cout << uni() << '\n';

   /*
    * Change seed to something else.
    *
    * Caveat: std::time(0) is not a very good truly-random seed.  When
    * called in rapid succession, it could return the same values, and
    * thus the same random number sequences could ensue.  If not the same
    * values are returned, the values differ only slightly in the
    * lowest bits.  A linear congruential generator with a small factor
    * wrapped in a uniform_smallint (see experiment) will produce the same
    * values for the first few iterations.   This is because uniform_smallint
    * takes only the highest bits of the generator, and the generator itself
    * needs a few iterations to spread the initial entropy from the lowest bits
    * to the whole state.
    */
   generator.seed(static_cast<unsigned int>(std::time(0)));

   std::cout << "\nexperiment: roll a die 10 times:\n";

   // You can save a generator's state by copy construction.
   base_generator_type saved_generator = generator;

   // When calling other functions which take a generator or distribution
   // as a parameter, make sure to always call by reference (or pointer).
   // Calling by value invokes the copy constructor, which means that the
   // sequence of random numbers at the caller is disconnected from the
   // sequence at the callee.
   experiment(generator);

   std::cout << "redo the experiment to verify it:\n";
   experiment(saved_generator);

   // After that, both generators are equivalent
   assert(generator == saved_generator);

   // as a degenerate case, you can set min = max for uniform_int
   boost::uniform_int<> degen_dist(4,4);
   boost::variate_generator<base_generator_type&, boost::uniform_int<> > deg(generator, degen_dist);
   std::cout << deg() << " " << deg() << " " << deg() << std::endl;

 #ifndef BOOST_NO_OPERATORS_IN_NAMESPACE
   {
     // You can save the generator state for future use.  You can read the
     // state back in at any later time using operator>>.
     std::ofstream file("rng.saved", std::ofstream::trunc);
     file << generator;
   }
 #endif
   // Some compilers don't pay attention to std:3.6.1/5 and issue a
   // warning here if "return 0;" is omitted.
   return 0;
 }
	/* boost random_demo.cpp profane demo
	*
	* Copyright Jens Maurer 2000
	* 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)
	*
	* $Id: random_demo.cpp 60755 2010-03-22 00:45:06Z steven_watanabe $
	*
	* A short demo program how to use the random number library.
	*/

	#include <iostream>
	#include <fstream>
	#include <ctime> // std::time

	#include <boost/random/linear_congruential.hpp>
	#include <boost/random/uniform_int.hpp>
	#include <boost/random/uniform_real.hpp>
	#include <boost/random/variate_generator.hpp>

	// Sun CC doesn't handle boost::iterator_adaptor yet
	#if !defined(__SUNPRO_CC) \|\| (__SUNPRO_CC > 0x530)
	#include <boost/generator_iterator.hpp>
	#endif

	#ifdef BOOST_NO_STDC_NAMESPACE
	namespace std {
	using ::time;
	}
	#endif

	// This is a typedef for a random number generator.
	// Try boost::mt19937 or boost::ecuyer1988 instead of boost::minstd_rand
	typedef boost::minstd_rand base_generator_type;

	// This is a reproducible simulation experiment. See main().
	void experiment(base_generator_type & generator)
	{
	// Define a uniform random number distribution of integer values between
	// 1 and 6 inclusive.
	typedef boost::uniform_int<> distribution_type;
	typedef boost::variate_generator<base_generator_type&, distribution_type> gen_type;
	gen_type die_gen(generator, distribution_type(1, 6));

	#if !defined(__SUNPRO_CC) \|\| (__SUNPRO_CC > 0x530)
	// If you want to use an STL iterator interface, use iterator_adaptors.hpp.
	// Unfortunately, this doesn't work on SunCC yet.
	boost::generator_iterator<gen_type> die(&die_gen);
	for(int i = 0; i < 10; i++)
	std::cout << *die++ << " ";
	std::cout << '\n';
	#endif
	}

	int main()
	{
	// Define a random number generator and initialize it with a reproducible
	// seed.
	// (The seed is unsigned, otherwise the wrong overload may be selected
	// when using mt19937 as the base_generator_type.)
	base_generator_type generator(42u);

	std::cout << "10 samples of a uniform distribution in [0..1):\n";

	// Define a uniform random number distribution which produces "double"
	// values between 0 and 1 (0 inclusive, 1 exclusive).
	boost::uniform_real<> uni_dist(0,1);
	boost::variate_generator<base_generator_type&, boost::uniform_real<> > uni(generator, uni_dist);

	std::cout.setf(std::ios::fixed);
	// You can now retrieve random numbers from that distribution by means
	// of a STL Generator interface, i.e. calling the generator as a zero-
	// argument function.
	for(int i = 0; i < 10; i++)
	std::cout << uni() << '\n';

	/*
	* Change seed to something else.
	*
	* Caveat: std::time(0) is not a very good truly-random seed. When
	* called in rapid succession, it could return the same values, and
	* thus the same random number sequences could ensue. If not the same
	* values are returned, the values differ only slightly in the
	* lowest bits. A linear congruential generator with a small factor
	* wrapped in a uniform_smallint (see experiment) will produce the same
	* values for the first few iterations. This is because uniform_smallint
	* takes only the highest bits of the generator, and the generator itself
	* needs a few iterations to spread the initial entropy from the lowest bits
	* to the whole state.
	*/
	generator.seed(static_cast<unsigned int>(std::time(0)));

	std::cout << "\nexperiment: roll a die 10 times:\n";

	// You can save a generator's state by copy construction.
	base_generator_type saved_generator = generator;

	// When calling other functions which take a generator or distribution
	// as a parameter, make sure to always call by reference (or pointer).
	// Calling by value invokes the copy constructor, which means that the
	// sequence of random numbers at the caller is disconnected from the
	// sequence at the callee.
	experiment(generator);

	std::cout << "redo the experiment to verify it:\n";
	experiment(saved_generator);

	// After that, both generators are equivalent
	assert(generator == saved_generator);

	// as a degenerate case, you can set min = max for uniform_int
	boost::uniform_int<> degen_dist(4,4);
	boost::variate_generator<base_generator_type&, boost::uniform_int<> > deg(generator, degen_dist);
	std::cout << deg() << " " << deg() << " " << deg() << std::endl;

	#ifndef BOOST_NO_OPERATORS_IN_NAMESPACE
	{
	// You can save the generator state for future use. You can read the
	// state back in at any later time using operator>>.
	std::ofstream file("rng.saved", std::ofstream::trunc);
	file << generator;
	}
	#endif
	// Some compilers don't pay attention to std:3.6.1/5 and issue a
	// warning here if "return 0;" is omitted.
	return 0;
	}