third_party/boost/include/boost/accumulators/statistics/median.hpp - webm/webmlive - Git at Google

 ///////////////////////////////////////////////////////////////////////////////
 // median.hpp
 //
 //  Copyright 2006 Eric Niebler, Olivier Gygi. 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)

 #ifndef BOOST_ACCUMULATORS_STATISTICS_MEDIAN_HPP_EAN_28_10_2005
 #define BOOST_ACCUMULATORS_STATISTICS_MEDIAN_HPP_EAN_28_10_2005

 #include <boost/mpl/placeholders.hpp>
 #include <boost/range/iterator_range.hpp>
 #include <boost/accumulators/framework/accumulator_base.hpp>
 #include <boost/accumulators/framework/extractor.hpp>
 #include <boost/accumulators/numeric/functional.hpp>
 #include <boost/accumulators/framework/parameters/sample.hpp>
 #include <boost/accumulators/framework/depends_on.hpp>
 #include <boost/accumulators/statistics_fwd.hpp>
 #include <boost/accumulators/statistics/count.hpp>
 #include <boost/accumulators/statistics/p_square_quantile.hpp>
 #include <boost/accumulators/statistics/density.hpp>
 #include <boost/accumulators/statistics/p_square_cumulative_distribution.hpp>

 namespace boost { namespace accumulators
 {

 namespace impl
 {
     ///////////////////////////////////////////////////////////////////////////////
     // median_impl
     //
     /**
         @brief Median estimation based on the \f$P^2\f$ quantile estimator

         The \f$P^2\f$ algorithm is invoked with a quantile probability of 0.5.
     */
     template<typename Sample>
     struct median_impl
       : accumulator_base
     {
         // for boost::result_of
         typedef typename numeric::functional::average<Sample, std::size_t>::result_type result_type;

         median_impl(dont_care) {}

         template<typename Args>
         result_type result(Args const &args) const
         {
             return p_square_quantile_for_median(args);
         }
     };
     ///////////////////////////////////////////////////////////////////////////////
     // with_density_median_impl
     //
     /**
         @brief Median estimation based on the density estimator

         The algorithm determines the bin in which the \f$0.5*cnt\f$-th sample lies, \f$cnt\f$ being
         the total number of samples. It returns the approximate horizontal position of this sample,
         based on a linear interpolation inside the bin.
     */
     template<typename Sample>
     struct with_density_median_impl
       : accumulator_base
     {
         typedef typename numeric::functional::average<Sample, std::size_t>::result_type float_type;
         typedef std::vector<std::pair<float_type, float_type> > histogram_type;
         typedef iterator_range<typename histogram_type::iterator> range_type;
         // for boost::result_of
         typedef float_type result_type;

         template<typename Args>
         with_density_median_impl(Args const &args)
           : sum(numeric::average(args[sample | Sample()], (std::size_t)1))
           , is_dirty(true)
         {
         }

         void operator ()(dont_care)
         {
             this->is_dirty = true;
         }


         template<typename Args>
         result_type result(Args const &args) const
         {
             if (this->is_dirty)
             {
                 this->is_dirty = false;

                 std::size_t cnt = count(args);
                 range_type histogram = density(args);
                 typename range_type::iterator it = histogram.begin();
                 while (this->sum < 0.5 * cnt)
                 {
                     this->sum += it->second * cnt;
                     ++it;
                 }
                 --it;
                 float_type over = numeric::average(this->sum - 0.5 * cnt, it->second * cnt);
                 this->median = it->first * over + (it + 1)->first * (1. - over);
             }

             return this->median;
         }

     private:
         mutable float_type sum;
         mutable bool is_dirty;
         mutable float_type median;
     };

     ///////////////////////////////////////////////////////////////////////////////
     // with_p_square_cumulative_distribution_median_impl
     //
     /**
         @brief Median estimation based on the \f$P^2\f$ cumulative distribution estimator

         The algorithm determines the first (leftmost) bin with a height exceeding 0.5. It
         returns the approximate horizontal position of where the cumulative distribution
         equals 0.5, based on a linear interpolation inside the bin.
     */
     template<typename Sample>
     struct with_p_square_cumulative_distribution_median_impl
       : accumulator_base
     {
         typedef typename numeric::functional::average<Sample, std::size_t>::result_type float_type;
         typedef std::vector<std::pair<float_type, float_type> > histogram_type;
         typedef iterator_range<typename histogram_type::iterator> range_type;
         // for boost::result_of
         typedef float_type result_type;

         with_p_square_cumulative_distribution_median_impl(dont_care)
           : is_dirty(true)
         {
         }

         void operator ()(dont_care)
         {
             this->is_dirty = true;
         }

         template<typename Args>
         result_type result(Args const &args) const
         {
             if (this->is_dirty)
             {
                 this->is_dirty = false;

                 range_type histogram = p_square_cumulative_distribution(args);
                 typename range_type::iterator it = histogram.begin();
                 while (it->second < 0.5)
                 {
                     ++it;
                 }
                 float_type over = numeric::average(it->second - 0.5, it->second - (it - 1)->second);
                 this->median = it->first * over + (it + 1)->first * ( 1. - over );
             }

             return this->median;
         }
     private:

         mutable bool is_dirty;
         mutable float_type median;
     };

 } // namespace impl

 ///////////////////////////////////////////////////////////////////////////////
 // tag::median
 // tag::with_densisty_median
 // tag::with_p_square_cumulative_distribution_median
 //
 namespace tag
 {
     struct median
       : depends_on<p_square_quantile_for_median>
     {
         /// INTERNAL ONLY
         ///
         typedef accumulators::impl::median_impl<mpl::_1> impl;
     };
     struct with_density_median
       : depends_on<count, density>
     {
         /// INTERNAL ONLY
         ///
         typedef accumulators::impl::with_density_median_impl<mpl::_1> impl;
     };
     struct with_p_square_cumulative_distribution_median
       : depends_on<p_square_cumulative_distribution>
     {
         /// INTERNAL ONLY
         ///
         typedef accumulators::impl::with_p_square_cumulative_distribution_median_impl<mpl::_1> impl;
     };
 }

 ///////////////////////////////////////////////////////////////////////////////
 // extract::median
 // extract::with_density_median
 // extract::with_p_square_cumulative_distribution_median
 //
 namespace extract
 {
     extractor<tag::median> const median = {};
     extractor<tag::with_density_median> const with_density_median = {};
     extractor<tag::with_p_square_cumulative_distribution_median> const with_p_square_cumulative_distribution_median = {};

     BOOST_ACCUMULATORS_IGNORE_GLOBAL(median)
     BOOST_ACCUMULATORS_IGNORE_GLOBAL(with_density_median)
     BOOST_ACCUMULATORS_IGNORE_GLOBAL(with_p_square_cumulative_distribution_median)
 }

 using extract::median;
 using extract::with_density_median;
 using extract::with_p_square_cumulative_distribution_median;

 // median(with_p_square_quantile) -> median
 template<>
 struct as_feature<tag::median(with_p_square_quantile)>
 {
     typedef tag::median type;
 };

 // median(with_density) -> with_density_median
 template<>
 struct as_feature<tag::median(with_density)>
 {
     typedef tag::with_density_median type;
 };

 // median(with_p_square_cumulative_distribution) -> with_p_square_cumulative_distribution_median
 template<>
 struct as_feature<tag::median(with_p_square_cumulative_distribution)>
 {
     typedef tag::with_p_square_cumulative_distribution_median type;
 };

 // for the purposes of feature-based dependency resolution,
 // with_density_median and with_p_square_cumulative_distribution_median
 // provide the same feature as median
 template<>
 struct feature_of<tag::with_density_median>
   : feature_of<tag::median>
 {
 };

 template<>
 struct feature_of<tag::with_p_square_cumulative_distribution_median>
   : feature_of<tag::median>
 {
 };

 // So that median can be automatically substituted with
 // weighted_median when the weight parameter is non-void.
 template<>
 struct as_weighted_feature<tag::median>
 {
     typedef tag::weighted_median type;
 };

 template<>
 struct feature_of<tag::weighted_median>
   : feature_of<tag::median>
 {
 };

 // So that with_density_median can be automatically substituted with
 // with_density_weighted_median when the weight parameter is non-void.
 template<>
 struct as_weighted_feature<tag::with_density_median>
 {
     typedef tag::with_density_weighted_median type;
 };

 template<>
 struct feature_of<tag::with_density_weighted_median>
   : feature_of<tag::with_density_median>
 {
 };

 // So that with_p_square_cumulative_distribution_median can be automatically substituted with
 // with_p_square_cumulative_distribution_weighted_median when the weight parameter is non-void.
 template<>
 struct as_weighted_feature<tag::with_p_square_cumulative_distribution_median>
 {
     typedef tag::with_p_square_cumulative_distribution_weighted_median type;
 };

 template<>
 struct feature_of<tag::with_p_square_cumulative_distribution_weighted_median>
   : feature_of<tag::with_p_square_cumulative_distribution_median>
 {
 };

 }} // namespace boost::accumulators

 #endif
	///////////////////////////////////////////////////////////////////////////////
	// median.hpp
	//
	// Copyright 2006 Eric Niebler, Olivier Gygi. 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)

	#ifndef BOOST_ACCUMULATORS_STATISTICS_MEDIAN_HPP_EAN_28_10_2005
	#define BOOST_ACCUMULATORS_STATISTICS_MEDIAN_HPP_EAN_28_10_2005

	#include <boost/mpl/placeholders.hpp>
	#include <boost/range/iterator_range.hpp>
	#include <boost/accumulators/framework/accumulator_base.hpp>
	#include <boost/accumulators/framework/extractor.hpp>
	#include <boost/accumulators/numeric/functional.hpp>
	#include <boost/accumulators/framework/parameters/sample.hpp>
	#include <boost/accumulators/framework/depends_on.hpp>
	#include <boost/accumulators/statistics_fwd.hpp>
	#include <boost/accumulators/statistics/count.hpp>
	#include <boost/accumulators/statistics/p_square_quantile.hpp>
	#include <boost/accumulators/statistics/density.hpp>
	#include <boost/accumulators/statistics/p_square_cumulative_distribution.hpp>

	namespace boost { namespace accumulators
	{

	namespace impl
	{
	///////////////////////////////////////////////////////////////////////////////
	// median_impl
	//
	/**
	@brief Median estimation based on the \f$P^2\f$ quantile estimator

	The \f$P^2\f$ algorithm is invoked with a quantile probability of 0.5.
	*/
	template<typename Sample>
	struct median_impl
	: accumulator_base
	{
	// for boost::result_of
	typedef typename numeric::functional::average<Sample, std::size_t>::result_type result_type;

	median_impl(dont_care) {}

	template<typename Args>
	result_type result(Args const &args) const
	{
	return p_square_quantile_for_median(args);
	}
	};
	///////////////////////////////////////////////////////////////////////////////
	// with_density_median_impl
	//
	/**
	@brief Median estimation based on the density estimator

	The algorithm determines the bin in which the \f$0.5*cnt\f$-th sample lies, \f$cnt\f$ being
	the total number of samples. It returns the approximate horizontal position of this sample,
	based on a linear interpolation inside the bin.
	*/
	template<typename Sample>
	struct with_density_median_impl
	: accumulator_base
	{
	typedef typename numeric::functional::average<Sample, std::size_t>::result_type float_type;
	typedef std::vector<std::pair<float_type, float_type> > histogram_type;
	typedef iterator_range<typename histogram_type::iterator> range_type;
	// for boost::result_of
	typedef float_type result_type;

	template<typename Args>
	with_density_median_impl(Args const &args)
	: sum(numeric::average(args[sample \| Sample()], (std::size_t)1))
	, is_dirty(true)
	{
	}

	void operator ()(dont_care)
	{
	this->is_dirty = true;
	}


	template<typename Args>
	result_type result(Args const &args) const
	{
	if (this->is_dirty)
	{
	this->is_dirty = false;

	std::size_t cnt = count(args);
	range_type histogram = density(args);
	typename range_type::iterator it = histogram.begin();
	while (this->sum < 0.5 * cnt)
	{
	this->sum += it->second * cnt;
	++it;
	}
	--it;
	float_type over = numeric::average(this->sum - 0.5 * cnt, it->second * cnt);
	this->median = it->first * over + (it + 1)->first * (1. - over);
	}

	return this->median;
	}

	private:
	mutable float_type sum;
	mutable bool is_dirty;
	mutable float_type median;
	};

	///////////////////////////////////////////////////////////////////////////////
	// with_p_square_cumulative_distribution_median_impl
	//
	/**
	@brief Median estimation based on the \f$P^2\f$ cumulative distribution estimator

	The algorithm determines the first (leftmost) bin with a height exceeding 0.5. It
	returns the approximate horizontal position of where the cumulative distribution
	equals 0.5, based on a linear interpolation inside the bin.
	*/
	template<typename Sample>
	struct with_p_square_cumulative_distribution_median_impl
	: accumulator_base
	{
	typedef typename numeric::functional::average<Sample, std::size_t>::result_type float_type;
	typedef std::vector<std::pair<float_type, float_type> > histogram_type;
	typedef iterator_range<typename histogram_type::iterator> range_type;
	// for boost::result_of
	typedef float_type result_type;

	with_p_square_cumulative_distribution_median_impl(dont_care)
	: is_dirty(true)
	{
	}

	void operator ()(dont_care)
	{
	this->is_dirty = true;
	}

	template<typename Args>
	result_type result(Args const &args) const
	{
	if (this->is_dirty)
	{
	this->is_dirty = false;

	range_type histogram = p_square_cumulative_distribution(args);
	typename range_type::iterator it = histogram.begin();
	while (it->second < 0.5)
	{
	++it;
	}
	float_type over = numeric::average(it->second - 0.5, it->second - (it - 1)->second);
	this->median = it->first * over + (it + 1)->first * ( 1. - over );
	}

	return this->median;
	}
	private:

	mutable bool is_dirty;
	mutable float_type median;
	};

	} // namespace impl

	///////////////////////////////////////////////////////////////////////////////
	// tag::median
	// tag::with_densisty_median
	// tag::with_p_square_cumulative_distribution_median
	//
	namespace tag
	{
	struct median
	: depends_on<p_square_quantile_for_median>
	{
	/// INTERNAL ONLY
	///
	typedef accumulators::impl::median_impl<mpl::_1> impl;
	};
	struct with_density_median
	: depends_on<count, density>
	{
	/// INTERNAL ONLY
	///
	typedef accumulators::impl::with_density_median_impl<mpl::_1> impl;
	};
	struct with_p_square_cumulative_distribution_median
	: depends_on<p_square_cumulative_distribution>
	{
	/// INTERNAL ONLY
	///
	typedef accumulators::impl::with_p_square_cumulative_distribution_median_impl<mpl::_1> impl;
	};
	}

	///////////////////////////////////////////////////////////////////////////////
	// extract::median
	// extract::with_density_median
	// extract::with_p_square_cumulative_distribution_median
	//
	namespace extract
	{
	extractor<tag::median> const median = {};
	extractor<tag::with_density_median> const with_density_median = {};
	extractor<tag::with_p_square_cumulative_distribution_median> const with_p_square_cumulative_distribution_median = {};

	BOOST_ACCUMULATORS_IGNORE_GLOBAL(median)
	BOOST_ACCUMULATORS_IGNORE_GLOBAL(with_density_median)
	BOOST_ACCUMULATORS_IGNORE_GLOBAL(with_p_square_cumulative_distribution_median)
	}

	using extract::median;
	using extract::with_density_median;
	using extract::with_p_square_cumulative_distribution_median;

	// median(with_p_square_quantile) -> median
	template<>
	struct as_feature<tag::median(with_p_square_quantile)>
	{
	typedef tag::median type;
	};

	// median(with_density) -> with_density_median
	template<>
	struct as_feature<tag::median(with_density)>
	{
	typedef tag::with_density_median type;
	};

	// median(with_p_square_cumulative_distribution) -> with_p_square_cumulative_distribution_median
	template<>
	struct as_feature<tag::median(with_p_square_cumulative_distribution)>
	{
	typedef tag::with_p_square_cumulative_distribution_median type;
	};

	// for the purposes of feature-based dependency resolution,
	// with_density_median and with_p_square_cumulative_distribution_median
	// provide the same feature as median
	template<>
	struct feature_of<tag::with_density_median>
	: feature_of<tag::median>
	{
	};

	template<>
	struct feature_of<tag::with_p_square_cumulative_distribution_median>
	: feature_of<tag::median>
	{
	};

	// So that median can be automatically substituted with
	// weighted_median when the weight parameter is non-void.
	template<>
	struct as_weighted_feature<tag::median>
	{
	typedef tag::weighted_median type;
	};

	template<>
	struct feature_of<tag::weighted_median>
	: feature_of<tag::median>
	{
	};

	// So that with_density_median can be automatically substituted with
	// with_density_weighted_median when the weight parameter is non-void.
	template<>
	struct as_weighted_feature<tag::with_density_median>
	{
	typedef tag::with_density_weighted_median type;
	};

	template<>
	struct feature_of<tag::with_density_weighted_median>
	: feature_of<tag::with_density_median>
	{
	};

	// So that with_p_square_cumulative_distribution_median can be automatically substituted with
	// with_p_square_cumulative_distribution_weighted_median when the weight parameter is non-void.
	template<>
	struct as_weighted_feature<tag::with_p_square_cumulative_distribution_median>
	{
	typedef tag::with_p_square_cumulative_distribution_weighted_median type;
	};

	template<>
	struct feature_of<tag::with_p_square_cumulative_distribution_weighted_median>
	: feature_of<tag::with_p_square_cumulative_distribution_median>
	{
	};

	}} // namespace boost::accumulators

	#endif