boost/boost/unordered/detail/util.hpp - nest-cam/4320010/boost - Git at Google


 // Copyright (C) 2003-2004 Jeremy B. Maitin-Shepard.
 // Copyright (C) 2005-2011 Daniel James
 // 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_UNORDERED_DETAIL_UTIL_HPP_INCLUDED
 #define BOOST_UNORDERED_DETAIL_UTIL_HPP_INCLUDED

 #include <boost/config.hpp>
 #if defined(BOOST_HAS_PRAGMA_ONCE)
 #pragma once
 #endif

 #include <boost/type_traits/is_convertible.hpp>
 #include <boost/type_traits/is_empty.hpp>
 #include <boost/iterator/iterator_categories.hpp>
 #include <boost/utility/enable_if.hpp>
 #include <boost/detail/select_type.hpp>
 #include <boost/move/move.hpp>
 #include <boost/preprocessor/seq/size.hpp>
 #include <boost/preprocessor/seq/enum.hpp>
 #include <boost/swap.hpp>

 namespace boost { namespace unordered { namespace detail {

     static const float minimum_max_load_factor = 1e-3f;
     static const std::size_t default_bucket_count = 11;
     struct move_tag {};
     struct empty_emplace {};

     namespace func {
         template <class T>
         inline void ignore_unused_variable_warning(T const&) {}
     }

     ////////////////////////////////////////////////////////////////////////////
     // iterator SFINAE

     template <typename I>
     struct is_forward :
         boost::is_convertible<
             typename boost::iterator_traversal<I>::type,
             boost::forward_traversal_tag>
     {};

     template <typename I, typename ReturnType>
     struct enable_if_forward :
         boost::enable_if_c<
             boost::unordered::detail::is_forward<I>::value,
             ReturnType>
     {};

     template <typename I, typename ReturnType>
     struct disable_if_forward :
         boost::disable_if_c<
             boost::unordered::detail::is_forward<I>::value,
             ReturnType>
     {};

     ////////////////////////////////////////////////////////////////////////////
     // primes

 #define BOOST_UNORDERED_PRIMES \
     (17ul)(29ul)(37ul)(53ul)(67ul)(79ul) \
     (97ul)(131ul)(193ul)(257ul)(389ul)(521ul)(769ul) \
     (1031ul)(1543ul)(2053ul)(3079ul)(6151ul)(12289ul)(24593ul) \
     (49157ul)(98317ul)(196613ul)(393241ul)(786433ul) \
     (1572869ul)(3145739ul)(6291469ul)(12582917ul)(25165843ul) \
     (50331653ul)(100663319ul)(201326611ul)(402653189ul)(805306457ul) \
     (1610612741ul)(3221225473ul)(4294967291ul)

     template<class T> struct prime_list_template
     {
         static std::size_t const value[];

 #if !defined(SUNPRO_CC)
         static std::ptrdiff_t const length;
 #else
         static std::ptrdiff_t const length
             = BOOST_PP_SEQ_SIZE(BOOST_UNORDERED_PRIMES);
 #endif
     };

     template<class T>
     std::size_t const prime_list_template<T>::value[] = {
         BOOST_PP_SEQ_ENUM(BOOST_UNORDERED_PRIMES)
     };

 #if !defined(SUNPRO_CC)
     template<class T>
     std::ptrdiff_t const prime_list_template<T>::length
         = BOOST_PP_SEQ_SIZE(BOOST_UNORDERED_PRIMES);
 #endif

 #undef BOOST_UNORDERED_PRIMES

     typedef prime_list_template<std::size_t> prime_list;

     // no throw
     inline std::size_t next_prime(std::size_t num) {
         std::size_t const* const prime_list_begin = prime_list::value;
         std::size_t const* const prime_list_end = prime_list_begin +
             prime_list::length;
         std::size_t const* bound =
             std::lower_bound(prime_list_begin, prime_list_end, num);
         if(bound == prime_list_end)
             bound--;
         return *bound;
     }

     // no throw
     inline std::size_t prev_prime(std::size_t num) {
         std::size_t const* const prime_list_begin = prime_list::value;
         std::size_t const* const prime_list_end = prime_list_begin +
             prime_list::length;
         std::size_t const* bound =
             std::upper_bound(prime_list_begin,prime_list_end, num);
         if(bound != prime_list_begin)
             bound--;
         return *bound;
     }

     ////////////////////////////////////////////////////////////////////////////
     // insert_size/initial_size

 #if !defined(BOOST_NO_STD_DISTANCE)

     using ::std::distance;

 #else

     template <class ForwardIterator>
     inline std::size_t distance(ForwardIterator i, ForwardIterator j) {
         std::size_t x;
         std::distance(i, j, x);
         return x;
     }

 #endif

     template <class I>
     inline typename
         boost::unordered::detail::enable_if_forward<I, std::size_t>::type
         insert_size(I i, I j)
     {
         return std::distance(i, j);
     }

     template <class I>
     inline typename
         boost::unordered::detail::disable_if_forward<I, std::size_t>::type
         insert_size(I, I)
     {
         return 1;
     }

     template <class I>
     inline std::size_t initial_size(I i, I j,
         std::size_t num_buckets =
             boost::unordered::detail::default_bucket_count)
     {
         // TODO: Why +1?
         return (std::max)(
             boost::unordered::detail::insert_size(i, j) + 1,
             num_buckets);
     }

     ////////////////////////////////////////////////////////////////////////////
     // compressed

     template <typename T, int Index>
     struct compressed_base : private T
     {
         compressed_base(T const& x) : T(x) {}
         compressed_base(T& x, move_tag) : T(boost::move(x)) {}

         T& get() { return *this; }
         T const& get() const { return *this; }
     };

     template <typename T, int Index>
     struct uncompressed_base
     {
         uncompressed_base(T const& x) : value_(x) {}
         uncompressed_base(T& x, move_tag) : value_(boost::move(x)) {}

         T& get() { return value_; }
         T const& get() const { return value_; }
     private:
         T value_;
     };

     template <typename T, int Index>
     struct generate_base
       : boost::detail::if_true<
             boost::is_empty<T>::value
         >:: BOOST_NESTED_TEMPLATE then<
             boost::unordered::detail::compressed_base<T, Index>,
             boost::unordered::detail::uncompressed_base<T, Index>
         >
     {};

     template <typename T1, typename T2>
     struct compressed
       : private boost::unordered::detail::generate_base<T1, 1>::type,
         private boost::unordered::detail::generate_base<T2, 2>::type
     {
         typedef typename generate_base<T1, 1>::type base1;
         typedef typename generate_base<T2, 2>::type base2;

         typedef T1 first_type;
         typedef T2 second_type;

         first_type& first() {
             return static_cast<base1*>(this)->get();
         }

         first_type const& first() const {
             return static_cast<base1 const*>(this)->get();
         }

         second_type& second() {
             return static_cast<base2*>(this)->get();
         }

         second_type const& second() const {
             return static_cast<base2 const*>(this)->get();
         }

         template <typename First, typename Second>
         compressed(First const& x1, Second const& x2)
             : base1(x1), base2(x2) {}

         compressed(compressed const& x)
             : base1(x.first()), base2(x.second()) {}

         compressed(compressed& x, move_tag m)
             : base1(x.first(), m), base2(x.second(), m) {}

         void assign(compressed const& x)
         {
             first() = x.first();
             second() = x.second();
         }

         void move_assign(compressed& x)
         {
             first() = boost::move(x.first());
             second() = boost::move(x.second());
         }

         void swap(compressed& x)
         {
             boost::swap(first(), x.first());
             boost::swap(second(), x.second());
         }

     private:
         // Prevent assignment just to make use of assign or
         // move_assign explicit.
         compressed& operator=(compressed const&);
     };
 }}}

 #endif

	// Copyright (C) 2003-2004 Jeremy B. Maitin-Shepard.
	// Copyright (C) 2005-2011 Daniel James
	// 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_UNORDERED_DETAIL_UTIL_HPP_INCLUDED
	#define BOOST_UNORDERED_DETAIL_UTIL_HPP_INCLUDED

	#include <boost/config.hpp>
	#if defined(BOOST_HAS_PRAGMA_ONCE)
	#pragma once
	#endif

	#include <boost/type_traits/is_convertible.hpp>
	#include <boost/type_traits/is_empty.hpp>
	#include <boost/iterator/iterator_categories.hpp>
	#include <boost/utility/enable_if.hpp>
	#include <boost/detail/select_type.hpp>
	#include <boost/move/move.hpp>
	#include <boost/preprocessor/seq/size.hpp>
	#include <boost/preprocessor/seq/enum.hpp>
	#include <boost/swap.hpp>

	namespace boost { namespace unordered { namespace detail {

	static const float minimum_max_load_factor = 1e-3f;
	static const std::size_t default_bucket_count = 11;
	struct move_tag {};
	struct empty_emplace {};

	namespace func {
	template <class T>
	inline void ignore_unused_variable_warning(T const&) {}
	}

	////////////////////////////////////////////////////////////////////////////
	// iterator SFINAE

	template <typename I>
	struct is_forward :
	boost::is_convertible<
	typename boost::iterator_traversal<I>::type,
	boost::forward_traversal_tag>
	{};

	template <typename I, typename ReturnType>
	struct enable_if_forward :
	boost::enable_if_c<
	boost::unordered::detail::is_forward<I>::value,
	ReturnType>
	{};

	template <typename I, typename ReturnType>
	struct disable_if_forward :
	boost::disable_if_c<
	boost::unordered::detail::is_forward<I>::value,
	ReturnType>
	{};

	////////////////////////////////////////////////////////////////////////////
	// primes

	#define BOOST_UNORDERED_PRIMES \
	(17ul)(29ul)(37ul)(53ul)(67ul)(79ul) \
	(97ul)(131ul)(193ul)(257ul)(389ul)(521ul)(769ul) \
	(1031ul)(1543ul)(2053ul)(3079ul)(6151ul)(12289ul)(24593ul) \
	(49157ul)(98317ul)(196613ul)(393241ul)(786433ul) \
	(1572869ul)(3145739ul)(6291469ul)(12582917ul)(25165843ul) \
	(50331653ul)(100663319ul)(201326611ul)(402653189ul)(805306457ul) \
	(1610612741ul)(3221225473ul)(4294967291ul)

	template<class T> struct prime_list_template
	{
	static std::size_t const value[];

	#if !defined(SUNPRO_CC)
	static std::ptrdiff_t const length;
	#else
	static std::ptrdiff_t const length
	= BOOST_PP_SEQ_SIZE(BOOST_UNORDERED_PRIMES);
	#endif
	};

	template<class T>
	std::size_t const prime_list_template<T>::value[] = {
	BOOST_PP_SEQ_ENUM(BOOST_UNORDERED_PRIMES)
	};

	#if !defined(SUNPRO_CC)
	template<class T>
	std::ptrdiff_t const prime_list_template<T>::length
	= BOOST_PP_SEQ_SIZE(BOOST_UNORDERED_PRIMES);
	#endif

	#undef BOOST_UNORDERED_PRIMES

	typedef prime_list_template<std::size_t> prime_list;

	// no throw
	inline std::size_t next_prime(std::size_t num) {
	std::size_t const* const prime_list_begin = prime_list::value;
	std::size_t const* const prime_list_end = prime_list_begin +
	prime_list::length;
	std::size_t const* bound =
	std::lower_bound(prime_list_begin, prime_list_end, num);
	if(bound == prime_list_end)
	bound--;
	return *bound;
	}

	// no throw
	inline std::size_t prev_prime(std::size_t num) {
	std::size_t const* const prime_list_begin = prime_list::value;
	std::size_t const* const prime_list_end = prime_list_begin +
	prime_list::length;
	std::size_t const* bound =
	std::upper_bound(prime_list_begin,prime_list_end, num);
	if(bound != prime_list_begin)
	bound--;
	return *bound;
	}

	////////////////////////////////////////////////////////////////////////////
	// insert_size/initial_size

	#if !defined(BOOST_NO_STD_DISTANCE)

	using ::std::distance;

	#else

	template <class ForwardIterator>
	inline std::size_t distance(ForwardIterator i, ForwardIterator j) {
	std::size_t x;
	std::distance(i, j, x);
	return x;
	}

	#endif

	template <class I>
	inline typename
	boost::unordered::detail::enable_if_forward<I, std::size_t>::type
	insert_size(I i, I j)
	{
	return std::distance(i, j);
	}

	template <class I>
	inline typename
	boost::unordered::detail::disable_if_forward<I, std::size_t>::type
	insert_size(I, I)
	{
	return 1;
	}

	template <class I>
	inline std::size_t initial_size(I i, I j,
	std::size_t num_buckets =
	boost::unordered::detail::default_bucket_count)
	{
	// TODO: Why +1?
	return (std::max)(
	boost::unordered::detail::insert_size(i, j) + 1,
	num_buckets);
	}

	////////////////////////////////////////////////////////////////////////////
	// compressed

	template <typename T, int Index>
	struct compressed_base : private T
	{
	compressed_base(T const& x) : T(x) {}
	compressed_base(T& x, move_tag) : T(boost::move(x)) {}

	T& get() { return *this; }
	T const& get() const { return *this; }
	};

	template <typename T, int Index>
	struct uncompressed_base
	{
	uncompressed_base(T const& x) : value_(x) {}
	uncompressed_base(T& x, move_tag) : value_(boost::move(x)) {}

	T& get() { return value_; }
	T const& get() const { return value_; }
	private:
	T value_;
	};

	template <typename T, int Index>
	struct generate_base
	: boost::detail::if_true<
	boost::is_empty<T>::value
	>:: BOOST_NESTED_TEMPLATE then<
	boost::unordered::detail::compressed_base<T, Index>,
	boost::unordered::detail::uncompressed_base<T, Index>
	>
	{};

	template <typename T1, typename T2>
	struct compressed
	: private boost::unordered::detail::generate_base<T1, 1>::type,
	private boost::unordered::detail::generate_base<T2, 2>::type
	{
	typedef typename generate_base<T1, 1>::type base1;
	typedef typename generate_base<T2, 2>::type base2;

	typedef T1 first_type;
	typedef T2 second_type;

	first_type& first() {
	return static_cast<base1*>(this)->get();
	}

	first_type const& first() const {
	return static_cast<base1 const*>(this)->get();
	}

	second_type& second() {
	return static_cast<base2*>(this)->get();
	}

	second_type const& second() const {
	return static_cast<base2 const*>(this)->get();
	}

	template <typename First, typename Second>
	compressed(First const& x1, Second const& x2)
	: base1(x1), base2(x2) {}

	compressed(compressed const& x)
	: base1(x.first()), base2(x.second()) {}

	compressed(compressed& x, move_tag m)
	: base1(x.first(), m), base2(x.second(), m) {}

	void assign(compressed const& x)
	{
	first() = x.first();
	second() = x.second();
	}

	void move_assign(compressed& x)
	{
	first() = boost::move(x.first());
	second() = boost::move(x.second());
	}

	void swap(compressed& x)
	{
	boost::swap(first(), x.first());
	boost::swap(second(), x.second());
	}

	private:
	// Prevent assignment just to make use of assign or
	// move_assign explicit.
	compressed& operator=(compressed const&);
	};
	}}}

	#endif