This commit was manufactured by cvs2svn to create branch 'named-args'.

[SVN r9294]
2001-02-20 16:01:02 +00:00
10 changed files with 0 additions and 1405 deletions
--- a/development/boost/iterator_concepts.hpp
+++ b/development/boost/iterator_concepts.hpp
@ -1,282 +0,0 @@
 #ifndef BOOST_ITERATOR_CONCEPTS_HPP
 #define BOOST_ITERATOR_CONCEPTS_HPP
 #include <boost/concept_check.hpp>
 #include <boost/iterator_traits.hpp>
 namespace boost_concepts {
  // Used a different namespace here (instead of "boost") so that the
  // concept descriptions do not take for granted the names in
  // namespace boost.
  //===========================================================================
  template <typename Iterator>
  class ReadableIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::return_category 
      return_category;
    void constraints() {
      boost::function_requires< boost::SGIAssignableConcept<Iterator> >();
      boost::function_requires< boost::EqualityComparableConcept<Iterator> >();
      boost::function_requires< boost::DefaultConstructibleConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<return_category, boost::readable_iterator_tag> >();
      reference r = *i; // or perhaps read(x)
      value_type v(r);
      boost::ignore_unused_variable_warning(v);
    }
    Iterator i;
  };
  template <typename Iterator, typename ValueType>
  class WritableIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::return_category 
      return_category;
    void constraints() {
      boost::function_requires< boost::SGIAssignableConcept<Iterator> >();
      boost::function_requires< boost::EqualityComparableConcept<Iterator> >();
      boost::function_requires< boost::DefaultConstructibleConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<return_category, boost::writable_iterator_tag> >();
      *i = v; // an alternative could be something like write(x, v)
    }
    ValueType v;
    Iterator i;
  };
  template <typename Iterator>
  class ConstantLvalueIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::return_category 
      return_category;
    void constraints() {
      boost::function_requires< ReadableIteratorConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<return_category, 
          boost::constant_lvalue_iterator_tag> >();
      typedef typename boost::require_same<reference, const value_type&>::type req;
      reference v = *i;
      boost::ignore_unused_variable_warning(v);
    }
    Iterator i;
  };
  template <typename Iterator>
  class MutableLvalueIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::return_category 
      return_category;
    void constraints() {
      boost::function_requires< ReadableIteratorConcept<Iterator> >();
      boost::function_requires< WritableIteratorConcept<Iterator, value_type> >();
      boost::function_requires< 
        boost::ConvertibleConcept<return_category, 
          boost::constant_lvalue_iterator_tag> >();
      typedef typename boost::require_same<reference, value_type&>::type req;
      reference v = *i;
      boost::ignore_unused_variable_warning(v);
    }
    Iterator i;
  };
  //===========================================================================
  template <typename Iterator>
  class SinglePassIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::motion_category 
      motion_category;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< boost::SGIAssignableConcept<Iterator> >();
      boost::function_requires< boost::EqualityComparableConcept<Iterator> >();
      boost::function_requires< boost::DefaultConstructibleConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<motion_category, 
          boost::single_pass_iterator_tag> >();
      // difference_type must be a signed integral type
      ++i;
      (void)i++;
    }
    Iterator i;
  };
  template <typename Iterator>
  class ForwardIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::motion_category 
      motion_category;
    void constraints() {
      boost::function_requires< SinglePassIteratorConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<motion_category, 
          boost::forward_iterator_tag> >();
    }
  };
  template <typename Iterator>
  class BidirectionalIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::motion_category 
      motion_category;
    void constraints() {
      boost::function_requires< ForwardIteratorConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<motion_category, 
          boost::bidirectional_iterator_tag> >();
      --i;
      (void)i--;
    }
    Iterator i;
  };
  template <typename Iterator>
  class RandomAccessIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::motion_category 
      motion_category;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< BidirectionalIteratorConcept<Iterator> >();
      boost::function_requires< 
        boost::ConvertibleConcept<motion_category, 
          boost::random_access_iterator_tag> >();
      i += n;
      i = i + n;
      i = n + i;
      i -= n;
      i = i - n;
      n = i - j;
    }
    difference_type n;
    Iterator i, j;
  };
  //===========================================================================
  template <typename Iterator>
  class ReadableRandomAccessIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< RandomAccessIteratorConcept<Iterator> >();
      boost::function_requires< ReadableIteratorConcept<Iterator> >();
      reference r = i[n];
      value_type v(r);
      boost::ignore_unused_variable_warning(v);
    }
    difference_type n;
    Iterator i;
  };
  template <typename Iterator>
  class WritableRandomAccessIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< RandomAccessIteratorConcept<Iterator> >();
      boost::function_requires< WritableIteratorConcept<Iterator, value_type> >();
      i[n] = v;
      boost::ignore_unused_variable_warning(v);
    }
    difference_type n;
    value_type v;
    Iterator i;
  };
  template <typename Iterator>
  class ConstantLvalueRandomAccessIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< RandomAccessIteratorConcept<Iterator> >();
      boost::function_requires< ReadableIteratorConcept<Iterator> >();
      typedef typename boost::require_same<reference, const value_type&>::type req;
      reference v = i[n];
      boost::ignore_unused_variable_warning(v);
    }
    difference_type n;
    value_type v;
    Iterator i;
  };
  template <typename Iterator>
  class MutableLvalueRandomAccessIteratorConcept {
  public:
    typedef typename boost::iterator_traits<Iterator>::value_type value_type;
    typedef typename boost::iterator_traits<Iterator>::reference reference;
    typedef typename boost::iterator_traits<Iterator>::difference_type
      difference_type;
    void constraints() {
      boost::function_requires< RandomAccessIteratorConcept<Iterator> >();
      boost::function_requires< WritableIteratorConcept<Iterator, value_type> >();
      boost::function_requires< ReadableIteratorConcept<Iterator> >();
      typedef typename boost::require_same<reference, value_type&>::type req;
      reference v = i[n];
      boost::ignore_unused_variable_warning(v);
    }
    difference_type n;
    value_type v;
    Iterator i;
  };
 } // namespace boost_concepts
 #endif // BOOST_ITERATOR_CONCEPTS_HPP
--- a/development/boost/iterator_traits.hpp
+++ b/development/boost/iterator_traits.hpp
@ -1,60 +0,0 @@
 #ifndef BOOST_ITERATOR_TRAITS_HPP
 #define BOOST_ITERATOR_TRAITS_HPP
 #include <boost/config.hpp>
 #include <boost/type_traits.hpp>
 namespace boost {
  template <typename Iterator>
  struct iterator_traits {
    typedef typename Iterator::value_type value_type;
    typedef typename Iterator::reference reference;
    typedef typename Iterator::pointer pointer;
    typedef typename Iterator::difference_type difference_type;
    typedef typename Iterator::return_category return_category;
    typedef typename Iterator::motion_category motion_category;
  };
  // Motion Categories
  struct single_pass_iterator_tag { };
  struct forward_iterator_tag : public single_pass_iterator_tag { };
  struct bidirectional_iterator_tag : public forward_iterator_tag { };
  struct random_access_iterator_tag : public bidirectional_iterator_tag { };
  // Return Type Categories
  struct readable_iterator_tag { };
  struct writable_iterator_tag { };
  struct mutable_lvalue_iterator_tag : virtual public writable_iterator_tag,
    virtual public readable_iterator_tag { };
  struct constant_lvalue_iterator_tag : public readable_iterator_tag { };
 #if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION)
  namespace detail {
    template <bool IsConst>
    struct pointer_return_category {
      typedef constant_lvalue_iterator_tag type;
    };
    template <>
    struct pointer_return_category<false> {
      typedef mutable_lvalue_iterator_tag type;
    };
  } // namespace detail
  template <typename T>
  struct iterator_traits<T*> {
    typedef T value_type;
    typedef T& reference;
    typedef T* pointer;
    typedef std::ptrdiff_t difference_type;
    typedef typename detail::pointer_return_category<is_const<T>::value>::type
      return_category;
    typedef random_access_iterator_tag motion_category;
  };
 #endif
 } // namespace boost
 #endif // BOOST_ITERATOR_TRAITS_HPP
--- a/development/libs/iterator/concept_tests.cpp
+++ b/development/libs/iterator/concept_tests.cpp
@ -1,13 +0,0 @@
 #include <boost/iterator_concepts.hpp>
 int
 main()
 {
  boost::function_requires< 
    boost_concepts::MutableLvalueRandomAccessIteratorConcept<int*> >();
  boost::function_requires< 
    boost_concepts::ConstantLvalueRandomAccessIteratorConcept<const int*> >();
  return 0;
 }
--- a/include/boost/counting_iterator.hpp
+++ b/include/boost/counting_iterator.hpp
@ -1,215 +0,0 @@
 // (C) Copyright David Abrahams and Jeremy Siek 2000-2001. Permission to copy,
 // use, modify, sell and distribute this software is granted provided this
 // copyright notice appears in all copies. This software is provided "as is"
 // without express or implied warranty, and with no claim as to its suitability
 // for any purpose.
 //
 // See http://www.boost.org for most recent version including documentation.
 //
 // Supplies:
 //
 //   template <class Incrementable> class counting_iterator_traits;
 //   template <class Incrementable> class counting_iterator_policies;
 //
 //     Iterator traits and policies for adapted iterators whose dereferenced
 //     value progresses through consecutive values of Incrementable when the
 //     iterator is derferenced.
 //
 //   template <class Incrementable> struct counting_iterator_generator;
 //
 //     A "type generator" whose nested type "type" is a counting iterator as
 //     described above.
 //
 //   template <class Incrementable>
 //     typename counting_iterator_generator<Incrementable>::type
 //     make_counting_iterator(Incrementable);
 //
 //     A function which produces an adapted counting iterator over values of
 //     Incrementable.
 // 
 // Revision History
 // 14 Feb 2001  Removed unnecessary typedefs from counting_iterator_traits
 //              (Jeremy Siek)
 // 11 Feb 2001  Use BOOST_STATIC_CONSTANT (Dave Abrahams)
 // 11 Feb 2001  Clean up after John Maddocks's (finally effective!) Borland
 //              fixes (David Abrahams).
 // 10 Feb 2001  Use new iterator_adaptor<> interface (David Abrahams)
 // 10 Feb 2001  Rolled in supposed Borland fixes from John Maddock, but not
 //              seeing any improvement yet (David Abrahams)
 // 09 Feb 2001  Factored out is_numeric computation. Borland still
 //              unhappy :( (David Abrahams)
 // 08 Feb 2001  Beginning of a failed attempt to appease Borland
 //              (David Abrahams)
 // 07 Feb 2001  rename counting_iterator() -> make_counting_iterator()
 //              (David Abrahams)        
 // 04 Feb 2001  Added counting_iterator_generator; updated comments
 //              (David Abrahams)
 // 24 Jan 2001  initial revision, based on Jeremy Siek's
 //              boost/pending/integer_range.hpp (David Abrahams)
 #ifndef BOOST_COUNTING_ITERATOR_HPP_DWA20000119
 # define BOOST_COUNTING_ITERATOR_HPP_DWA20000119
 # include <boost/config.hpp>
 # include <boost/detail/iterator.hpp>
 # include <boost/iterator_adaptors.hpp>
 # include <boost/type_traits.hpp>
 # include <boost/detail/numeric_traits.hpp>
 # include <boost/static_assert.hpp>
 # ifndef BOOST_NO_LIMITS
 #  include <limits>
 # endif
 namespace boost {
 namespace detail {
  // Template class counting_iterator_traits_select -- choose an
  // iterator_category and difference_type for a counting_iterator at
  // compile-time based on whether or not it wraps an integer or an iterator,
  // using "poor man's partial specialization".
  template <bool is_integer> struct counting_iterator_traits_select;
  // Incrementable is an iterator type
  template <>
  struct counting_iterator_traits_select<false>
  {
      template <class Incrementable>
      struct traits
      {
       private:
          typedef boost::detail::iterator_traits<Incrementable> x;
       public:
          typedef typename x::iterator_category iterator_category;
          typedef typename x::difference_type difference_type;
      };
  };
  // Incrementable is a numeric type
  template <>
  struct counting_iterator_traits_select<true>
  {
      template <class Incrementable>
      struct traits
      {
          typedef typename
            boost::detail::numeric_traits<Incrementable>::difference_type
          difference_type;
          typedef std::random_access_iterator_tag iterator_category;
      };
  };
  // Template class distance_policy_select -- choose a policy for computing the
  // distance between counting_iterators at compile-time based on whether or not
  // the iterator wraps an integer or an iterator, using "poor man's partial
  // specialization".
  template <bool is_integer> struct distance_policy_select;
  // A policy for wrapped iterators
  template <>
  struct distance_policy_select<false>
  {
      template <class Distance, class Incrementable>
      struct policy {
          static Distance distance(Incrementable x, Incrementable y)
              { return boost::detail::distance(x, y); }
      };
  };
  // A policy for wrapped numbers
  template <>
  struct distance_policy_select<true>
  {
      template <class Distance, class Incrementable>
      struct policy {
          static Distance distance(Incrementable x, Incrementable y)
              { return numeric_distance(x, y); }
      };
  };
  // Try to detect numeric types at compile time in ways compatible with the
  // limitations of the compiler and library.
  template <class T>
  struct is_numeric {
    // For a while, this wasn't true, but we rely on it below. This is a regression assert.
    BOOST_STATIC_ASSERT(::boost::is_integral<char>::value);
 # ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS
    BOOST_STATIC_CONSTANT(bool, value = std::numeric_limits<T>::is_specialized);
 # else
 #  if !defined(__BORLANDC__)
    BOOST_STATIC_CONSTANT(bool, value = (
        boost::is_convertible<int,T>::value && boost::is_convertible<T,int>::value));
 #  else
    BOOST_STATIC_CONSTANT(bool, value = ::boost::is_arithmetic<T>::value);
 #  endif
 # endif
  };
  // Compute the distance over arbitrary numeric and/or iterator types
  template <class Distance, class Incrementable>
  Distance any_distance(Incrementable start, Incrementable finish, Distance* = 0)
  {
      return distance_policy_select<(
          is_numeric<Incrementable>::value)>::template
          policy<Distance, Incrementable>::distance(start, finish);
  }
 } // namespace detail
 template <class Incrementable>
 struct counting_iterator_traits {
 private:
    typedef ::boost::detail::counting_iterator_traits_select<(
        ::boost::detail::is_numeric<Incrementable>::value
        )> binder;
    typedef typename binder::template traits<Incrementable> traits;
 public:
    typedef typename traits::difference_type difference_type;
    typedef typename traits::iterator_category iterator_category;
 };
 template <class Incrementable>
 struct counting_iterator_policies : public default_iterator_policies
 {
    const Incrementable& dereference(type<const Incrementable&>, const Incrementable& i) const
        { return i; }
    template <class Difference, class Iterator1, class Iterator2>
    Difference distance(type<Difference>, const Iterator1& x,
                        const Iterator2& y) const
    {
        return boost::detail::any_distance<Difference>(x, y);//,(Difference*)());
    }
 };
 // A type generator for counting iterators
 template <class Incrementable>
 struct counting_iterator_generator
 {
    typedef counting_iterator_traits<Incrementable> traits;
    typedef iterator_adaptor<Incrementable,
        counting_iterator_policies<Incrementable>,
        Incrementable,
        const Incrementable&,
        const Incrementable*,
        typename traits::iterator_category,
        typename traits::difference_type
    > type;
 };
 // Manufacture a counting iterator for an arbitrary incrementable type
 template <class Incrementable>
 inline typename counting_iterator_generator<Incrementable>::type
 make_counting_iterator(Incrementable x)
 {
  typedef typename counting_iterator_generator<Incrementable>::type result_t;
  return result_t(x);
 }
 } // namespace boost
 #endif // BOOST_COUNTING_ITERATOR_HPP_DWA20000119
--- a/include/boost/half_open_range.hpp
+++ b/include/boost/half_open_range.hpp
@ -1,426 +0,0 @@
 // (C) Copyright Jeremy Siek and David Abrahams 2000-2001. Permission to copy,
 // use, modify, sell and distribute this software is granted provided this
 // copyright notice appears in all copies. This software is provided "as is"
 // without express or implied warranty, and with no claim as to its suitability
 // for any purpose.
 //
 // Revision History:
 // 11 Feb 2001  Use new iterator_adaptor interface, Fixes for Borland.
 //              (Dave Abrahams)
 // 04 Feb 2001  Support for user-defined iterator categories (Dave Abrahams)
 // 30 Jan 2001  Initial Checkin (Dave Abrahams)
 #ifndef BOOST_HALF_OPEN_RANGE_HPP_
 # define BOOST_HALF_OPEN_RANGE_HPP_
 # include <boost/counting_iterator.hpp>
 # include <functional>
 # include <cassert>
 # include <boost/operators.hpp>
 # include <string>
 # include <stdexcept>
 # include <iterator>
 namespace boost {
 namespace detail {
  // Template class choose_finish -- allows us to maintain the invariant that
  // start() <= finish() on half_open_range specializations that support random
  // access.
 #ifdef __MWERKS__
  template <class T>
  const T& choose_finish(const T&, const T& finish, std::input_iterator_tag)
  {
      return finish;
  }
  template <class T>
  const T& choose_finish(const T&, const T& finish, std::output_iterator_tag)
  {
      return finish;
  }
  template <class T>
  const T& choose_finish(const T& start, const T& finish, std::random_access_iterator_tag)
  {
      return finish < start ? start : finish;
  }
 #else
  template <bool is_random_access> struct finish_chooser;
  template <>
  struct finish_chooser<false>
  {
      template <class T>
      struct rebind
      {
          static T choose(const T&, const T& finish)
              { return finish; }
      };
  };
  template <>
  struct finish_chooser<true>
  {
      template <class T>
      struct rebind
      {
          static T choose(const T& start, const T& finish)
              { return finish < start ? start : finish; }
      };
  };
  template <class Category, class Incrementable>
  struct choose_finish
  {
      static const Incrementable choose(const Incrementable& start, const Incrementable& finish)
      {
          return finish_chooser<(
              ::boost::is_convertible<Category*,std::random_access_iterator_tag*>::value
              )>::template rebind<Incrementable>::choose(start, finish);
      }
  };
 #endif
 }
 template <class Incrementable>
 struct half_open_range
 {
    typedef typename counting_iterator_generator<Incrementable>::type iterator;
 private: // utility type definitions
    // Using iter_t prevents compiler confusion with boost::iterator
    typedef typename counting_iterator_generator<Incrementable>::type iter_t;
    typedef std::less<Incrementable> less_value;
    typedef typename iter_t::iterator_category category;
    typedef half_open_range<Incrementable> self;
 public:
    typedef iter_t const_iterator;
    typedef typename counting_iterator_traits<Incrementable>::value_type value_type;
    typedef typename counting_iterator_traits<Incrementable>::difference_type difference_type;
    typedef typename counting_iterator_traits<Incrementable>::reference reference;
    typedef typename counting_iterator_traits<Incrementable>::reference const_reference;
    typedef typename counting_iterator_traits<Incrementable>::pointer pointer;
    typedef typename counting_iterator_traits<Incrementable>::pointer const_pointer;
    // It would be nice to select an unsigned type, but this is appropriate
    // since the library makes an attempt to select a difference_type which can
    // hold the difference between any two iterators.
    typedef typename counting_iterator_traits<Incrementable>::difference_type size_type;
    half_open_range(Incrementable start, Incrementable finish)
        : m_start(start),
          m_finish(
 #ifndef __MWERKS__
            detail::choose_finish<category,Incrementable>::choose(start, finish)
 #else
            detail::choose_finish(start, finish, category())
 #endif
              )
        {}
    // Implicit conversion from std::pair<Incrementable,Incrementable> allows us
    // to accept the results of std::equal_range(), for example.
    half_open_range(const std::pair<Incrementable,Incrementable>& x)
        : m_start(x.first),
          m_finish(
 #ifndef __MWERKS__
              detail::choose_finish<category,Incrementable>::choose(x.first, x.second)
 #else
            detail::choose_finish(x.first, x.second, category())
 #endif
              )
        {}
    half_open_range& operator=(const self& x)
    {
        m_start = x.m_start;
        m_finish = x.m_finish;
        return *this;
    }
    half_open_range& operator=(const std::pair<Incrementable,Incrementable>& x)
    {
        m_start = x.first;
        m_finish =
 #ifndef __MWERKS__
            detail::choose_finish<category,Incrementable>::choose(x.first, x.second);
 #else
            detail::choose_finish(x.first, x.second, category();
 #endif
    }
    iterator begin() const { return iterator(m_start); }
    iterator end() const { return iterator(m_finish); }
    Incrementable front() const { assert(!this->empty()); return m_start; }
    Incrementable back() const { assert(!this->empty()); return boost::prior(m_finish); }
    Incrementable start() const { return m_start; }
    Incrementable finish() const { return m_finish; }
    size_type size() const { return boost::detail::distance(begin(), end()); }
    bool empty() const
    {
        return m_finish == m_start;
    }
    void swap(half_open_range& x) {
        std::swap(m_start, x.m_start);
        std::swap(m_finish, x.m_finish);
    }
 public: // functions requiring random access elements
    // REQUIRES: x is reachable from this->front()
    bool contains(const value_type& x) const
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        return !less_value()(x, m_start) && less_value()(x, m_finish);
    }
    bool contains(const half_open_range& x) const
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        return x.empty() || !less_value()(x.m_start, m_start) && !less_value()(m_finish, x.m_finish);
    }
    bool intersects(const half_open_range& x) const
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        return less_value()(
            less_value()(this->m_start, x.m_start) ? x.m_start : this->m_start,
            less_value()(this->m_finish, x.m_finish) ? this->m_finish : x.m_finish);
    }
    half_open_range& operator&=(const half_open_range& x)
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        if (less_value()(this->m_start, x.m_start))
            this->m_start = x.m_start;
        if (less_value()(x.m_finish, this->m_finish))
            this->m_finish = x.m_finish;
        if (less_value()(this->m_finish, this->m_start))
            this->m_start = this->m_finish;
        return *this;
    }
    half_open_range& operator|=(const half_open_range& x)
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        if (!x.empty())
        {
            if (this->empty())
            {
                *this = x;
            }
            else
            {
                if (less_value()(x.m_start, this->m_start))
                    this->m_start = x.m_start;
                if (less_value()(this->m_finish, x.m_finish))
                    this->m_finish = x.m_finish;
            }
        }
        return *this;
    }
    // REQUIRES: x is reachable from this->front()
    const_iterator find(const value_type& x) const
    {
        BOOST_STATIC_ASSERT((boost::is_same<category, std::random_access_iterator_tag>::value));
        return const_iterator(this->contains(x) ? x : m_finish);
    }
    // REQUIRES: index >= 0 && index < size()
    value_type operator[](size_type index) const
    {
        assert(index >= 0 && index < size());
        return m_start + index;
    }
    value_type at(size_type index) const
    {
        if (index < 0 || index >= size())
            throw std::out_of_range(std::string("half_open_range"));
        return m_start + index;
    }
 private: // data members
    Incrementable m_start, m_finish;
 };
 template <class Incrementable>
 half_open_range<Incrementable> operator|(
    half_open_range<Incrementable> x,
    const half_open_range<Incrementable>& y)
 {
    return x |= y;
 }
 template <class Incrementable>
 half_open_range<Incrementable> operator&(
    half_open_range<Incrementable> x,
    const half_open_range<Incrementable>& y)
 {
    return x &= y;
 }
 template <class Incrementable>
 inline bool operator==(
    const half_open_range<Incrementable>& x,
    const half_open_range<Incrementable>& y)
 {
    const bool y_empty = y.empty();
    return x.empty() ? y_empty : !y_empty && x.start() == y.start() && x.finish() == y.finish();
 }
 template <class Incrementable>
 inline bool operator!=(
    const half_open_range<Incrementable>& x,
    const half_open_range<Incrementable>& y)
 {
    return !(x == y);
 }
 template <class Incrementable>
 inline half_open_range<Incrementable>
 make_half_open_range(Incrementable first, Incrementable last)
 {
  return half_open_range<Incrementable>(first, last);
 }
 template <class Incrementable>
 bool intersects(
    const half_open_range<Incrementable>& x,
    const half_open_range<Incrementable>& y)
 {
    return x.intersects(y);
 }
 template <class Incrementable>
 bool contains(
    const half_open_range<Incrementable>& x,
    const half_open_range<Incrementable>& y)
 {
    return x.contains(y);
 }
 } // namespace boost
 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
 namespace std {
 template <class Incrementable> struct less<boost::half_open_range<Incrementable> >
        : binary_function<
            boost::half_open_range<Incrementable>,
            boost::half_open_range<Incrementable>,bool>
 {
    bool operator()(
        const boost::half_open_range<Incrementable>& x,
        const boost::half_open_range<Incrementable>& y) const
    {
        less<Incrementable> cmp;
        return !y.empty() && (
            cmp(x.start(), y.start())
            || !cmp(y.start(), x.start())
               && cmp(x.finish(), y.finish()));
    }
 };
 template <class Incrementable> struct less_equal<boost::half_open_range<Incrementable> >
        : binary_function<
            boost::half_open_range<Incrementable>,
            boost::half_open_range<Incrementable>,bool>
 {
    bool operator()(
        const boost::half_open_range<Incrementable>& x,
        const boost::half_open_range<Incrementable>& y) const
    {
        typedef boost::half_open_range<Incrementable> range;
        less<range> cmp;
        return !cmp(y,x);
    }
 };
 template <class Incrementable> struct greater<boost::half_open_range<Incrementable> >
        : binary_function<
            boost::half_open_range<Incrementable>,
            boost::half_open_range<Incrementable>,bool>
 {
    bool operator()(
        const boost::half_open_range<Incrementable>& x,
        const boost::half_open_range<Incrementable>& y) const
    {
        typedef boost::half_open_range<Incrementable> range;
        less<range> cmp;
        return cmp(y,x);
    }
 };
 template <class Incrementable> struct greater_equal<boost::half_open_range<Incrementable> >
        : binary_function<
            boost::half_open_range<Incrementable>,
            boost::half_open_range<Incrementable>,bool>
 {
    bool operator()(
        const boost::half_open_range<Incrementable>& x,
        const boost::half_open_range<Incrementable>& y) const
    {
        typedef boost::half_open_range<Incrementable> range;
        less<range> cmp;
        return !cmp(x,y);
    }
 };
 } // namespace std
 #else
 namespace boost {
 // Can't partially specialize std::less et al, so we must provide the operators
 template <class Incrementable>
 bool operator<(const half_open_range<Incrementable>& x,
               const half_open_range<Incrementable>& y)
 {
    return !y.empty() && (
        x.empty() || std::less<Incrementable>()(x.start(), y.start())
        || !std::less<Incrementable>()(y.start(), x.start())
                && std::less<Incrementable>()(x.finish(), y.finish()));
 }
 template <class Incrementable>
 bool operator>(const half_open_range<Incrementable>& x,
               const half_open_range<Incrementable>& y)
 {
    return y < x;
 }
 template <class Incrementable>
 bool operator<=(const half_open_range<Incrementable>& x,
               const half_open_range<Incrementable>& y)
 {
    return !(y < x);
 }
 template <class Incrementable>
 bool operator>=(const half_open_range<Incrementable>& x,
               const half_open_range<Incrementable>& y)
 {
    return !(x < y);
 }
 } // namespace boost
 #endif
 #endif // BOOST_HALF_OPEN_RANGE_HPP_
--- a/include/boost/iterator.hpp
+++ b/include/boost/iterator.hpp
@ -1,60 +0,0 @@
 //  interator.hpp workarounds for non-conforming standard libraries  ---------//
 //  (C) Copyright Boost.org 2000. Permission to copy, use, modify, sell and
 //  distribute this software is granted provided this copyright notice appears
 //  in all copies. This software is provided "as is" without express or implied
 //  warranty, and with no claim as to its suitability for any purpose.
 //  See http://www.boost.org for most recent version including documentation.
 //  Revision History
 //  12 Jan 01 added <cstddef> for std::ptrdiff_t (Jens Maurer)
 //  28 Jun 00 Workarounds to deal with known MSVC bugs (David Abrahams)
 //  26 Jun 00 Initial version (Jeremy Siek)
 #ifndef BOOST_ITERATOR_HPP
 #define BOOST_ITERATOR_HPP
 #include <iterator>
 #include <cstddef>           // std::ptrdiff_t
 #include <boost/config.hpp>
 namespace boost
 {
 # ifdef BOOST_NO_STD_ITERATOR
  template <class Category, class T,
    class Distance = std::ptrdiff_t,
    class Pointer = T*, class Reference = T&>
  struct iterator
  {
    typedef T         value_type;
    typedef Distance  difference_type;
    typedef Pointer   pointer;
    typedef Reference reference;
    typedef Category  iterator_category;
  };
 # else
  // declare iterator_base in namespace detail to work around MSVC bugs which
  // prevent derivation from an identically-named class in a different namespace.
  namespace detail {
   template <class Category, class T, class Distance, class Pointer, class Reference>
 #  if !defined(BOOST_MSVC_STD_ITERATOR)
   struct iterator_base : std::iterator<Category, T, Distance, Pointer, Reference> {};
 #  else
   struct iterator_base : std::iterator<Category, T, Distance>
   {
     typedef Reference reference;
     typedef Pointer pointer;
     typedef Distance difference_type;
   };
 #  endif
  }
  template <class Category, class T, class Distance = std::ptrdiff_t,
            class Pointer = T*, class Reference = T&>
   struct iterator : detail::iterator_base<Category, T, Distance, Pointer, Reference> {};
 # endif
 } // namespace boost
 #endif // BOOST_ITERATOR_HPP
--- a/include/boost/pending/detail/int_iterator.hpp
+++ b/include/boost/pending/detail/int_iterator.hpp
@ -1,75 +0,0 @@
 //  (C) Copyright Jeremy Siek 1999. Permission to copy, use, modify,
 //  sell and distribute this software is granted provided this
 //  copyright notice appears in all copies. This software is provided
 //  "as is" without express or implied warranty, and with no claim as
 //  to its suitability for any purpose.
 #ifndef BOOST_INT_ITERATOR_H
 #define BOOST_INT_ITERATOR_H
 #include <boost/iterator.hpp>
 #if !defined BOOST_MSVC
 #include <boost/operators.hpp>
 #endif
 #include <iostream>
 //using namespace std;
 #ifndef BOOST_NO_OPERATORS_IN_NAMESPACE
 namespace boost {
 #endif
 // this should use random_access_iterator_helper but I've had
 // VC++ portablility problems with that. -JGS
 template <class IntT>
 class int_iterator
 {
  typedef int_iterator self;
 public:
  typedef std::random_access_iterator_tag iterator_category;
  typedef IntT value_type;
  typedef IntT& reference;
  typedef IntT* pointer;
  typedef std::ptrdiff_t difference_type;
  inline int_iterator() : _i(0) { }
  inline int_iterator(IntT i) : _i(i) { }
  inline int_iterator(const self& x) : _i(x._i) { }
  inline self& operator=(const self& x) { _i = x._i; return *this; }
  inline IntT operator*() { return _i; }
  inline IntT operator[](IntT n) { return _i + n; }
  inline self& operator++() { ++_i; return *this; }
  inline self operator++(int) { self t = *this; ++_i; return t; }
  inline self& operator+=(IntT n) { _i += n; return *this; }
  inline self operator+(IntT n) { self t = *this; t += n; return t; }
  inline self& operator--() { --_i; return *this; }
  inline self operator--(int) { self t = *this; --_i; return t; }
  inline self& operator-=(IntT n) { _i -= n; return *this; }
  inline IntT operator-(const self& x) const { return _i - x._i; }
  inline bool operator==(const self& x) const { return _i == x._i; }
  // vc++ had a problem finding != in random_access_iterator_helper
  // need to look into this... for now implementing everything here -JGS
  inline bool operator!=(const self& x) const { return _i != x._i; }
  inline bool operator<(const self& x) const { return _i < x._i; }
  inline bool operator<=(const self& x) const { return _i <= x._i; }
  inline bool operator>(const self& x) const { return _i > x._i; }
  inline bool operator>=(const self& x) const { return _i >= x._i; }
 protected:
  IntT _i;
 };
 template <class IntT>
 inline int_iterator<IntT>
 operator+(IntT n, int_iterator<IntT> t) { t += n; return t; }
 #ifndef BOOST_NO_OPERATORS_IN_NAMESPACE
 } /* namespace boost */
 #endif
 #ifdef BOOST_NO_OPERATORS_IN_NAMESPACE
 namespace boost {
  using ::int_iterator;
 }
 #endif
 #endif /* BOOST_INT_ITERATOR_H */
--- a/include/boost/pending/integer_range.hpp
+++ b/include/boost/pending/integer_range.hpp
@ -1,59 +0,0 @@
 // (C) Copyright David Abrahams and Jeremy Siek 2000-2001. Permission to copy,
 // use, modify, sell and distribute this software is granted provided this
 // copyright notice appears in all copies. This software is provided "as is"
 // without express or implied warranty, and with no claim as to its suitability
 // for any purpose.
 //
 // Revision History:
 // 04 Jan 2001  Factored counting_iterator stuff into
 //              boost/counting_iterator.hpp (David Abrahams)
 #ifndef BOOST_INTEGER_RANGE_HPP_
 #define BOOST_INTEGER_RANGE_HPP_
 #include <boost/config.hpp>
 #include <boost/counting_iterator.hpp>
 namespace boost {
 //=============================================================================
 // Counting Iterator and Integer Range Class
 template <class IntegerType>
 struct integer_range {
    typedef typename counting_iterator_generator<IntegerType>::type iterator;
    typedef iterator const_iterator;
    typedef IntegerType value_type;
    typedef std::ptrdiff_t difference_type;
    typedef IntegerType reference;
    typedef IntegerType const_reference;
    typedef const IntegerType* pointer;
    typedef const IntegerType* const_pointer;
    typedef IntegerType size_type;
    integer_range(IntegerType start, IntegerType finish)
        : m_start(start), m_finish(finish) { }
    iterator begin() const { return iterator(m_start); }
    iterator end() const { return iterator(m_finish); }
    size_type size() const { return m_finish - m_start; }
    bool empty() const { return m_finish == m_start; }
    void swap(integer_range& x) {
        std::swap(m_start, x.m_start);
        std::swap(m_finish, x.m_finish);
    }
 protected:
    IntegerType m_start, m_finish;
 };
 template <class IntegerType>
 inline integer_range<IntegerType>
 make_integer_range(IntegerType first, IntegerType last)
 {
  return integer_range<IntegerType>(first, last);
 }
 } // namespace boost
 #endif // BOOST_INTEGER_RANGE_HPP_
--- a/include/boost/pending/iterator_adaptors.hpp
+++ b/include/boost/pending/iterator_adaptors.hpp
@ -1 +0,0 @@
 #include <boost/iterator_adaptors.hpp>
--- a/include/boost/pending/iterator_tests.hpp
+++ b/include/boost/pending/iterator_tests.hpp
@ -1,214 +0,0 @@
 #ifndef BOOST_ITERATOR_TESTS_HPP
 # define BOOST_ITERATOR_TESTS_HPP
 // This is meant to be the beginnings of a comprehensive, generic
 // test suite for STL concepts such as iterators and containers.
 //
 // Revision History:
 // 08 Feb 2001  Fixed bidirectional iterator test so that
 //              --i is no longer a precondition.
 //              (Jeremy Siek)
 // 04 Feb 2001  Added lvalue test, corrected preconditions
 //              (David Abrahams)
 # include <iterator>
 # include <assert.h>
 # include <boost/type_traits.hpp>
 # include <boost/static_assert.hpp>
 # include <boost/concept_archetype.hpp> // for detail::dummy_constructor
 namespace boost {
  // use this for the value type
 struct dummyT { 
  dummyT() { }
  dummyT(detail::dummy_constructor) { }
  dummyT(int x) : m_x(x) { }
  int foo() const { return m_x; } 
  bool operator==(const dummyT& d) const { return m_x == d.m_x; }
  int m_x;
 };
 // Tests whether type Iterator satisfies the requirements for a
 // TrivialIterator. 
 // Preconditions: i != j, *i == val
 template <class Iterator, class T>
 void trivial_iterator_test(const Iterator i, const Iterator j, T val)
 {
  Iterator k;
  assert(i == i);
  assert(j == j);
  assert(i != j);
 #ifdef BOOST_NO_STD_ITERATOR_TRAITS
  T v = *i;
 #else
  typename std::iterator_traits<Iterator>::value_type v = *i;
 #endif
  assert(v == val);
 #if 0
  // hmm, this will give a warning for transform_iterator...  perhaps
  // this should be separated out into a stand-alone test since there
  // are several situations where it can't be used, like for
  // integer_range::iterator.
  assert(v == i->foo());
 #endif
  k = i;
  assert(k == k);
  assert(k == i);
  assert(k != j);
  assert(*k == val);
 }
 // Preconditions: i != j
 template <class Iterator, class T>
 void mutable_trivial_iterator_test(const Iterator i, const Iterator j, T val)
 {
  *i = val;
  trivial_iterator_test(i, j, val);
 }
 // Preconditions: *i == v1, *++i == v2
 template <class Iterator, class T>
 void input_iterator_test(Iterator i, T v1, T v2) 
 {
  Iterator i1 = i, i2 = i;
  assert(i == i1++);
  assert(i != ++i2);
  trivial_iterator_test(i, i1, v1);
  trivial_iterator_test(i, i2, v1);
  ++i;
  assert(i == i1);
  assert(i == i2);
  ++i1;
  ++i2;
  trivial_iterator_test(i, i1, v2);
  trivial_iterator_test(i, i2, v2);
 }
 // how to test output iterator?
 template <bool is_pointer> struct lvalue_test
 {
    template <class Iterator> static void check(Iterator)
    {
 # ifndef BOOST_NO_STD_ITERATOR_TRAITS
        typedef typename std::iterator_traits<Iterator>::reference reference;
        typedef typename std::iterator_traits<Iterator>::value_type value_type;
 # else
        typedef typename Iterator::reference reference;
        typedef typename Iterator::value_type value_type;
 # endif
        BOOST_STATIC_ASSERT(boost::is_reference<reference>::value);
        BOOST_STATIC_ASSERT((boost::is_same<reference,value_type&>::value
                             || boost::is_same<reference,const value_type&>::value
            ));
    }
 };
 # ifdef BOOST_NO_STD_ITERATOR_TRAITS
 template <> struct lvalue_test<true> {
    template <class T> static void check(T) {}
 };
 #endif
 template <class Iterator, class T>
 void forward_iterator_test(Iterator i, T v1, T v2) 
 {
  input_iterator_test(i, v1, v2);
 // borland doesn't allow non-type template parameters
 # if !defined(__BORLANDC__) || (__BORLANDC__ > 0x551)
  lvalue_test<(boost::is_pointer<Iterator>::value)>::check(i);
 #endif
 }
 // Preconditions: *i == v1, *++i == v2
 template <class Iterator, class T>
 void bidirectional_iterator_test(Iterator i, T v1, T v2)
 {
  forward_iterator_test(i, v1, v2);
  ++i;
  Iterator i1 = i, i2 = i;
  assert(i == i1--);
  assert(i != --i2);
  trivial_iterator_test(i, i1, v2);
  trivial_iterator_test(i, i2, v2);
  --i;
  assert(i == i1);
  assert(i == i2);
  ++i1;
  ++i2;
  trivial_iterator_test(i, i1, v1);
  trivial_iterator_test(i, i2, v1);
 }
 // mutable_bidirectional_iterator_test
 // Preconditions: [i,i+N) is a valid range
 template <class Iterator, class TrueVals>
 void random_access_iterator_test(Iterator i, int N, TrueVals vals)
 {
  bidirectional_iterator_test(i, vals[0], vals[1]);
  const Iterator j = i;
  int c;
  for (c = 0; c < N-1; ++c) {
    assert(i == j + c);
    assert(*i == vals[c]);
    assert(*i == j[c]);
    assert(*i == *(j + c));
    assert(*i == *(c + j));
    ++i;
    assert(i > j);
    assert(i >= j);
    assert(j <= i);
    assert(j < i);
  }
  Iterator k = j + N - 1;
  for (c = 0; c < N-1; ++c) {
    assert(i == k - c);
    assert(*i == vals[N - 1 - c]);
    assert(*i == j[N - 1 - c]);
    Iterator q = k - c; 
    assert(*i == *q);
    assert(i > j);
    assert(i >= j);
    assert(j <= i);
    assert(j < i);
    --i;
  }
 }
 // Precondition: i != j
 template <class Iterator, class ConstIterator>
 void const_nonconst_iterator_test(Iterator i, ConstIterator j)
 {
  assert(i != j);
  assert(j != i);
  ConstIterator k(i);
  assert(k == i);
  assert(i == k);
  k = i;
  assert(k == i);
  assert(i == k);
 }
 } // namespace boost
 #endif // BOOST_ITERATOR_TESTS_HPP