boost/graph/detail/array_binary_tree.hpp
//
//=======================================================================
// Copyright 1997, 1998, 1999, 2000 University of Notre Dame.
// Authors: Andrew Lumsdaine, Lie-Quan Lee, Jeremy G. Siek
//
// 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_ARRAY_BINARY_TREE_HPP
#define BOOST_ARRAY_BINARY_TREE_HPP
#include <iterator>
#include <functional>
#include <boost/config.hpp>
#include <boost/iterator.hpp>
namespace boost {
/*
* Note: array_binary_tree is a completey balanced binary tree.
*/
#if !defined BOOST_NO_STD_ITERATOR_TRAITS
template <class RandomAccessIterator, class ID>
#else
template <class RandomAccessIterator, class ValueType, class ID>
#endif
class array_binary_tree_node {
public:
typedef array_binary_tree_node ArrayBinaryTreeNode;
typedef RandomAccessIterator rep_iterator;
#if !defined BOOST_NO_STD_ITERATOR_TRAITS
typedef typename std::iterator_traits<RandomAccessIterator>::difference_type
difference_type;
typedef typename std::iterator_traits<RandomAccessIterator>::value_type
value_type;
#else
typedef int difference_type;
typedef ValueType value_type;
#endif
typedef difference_type size_type;
struct children_type {
struct iterator
: boost::iterator<std::bidirectional_iterator_tag, ArrayBinaryTreeNode,
difference_type, array_binary_tree_node*, ArrayBinaryTreeNode&>
{ // replace with iterator_adaptor implementation -JGS
inline iterator() : i(0), n(0) { }
inline iterator(const iterator& x) : r(x.r), i(x.i), n(x.n), id(x.id) { }
inline iterator& operator=(const iterator& x) {
r = x.r; i = x.i; n = x.n;
/*egcs generate a warning*/
id = x.id;
return *this;
}
inline iterator(rep_iterator rr,
size_type ii,
size_type nn,
const ID& _id) : r(rr), i(ii), n(nn), id(_id) { }
inline array_binary_tree_node operator*() {
return ArrayBinaryTreeNode(r, i, n, id); }
inline iterator& operator++() { ++i; return *this; }
inline iterator operator++(int)
{ iterator t = *this; ++(*this); return t; }
inline iterator& operator--() { --i; return *this; }
inline iterator operator--(int)
{ iterator t = *this; --(*this); return t; }
inline bool operator==(const iterator& x) const { return i == x.i; }
inline bool operator!=(const iterator& x) const
{ return !(*this == x); }
rep_iterator r;
size_type i;
size_type n;
ID id;
};
inline children_type() : i(0), n(0) { }
inline children_type(const children_type& x)
: r(x.r), i(x.i), n(x.n), id(x.id) { }
inline children_type& operator=(const children_type& x) {
r = x.r; i = x.i; n = x.n;
/*egcs generate a warning*/
id = x.id;
return *this;
}
inline children_type(rep_iterator rr,
size_type ii,
size_type nn,
const ID& _id) : r(rr), i(ii), n(nn), id(_id) { }
inline iterator begin() { return iterator(r, 2 * i + 1, n, id); }
inline iterator end() { return iterator(r, 2 * i + 1 + size(), n, id); }
inline size_type size() const {
size_type c = 2 * i + 1;
size_type s;
if (c + 1 < n) s = 2;
else if (c < n) s = 1;
else s = 0;
return s;
}
rep_iterator r;
size_type i;
size_type n;
ID id;
};
inline array_binary_tree_node() : i(0), n(0) { }
inline array_binary_tree_node(const array_binary_tree_node& x)
: r(x.r), i(x.i), n(x.n), id(x.id) { }
inline ArrayBinaryTreeNode& operator=(const ArrayBinaryTreeNode& x) {
r = x.r;
i = x.i;
n = x.n;
/*egcs generate a warning*/
id = x.id;
return *this;
}
inline array_binary_tree_node(rep_iterator start,
rep_iterator end,
rep_iterator pos, const ID& _id)
: r(start), i(pos - start), n(end - start), id(_id) { }
inline array_binary_tree_node(rep_iterator rr,
size_type ii,
size_type nn, const ID& _id)
: r(rr), i(ii), n(nn), id(_id) { }
inline value_type& value() { return *(r + i); }
inline const value_type& value() const { return *(r + i); }
inline ArrayBinaryTreeNode parent() const {
return ArrayBinaryTreeNode(r, (i - 1) / 2, n, id);
}
inline bool has_parent() const { return i != 0; }
inline children_type children() { return children_type(r, i, n, id); }
/*
inline void swap(array_binary_tree_node x) {
value_type tmp = x.value();
x.value() = value();
value() = tmp;
i = x.i;
}
*/
template <class ExternalData>
inline void swap(ArrayBinaryTreeNode x, ExternalData& edata ) {
using boost::get;
value_type tmp = x.value();
/*swap external data*/
edata[ get(id, tmp) ] = i;
edata[ get(id, value()) ] = x.i;
x.value() = value();
value() = tmp;
i = x.i;
}
inline const children_type children() const {
return children_type(r, i, n);
}
inline size_type index() const { return i; }
rep_iterator r;
size_type i;
size_type n;
ID id;
};
template <class RandomAccessContainer,
class Compare = std::less<typename RandomAccessContainer::value_type> >
struct compare_array_node {
typedef typename RandomAccessContainer::value_type value_type;
compare_array_node(const Compare& x) : comp(x) {}
compare_array_node(const compare_array_node& x) : comp(x.comp) {}
template< class node_type >
inline bool operator()(const node_type& x, const node_type& y) {
return comp(x.value(), y.value());
}
template< class node_type >
inline bool operator()(const node_type& x, const node_type& y) const {
return comp(x.value(), y.value());
}
Compare comp;
};
} // namespace boost
#endif /* BOOST_ARRAY_BINARY_TREE_HPP */