boost/heap/detail/tree_iterator.hpp
// boost heap: node tree iterator helper classes
//
// Copyright (C) 2010 Tim Blechmann
//
// 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_HEAP_DETAIL_TREE_ITERATOR_HPP
#define BOOST_HEAP_DETAIL_TREE_ITERATOR_HPP
#include <functional>
#include <vector>
#include <boost/core/allocator_access.hpp>
#include <boost/iterator/iterator_adaptor.hpp>
#include <boost/type_traits/conditional.hpp>
#include <queue>
namespace boost {
namespace heap {
namespace detail {
template<typename type>
struct identity
{
type& operator()(type& x) const BOOST_NOEXCEPT
{ return x; }
const type& operator()(const type& x) const BOOST_NOEXCEPT
{ return x; }
};
template<typename Node>
struct dereferencer
{
template <typename Iterator>
Node * operator()(Iterator const & it)
{
return static_cast<Node *>(*it);
}
};
template<typename Node>
struct pointer_to_reference
{
template <typename Iterator>
const Node * operator()(Iterator const & it)
{
return static_cast<const Node *>(&*it);
}
};
template <typename HandleType,
typename Alloc,
typename ValueCompare
>
struct unordered_tree_iterator_storage
{
unordered_tree_iterator_storage(ValueCompare const & cmp)
{}
void push(HandleType h)
{
data_.push_back(h);
}
HandleType const & top(void)
{
return data_.back();
}
void pop(void)
{
data_.pop_back();
}
bool empty(void) const
{
return data_.empty();
}
std::vector<HandleType, typename boost::allocator_rebind<Alloc, HandleType>::type> data_;
};
template <typename ValueType,
typename HandleType,
typename Alloc,
typename ValueCompare,
typename ValueExtractor
>
struct ordered_tree_iterator_storage:
ValueExtractor
{
struct compare_values_by_handle:
ValueExtractor,
ValueCompare
{
compare_values_by_handle(ValueCompare const & cmp):
ValueCompare(cmp)
{}
bool operator()(HandleType const & lhs, HandleType const & rhs) const
{
ValueType const & lhs_value = ValueExtractor::operator()(lhs->value);
ValueType const & rhs_value = ValueExtractor::operator()(rhs->value);
return ValueCompare::operator()(lhs_value, rhs_value);
}
};
ordered_tree_iterator_storage(ValueCompare const & cmp):
data_(compare_values_by_handle(cmp))
{}
void push(HandleType h)
{
data_.push(h);
}
void pop(void)
{
data_.pop();
}
HandleType const & top(void)
{
return data_.top();
}
bool empty(void) const BOOST_NOEXCEPT
{
return data_.empty();
}
std::priority_queue<HandleType,
std::vector<HandleType, typename boost::allocator_rebind<Alloc, HandleType>::type>,
compare_values_by_handle> data_;
};
/* tree iterator helper class
*
* Requirements:
* Node provides child_iterator
* ValueExtractor can convert Node->value to ValueType
*
* */
template <typename Node,
typename ValueType,
typename Alloc = std::allocator<Node>,
typename ValueExtractor = identity<typename Node::value_type>,
typename PointerExtractor = dereferencer<Node>,
bool check_null_pointer = false,
bool ordered_iterator = false,
typename ValueCompare = std::less<ValueType>
>
class tree_iterator:
public boost::iterator_adaptor<tree_iterator<Node,
ValueType,
Alloc,
ValueExtractor,
PointerExtractor,
check_null_pointer,
ordered_iterator,
ValueCompare
>,
const Node *,
ValueType,
boost::forward_traversal_tag
>,
ValueExtractor,
PointerExtractor
{
typedef boost::iterator_adaptor<tree_iterator<Node,
ValueType,
Alloc,
ValueExtractor,
PointerExtractor,
check_null_pointer,
ordered_iterator,
ValueCompare
>,
const Node *,
ValueType,
boost::forward_traversal_tag
> adaptor_type;
friend class boost::iterator_core_access;
typedef typename boost::conditional< ordered_iterator,
ordered_tree_iterator_storage<ValueType, const Node*, Alloc, ValueCompare, ValueExtractor>,
unordered_tree_iterator_storage<const Node*, Alloc, ValueCompare>
>::type
unvisited_node_container;
public:
tree_iterator(void):
adaptor_type(0), unvisited_nodes(ValueCompare())
{}
tree_iterator(ValueCompare const & cmp):
adaptor_type(0), unvisited_nodes(cmp)
{}
tree_iterator(const Node * it, ValueCompare const & cmp):
adaptor_type(it), unvisited_nodes(cmp)
{
if (it)
discover_nodes(it);
}
/* fills the iterator from a list of possible top nodes */
template <typename NodePointerIterator>
tree_iterator(NodePointerIterator begin, NodePointerIterator end, const Node * top_node, ValueCompare const & cmp):
adaptor_type(0), unvisited_nodes(cmp)
{
BOOST_STATIC_ASSERT(ordered_iterator);
if (begin == end)
return;
adaptor_type::base_reference() = top_node;
discover_nodes(top_node);
for (NodePointerIterator it = begin; it != end; ++it) {
const Node * current_node = static_cast<const Node*>(&*it);
if (current_node != top_node)
unvisited_nodes.push(current_node);
}
}
bool operator!=(tree_iterator const & rhs) const
{
return adaptor_type::base() != rhs.base();
}
bool operator==(tree_iterator const & rhs) const
{
return !operator!=(rhs);
}
const Node * get_node() const
{
return adaptor_type::base_reference();
}
private:
void increment(void)
{
if (unvisited_nodes.empty())
adaptor_type::base_reference() = 0;
else {
const Node * next = unvisited_nodes.top();
unvisited_nodes.pop();
discover_nodes(next);
adaptor_type::base_reference() = next;
}
}
ValueType const & dereference() const
{
return ValueExtractor::operator()(adaptor_type::base_reference()->value);
}
void discover_nodes(const Node * n)
{
for (typename Node::const_child_iterator it = n->children.begin(); it != n->children.end(); ++it) {
const Node * n = PointerExtractor::operator()(it);
if (check_null_pointer && n == NULL)
continue;
unvisited_nodes.push(n);
}
}
unvisited_node_container unvisited_nodes;
};
template <typename Node, typename NodeList>
struct list_iterator_converter
{
typename NodeList::const_iterator operator()(const Node * node)
{
return NodeList::s_iterator_to(*node);
}
Node * operator()(typename NodeList::const_iterator it)
{
return const_cast<Node*>(static_cast<const Node*>(&*it));
}
};
template <typename Node,
typename NodeIterator,
typename ValueType,
typename ValueExtractor = identity<typename Node::value_type>,
typename IteratorCoverter = identity<NodeIterator>
>
class recursive_tree_iterator:
public boost::iterator_adaptor<recursive_tree_iterator<Node,
NodeIterator,
ValueType,
ValueExtractor,
IteratorCoverter
>,
NodeIterator,
ValueType const,
boost::bidirectional_traversal_tag>,
ValueExtractor, IteratorCoverter
{
typedef boost::iterator_adaptor<recursive_tree_iterator<Node,
NodeIterator,
ValueType,
ValueExtractor,
IteratorCoverter
>,
NodeIterator,
ValueType const,
boost::bidirectional_traversal_tag> adaptor_type;
friend class boost::iterator_core_access;
public:
recursive_tree_iterator(void):
adaptor_type(0)
{}
explicit recursive_tree_iterator(NodeIterator const & it):
adaptor_type(it)
{}
void increment(void)
{
NodeIterator next = adaptor_type::base_reference();
const Node * n = get_node(next);
if (n->children.empty()) {
const Node * parent = get_node(next)->get_parent();
++next;
while (true) {
if (parent == NULL || next != parent->children.end())
break;
next = IteratorCoverter::operator()(parent);
parent = get_node(next)->get_parent();
++next;
}
} else
next = n->children.begin();
adaptor_type::base_reference() = next;
return;
}
ValueType const & dereference() const
{
return ValueExtractor::operator()(get_node(adaptor_type::base_reference())->value);
}
static const Node * get_node(NodeIterator const & it)
{
return static_cast<const Node *>(&*it);
}
const Node * get_node() const
{
return get_node(adaptor_type::base_reference());
}
};
} /* namespace detail */
} /* namespace heap */
} /* namespace boost */
#endif /* BOOST_HEAP_DETAIL_TREE_ITERATOR_HPP */